Home Heating Sample of the compilation of the cargo plan of the container carrier. Cheat sheet: vessel freight plan. Heavy and diesel fuel, lubricating oils

Sample of the compilation of the cargo plan of the container carrier. Cheat sheet: vessel freight plan. Heavy and diesel fuel, lubricating oils

Once upon a time I came across a table for calculations Draft Survey . All would be good, but for some reason I didn't quite suit me. The table had 3 main sheets: Survey, form and explanation. On the Survey tab, calculations were made, which were automatically copied to the Form tab, and the explanation tab showed how to make calculations, for those who forgot it. There were also 2 additional sheets: Conversion Table & Distance Table, which have a rather weak attitude to Draft Survey calculations, but they are always at the calculations at hand.

What did this table did not suit me? And the fact that all the hydrostatics had to be considered manually. Maybe someone will say that this is not so problematic, but I can not agree with that because, despite the fact that for DRAFT Survey, a certain time is distinguished, it is often missing.

Suppose that shipowner requires a report on loading (unloading) once a day, although I was both in companies that require data in the morning and in the evening. Do you really have so much time to make calculations manually? Sometimes the owner requires as a prompt response as possible. Then, how quickly you can provide the necessary information, the attitude towards you is depeted.

There are cases and more significant, for example, the following. Japan. Khachinoh. Unloading cereals to the terminal of Tohoku. After the first day of unloading due to automatic scale failure, the discrepancy between these terminal with the actual was exactly a thousand tons. Of course, immediately all on the ears. Disassembly. As a result, the missing found. Would you be able to find if it fell down at the end of the unloading? And a plane ticket with a silver wing ...

India. Mundra. In general, the port on the rogues is just classic. We load bauxes. Final Survey. Surveyor in vagliy cuts precipitation. As a result, he inflated me at 300 tons. Only I signed that he used a calculator, and I tables. Just it turned out that he was mistaken at calculations in Initial Survey. For decency, I indignant, I scream that I call the representative of P & I Club, showing quickly made calculations, where I have a slightly more, he comprehensively attributes to me 50 tons, for which the captain gives him a cigarette block. The shipper, it must be assumed, he also dismissed something for saved 250 tons. And the load with a breath of 100 tons quietly went to Japan. As a result, everything is good and all satisfied and the vessel, the owner, and the shipper, and the consignee, and the surveyor.

I think that such cases each in their own practice was a lot. I hope that now, given the above, no one will challenge the importance of rapid settlements of Draft Survey.

What did I do with the table? Just added another tab called Hydrostatic and formulas related to the Survey tab. He took the hydrostatic and completely driven from there to the new tab all the data required for the calculations. For my steamer in 48000 DWT, there was less than 900 digits, and the 1st column (precipitate) is obtained by a simple copying method, and this is minus 130 digits. In short, all the work on the preparation of tables for a specific steamer took no more than 2 hours. And all ... Next, we do not turn to this tab at all, but we use only the 1st tab of the Survey. I hope no one needs to explain how to use it. I can only say that for calculations you need to fill out only cells highlighted in green. The rest will be counted automatically.

Methods for determining the weight of the cargo on board the vessel by Draft Survea

After receiving the ship's free practice on board, the surveyor for draprot-survea arrives.

The purpose of Draft Survea is to determine the weight of the cargo on board the vessel. Measuring the draft using the ship's cargo documentation and information on the calculation of the shipped volume of the vessel using the density of the water in which the vessel is located, the surveyor can calculate the weight of the vessel. From this total, he subtracts the weight of the vessel and other weights on board the vessel, which are not weight of cargo, the difference will be the weight of the cargo (see Applied Blanks 1, 2, 3, 4). However, in practice, it is necessary to take into account that the ship is flexible and is not at rest, the information of the builders of the vessel's vessel varies. It is very difficult to accurate precipitation, find out the actual weight of the ballast.

The time for holding Draft Survea will depend on many factors: the size of the vessel, the number of ballast, the number of tanks, the state of the vessel. Ordinary practice is the presence of a surveyor from the beginning to the end of freight operations. In large courts for the production of Draft Survea, two surveyors are needed.

The accuracy of measurements at Draft Survea affects the decor on the vessel and the limited time. Minor errors will not entail tangible damage if the vessel has small dimensions. However, when transporting large batches of valuable cargo, 1% of the mass of this cargo presents a large amount of money. The surveyor must prove that he has made every effort to carry out the most accurate measurements using standard methods. The surveyor must be sure what makes, and be able to, as far as possible, prove its right.

1.0. Determining the mass of cargo by sediment of the vessel.

1.1. Removal of the sediment of the vessel.

The sediment of the vessel (T) is the depth to which the vessel body is immersed in water. To remove the precipitate values \u200b\u200bon the nose and feed perpendicular (Forstevne and Ahterstevne, respectively), grooves are applied with both sides. The grooves of the recesses are also applied with both sides in the middle (on Middle) the vessel to remove the precipitate on the Middle.

Gaining brands can be indicated by Arabic figures and are presented in the metric measurement system. (meters, centimeters - Appendix 1), as well as Arabic or Roman numbers - English measurement system (feet, inches - Appendix 2).

With a metric measurement system of precipitation The height of each digit is 10.0 cm, the distance between the vertical numbers is also 10.0 cm, the thickness of the number on the marine ships of 2.0 cm, on the river 1.5 cm. In the English sediment measurement system, each The numbers are 1/2 feet (6 inches), the distance between the vertical numbers is also 1/2 feet, the thickness of the number 1 "(inch).

The line of contact of the vessel case with water (actual waterline) in the crossbar of the grooves of the deepening in the nose part of the vessel gives the sediment of the nasal part (TN), in the middle of the vessel - the sediment on the face (TM), in the feed part - the singement of the feed part (TC).

The removal of the precipitate is made from both boards of the vessel with the highest possible accuracy of the pier and / or boats.

With the excitement of the sea, it is necessary to determine the average amount of amplitude of washing with water of each groove of the recess, which will be the actual sediment of the vessel in this place (Fig. 1.):

The actual precipitate (Fig. 1.) is: (22'07 "+ 20'06") / 2 \u003d 21'06.5 ". If it is impossible to remove the precipitate from both boards, the sediment is removed from the grooves of the deepening in the nose, on the face and in the feed part from one side.

For the obtained precipitate values, the middle sediment is calculated (Formula 1):

where T '- averaged precipitation, m;

T - sediment, removed in the nasal, stern parts and on the face, m;

In the transverse distance between the grooves of the recess of the right and left side, m;

q - Roll angle (removed from the Krenometer located on the soda bridge of the vessel) of the vessel with the highest possible accuracy with the pier, °

(1 ° roll is approximately equal to the width of the vessel).

The amendment sign is negative if the roll towards the observed side, and is positive at the opposite direction of the roll . Calculation of medium precipitation in the nasal, stern parts and on the face is made separately.

The precipitate on the face can be determined by measuring the height of the surface side from the line of the main deck to the water mirror, which is then subtracted from the height from the keel to the main deck (Fig. 2.):

Definition of precipitation on Middle


Designations to Fig. 2.:

1 - line of the main deck;

2 - Waterlinia;

3 - the height of the surface side to Waterlinia;

4 - sediment to Waterlinia;

5 - sediment to the summer truck;

6 - summer surface board;

7 (n) - height from keel to the main deck;

8 - Line of Kiel.

1. 2. Determination of the average of the average estimated precipitation, which takes into account the correction to the sediment in the nasal and forage parts of the vessel, as well as the trim and deformation of the vessel.


Measurements of precipitation in the nasal part of the vessel are recorded by the grades of the grooves deposited on the Forstevna, and not on the nasal perpendicular, which is the calculated line. As a result, an error appears that is eliminated by the introduction of amendment. (see Fig. 3., Formula 5):

Introduction Amendments to sediment in the nasal and forage parts of the vessel and the Middle



f - distance from Forstevnya to nasal perpendicular, m;

LBM \u003d LBP - (F + A) - Different - the difference in the sediment of the vessel in the nasal and feed parts, m;

LBP is the distance between the perpendiculars passing through the intersection points of the cargo waterline with the front edge of the belt and the axis of the steering wheel (the distance between the nasal and feed perpendiculars), m.

When the vessel differentials, the precipitation of the vessel's feed part are recorded on the grooves on Akhtershtevne, and not for the feed perpendicular, therefore, the same amendment must also be administered for precipitation, removed in the stern (Formula 6):


a is the distance from the grades of the deepening to the stern perpendicular, m.

Distances butand f.can be determined using a large-scale ship drawing or a longitudinal cutting of the vessel.

In most cases, there are tables or graphs of the dependence of the range of corrective amendments.

The precipitation of the nasal and vessels of the vessel, taking into account the amendments to the deviation of the stews, are calculated by formulas 7, 8:


The average sediment between the nasal and the vessel of the vessel is determined by formula 9.:


The amendment to the sediment on the face is introduced in the event that when removing the precipitation, the recess scale is shifted into the nasal or feed part of the ship from the circle of Plimsol (Formula 10):

where dIF. '- a differential defined after the introduction of amendments to the precipitation of the nasal and vessels of the vessel;

m is the distance from the circle of Plymside to the deepening brand on the Middle, m.

The amendment sign is negative when the brand of deepening is shifted into the feed and positive when the measurement of recesses in the nose from Plymsole circle.

Precipitation on the Middle Taking into account the amendments are calculated by formula 11:

Averaged precipitate is calculated by formula 12.:

The average of the average estimated sediment, which takes into account the deformation of the vessel (bending-deflection) is determined by formula 13, 14, 14 A:


1. 3. Determination of the vessel displacement.

Weight displacement - the mass of the vessel, equal to the mass of water displaced by the vessel. Since the vessel's displacement varies depending on the degree of loading, any value of precipitation (deepening the vessel body into water) corresponds to certain displacement.

Full load capacity - deadweight. - Determined as follows (Formula 15, 16):


If we take a mass of ship reserves and the mass of the "dead" cargo unchanged, the weight of the cargo will be equal to the difference between the deadweight of the vessel with the cargo (DVTG) and the deadweight of the vessel before loading / after unloading (DV0). The amount of cargo defined in this way should be clarified, taking into account changes in the mass of ship reserves during the production of freight operations.

Part ship reserves include:

  • mass of fuel and lubricating oils;
  • drinking and technical fresh water;
  • the mass of shipping stocks of provisions and supply (paints, spare parts, etc.);
  • the mass of the ship crew with a luggage at the rate of 1 ton of baggage by 12 people.

Part "Dead" cargo the mass of the non-tested ballast, the remains of water in tanks, etc.


Displacement of the vessel is determined by cargo scale (Appendix 3),which is a drawing table consisting of a row scale with divisions:

  • deadweight scale, T;
  • scale, T;
  • scale of precipitation, m and / or feet;
  • scale of the timing of a differential, TM / cm;
  • the scale of the number of tons per 1 cm precipitate shows the amount of cargo for a specific precipitate to be removed or immersed to change the sediment of the vessel by 1 cm (can be expressed in tons per inch);
  • scale size of the surface side, m and / or feet.

When using a cargo scale, it is necessary to determine the values \u200b\u200bof water displacement and the deadweight on the scale for fresh water (G \u003d 1,000) if the vessel is in fresh water, and on the sea water scale (G \u003d 1.025), if the vessel is in sea water. The value of the indicator of the number of tons per 1 cm precipitate should be removed from the cargo only in the area of \u200b\u200bthe medium precipitation found.

Displacement (D)determined before and after loading (unloading) of the vessel on the average average calculated sediment on a cargo scale, a hydrostatic table (Appendix 4) or a hydrostatic curve (Appendix 5). Typically, the displacement is indicated for sea water (r \u003d 1.025 t / m3).

1. 4. Amendments to the timeline.

Cargo hydrostatic tables or hydrostatic curves, which provide displacement with different sediments, are designed for the vessel on a level keel. The true displacement of the vessel having a differential in the feed or nasal part differs from the displacement given in the cargo or table, therefore must be applied amendments to differentiate (Formula 18, 19 - if calculations are carried out in the metric system; Formulas 20, 21 - if the calculations are carried out in the English system):


For this, you should first add 50 cm (6 inches) to the size of the precipitate and remove the value from the hydrostatic tables of the differential moment, and then the deduction of 50 cm (6 inches) from it) and according to these data, determine the value of differential moments. The difference between the differential moments will be this value.

The first amendment sign obtains algebraically (Table 1):

The sign of the second amendment is positive. The general correction to the differential is expressed by Formula 22:

Displacement adjusted for a differentiate determined according to Formula 23.:

1. 5. Amendment on the density of sea water.

In cases where the actual water density differs from the accepted (R \u003d 1.025 t / m3), it is necessary to introduce an amendment to the density measured by the area, the hydrometer, or accepted according to the port meteorological service.

Selection of seawater samples to determine the actual density must be made at a depth corresponding to about half of the sediment of the vessel and approximately in the middle of the vessel. To get more accurate data, you can take samples also near the nasal and stern parts of the vessel.

If, when determining the density of water, an aryometer (hydrometer) is used, calibrated at a temperature of 15 ° C, then the actual density is determined by the following table. 2.on the measurement density and the actual water temperature.

The correction to the density of water is determined by formula 24, 24 A:


Displacement, taking into account the correction on the density of seawater, is determined by formula 25.:

2.0. Determining the mass of ship reserves.

Before and after loading (unloading) of the vessel, it is necessary to determine the number of variable reserves that it is necessary to deduct from the displacement, as not related to useful cargo.

TO variable ship reserves relate:

  • fuel (diesel, fuel oil);
  • lubricating oil;
  • fresh water (drinking, technical);
  • ballast water.

To determine the mass of variable stocks immediately after removal of the sediment, the vessel should be checked all ship tanks.

Determination of the amount of fresh water and ballast.

On the vessel, fresh water can be kept in the galley and sanitary tanks, in the forpic and ahterpic tanks, in diplomas and bottom tanks (boiler water).

The bottom of the vessel consists of a double bottom, which contains interdonal tanks intended for the ballast. Interdonal tanks pass either along the entire width of the vessel, or divided along the vessel's axis into two symmetric tanks. Often, the interdonal tanks are separated from each other with special tanks serving to ensure the safety of the vessel in case of samples.

The water level in the tanks is measured by measuring tape (roulette)through measurement tubes. After determining the water level by calibration tablesThe vessel is determined by the amount of water in tons or cubic meters. If the amount of water is given in units of volume, it is translated into tons, multiplying the volume on the density at a temperature. Measuring the amount of water with a significant differential Different requires the introduction of an amendment to a differential in calibration tables or calculating the amendment to the differential method of calculating the "wedge" (Appendix 6).

Water on the vessel can also be in Llalah (Water collectors of ship drains) located along the sides. Before measuring the precipitation, the waste tanks must be emptied.

Determination of the amount of fuel and lubricating oils.

Fuel (diesel, fuel oil) is in bottom, consumables and tanks, as well as in diplomas. In the engine room there are small tanks of lubricating oil. Responsibility for measuring the amount of fuel and lubricating oil carries a senior mechanic who has gauge tables composed in tons either in cubic meters. These measurements and calculations of all reserves are reduced to table. 3, 3a.

3.0. The time required for holding surf surveillance.

For holding surge Survea on a small standard vessel and obtaining productive indicators, a qualified surveyor will be required about half an hour. If this is a large dimensional vessel carrying bulk goods and arrived in Ballast, it will take at least four hours to process it with the participation of at least two surveyors. The size of the majority of vessels are average, they can be put between the two examples above. Much also depends on the type of vessel and the participation of the crew.

There is a huge difference in the costs of the time and effort required for the initial, final destruction of surveillance and determining the mass of cargo. During the initial and final destruction of surveillance (before and after loading), all variables are measured - precipitation, variable ship reserves (ballast and fresh water, fuel, lubricants, etc.). It is believed that this method helps to eliminate errors that could arise when determining the mass of the vessel by generating and the mass of ship reserves, and gives a more accurate result. The measurements of ballast tanks and the removal of the precipitate are held upon arrival of the vessel in the port and at the end of the loading.

The simpler method is a survey for deadweight. It includes measurements of precipitation and variables only when the vessel is already fully loaded. It is used if the vessel constantly carries out the transportation of a certain kind of cargo on a specific route, all its variables are known and the ship permanent (constant) is accurate. This method has some other benefits in addition to saving time. Since measurements are conducted with a loaded ship, it is possible to avoid deviations arising from measurements carried out on the vessel with a large differential.

4.0. Accuracy of measurements.

An experimental surveyor operating in ideal conditions will measure with an accuracy of ± 0.1 - 0.3% on a large-sized vessel and up to ± 0.4 - 0.7% at a small vessel. If you really look at things, ideal conditions for work is almost impossible to provide. Therefore, measurements are carried out with an accuracy of 0.5% of the total weight of the cargo.

With insufficient quality devices used to remove measurements, the accuracy of measurements will vary within 1%. Errors of technology can remain unnoticed for the surveyor, and even more so for its employer who has no idea about the principle of operation of this method. Even when using the best technique, adverse weather conditions and the lack of crew help may affect the accuracy of measurements to 0.5%. Since the measurements removed represent only the initial information, inaccurate measurements entail errors in further calculations. The disagreements of the operation of the surveyor and the crew, its inconsistency will also affect the draprot of surveillance, like:

  • recalculation of the crew of the mass of ballast and fuel during surveillance;
  • blocking measurement tubes;
  • changing documents;
  • creating other obstacles to the normal operation of the surveyor.

It would seem that such minor things occurring during the removal of the precipitate, as the opening or closing of the trim, fluctuations caused by the movement of the cranes can entail a significant change in the differential and precipitate.

The only protection of the surveyor is attention to the smallest details, as well as the dexterity acquired with marine experience. A detailed study of the plans of the vessel also often reveals inaccuracies and errors, but since not every plan can accurately comply with this ship, to make some conclusions on the basis of this.

5.0. Draft.

The first step Draft Survea is the removal of the sediment. The precipitate will take off in the nasal, theft and on the face of both boards of the vessel (six values). The surveyor must be as close as possible to water to remove more accurate precipitation. When processing large-sized courts, it is necessary to use a boat to remove the seeds from the maritime. Attempting to remove the rainfall indicators of a large balker in a ballast with a ladder can lead to an error of up to 100 tons.

It is important to pay attention to the clarity of cargo grades. On some maritime ships, cargo stamps are applied by Arabic numbers (metric measurement system) on one board and Roman numerals (English measurement system - feet) on the other. In this case, at the end of the removal of the precipitate, all readings in some one system should be translated.

Make it difficult to remove water fluctuations. Special measurement tubes are used. Inside the narrow glass tube passes water and, while reaching a certain level, stops. Then the load is removed by cargo.

Another way to remove the seeds from the maritime is the measurement of the vessel roll (if available) a special device - a bentometer. Next, with the help of simple trigonometry, precipitation is calculated. However, accurate brenometers are rarity, therefore, this method is applicable only in conjunction with another for further comparison of the indicators obtained.

Report on Draft Survetu must necessarily contain a description of weather conditions during surveillance. In emergency cases, it is better to postpone the surveillance due to bad weather conditions.

The flows and shallow water also make it difficult to remove the sediment, significantly changing its meanings. If the vessel moves relative to the water, especially if there is a small clearance under a kilometer (the distance between the vessel housing and the soil), it is more immersed in water, increasing the sediment as a result of the "appetizer effect" and changing the differential. It has been experimentally established that the effect of the flow rate of up to four nodes on the change in precipitation and the differential is insignificant. If the flow rate is four nodes and more, the sediment may increase to 6 cm depending on the shape of the vessel.

The flow is a valid problem for river berths. Theoretical and practical work carried out to calculate the "appetizer effect" is insufficient. Therefore, for the surveyor there is a single choice - to rely on your professional experience.

In bright sun and low water temperature, the trends of the courts towards the enclosure of the case can be traced. The deck is expanding, and the bottom of the ship is not, which leads to the wig in the hull of the vessel. Exit such position - special adjustment methods will help avoid errors in the calculations.

6.0. Density.

The next step is the surf surveillance after removing the precipitate - measurement of the density of the water in which the ship is located. Measure the density of water is important immediately at the end of the removal of the sediment, since it may change with tide, as well as with a change in water temperature. The very concept of "density" is often incorrectly perceived - we are talking about the ratio of mass and volume.

All errors in determining the density of water are a consequence of insufficient practices and misunderstanding of relations between different densities. Typical errors are as follows:

  • incorrect taking of water samples;
  • neglect using the water temperature corrections;
  • the use of special gravity (density) in vacuum instead of using mass indicators in the air.

The optimal option for determining the density of water is to remove the samples three times at different depths in the nasal, theft and on the Middle (9 values). The number of samples may be smaller if the ship is small or if the practice proves that for this pier, the density of water is a constant value at a certain depth. Total should be taken of water samples at least than a liter. Then water is placed in a special transparent vessel for testing. This should be done immediately, while the temperature of the fence water is preserved.

There is no need to measure the temperature of the water when using a glass hydrometer. It is important to determine the values \u200b\u200bof the density of water at the time of the implementation of the Survea destruction. The use of a correction to the density measured using a hydrometer leads to distortion of the values \u200b\u200bobtained. With a change in temperature, the hull of the vessel will expand and shrink, the same changes will occur with the hydrometer - therefore it is not necessary to enter the density corrections.

The surveyor must make sure that the base of the hydrometer and the surface of the water is not contaminated with oil or lubricant. Then omit the device into water and fix the value of the intersection of the water level and the instrument scale. It is important that the eyes are opposite the device, and not at an angle. The hydrometer should be designed specifically for sea water.

The density values \u200b\u200bwill be in the range of 0.993 - 1.035 t / m3. To remove measurements, a hydrometer is needed, capable of measuring the mass in the air (obvious density), a mass in vacuo (actual density) and a special rate of gravity (relative density). Surveyor must determine the mass of cargo in the air, as this is a generally accepted commercial mass. Therefore, in the calculations, it must use the obvious density or mass of a unit of volume in the air.

Units of measure usually kg / l. If the hydrometer is designed to measure the mass in a vacuum or removal of gravity, an amendment 0.0011 Gm / ml is used to subtract it from the resulting density value to obtain the mass value in the air.

Summing up, highlight the main thing for the surveyor when determining the density of water:

  • take the right amount of samples;
  • use accurate hydrometer;
  • do not apply corrections to temperature;
  • determine the mass of a unit of volume in the air, kg / l.

7.0. Mass that need to be determined.

After the values \u200b\u200bof the precipitate and density of water are determined, the values \u200b\u200bof all masses are set, which will then be subtracted from the displacement to determine the mass of the cargo. The mass of the vessel will be determined, the number of ballast, ship reserves, as well as the importance of a ship permanent or ship constant. On a small vessel with this task one surveyor can cope. If this is a very large vessel, waiting for loading or preparing to leave for a flight, Surveyor will need an assistant. While the first will determine the values \u200b\u200bof the precipitate and the density of water, the second will be measured by the measurement of ship tanks.

The mass of the vessel will give up.

The value of the vessel's mass will be generated on faith according to the ship's information. If during the initial and final destruction of surveillance, the same erroneous value of the vessel's mass is used, it will not entail an error. If one value was used on the initial Draft Survea, and the final one, this will result in an error. When conducting a surveillance to the deadweight, any error in determining the mass of the vessel will give rise to the erroneous value of the mass of the cargo.

Ballast.

The determination of the number of ballast is the greatest amount of work. The surveyor must produce measurements of all ballast tanks and determine the number of ballast in them. To do this, it is best to use a roulette of steel with labeling water paste.

Ideally, that the vessel does not have a roll, it was on a smooth keel, but in practice it is almost impossible to achieve. The roll can be corrected by the movement of the ballast from some tanks to others. However, this operation will take a lot of time and may entail problems associated with the Ballast Pump during Survea, which will affect its accuracy. Enter the correction to roll for each ballast tank is also a time-consuming operation that will not need if the roll is small.

The ship located in the ballast always has a large differential on the stern. Some vessels are equipped with appropriate tables to adjust the differential when carrying out calculations in ballast tanks, some are not. To avoid calculating the amendments to the differential, many surveyors insist that ballast tanks are either empty or complete during surveillance. Surveyor, making sure that part of ballast tanks is filled, performs measurements of the remaining empty tanks. This procedure does not take much time, it is acceptable for small tanks of vessels that do not have too large differential.

Measurements carried out in full ballast tanks of a vessel with a large differential will be a source of errors. More accurate measurements in empty tanks will be more accurate, but the likelihood of the existence of ballast water remains in tanks is left, the amount of which cannot be determined.

Measurement of ballast tricks is a complex operation and is also a source of possible errors. Three should be empty and dry before carrying out the initial Draft Survea. If this is not possible, the surveyor must measure emptiness in different parts of the truma to obtain the correct depth value with which it enters the calibration tables.

By carrying out the necessary measurements and having received the values \u200b\u200bof the depth of water in the tanks, the surveyor with the help of calibration tables or by calculations translates these values \u200b\u200binto m. Knowing the density of water in each tank, which it also had to determine, the surveyor sets the amount of water in tanks. However, it is difficult to determine the density of water in ballast tank, and to believe the approvals of the senior assistant that Ballast was taken on board in the open sea, not enough. The error in the meaning of the density of ballast water for large vessels may entail a change in the weight of the cargo to 150 tons and more.

Thus, the surveyor must have any available way to take water samples from all or from several ballast tanks and determine its density with the same hydrometer, which he measured the density of the waters.

Summing up, allocate the main thing for the surveyor, which determines the number of ballast on board the vessel:

  • carefully read the plans of the location of ballast tanks;
  • ballast tanks are measured using a steel tape with labeling water;
  • determine the density of water in each tank;
  • calculate the volume occupied by water in each tank, applying the necessary corrections for the roll and the differential;
  • determine the amount of ballast water in each tank using the product and density product.

Fresh water.

The amount of fresh water is determined similar to the number of ballast. It is less labor-intensive work, freshwater tanks less and usually no need to determine the density of water.

Heavy and diesel fuel, lubricating oils.

If during the parking lot in the port, the ship did not take on board the fuel, the surveyor uses in the calculations of the fuel and lubricating oils specified in the fuel quality certificate (Bunker Receipt - see table. 3.). If the vessel between the initial and final Draft Survet took on board the fuel or if there is a survey for a deadweight, the surveyor should produce measurements of fuel tanks and determine the amount of fuel and lubricating oils. Calculations and adjustment on the roll and the differential are manufactured as for ballast tanks. For fuel and lubricating oils, density values \u200b\u200bare usually used at 15 ° C. For measurements of fuel tanks, it would be more expedient to use a special hydrometer for fuel, which determines the exact value of the density. However, such hydrolyters are not used, since the amount of fuel and oil is not large, and the probability of error is also very small. It must be remembered that chilled fuel or oil is very slowly moving, therefore if the differential change occurred, you can spend some time to determine the exact depth of the fluid in the tank. Measurements of emptiness in the tank in this case will give a more accurate result.

Stocks and ship constant.

Ship constant Contrary to the name is a non-permanent value. It is the difference in pure displacement and the magnitude of all variable reserves of the vessel (ballast, fresh water, fuel and lubricants, seduction water, etc.).

The constant includes the crew of ship reserves, paint, the remaining dirt in tanks, minor discrepancies in the marks of cargo grades, the inaccuracy of the mass definition of the vessel weigh.

During the initial Draft Survea held on the ship in Ballast, the surveyor determines the constant with the settlement path. For a small balker, the normal value of the constant is about 250 tons. The court of a higher construction has a constant greater than the new construction ships. The value of the constant will vary with the change on board the number of fixing materials, stocks, as well as when ice and snow appears on the deck. Due to these indefinable settlement paths, the vessel mass can email by 60 tons.

In some cases, the surveyor receives a negative constant. This is usually a sign of error. However, if after repeated measurements and calculations of the constant remained negative, this value should be used.

Negative constant may result in the following reasons:

  • Driving a cargo scale.
  • Some vessels use calibration tables for ballast tanks and the data on the vessel body developed for another vessel of the same type. The same type of vessels differ slightly from each other, but the tables are used alone.
  • On some ships, the cause of significant errors is a differential, much greater permissible. Such vessels are a kind of scourge for the Draft Surveyors. If the senior assistant cannot provide the values \u200b\u200bof the constant on previous flights if theoretically invalid result is obtained, the accuracy of the results of this Draft Survea will be dubious.

When conducting a surveillance to the Deadweight, the importance of the ship constant Surveyor either determines approximately or takes its meaning to faith according to the ship's information. Deviation of the constant from its actual value means the same deviation of the amount of cargo from its valid amount aboard.

Survy for Deadweight is often more accurate than full draphing surveys, as there is an opportunity to avoid errors of the initial draft surveillance associated with a large vessel differential. Measures are carried out on a loaded ship, all calculations are carried out as for the vessel on an even keel, which avoids many errors.

If the vessel is regularly processed, it is useful to compare the constant values \u200b\u200bfor several flights and determine the value with which the surveys was most accurate.

1. Task

2. Annotation

3. Summary

4. Description of the ship

Description of the Ship

5. Description of cargo

6. Description of the cargo

7. Requirements for cargo plan

8. Calculation of the download of the vessel

8.1 Determination of estimated displacement, deadweight

8.2 Determination of the flight time

8.2.1 Determination of the running time and the necessary reserves for the transition

8.2.2 Determination of pure lifting capacity

8.2.3 Definition of parking time and parking lots

8.2.4 Definition of stocks

8.3 Determining the moment of optimal differential

8.4 Distribution of stocks and cargo for cargo premises

8.5 Check total longitudinal strength

8.5.1 Determination of the bending moment of gravity for the Middle of the empty ship

8.5.2 Determining the bending moment from the received goods and reserves (Deadweight forces)

8.5.3 Determining the bending moment on the Middle of the Maintenance Forces

8.5.4 Determination of the bending moment

8.5.5 Definition of the permissible moment

8.6 Local Storage Check

8.7 The calculation of stability

8.8 Registration register of Russia to stability

8.9 Definition of the weather criterion

List of used literature

Middle sediment DSR ship 8.2 m

Different for feed 0.2 m

Length between perpendiculars L 140 m

Ship width in 17 m

Coefficient of total completeness of St. 0.75

Displacement estimated ΔP 12700 t

Displacement of the vessel by email Δ0 3300 t

Abscissa ts.t. vessel empty x0 7.5 m

Trucking vessel W 17900 m3

Daily fuel consumption on the go 12 t

Daily fuel consumption in the parking lot 10 t

Daily water consumption 15 t

RSNAB 40 t supply supply

The weight of the crew and baggage REC 15 t

RPR provisions 40 t

LP 3000 Miles Transport Distance

Average vessel speed VSR 12.5 node

Daily norm of work in the port of loading MSS 2000 t / day

Daily norm of work in the port of unloading M'ss 1200 t / day

Time for auxiliary operations:

in the port of loading TVSP 6 hours

in the port of unloading T'VSP 8 hours

CCT PCT 10% Storm Stock

Time delayed vessel on the way Tzad 0.3 days

Table number 1. Volumes of freight premises

Room

Volume, m3

Room

Volume, m3

TRYM number 1.

Twinek number 3.

Twinek No. 1.

TRYM number 4.

Twinek number 1 in

Twinek No. 4.

TRYM number 2.

TRYM number 5.

Twinek No. 2.

Twinek No. 5.

TRYM number 3.

Twinek number 5 in

Total ship cargo vessel

Table number 2.

The name and characteristics of goods presented for transportation

Table number 3.

Coordinates of the center of gravity stocks

Ship empty and stocks:

X g, m

Z g, m

Ship empty

Provisions

Supply

Applicate Metcenter

-

The purpose of this course project is to study the technology of transportation of goods on the specified type of vessel. In the course of the course of the course project, acquaintance with the characteristics of goods presented to transport and the type of vessel, which will transport this cargo, and also how cargo is placed and loading, according to their volume and weight characteristics and their compatibility. At the same time, it is necessary to understand how the strength of the vessel body is observed, the initial stability of the vessel when the reserves during the navigation and after the load is unloading in the port ports.

Consequently, the implementation of the course task sets its task to study the technology and the organization of transportation of goods on sea transport, which allows in the future in practice to apply the knowledge gained.

3. Summary

The Aim of the Present Project IS Studding Procedure of the Given Cargoes on Board The Given Ship. While working on the project one can get acquainted with characteristics of the cargoes necessary for the transportation the type of vessel on which board the cargo will be shipped, and with procedure of loading and stowing the cargoes in accordance with their weight and volume characteristics and compatibility Of Cargoes. One Must Understand IT IS Necessary to Pay Attention to Durability of the Hull and Stability of The Vessel While Spending Stocks, During Her Sailing and After Unloading Cargoes at the First Port of Call.

Consequently The Main Problems of this Project Are The Procedure and Organization The Shipment of Cargo by Sea. This Project Helps to Put Knowledge Into Practice.

The main part of the ship is the hull of the vessel. The housing of the vessel is divided into three main parts: nasal (front) part, called the nose of the vessel; The rear, called the vessel feed; Part of the vessel located between the two parts is called Middle (middle part of the ship).

The hull of the vessel is the main part of the ship. This is the area between the main deck, sides and bottom. It is made of a frame covered with a trim. Part of the vessel body located below the water is the underwater part of the vessel case. The distance between Waterlinia and the main deck is the surface of the vessel. The vessel body is divided into a certain amount of waterproof compartments, decks and bulkheads. The bulkheads are steel vertical walls walking along and across the vessel.

The hull of the vessel consists of machine compartment, cargo premises and several tanks. In the dry cargos, the cargo space is divided into holds and twindes.

In the nose of the housing there is a long-facing tank, and in the fodder (rear) part - ah terpic tank. They are designed for fresh water and fuel. If the vessel has a double wall, then the space between the sides contains deck pockets.

All permanent buildings above the main deck are called superstructures. Currently, dry cargo services are built, standardized with the location of the machine compartment and the bridge superstructure in the back of the vessel housing in order to win more space for cargo. The nasal raised part of the deck is called a tank, and the feed raised part is f. On the deck there is a car processing equipment, such as cranes, winchs, cargo arrows, etc.


The Main Body of A Ship Is Called A Hull. The Hull Is Divided Into Three Main Parts: The Foremost Part IS Called The Bow; The Rearmost Part IS Called The Stern; The Part in Between Is Called Midships. The Hull Is The Main Part of the Ship. This Is The Area Between The Main Deck, The Sides (Port and Starboard) And The Bottom. IT IS MADE UP OF FRAMES COVERED WITH PLATING. The Part of the Below Water Is The Ship's Underwater Body. The Distance Between The Main Deck Is The Vessel's FreeBoard. The Hull Is Divided Up Into A Number of Watertight Compartments by Decks and Bulkheads. Bulkheads Are Vertical Steel Walls Going Across The Ship and Along.

The Hull Contains The Engine Room, Cargo Spaces and a Number of Tanks. In Dry Cargo SHIPS THE CARGO SPACE IS DIVIDED INTO HOLDS.

At the Forepeak Tanks, And At The After End Are Afterpeak Tanks. They Are Used for Fresh Water and Fuel. If a Ship Has Double Sides, The Space Between The Sides Contains Wing Tanks.

All Permanent Housing Above The Main Deck Is Known As Superstructure. NowAdays, Cargo Vessels Are Normally Built With the After Location of the Engine Room and Bridge Superstructure to Gain More Space for Cargo. The Forward Raised Part of the Deck is Called The Forecastle and Its After Raised Part Is The Poop. ON Deck Their Cargo Handling Facilities, Such As Cranes, Winches, Derricks etc.

Iron ore (in bags)

Iron ore refers to bulk loads and is usually transported on balckers-outerness. Transportation in bags is carried out only for small batches of cargo.

The main properties of ore as a bulk cargo - flowability, stalking, strain. Small specific loading volume is a danger from the point of view of maintaining the strength of the vessel hull and the stability of the vessel, on this, the loading of ore on non-specialized vessels should be carried out with precise compliance with the freight plan.

Iron ore concentrate are divided into dry (gray, particle diameter is less than 0.05 mm); wet (up to 10% humidity); wet (13% humidity). Humidity is an important indicator of this cargo, since it defines its properties, such as fatigue, dischargeability, etc. With humidity up to 7%, the cargo should be considered not fatal.

At temperatures below 0 ° C and humidity above 13% of the ore is fatal, which makes it difficult to transport, on this in the process of transportation it is necessary to maintain a given temperature and humidity regime, for which it is necessary to regularly measure the indicators of the trumulous air, if necessary, produce natural or forced ventilation.

As a result of a large density of ore, the hold or twine may not be loaded with it completely since in this case the requirement for the local strength of the case is violated, according to which it is not possible to load a freight premises to be completely loaded with a load of less than 1.3 cubic meters. meter per ton.

The specific loading volume of iron ore in bags is 0.5 cubic meters. meter per ton.


Rice white (in bags)

Rice is transported in single and double bags from 80 to 100 kg. Riga differs from other grain extraordinary susceptibility to different odors and active hygroscopicity. It has a high percentage of humidity and at the same time can absorb moisture or evaporate it depending on the condition of air in the holds. Normal is considered to be the loss of mass due to the evaporation of moisture not more than 2.5%

When transporting rice, in addition to the usual preparation of cargo premises to the transport of grain, a number of additional measures must be taken.

Rice requires a very carefully designed and efficient ventilation system for two reasons. Firstly, rice distinguishes a certain amount of carbonic acid in the form of gas, and, secondly, the moisture content leads to fogging (moisture condensation on the walls) of the trim. For this, condensate will drip out of certain points of metal design, if the necessary precautions are not taken.

The rice is heated pretty quickly, and this fact is associated with a decrease in humidity than and explains the weight reduction in the "traditional" change from 1 to 3%.

The lower part (bottom, floor) of the hold should be covered with subtle and bactas, laid across the vessel and boards laid by the distance of the vessel.

Vodka and wine in bottles (in boxes)

Water-vodka products are transported in barrels or bottles packed in boxes. Wood or cardboard boxes are used for packing bottles. To protect bottles from combat, they are installed in cells and shifted with packing material. All boxes must have a special labeling "carefully fragile" or "top not conntive", warning about the presence inside the glass box, and showing the top of the drawer.

Loading wine-vodka products are made with great caution, excluding mechanisms, rocking lifts, dropping boxes from height.

In the hold, the boxes are stacked on a flat surface. We should not ship on top of wine boxes with vodka products heavy loads that can damage the underlying cargoes.

When conducting wine-vodka products, strict control over the quality and amount of cargo is required. Cargo with traces of autopsy, damage, inclusions or battle for transportation are not accepted. If the load is still immersed at the request of the shipper, then each damaged place is opened and check in the presence of the Commission. The fact of autopsy and results constitute a special act.

Specific loading volume - 1.7 cubic meters. meter per ton.

Bananas (in bunches)

Bananas refer to perishable goods of tropical origin. Their feature is a small temperature range, in which they retain the shelf life from 1 ° C to 5-8 ° C, so their transportation is carried out, as a rule, on special vessels - banananoses. On ordinary ships, their transportation is permitted only short time and subject to strict temperature regime.

Before loading, the temperature in the holds must be lower than the optimal 5-6 ° C.

Bananas are transported in bunches (whole branches), packed in polyethylene bags with holes or kraft paper or straw or cane branches. When loading, it is necessary to take into account the vulnerability of cargo to chemical and mechanical effects, so other goods should not be placed on top of the bananas.

For the preserved transport of this cargo, it is necessary to observe the temperature regime by regular ventilation.

1 ton of bananas in bunches occupies 3.76 - 4.25 cubic meters. meters.

Iron Ore (in Bags)

Iron Ore Is Bulk Cargo and It Is Carried Usually On Bulk Vessels. Carrying on Usual Ships Is Done Only for Small Lots of Cargoes.

The Main Properties of Ore As A Bulk Cargo Are Selfrizzing, Selftightening and Others. Small Volume Peretion of Cargo Maybe Dangerous of Hull, Therefore The Loading of Ore On Nonspecialized Ships Must Be Organized with Whole According of Cargo-Plan. SHOPS MUST BE ORGANIZED WITH WHOLE ACCORDING OF CARGO-PLAN.

IRON ORE IS DIVIDED TO DRY (Gray, Diameter of Pieces IS THAN 0.05 MM); DAMPLY (TO 10% OF DAMPNESS); WET (13% of dampness). Dampness Is Important Property Of Cargo Because Other Properties Depend On It. IF Dampness Is Less, Than 7%, Then Cargo is nonfreezing.

AT Temperature Beelow 0 and Humidity Above 13% OrezesWezes Together, That Complicates Its Transportation, On It During Complication Its Necessary to Support Set Temperature and Mode for What On A Regular Basis To Measure Parameters Tremary Air If Necessary to Make Natural OR Compulsory Ventilation.

In Consequence of the Big Density of Ore Hold Or The Twin Deck Cannot Be Loaded by Her Completely AS The Requirement to Local Durability of the Case According to Which Be Unusable A Cargo Premise In This Case Is Broken Cannot Loaded Completely by A Cargo.

Loading Volume of Iron Ore - 0.5 m 3 / T

White Rice (in Bags)

Rice Transport In Unary and Double Bags from 80 Up to 100 KG. Rice Differs from others Grain An Extreme Susceptibility to Various Smells and Active Hygroscopicity. IT HAS HIGH PERCENT OF HUMIDITY AND THUS CAPABLE TO ABSORB IN ITSELF A MOISTURE OR TO EVAPORATE IT DEPENDING ON CONDITION OF AIR IN HOLDS. Normal Loss of Weight Owing to Evaporation of a Moisture No More Thank 2,5% Is Considered

By Transportation Rice, Except For Usual Preparation of Cargo Premises for Transportation Grain, IT IS NECESSARY TO Accept A Number of Additional Measures.

Rice Demands Very Carefully Developed and Effective System of Ventilation For Two ReaSons. FIRST, RICE ALLOCATES A QUANTITY OF A COAL ACID IN THE FORM OF GAS, AND SECONDLY, MOISTURE CONTENT LEADS ON WALLS HOLDS. ON IT THE CONDENSATE WILL DRIP ON CARGO From The Certain Points of a Metal Design If Necessary Safety Measures Will Not Be Accepted.

Rice IS Exposed to Heating Quickly Enough, and this Fact IS Connected with Downturn of Humidity, Than and Reduction of Weight In "Traditional" Change from 1 Up to 3% Speaks.

The Bottom Part (The Bottom, a Floor) Hold Should Be Covered Thin and Battens, Laid Across a Vessel and The Boards Laid Afar of a Vessel.

Vodka and Wine In Bottles (in Boxes)

Alcohol Is Transported in Cans or Bottles Packed in Boxes. Wooden and Cardboard Boxes Are Used to Packing of Bottles. For Protection Bottles From Beating The Are in Calls and separated. All Boxes Should Have Special Marks "Cautiously Fragile" Or "Top Handle with Care" Warning About Presnce Inside a Box of Glass and Showing Top of a Box.

Loading Alcoholic Products Make with the Big Care Excluding Jerks of Mechanisms, Rocking of Rises, Dumping Boxes from Height.

In Hold Boxes Keep Within On An Equal Surface. IS NOT NECESSARY TO LOAD ATOP OF BOXES WITH ALCOHOLIC PRODUCTS HEAVY CARGOES WHICH CAN DAMAGE UNDERLAYING CARGOES.

While Loading IT IS Necessary to Control Guarantying and Quality of Cargo. Cargoes with Spots of Damage, Beating or Leaking Don't Accepted to Carrying. If It is loaded by Requirement of Special Commission. This Checking and Its Result Must Be Fixed in Special Document.

Loading Volume of Alcohol IS 1.7 m 3 / Tonn.

Bananas (in Bunches)

Bananas Concern to Perishable Cargoes of a Tropical Origin. Their Feature Is The Small Range of Temperatures at Which The Keep The Validity from 1 ° C TO 5-8 ° C, On It Their Transportation Is Carried Out on Special Banana-Carriers. ON USUALY SHIPS THEY ARE CAN CARRIER ONLY DURING SMALL PERIOD AND WITH PROPER TEMPERATURE REGIME.

Before Loading Temperature in Holds Mast Is Below Optimal On 5-6 ° C.

Bananas Are Carried in Bunches (Whole Brunches), Packed in Palliation Bags with Ventilation or Craft-Paper or Solemn or Brunches of Reed.

At Loading IT IS NECESSARY TO CONSIDER VULNERABILITY OF A CARGO TO CHEMICAL AND MECHANICAL INFLUENCE, THEREFORE ATOP OF BANANAS OTHER CARGOES SHOULD NOT BE PLACED.

For Safe Transportation of the Given Cargo Strict Observance of a Temperature Mode by Regular Ventilation Is undesery.

1 Ton of Bananas in Bunches Requires 3.76-4.25 m 3


The accommodation of cargo on the vessel should ensure the following basic conditions:

1. Eliminating the possibility of damageing of goods from their mutual harmful effect (the effect of moisture, dust, odors, the emergence of chemical processes, etc.), as well as damage to the lower layers of cargo from the pressure of the upper;

2. Creating the possibility of unhindered unloading and loading in the intermediate ports of the navigation;

3. Ensuring maximum productivity with cargo operations;

4. Exclusion of mixing of goods from various anti-therapists;

5. Ensuring admission to the board of an integer number of ceiling parties;

6. Preservation of the general and local strength of the vessel;

7. Provision during transitions of optimal (or at least close to it) of the differential;

8. The guarantee that at all stages of the flight the stability of the vessel will not be the following limits provided for by the regulations of the Register; At the same time, the emergence of excessive stability should be excluded;

9. The maximum use of the load capacity and truckability of the vessel (depending on which of the specified values \u200b\u200bwill be limiting);

10. Ensuring the load of obtaining the highest possible freight traffic conditions.

Such numerous, sometimes inconsistent requirements make the preparation of a freight plan. The usual sequence of operations when calculating the download of the vessel is as follows:

1. Determination of the total amount of cargo that can be accepted for transportation in this flight;

2. Selection of goods, based on the conditions for the full use of the ship's loading capacity or its cargo capacity or obtaining maximum freight;

3. Distribution of load on freight compartments, taking into account the need to ensure the strength of the housing (under the cargo compartment is understood by the plus of the twindeks above it);

4. Placement by cargo cargo, depending on the possibility of joint transportation and maintenance, as well as sequence of unloading in intermediate ports;

5. Definition, correction and verification of the differential;

6. Determination, correction and inspection of stability.

If the vessel makes a flight with an intermediate port ports, then the calculations begin with the last intermediate port, in the reverse order: first place reserves for the last transition and cargo to the last port, then for the penultimate transition and cargo, etc.

The cargo plan is drawn up before the loading start - the so-called preliminary plan. During the loading, sometimes retreats are made due to the non-projective load, detected inaccuracies in the calculation, forwarding of cargo parties, etc. Therefore, after the end of the cargo operations, the executive cargo plan corresponds to the actual loading of the vessel. It finally refines the characteristics of strength, stability and a differential. It is this plan that is sent to the port of destination.

The cargo plan is most often performed in the form of a schematic vertical section along the diametrical plane - for a dry cargo vessel and horizontal - for a tanker.

With particularly complex compositions of goods on shipping vessels sometimes show the location of goods and horizontal cuts. Such cargo plans may have two schemes and are more and called multi-plates.

8. Calculation of the download of the vessel

The item is performed by the calculations of the download in accordance with the proposed method.

8.1 Determination of estimated displacement, deadweight

The estimated displacement is determined as follows:

1. According to a given sediment, which will not go into a breakdown of seasonal zones.

2. For a cargo mark, corresponding to the season of swimming, i.e. If the vessel follows from one diving area to another, which may be located in the area of \u200b\u200bthe seasonal brand L - Summer Zone, Z - Winter Zone, Zea - Winter North Atlantic, P - Fresh, T - Tropical Zone, TP - Tropical Fresh Zone.

3. In our case, we find D cf \u003d 8.2 m., What corresponds to D p \u003d 12700 tons.

We define the total lifting capacity of D W (Deadweight), which is equal to:

D w \u003d d p - d 0 \u003d 12700 - 3300 \u003d 9400 tons.

8.2 Determination of the flight time

8.2.1 Determination of the running time and the necessary reserves for the transition

t x \u003d · + T ass. , day;

t x \u003d · + 0.3 \u003d 10.3 days;

P Zap. \u003d To pieces · t x · q t x + to pieces · t x · q in x, m.;

P Zap. \u003d 1.1 · 10.3 · 12 + 1.1 · 10.3 · 15 \u003d 305.91 t.

Full load capacity (Deadweight) D w \u003d d P + D 0.

Deadweight can be expressed as a sum of the weights of cargo and reserves that can be taken aboard the vessel on a certain draft of D CP.

D w \u003d p cargo + p t + p in + p. + P. + P.

D w \u003d 12700 - 3300 \u003d 9400 tons.

Clean lifting capacity D h is the weight of the cargo without weight of fuel, water, ship supply, crew, provisions.

D h \u003d d w - s (p cargo + p t + p in + p San + P ek + p pr)

P NF.GR. \u003d 2300 + 3000 + 1400 \u003d 6700 tons.

W NF.GR \u003d 1150 + 4410 + 2380 \u003d 7940 m 3.

W vessel \u003d 17900 m 3

P F.Gr. \u003d (W - W NF.GR) / M F.Gr.

P F.Gr. \u003d (17900 - 7940) / 4 \u003d 9960/4 \u003d 2490 tons.

D h \u003d Sr 1 + R 2 + R 3 + R 4;

D h \u003d 2300 + 3000 + 1400 + 2490 \u003d 9190 tons.

8.2.3. Definition of parking time and parking lots

t art. \u003d + T VSP + + T ¢ VSP. ;

t art. \u003d + 0.25 + + 0.33 \u003d 12.8 days;

P T tent \u003d t art. · Q T st \u003d 12.8 · 10 \u003d 128 tons.

P in st \u003d t art. · Q in st \u003d 12.8 · 15 \u003d 193t.

SR Zap. \u003d R Zap.Os + R Zap.St. + R PR + R Sn + R eq. \u003d 305.91 + 321 + 40 + 40 + 15 \u003d

Determination of fuel and water reserves for transition and parking

R T \u003d R x T + R st t \u003d to pieces · t x · q x t + r T st \u003d 1.1 · 10.3 · 12 + 127 \u003d 135.96 + 128 \u003d 264 t;

R B \u003d R x B + R in st \u003d to pieces · t x · q x in + r in st \u003d 1,1 · 10.3 · 15 + 193 \u003d 169,95 + 193 \u003d

We define the average shoulder nasal X H and feed x to compartments:

X H \u003d SW j n · x j n / sw j n,

X K \u003d SW J K · x j to / SW J to

where W j n and w j to the cargo capacity j of the nasal and feed truck; X jn and x j to the abscissa center of gravity of cargo in the nose and stern from the Middle, i.e. Horizontal distance of its center of gravity from the Middle in meters.

The total variable load is taken equal to the net lifting capacity of the vessel:

D h \u003d r n + r

Deciding the equation with respect to the total distributed mass of the nasal rose and feed P to the compartments, we obtain:



Then the distributed mass in each specific compartment will be:

P i n, p i to - weight of cargo for any cargo room; W i n, w i to - the volume of any cargo room.

P 1treum \u003d 937 · (4583/1228) \u003d 382 t

P 1 top. \u003d 738 · 4583/1228) \u003d 301 t

P 2Thum \u003d 2417 · 4583/1228) \u003d 987T

P 3Thum \u003d 2783 · (4583/1228) \u003d 1136 t

P 4ThMUM \u003d 2752 · (4607/6672) \u003d 1900t

P 5trum \u003d 417 · (4607/6672) \u003d 288 t

P 5 top. \u003d 1096 · (4607/6672) \u003d 757 t

8.4 Distribution of stocks and cargo for cargo premises

Room

Weight, T.

X G (+)

M x (+)

X G (-)

M x (-)

Z G.

M Z.

7,5

7,24

-43

3,94

1041,316

-48

10,23

3707,864

-40

17

Provisions

-72

7,2

Supply

-17,1

3,27

 1 R.

4022

+ Σ 1 m x

24750

-Σ 1 m x

-32926,213

Σ 1 m z

29314,98

Thym 1.

51,5

4

50

4,6

50

5,39

Twinek 1.

51

8,7

51

9,7

51

11,2

Twineek 1 B.

52

13,7

51

15,04

TRYM 2.

30

1,1

wine and vodka

32

1,4

31

2,9

30,5

4,51

Two Twinek 2.

31

8,5

30

9

30

9,5

Thym 3.

5

1,55

wine and vodka

5

2

5

2,9

5

4

Twinek 3.

5

8,5

5

8,6

5

9

5

10

Thym 4.

-16

2

-16

2,9

-16

3,5

-16

5

Twinek 4.

wine and vodka

-16

9

-16

9,5

-16

10,6

Thym 5.

-55

4,7

wine and vodka

-55

5,3

-55

6

-55

6,4

Twinek 5.

-56

8,7

wine and vodka

-56

9,5

-55

9,9

-55

10,4

Tweed 5 B.

-55

-14093,376

12,5

-55

-9805,5164

12,9

-55

-13589,022

13,2

-55

-4146,8866

13,8

8678

Σ 2 m x

111436,4

Σ 2 m x

-103240,45

Σ 2 m z

59585,1

P common

12700

Σ О M x

136186,4

Σ О M x

-136166,66

Σ о m z

88900

X g \u003d.

0,002

Z G \u003d.

7

TRYM 1.

P \u003d 382 0 + 40.7 + 196.6 + 144.7 \u003d 382

W \u003d 937 1.7 * 40.7 + 1.47 * 196.6 + 4 * 144.7 \u003d 926.99

Twinek 1.

P \u003d 402 8,9 + 233,9 + 159.2 \u003d 402

W \u003d 985 4,45 + 343,8 + 636.8 \u003d 985

Twineek 1 Upper

P \u003d 301 0 + 0 + 46 + 167.6 \u003d 213

W \u003d 738 67,6 + 670.4 \u003d 738

TRYM 2.

P \u003d 987 7.5 + 51,7 + 547.8 + 380 \u003d 987

W \u003d 2417 3.75 + 88 + 805.3 + 1520 \u003d 2416.9

Two twine.

P \u003d 701 312.5 + 157.3 + 231.2 \u003d 701

W \u003d 1717 156.3 + 267,4 + 339.8 \u003d 763.7

Thym 3.

P \u003d 1136 235.3 + 214 + 435,1 + 252.6 \u003d 1136

W \u003d 2783 117.7 + 363.8 + 639,6 + 1010,4 \u003d 2131.5

Two twine.

P \u003d 674 192,4 + 81,1 + 201,1 + 199,4 \u003d 673

W \u003d 1651 96,2 + 137.9 + 295,6 + 797.6 \u003d 1327.3

Thym 4.

P \u003d 1900 921.2 + 306.5 + 363.2 + 309.1 \u003d 1900

W \u003d 2752 460.5 + 521,9 + 533,6 + 1236 \u003d 2752

Two twine.

P \u003d 1132 0 + 214 + 276 + 218 \u003d 708

W \u003d 1640 214 * 1.7 + 276 * 1,47 + 218 * 4 \u003d 1640

Thym 5.

P \u003d 288 145.1 + 28,2 + 109.8 + 4.9 \u003d 288

W \u003d 417 72,6 + 48 + 161,4 + 20 \u003d 302

Twinek 5.

P \u003d 530 221 + 128.3 + 112,7 + 68 \u003d 530

W \u003d 767 110,5 + 217.6 + 166,1 + 272 \u003d 766.2

Tweese 5 Upper

P \u003d 757 256.2 + 178.2 + 247.1 + 75,4 \u003d 756.9

W \u003d 1096 128.1 + 302.9 + 363.2 + 301.6 \u003d 1095.8

8.5 Check total longitudinal strength

The total longitudinal strength of the vessel body is checked by comparing the greatest bending moments in the area of \u200b\u200bthe Middle MZ. With the regulatory value of the allowable bending moment M Extras.

8.5.1 Determination of the bending moment of gravity for the Middle of the empty ship

M o \u003d k · d o · l ^^

k O \u003d 0.126 (for dry cargo vessels with a car in the stern)

a) amplitude pitching:

q IR \u003d x 1 ∙ x 2 ∙ y \u003d 1.0 ∙ 1.0 ∙ 24.0 \u003d 24.0 degrees (on table values)

b) I will postpone the value on the Q axis to the right from the start of the coordinates.

c) Restore perpendicular before intersection with DDO. We get a point A.

d) I will postpone from the point and the segment equal to 2 ∙ Q IR left. Received a point A '

e) from the point and we will spend tangent to DDO.

e) from point A to the right postpone the segment equal to 57.3 ˚ (1 happy.)

g) from the point in restore the perpendicular to the intersection with the tangent. Received L ORD.

L ORD \u003d 0.12 m.

The register of Russia makes certain requirements for the sustainability of transport courts, the verification of the execution of which is mandatory when drawing up a cargo plan before the yield of the vessel in the sea.

The requirements for register of Russia to stability are set forth in detail in the rules of classification and construction of the maritime courts of the register of Russia and are reduced to the following.

For transport ships, 20 m long and more must be satisfied with stability criteria:

a) A dynamically applied removing moment on the wind pressure M V should be equal to or less than the tipping point M C, determined taking into account the conditions of the amplitude of the pitch, i.e. Conditions must be respected

K \u003d m C / m V ³ 1.0

where to - the weather criteria;

b) The maximum shoulder of the static stability diagram L MAX should be at least 0.25 m for ships long L ³ 80 m and not less than 0.2 m for ships L ³ 105 m long. for intermediate length values, the value L Max is determined by linear interpolation ;

c) the angle of the roll, at which the shoulder of stability reaches the maximum Q m must be at least 30 ˚ . Q m³ 30 ˚ ;

d) the angle of the sunset of the static stability diagram Q v should be at least 60 ˚ . q v ³ 60 ˚ ;

e) the initial metuclear height with all the variants of the load, with the exception of the vessel, we generate, should be positive (H O ³ 0).

The stability for the courts is considered by the weather criterion to sufficient, if, with the worst, in relation to stability, the load version of the load is dynamically applied with the wind pressure of the MR is equal to less than the overturning moment M of OPP, i.e. If the conditions are observed:

k \u003d m ORD / m kr

M ORD / M CR ³ 1

M kr \u003d 0.001 ∙ p v ∙ a v ∙ z, where r V - wind pressure, pas

p V \u003d 1196 PA (accepted on the register table, depending on the area of \u200b\u200bsailing area and the shoulder of sailing).

And V is the sail area of \u200b\u200bthis ship, m 2.

A v \u003d 110 m 2.

z - Distance from the center of sailboy from the plane of the active waterline

M kr \u003d 0.001 ∙ 1196 ∙ 110 ∙ 7 \u003d 921 TM.

K \u003d 1524/921 \u003d 1.65\u003e 1.

Consequently, for the calculated vessel, the stability is sufficient.

1. Zhukov E.I., written M. N. "The Technology of Maritime Transportation".

2. Belousov L.N. "Labor technology".

3. Kozyrev V.K. "Surgon".

4. Team V.I. "Organization of work and shipping by sea".

5. "The rules for the safety of the general cargo transportation. 4 - m Volume 2.

6. Kitaevich B.E. "Sea freight operations. Educational and practical manual in English. "

7. Snopkov V.I. "Sea transportation of goods", "Transportation of goods by the sea."

8. Encyclopedic dictionary "Ensuring the safety of goods on maritime transport."

2.12 Technique of compilation of cargo

Immersing and unloaded in accordance with the cargoplast in the constituent parties are not allowing mixing them. When processing vessel, the ports are required: place goods in accordance with the agreed captain cargoplane. Cargo placement scheme on the vessel; It is drawn up with the aim of the most rational use of cargo premises and giving the vesge of the necessary stability. Distinguish preliminary (before loading) and the final (executive) G.P. (after the end of loading); Single-band (section of the ship on a diametrical plane, which shows the placement of goods on holds, twindeks and on deck) and multi-band G.P. (Compiled for container ships and universal vessels with a large number of cavalry parties, when it is necessary to know the location of goods in the horizontal plane). Drawing up G.P. It is made taking into account the compatibility of goods. Data on shipments filed for transportation on the vessel are reduced to special. Table. First in this table. Data on non-accurate loads (packing, weight, specific loading volume, time for loading in accordance with loading and unloading standards, etc.). Then the amount of cargo pass through and is filled with the rest of the table. When calculating the package of goods, the styling coefficient and the volume of separation materials are taken into account. His specificity has G.P., compiled for specialized cargo ships. G.P. ship-container carrier is called containeroplane; It is complemented by a rotary plan, which is spoken. Flowers are circled with containers batch sent to the appropriate unloading port. If the ship is readily, the loading is drawn up - the act of readiness of the ship to load is signed by the captain and stevedor. Before loading, a cargo plan is drawn up - a graphic image of the accommodation of cargo. Preliminary - is compiled by the port before the start of the cargo work. Executive - constitutes an assistant after the end of the loading. Types of freight plan: single-band and multibound. When drawing up a cargo plan: cargo capacity (W) - capacity (volume) of all cargo premises; Load capacity (P) - capacity (mass) of all cargo premises; The stability of the vessel; Case strength (general and local). Distribution of goods on the ship. In the case of heavy loads (ore), it is necessary to take into account the strength of decks. The shipping company should prescribe the loading norm of individual vessel. Loads on the vessel must be located by weight proportional to the volume of individual cargo premises. In this case, the strength of the vessel will be saved. The amount of cargo intended for loading into any of the ship premises can be determined by the formula: p \u003d W P / W, where p is the desired weight of the cargo; W is the volume of the cargo premises; W-cargo capacity of the vessel (respectively in the piles or grains); P is the weight of all goods taken by the vessel. Virtually longitudinal strength is fully ensured if the weight of the cargo will differ from the result obtained according to the above formula within 10-12%. By loading the deck of any vessel, it should be borne in mind that its strength in the end parts of the vessel is greater than in its middle. Similarly, on the sides and bulkheads of the deck has greater strength than in the middle, if, of course, the deck is not backed by pilots.

Correctly composed freight plan should provide: seaworthiness of the vessel; maintenance of goods; the ability to take and produce cargo on the bills (popartion); The simultaneous processing of the holds characterized by the factor of the harness of the tricks, Km \u003d W / N Wmax, where the KM coefficient showing the ratio of the cargo of the vessel W to the cargo capacity of the largest HMAX trumma multiplied by the number of holds; P-number of holds. If there is a different cargo in the holds, the coefficient showing the ratio of the total number of louders that must be worked out throughout the ship, to the number of loud hours for the largest hold, multiplied by the number of holds. CL \u003d L / N LMAX Providing high-speed processing of ships in ports; Full use of load capacity and cargo capacity, i.e. full loading of the vessel. The procedure for compiling a freight plan. Check, there is no cargo dangerous for the vessel and passengers. Determine the possibility of placing goods from the point of view of their compatibility and uniform distribution by holdings, to draw up a statement from which it should be seen that incompatible goods managed to distribute into different cargo premises; The use of the cube of the tricks and the distribution of weight loads on separate compartments will not cause harmful stresses in the vessel housing. To verify the influence of loading on the course of trucks, partitions according to the classification, adopted in the Regulation on the ship-daily regulations of trucks in ports, and determine the coefficient of non-uniformity of cargo distribution by trimmies. Having a cargo placement scheme for holds, make a freight plan. Check the transverse stability.






Bags enters the cage, the more stable stack. Sometimes bags are laid by a well. Most of the carboards in the conditions of applying automation and mechanization of loading and unloading work is advisable to transport packages. Under the transport package they understand the enlarged cargo unit (cargo place), formed from smaller (at least two) in the transport package (bags, drawers, bales), ...

Capital equipment repair. Conclusion Thus, the paper has developed a technical regulation on the safe performance of the unloading of coal on the car pipeline. This Regulation includes the following sections: - General requirements for the safety of work; - Rules of loading and unloading work with the help of a car pipeline on thermal power plants; - Rules for ensuring ...



Their high efficiency. 2. General characteristics of the enterprise, the main activities, management structure 2.1 History of the enterprise "Minskzheldrans" (Minsk mechanized distance of loading and unloading) For the first time, loading and unloading works by railway workers on Minsk node began to be held in 1922 at Minsk-Passenger Stations, Minsk -Work, and from 1925 ...

The entry of the vessel in the unloading ports and parking lots under unloading - include operations and techniques similar to those performed when shipping ships from the port and their parking lot under loading. The technological process of operation of ports includes such workflows: receiving goods to transportation - operations and techniques: the preparation of the port, individual territories, berths, warehouses for cargo receiving; Receiving goods from ...

N. extaway Details Draft Survea

Inquisitive - already starpomam

and more cadets.

In the world, billions of tons of cargo are transported in the naval ships. Obviously, the question is how much cargo is immersed on the ship or how much it will always be relevant from it.

This amount can be determined both by the coastal measuring complexes and by the sedimentation of the vessel - by the method of Draft Survea.

The organization of measurements on the shore may be a bulky and compact Survey Draft will serve as a good alternative to coastal measurements. On modern terminals, there are no problems with the organization weighing the shipment, but then the Draft Survey may turn out to be, as practice shows, it is quite unnecessary independent (control, if you want) a means of determining the amount of cargo on the vessel.

Usefulness Draft Survea is quite understandable. It remains only to worry about his reasonably achievable reliability and accuracy.

Direct participants Draft Survei are senior (freight) Assistant Captain Ship and Independent Surveyor.

For the inaccuracy of determining the amount of cargo, the surveyor does not bear any responsibility, but to fly from work can only for non-compliance with the instructions Head. -Ofis. Let's leave him alone.

But Starpomas, perhaps, it is worth understanding the problems of Draft Survea exhausted.

So, the vessel took the bulk cargo in the port, the amount of cargo is determined by the operator of the coastal measuring complex and / or an independent surveyor and included in the billion.

In the port of unloading with a new operator and / or new surveyor, the amount of cargo is smaller than in the Covenant. Disputes and simple vessel. And the operator, and the surveyor ports are missing. Losses and troubles arise primarily at the shipowner. Obviously, the struggle for the knowledge of a reliable amount of cargo by Starpomoy should be started in advance in the port of loading. In the port of unloading, he will protect its already, and not other people's numbers. Starpom, as the only participant and loading, and unloading - a key figure Draft Survea.

The device and the specifics of their vessel Starpom knows better than the surveyor of the stellar company itself, it remains only to know better than him and the technique of Draft Survea.

It's not hard.

The most fully existing standards Draft Survea are given in the International Code (Internet address: Unece. ORG / ENERGY / SE / PDFS / ECE _ ENERGY _19 R. PDF).

History it.

General scheme

The standard procedure requires the initial survey to start loading:

· Determine the sediment deepening and calculate the displacement D i;

· Measure the levels of the liquid ballast and calculate its number BL I;

· Measure the levels of ship reserves and calculate their number ST I;

· Dispose from ship documents with displacement by empty Ls. and calculate the so-called "constant":

Const \u003d D I - BL I - ST I - LS (1)

After loading, the final survey is required:

· Determine respectively D f, bl f, st f;

· Calculate the amount of received cargo:

CARGO \u003d D F - BL F - ST F - LS - Const (2)

We note that at the same time some mixture (every time different) from the errors of measurements and calculations of the initial surveillance will enter Const. And then the will of the case may be neutralized or aggravated by a similar mixture of ultimate surveillance. The result by formula (2) is unreliable, which is confirmed by the practice - Const. Not stable and sometimes in very wide limits.

Assignment code that if oscillations Const. Do not exceed 10%, then the draphing of the surveys was carried out qualitatively, not enough. Just from flight to the flight and during loading, and when unloading may be repeated. One (and not one) and the same systematic error. This is instantly revealed if you compare not only the results of Surveev, and the results of surveillance with measurements by the coastal complex.

Substituting in formula (2) an expression for Const, we get:

Cargo \u003d (d f - d i) - (BL F - BL i) - (ST F - ST I) - (LS - Ls) (3)

It turns out that the amount of cargo adopted is numerically equal to the algebraic amount of changes in water displacement, ballast and stocks between the initial and final surveillances .

For Draft Survei Const. It is not unnecessary and can only be applied when planning a flight so that, for example, not to promise to transport the cargo more than the precipitate on the freight brand.

Consider possible errors in formula (3).

Displacement of empty

In the overwhelming majority change Ls. Between the initial and finite surveillances, LS - Ls \u003d 0 does not occur and the error here does not occur.

Nevertheless, the following options are:

· Anchor was put on the ground, and then the anchor chain was worked out (there was a damage of the vessel along the pier);

· The boat was descended (for measuring the precipitate, for example), and with the final survea was already on a regular place;

· The hatch covers before loading were removed and laid on the shore (such vessels are), and with the final survea were already on the ship;

· Finally, the intricate ladder was lowered until it stopped on the berth (it happens toasting the watch), and then raised above the pier or replaced by light similar.

In any case, on ship drawings and certificates for this equipment can be determined in advance its mass and calculate the change Ls. Without (from the point of view of surveillance) errors.

Ship stocks

Consumable ship reserves of fresh water and provisions are discharged into shipboards of tanks, so that the amount of reserves and contaminated waters, adopted in the initial survea, should be equal to their sum in the final surveillae, the change is zero, and the error to the load will be zero.

The requirement of the Code to determine the number of fresh water stocks and in the initial, and in the final surveillance only provokes the overall error due to the errors of measurements and errors of ship tanks. For the purposes of Draft Survea, these measurements and calculations are harmful.

For the same reason, the measurements of fuel and lubricating oil are not needed. The time of operation of the main engine (if, for example, the movement of the vessel from the pier to the pier), the auxiliary diesel engine and the boiler are known through the machine magazine, the hour consumption of fuels is known according to passport data of the mechanisms, so that these changes can be calculated practically without (from the point of view of surveillance) Error.

By the way, in many ships for sanitary needs, not only fresh, but also intricate water is used (about 50 liters per person per day), which also turns out to be in prefabricated tanks by almost completely compensating for the usual consumption of fuel.

Ballast

In view of the above, real accuracy problems occur when calculating the cargo by the formula:

CARGO \u003d (D F - D i) - (BL F - BL i) (4)

The errors in determining the number of ballast is the most cumbersome in the description of the topic, so I will highlight it in a separate article.

For most vessels and in most cases, the Ballast of the vessel in the transition can be repaid in advance before the loading starts and the more you can not change it until the end of the loading. The change in the ballast will be zero and excessive error for the amount of cargo will not arise.

Women's displacement

CARGO \u003d (D F - D i) (5)

The density of intricate water

The procedure for taking sampling and measurement of water density is quite fully set forth in the code. We only note that the hydrometer (good quality) and a glass of samples (you can and simplified form) is better to have its own ship. This levels errors from using different devices in the loading port and in the unloading port.

In the example given in the Code, the density indicated 1.0285 t / m 3, and the last figure is only guessed. There may be 4, and 6, that is, the error can reach 0.0001 t / m 3.

For small vessels (loading capacity of about 1000 T), this gives an error in the amount of cargo about 0.1 tons. For large ships (Handysize - about 30,000 tons of cargo) the error will be only about 5 tons, and in the supereh (Capesize. , 100-150 thousand tons of cargo) The error will be about 10-15 tons.

It is quite acceptable today, and in the future. It is not necessary to organize more accurate measurements.

Measurement precipitate

In fact, in most cases, no measurement is made, the precipitates are visually evaluated on a very coarse (decimeter, half-patter) groove scale scale:

· In the middle part of the vessel - under an acute angle in a narrow slit between the board of the vessel and the pier or in acrobatic postures from the stormtrape from the maritime side;

· In the tips - squinting from the pier, remotely half the width of the vessel case.

All this is often done with unfavorable weather, agitated surface of the water area, poor illumination. Yes, and the technical condition of the grooves of the deepening and the accuracy of their edges in height is often forced to desire a lot of better.

The error of this definition is 1-2 cm by no means uncommon (it happens and worse!).

Meanwhile, the number of tons per 1 cm of precipitate on small ships is about 5 tons, on large to 40 tons, and on superes up to 70-80 tons and error in tens, and then in a hundred and other tons of cargo are quite likely.

For the purpose of the safety of the seafood, the grooves is usually quite good, however, for the purposes of the Draft Survea (commercial! - the price of cargo 100, 500, and even 1000 USD. For each ton), they are not suitable at all.

The vessel is afloat the beginning of the axis "Z. »For calculations of hydrostatics is under water and is not available as a base for measuring precipitation.

On the vessel along the upper deck in the board in the dock should be welded the planks (similar deckline over the disk of Plymsol), the elevation of which over the keel in the dock can be measured with an accuracy of 1 mm. (ATTENTION! Due to shipbuilding tolerances, including on the height of the side, the elevation of the planks should be taken by the actual, and not calculated.)

Standing on the deck, in comfortable conditions, using a device based on a conventional roulette and a sedative tube (similar to the specified in the code), you can measure the surface board from the slats with an accuracy of 1 mm and then calculate the precipitate with an accuracy of up to 1-2 mm, that is, The number of cargo is up to 1 ton on a small ship, up to 10 tons - on a large and up to 15 tons - on super.

It is even better to have a laser tape measure with the auent of measurements, which will give a reliable measurement of measurements from the planks to the water even if during measurements and the vessel itself will be shattered.

If you consider these events cumbersome, then take into account that doubts and disputes with the usual "definition" of precipitation take longer than the undisputed instrumental measurement.

If this does not convince you, then try to visually determine with an acceptable accuracy (1 cm) the sediment in photo 1 under great weather conditions. Do you think it succeeded?

Then try the same, in photo 2. Due to any meaning? Now note that the upper edge of the 4M brand (this is 410 cm) coincides with the lower edge of the brand "42" (and this is 420 cm). So what kind of precipitate in reality?

This kind of incidents are by no means one in various vessels. The author happened to be perplexed and on Panamax. Meanwhile, dozens, or even a hundred-other tons of cargo, dozens and hundreds of thousands of dollars are in uncertainty. Dependence on other people's flaws is very unpleasant.

It is clear that the cargo, and money is not your own. And if you still remain a supporter of non-precipitation, but the definition of its "sea convex eye", then this article is not for you, but at least think about your professional honor and at least some responsibility to the shipowner.

Shape of the housing

With advanced methods of construction of ships, a mathematical model is used to describe the shape of the housing, the exact calculation of the displacement for which it is not possible. We only note that the electronic version of this Matmodel should be on board the vessel.

Here we consider the court of the traditional method of building when the shape of the body is described by the theoretical drawing, which is developed at the stage of still sketching design, as a rule, with 10 theoretical swarthings.

At the stage of the technical project, a refined drawing is carried out with the 20th splits, according to which the vessel's refined hydrostatic data is calculated.

Further refinement of the drawing (especially in the extremities) is at the stage of the work project and the plaque body for shipyard is drawn up here in an enlarged scale with a complete set of practical spangling. Hydrostatic data is usually not recalculated.

When drawing on the plaza on 1: 1, additional clarifications are made and the plaster ordinate table is published.

Well, finally, the assembly of the vessel in Stapel will make the next adjustments to the form of the corps, which will indirectly affect the surrender act of the main dimension of the vessel.

The system analysis of changes in the shape of the case in these circumstances is unlikely possible. We will take on faith's individual opinions of specialists that the error in the calculation of displacement on the plazal ordinate table will not exceed 0.1%, that is, about 1 tons on small ships, about 35 tons on large and up to 100-150 tons on the cute. It is possible that for individual courts it will be necessary to take into account and deviations on the act of main dimensions.

Meanwhile, the projectors of the courts in the overwhelming majority of cases are used to calculate hydrostatic theoretical drawing of the technical, or even a sketch project.

Or such a case. For the vessels of the old building, information about stability (and in them and hydrostatics) according to the requirements of MK SOLAS were massively recalculated. For one group of ships, it did one project office, for other vessels of the same series - the other (maybe the third, but not yet caught). The calculation of the amount of cargo by different information in the same initial data gave a difference of 30 tons with a total amount of cargo about 3000 tons.

For the accuracy of calculating the seaworthy qualities of the vessel, all this is not important, but, as in the case of the grooves, it is not acceptable for the needs of Draft Survea, which no one ever spoke about the projectors.

For the courts under construction, it may be the norm to fulfill all the calculations of hydrostatic for operational documents on the plates of plain ordinary tables. For exploited vessels, it is desirable to order such hydrostatics specifically for the Draft Survea without reprinting (possibly) of other applications.

It is possible that for a number of vessels, the results will be quite close to the same, but the costs should not be considered in vain and in this case - the evidence of the information of errors to the minimum will appear.

Preliminary results

As follows from the above, the usual recording of the results of the Draft Surway type 13473,685 and even 3473,685 tons of the cargo of the nele. Three decimal numbers always fiction. Pseudo-flow only leads from genuine problems of the Survea Draft. You need to worry about three digits before the comma.

The Code said that the determination of the amount of cargo Draft Surveil with an accuracy of 0.5% of global practice is accepted.

It is not very clear. Now, if someone knew the truth, then ± 0.5% would be clear.

Coastal measurements were determined by 20 100 tons of cargo, and the Survey Draft gave 20,000 tons. The difference does not exceed 0.5%, and the true value is less less or more? Or all the same between?

If the difference is more than 0.5% - what to believe? Arithmetic customized? And where to?

Freight of about 20 000 tons and 0.5% is 100 tons. Even at a very humble price of 100 USD. For 1 t, either the seller, or the buyer will be infringed by 10,000 USD. . Does it agree to the compensation in the form of an assurance of the adopted world practice? Maybe you first need to ask?

It is clear that there should be no stamp and not to ask for consent, but also the right to unwind out the foreign cargo is very doubtful.

Perhaps the specialists of logistics it is time to divide the draft surveys to the "Survey - Pro Forma" (rude assessment of the amount of cargo) and the "Survey - measurement" of the amount of cargo.

Once again we emphasize that it is impossible to abandon the Draft Survea completely. It is needed at least as independent control over the coastal measuring complex - there is no curious "details" and the results of its measurements are not indisputable truths.

If the vessel is also used as a meter of the number of bulk goods, then each error of the Draft "Surway - measurements" with acceptable efforts should be minimized. In small vessels, integer units of tons of cargo may be reliable, on large vessels - dozens, and on Supper - hundreds.

In case of interest in readers, they can refer to subsequent articles that will be devoted to the clarified calculation of the term D F - D I and BL F - BL I in formula (4).


Photo 1. (option)

Photo 1. (option)

Photo 1.

Photo 2.

Calculation of displacement with Draft Survea

The displacement of the vessel is determined by the form of its body and precipitation at a given density of the intricate water.

Problems with the form of the housing, water density and precision accuracy of the precipitate are considered in the previous article "Some details of the Survea Draft", consider the problems of accurate calculation of displacement.

Estimated Waterlinia

The landing of the vessel is uniquely determined by the following Waterlinia on its building.

All wage shoes have a larger or smaller bending in the longitudinal direction, more or less changeable when changing the number and location of cargo, liquid ballast and ship reserves.

We take the shape of the housing unchanged and then the waterline will be bent, which is mathematically absolutely adequate, but much more convenient for analysis.

Waterlinnia bend happens with one point of the inflection (Parabole Shape as in Figure 1) and with two, and then the three points of the inflection (S. - Form).

International Code Draft Survea (Internet address: Unece. ORG / ENERGY / SE / PDFS / ECE _ ENERGY _19 R. PDF. ) Measurement of the sediment on the recess marks of everything in 3-points along the length of the vessel T f, t m, t a And the form of bend due to this remains unknown.

Sound of the Codex formula for the amendments to the mentioned T, we will understand what to connect points T f and t a straight line and, continuing it to perpendicular to the vessel, get precipitation D F and D A on perpendiculars, and spending a parallel line through T M. , get a precipitate on the face D M. . It is assumed that precipitation D. Lying on Parabolic Waterlinia.

Waterlinia bending arrow equal

F \u003d df + da / 2-dm f \u003d D f + d a - D M. (1)

The figure it is clear that the errors are obtained and the biggest, the greater the bend arrow and distances. L F, L M, L A From the lines of grades of deepening to perpendiculars and mid.


Accurate values \u200b\u200bof distances

With the drawing of the total location of the vessel, pass along the berth and on the deck, on the fingers, by recounting the number of sppes from the nearest main transverse burden of the vessel to the relevant lines of grooves - only so you reliably determine which practical splits are stamps. Marking drawings on the vessel are unreliable, non-reporting.

Now I would very much like, but never succeeded, see the instructions of the projector at how many millimeters in the nose or in the stern the perpendicular and the Middle of theoretical drawing from the practical spangouts closest to them.

With the help of theoretical drawing, calculate this interpretation itself and only after that you can correctly determine the distances L F, L M, L a.

There are theoretical drawings without applied practical spangling or drawings on the ship simply not. Get a designed to be designed by the request for accurate official information about this relationship. Indirect signs may be unreliable.

For Draft Survea, only only perpendicular and the Middle of theoretical drawing are needed exclusively, since the vessel's hydrostatics is designed for this drawing.

Despite a fairly extensive practice, I never managed to see in information about the stability of the competent record "The length of the vessel between the perpendicular of the theoretical drawing ... M". But see someone else's LBP. (From the rules about the cargo mark) accounted for. Moreover, there were cases when the truly inspector with the assurance of the "wet" print, the faithful numbers were corrected by the wrong figures.

Length of the vessel between perpendiculars LBP. For Draft Survea is the length on the theoretical drawing constructivewaterlinia, and the middle of this length and is the necessary Middle.

In the LBP code interpreted incorrectly as the length of cargo Waterlinia. It is incorrectly interpreted and Midel - taken the middle of the length of special Waterlinia (read the rules about the cargo mark). The Plymsole disk indicates (if it is also correctly installed) completely different Midel, to the Draft Surveta has nothing to do.

Recommending the post on the ship, do not consider work, also once again deal with distances, make a diagram of distances or check it if it is. It is important.

Guided by the Code, the surveyor in the port of the loading incorrectly took the situation of the Middle and was mistaken in the amount of cargo for several tens of tons. Surveyor in the port of unloading, also the Codex, repeated the error, and the amount of cargo in both has come true. That's just there is also weighing the load by the coastal complex! It will show that both surveyors are wrong. Again disputes, again the simple ship.

(By the way, with precipitation similar history: there should be accurate knowledge from the top or from the lower edge of the keel, the hydrostatics is calculated and what a thickness of the keel is accepted by the calculator. Otherwise, an unnecessary error may occur again, alone and only a few tons of cargo.)

Middle precipitate

Going to Fig.2, which clearly depicts the essence of the Code requirements, we will see that direct D F - D A It is considered to be the line of the Different Trim , And the tangent parallel to it is considered to be cut off the nasal and feed parabolic wedges (shaded), equal to each other.

The center of the volume of each parabolic wedge for rectangular in the plan of the case towers over the tangent of exactly 3/10 F. . Since the vessel's tip in the plan is rounded and the volume center is therefore somewhat decreased, then in the code its position is expertly reduced to 2.5 / 10, that is, up to 1/4f.

Equivalent parabolic straight waterline will pass through the centers of volumes in parallel D F - D A and the average sediment will be equal

Mmm \u003d d M + 1/4 F (2)

In the Code, for some reason, the expression is substituted into this expression F. and obtained mathematically adequate, but fully shadowing physical meaning faceless formula

Mmm \u003d 1/8 (d f + 6 d m + d a) (3)

It is clear that the stamp should calculate the sediment only through F. At the same time, watching the bending arrow functionally important for the vessel, to know which information about strength is required on some vessels.

Here the code again allows a number of errors: constructing on real measurements of the sediment at 5 points along the length of the vessel was never given by parabolic waterline, and the detailed calculations on the scale of Bonejan did not give any equality of wedges, or 1/4 coefficient. Deviations are both small and significant. Lottery.

Some survey firms trying to clarify the formula (3), for vessels full formationsconsider S. -Add bend inevitable and always take 1/3 for them F:

Mmm \u003d 1/6 (d f + 4 d m + d a) (4)

Others believe is always parabolic, but for vessels full formations wedges do not curl and always take 3/10 F:

Mmm \u003d 1/20 (3 D f + 14 d M + 3 D a) (5)

It seems that the 1/4 - 1/3 interval covers the entire range of possible changes to the coefficient for F. But, unfortunately, no one indicates the border between the full and sharp knowledge. To taste the surveyor in the port of loading? But it may not divide the surveyor in the port of unloading or operator of the coastal measuring complex. But the more the algebraic difference between the arrow of the bend of the vessel with a cargo and without cargo, the greater the uncertainty with the amount of cargo.

Lord Starpomas, watch the arrow of the bend of your vessel and evaluate the difference in tons of cargo when applying different formulas.

The Codex provides the recommendation to "clarify" the coefficient of some chart for the factor. Apply the points of Factor 0.75 and 0.67 on it (correspond to 1/4 and 1/3) and you will see that with the utilization factor, less than 0.65 considers the bending always parabolic (and even worse), and with the coefficient of more than 0 , 85 always S. -Food (and even worse), and between them bending an incomprehensible form.

No clarity does not contribute to the code, the question remains open. The search for new formulas continues, but the necessary accuracy (1-2 mm) is still not achieved.

Meanwhile, uncertainty with the coefficient for F. , as well as the remaining errors mentioned above are completely eliminated by the tooltop measurements of the sediment at 5 points along the length of the vessel.

Let me remind you that it will take it (with regard to the discussions on each of the 3-points with the usual "reading" of the brands) is no more than with instrumental and therefore undisputed measurements at 5 points.

Previously, the curved waterline of 5 points was drawn up with flexible regions or patterns. Laborious and for Draft Survea is unacceptable. Now the computer program can easily and accurately approximate the waterline into the polynomial row, giving and the shape of bending, and accurate precipitate values \u200b\u200bat any point along the length of the vessel.

Calculation of displacement

D. we lower that the blind occasion of the surveyor, guided by the code, was still valid MMM and TRIM. With successful accuracy.

Further, the code requires to write out of the hydrostatic keel hydrostatic table from the MMM sedimentation value Δ, the number of tons per 1 cm of the TRS and the position of the center of the vessel. LCF. . Let him be waiting for another luck - the table is designed for sure. And even at the same time, unnecessary errors are possible: with large differentials on the feed of ships with the bouillum, it will be at least partially over the water, and from the table will be brought away or, on the contrary, the feed patch is immersed, and will be taken away.

The code is then required to rotate the waterline around the point. LCF. Prior to the position of the new level keel and the elementary formula of the proportion to calculate the change in the precipitation in meters x \u003dLCF / LBP ∙ Trim and then the first amendment to the table displacement in tons

Δ1 \u003d LCF / LBP ∙ Trim ∙ 100 TRS (6)

Even since the classics of the ship's theory, it is known that the formula is accurate only for a conditional vessel with straight-watched on the entire perimeter of waterline by sides and admissible to solve the buoyancy equations in differentials not more than 1% LBP. (and for some ships even up to 0.5%).

For the purposes of the Draft Surveta accuracy should be much higher, and here there are also actual differentials reach 3, or even 5% (for the ship without cargo, for example).

To account for indirectness, the Codex offers a second amendment to the table displacement:

Δ2 \u003d 50 / LBP ∙ Trim 2 ∙ (MTS + - MTS -) (7)

that in essence means approximate differentiation to find the rate of change of the differential moment MTS (the values \u200b\u200bof which are also inaccurate) in the range of only 1M (from 0.5 m down from mmm to 0.5 m up from MMM), and then approximately to integrate it, but already in the range actual differential. For a ship without cargo with significant differentials, it is again possible significant errors.

The desired code of displacement is obtained by the formula:

D. = ∆ + ∆1 + ∆2, (8)

all Facts E. which, as we see, may have unnecessary errors. Formula does not guarantee the reliability of the result.

At the same time, all vessels, according to paragraph 2.1.3.4 of the resolution of IMO A.749 (18) must have a table of hydrostatics, allowing without approximate calculations, simple interpolation to determine displacement in the entire range of possible differentials.

Courts on which it will be stubbornly approximate the waterline of 3 points must be equipped with at least a table of hydrostatics with a differential. Calculations according to formulas (6), (7), (8) must be excluded in all cases. This, by the way, will reduce the duration of the calculations.

Note, once to obtain a flat keel table, the body shape is described for a computer, then get a table with a differential with a penny cost. Shipowners are likely to know, save, and classification societies, for unknown reasons, massively admit the absence of such a table on ships, ignoring the requirements of MK Solas.

Courts on which it will still prefer waterline in the form of a polynomial series, must have (also with a penny cost) table of conditional volumes of the housing over sppes (analogue of the scale of Bonejan) in electronic form. Water displacement can be obtained without unnecessary errors using the electronic curved waterline.

On ships, the form of which is described by Matmodelli, to obtain the correct value of water displacement, only the knowledge of the actual density of the fence water and the sediment at 5 points along the length of the vessel is necessary.

Conclusions

Existing methods Draft surveillance are based on hydrostatics quite accurately accurate to assess the safety of navigation. Specific - commercial - the purpose of the Draft Survea requires calculations of increased accuracy. Nothing prevents the use of these calculations and for other purposes.

The emerging limit error in determining the amount of cargo Draft Survei to 0.1% can and should be achieved. For this, shipowners need only (easy and inexpensive) to ensure the possibility of instrumental measurements of the sediment at 5 points along the length of the vessel and supply vessels with high-quality hydrostatic data.

The precipitate persistent in the measurement is only at 3 points it is necessary to supply Courts at least the tables of hydrostatics with a differential.

It's time to learn the practice of using archaic approximate calculations.

How not to lose accuracy on ships wherever the initial and final surveillances have to operate with a liquid ballast - in the next article.

Fig. 1 Definition of precipitate D. on the perpendicular of the vessel.

Fig. 2 Definition of medium sediment MMM

Liquid ballast with Draft Survea

Inquisitive - already starpomam

And more cadets.

In previous articles "Some details of the Survea Draft" and "Calculation of Displacement with Draft Survea" it is shown that for a more accurate measurement of Draft Surpection by the amount of bulk cargo on the vessel, each possible error must be minimized.

In this final article, we consider the possibility of minimizing the error in determining the change in the number of ballast between the initial and final surveillances, and we will make a generalized conclusion about Draft Survei.

Obviously, the smaller the change of ballast BL F - BL I The smaller the error when calculating this change. And when the ballast does not change at all - the error to the load is generally zero.

First, we will try to reduce the change in the ballast on large - entire tanks.

Operational ballast

We will perform a virtual flight for bulk cargo on the vessel of an unlimited area of \u200b\u200bswimming, for example, 120 m long, having, in addition to the fringe and ahterpics, 5 pairs of Ballast's bottom tanks (about 1500 tons) and 5 pairs of sublissal tanks (about 1000 tons).

On the eve of the hard storm in the ocean (the wavelength is comparable to the length of the vessel), all the bottoms and sublock tanks were pressed by ballast according to the requirements of strength information. The requirements of information about stability are carried out with a margin.

The storm is not eternal, and our ship, steadily moving towards the port of loading, entered into the closed sea, the wavelength has become 2-3 times shorter than the ship's length. According to the requirements of stability information, ballast is needed only in 4 pairs of bottom tanks (about 1200 tons); The requirements of information on strength are performed with a margin.

In the adjusting and port waters to ensure stability (ridel, the normalized corner of the roll from the wind) and the strength (already on almost quiet water) the ballast on our ship is not required at all.

However, it is necessary to have a normal landing to provide maneuverability on small moves (immersion of the propeller, controllability, sufficiency of visibility from the chassis), and possibly to maintain the performance of the mechanisms and to ensure the passage (bridges, precursing freight devices) of the vessel's surface dimensions. For our vessel in this case, we need only 3 pairs of bottom tanks (about 900 tons of ballast).

This minimum possible ballast and call "operational". A different ship in percentages to complete it will be greater, and some at all will not need. Operational ballast as loading should pump completely if the full load capacity of the vessel is in demand, or partly, if a smaller cargo is accepted.

Now the Starpoma remains only to prove the Surveyor that between the initial and final surveillances

Ballast remains in "empty" tanks have not changed;

From the "full" tanks, such a volume of the operational ballast is fraught with such a volume of operational ballast.

But about this later.

In the meantime, the remark for the unloading vessel: and in this case, some minimally sufficient number of operational ballast can be determined.

Let it be, for example, also 900 tons, which can be accepted as unloading between the initial and final surveillances. The performance of ballast pumps 2x 162 m 3 / h and after the measurements of the final surveillance there are always 2 hours before the vessel's waste for downloading 600 tons of the ballast in the remaining 2 pairs of "empty" bottom tanks. Safe incessing the outdoor exit to the open sea will be provided, and if there is a threat of heavy storm, then for 3 hours add another 1000 tons of ballast in sublock tanks, too, you can also have time without any problems.

The change in the ballast is minimized.

Now separately for each tank.

Tuning equipment

Very important moment! After all, at one single point of measurement, and even blindly obtained, it will be necessary to judge the entire volume of the ballast in the tank.

The measurement tube should provide a case access (practically vertically and without curves) to the lower point of the tank: it is necessary to measure the level of the pouring. The tube should be located in the forage part of the tank.

We divide the tanks into two types - having a flat part of the bottom (bottom) and not having such a part (natterpik, ahterpik, sublocks).

If the first type of the vessel is located in the cistern of the first type, it is necessary to achieve its transfer to the deck point over the flat part of the bottom. Otherwise, the clutches in the form of a rigid rod will be stuck in the rounding of the cheekbones with the undercase of the level of the pouring level, and the footbaths in the form of a roulette with a loader, bending when they slip on the roundabout of cheekbones, will give instead of high-quality measurement "blue torment".

In the tanks of the second type, due to their design features, it is often possible to provide the full depth of the satellum lowering. The magnitude of this charter must be determined when setting the ship to the dock.

For all tanks in the dock, it is necessary to determine the actual elevation of the deck above the zero point as the control depth of the idle of the foot.

The coordinates of the measurement tube from the turbidity of tanks in terms of and the values \u200b\u200bof control depths should be made to the projector to calculate the tables of tank volumes. Without accompanying these data, the volume tables turn into an encrypted puzzle.

Additional requirements for tank equipment arise from the specifics of the correct measurement levels.

Measurement levels

The ship has become a loading with a large differential on the stern. A clear line of a level of 9 cm appeared on the tank in the tank. The volume table is 3 m 3 ballast. We measure the depth of lowering the footbath. The height of the side and the death of the deck plus the thickness of the deck and the height of the deck sleeve, and now minus the depth of lowering - it turns out to be undercase with a footrest 18 cm! It happens less, but it happens more. So, the design of the tube did not pass through, but with a bottom and a side neckline. The end of the tube rotted, and it was cut in repair, and then not restored, and the new donyshko was welded as easier - by the cut. And so - in every repair.

With the depth of the pouring 9 + 18 \u003d 27 cm on the volume table, it is 30 m 3 ballast. So how much is actually 3 or 30?

While it does not matter. The main thing - whether the number of ballast to the final surveillance will change.

Loading is completed, there is no differential. Measurement in the same tank gives a clear 0. Ballast is growing on the bottom or daddy? Neither refusably neither one or the other.

But this happens not in one tank. Draft surveys at the same time do not even pro-form, but simply "Lipa".

Drank tubes must be cut down and those open the tubes for the free passage of the footbath. With a through tube, Navarysh is planned under it on the bottom. Ideally and he is not needed. Just use a footbath, the end of which is covered with skin (rubber, plastic), when measuring the damage protecting the paint coating of the bottom inside the tank.

On another vessel with the initial survea with a large differential on the stern, but with normal tubes, the level measurements were 2-3-4 cm, which gives a negligible small amount of ballast.

At the final survea, the differential was even a bit on the nose, the level of level in each of the tanks became different, but the order of numbers is also from 0 to 3-4 cm. What happened? Ballast is not a flow so how they are clogged, the flows are caught? Or increased due to slow housing (filtering)? Or do not keep the ballast system valves? Or maybe an unexpected error of mechanics during operations with the system? Again, uncertainty with dozens of tons of ballast.

The free flow of ballast residues should be carefully checked at the acceptance of the vessel from the new building or repair. Between repairs, the crew must at least epizodically flush over the injection of pumping a small amount of pure intricate water.

Especially intense should be washing after the ballasting of the rivers treated with water, the surplus zone, etc. Such a ballast should be replaced clean in the very near future to prevent the weighing sediment on the bottom of the tank.

Some ships after loading receive a differential on the nose and measurements in the feed tubes will show the zero level of ballast. It is not necessary to guess, flowed the same remnants or increased, and even evaporated at all. On such vessels, measurement tubes are needed and in the nose of the bottom tanks.

In the tanks of the second type, the second tube may not be installed, but the remains of the ballast should be of such a value, so that the actual measurement in the feed tube should be possible when onto the nose. Free surfaces of these residues will not have virtually no effect on stability, and their values \u200b\u200bwill almost not reduce the vessel's carrying capacity.

FROM We figured the lower levels of ballast, moving to the top.

Measurement of "full" tanks are required as well as "empty". About °

Prior to the measurement of the "complete" tank, the cork of the measuring tube must be opened, ensuring the free sink of ballast from the tube along its upper edge. Do not torment the tank and the pressing system - the airbag in the tank will still be an unknown volume.

Measurement in the "complete" tank should be made with a naturally free ballast surface, without affecting a compressed airbag. Suppress the tank after Draft Survea.

Just being confident in the correct determination of the change in the levels of the Ballast, it is possible to move to the correct definition of a change in its volume.

Tables of tank volumes

The volume table of each tank should be preceded (in addition to the data on the measuring tube) the tank circuit with its geometrical characteristics. Decipher the small-scale general schemes or dig in the working drawings (moreover, they are often missing on the ship) there is no time at the surveyor. The scheme will allow you to always get a correct idea of \u200b\u200bthe configuration of the free surface of the ballast in the tank, taking into account protrusions, ledges, deposit tanks, Mine Echohototovwaste wells holds, etc. Even for the simplest bottoms of the tank - from the side to diametral and from the bulkhead before the bulkhead - there can be a need to know the radius of the rounding of the cheekbones or the degree of narrowing of the tank to the nose or the stern.

Table of volumes should be calculated only and exclusively by plasma andonly from the lowest point / plane of the tank to the highest point of the measuring tube. The first column should be called (and be!) "Plive level". All sort of "Countdown on a footboard", "Metroshtok", "Level" "Sound "I. t..P. Not unambiguous, not informative. 0.

Very needed in the tables the range of calculating vessels is obviously sufficient - from possible on The nose with full load capacity up to a larger than that of the vessel weigh (the remains of ship reserves, as a rule, increase it).

Hundreds of revised tables and most of them are shorter than necessary range. Surveyors recommend at the same time each time the ballasting is to drive the actual trimmer of the vessel into the framework of the existing in the tables. Unlikely this recommendation can be called reasonable. Obviously, it is more expedient once for the rest of the life of the vessel to take the table.

Standard Tank Permeability Coefficient (0,98 etc.) should not be applied inTables for Draft Survea. Case set volume, pipelinesdove(including transit), mines, wells and so on should be taken by constructiontive drawings and correctly distributed in the height of the tank. A brief list of recorded subtractable volumes must be brought in the tank diagram. Painstakingly, but not at all difficult!

Example: The simplest cylindrical tank - from the side to diameter 6.5m And from the bulkhead beforebigbed 19.8M With a radius of cheekbones 0.5m. N.and one vessel in the table volume (the booklet is all in the vested signatures and stamps) at the level pillow 0.5m Volume specified 62,87 m 3, and on another vessel of the same series, but with a booklet of another project organization (also signatures and stamps), the volume is indicated 60,61 m 3, and suchtstern 8. Nearly 20 t Differences when loading the vessel of just 3000 t.

In the booklets, the levels of pouring are newly given through 1 cm. It would be possible to print them and after 1mm - the accuracy of the tables will not improve .

The ambiguity of the results of measurements of the levels of pouring and negligent volumes of volumes may come smelneyall other efforts to clarify the amount of cargo on the ship. Starp will always be a batch in disputes about shortage of cargo. about


With correct measurements and tables, you can convincingly prove both the invariance of ballast residues and the magnitude of the change of ballast.

The volume of the ballast between the upper and lower levels is determined by the tables. The density of the accepted ballast is always known for the samples of intricate water to calculate the displacement. To determine the density of the ballast, pumped as loading, you need to have a sampler, which is adapted to input into the measurement tube.

Thus, the change in the number of ballast between the initial and end surveillances can and, therefore, it is necessary to take into account quite correctly.

With the previous articles, this is perhaps all the main problems of Draft Survea. The remaining details can be solved in the course of the process.

Conclusion

The draprot of surveys was, there will be. However, the joint efforts of his method is time to raise to a higher level.

From very unspecific accuracy 0.5% (only because of the ballast, the error is more), it is possible and you need to move to the guaranteed accuracy of the surprise surveillance not more than 0.1% by cargo.

Very important Self-forming of stupoms (surveyor - only independentthe measurement tel), but the main thing is to persuade shipowners for one-time and relatively small costs of providing the vessel:

· The possibility of instrumental measurements of the sediment at 5 points in length;

· Reasonably arranged fruit tubes in ballast tanks;

· Correct data on the hydrostatics of the vessel and the volumes of ballast tanks.

We call such ships standard in the sense of the Draft Survea.

They will certainly have to be not only pride of the shipowner, but also to get a variety of preferences. At least in the form of the right to enter the flight without loss of time in ports on disputes on the number of cargo, saving port expenses and travel time. But this is all the care of logistics specialists and P & I clubs.

Happy swimming!

Well, something outsuen:

Or maybe the modernized Draft Survey will be replaced with Petroleum Survey, very cumbersome in its today?

Surveyor Yakovenko Gennady Pavlovich

Sevastopol

tel. 8 0692 54 72 22

Mob .8 067 233 44 65

E-mail: [Email Protected]

New on the site

>

Most popular