RU187128U1 - WEIGHT TESTING SYSTEM FOR LIQUEFIED NATURAL GAS AND LIQUID NITROGEN - Google Patents

Abstract

The utility model relates to high-precision weighing devices, namely, to weighing systems for liquefied natural gas (LNG) and liquefied nitrogen in a cryogenic tank, and can be used as a standard measuring instrument for testing, calibration and calibration of gas dispensers used for refueling LNG cryogenic fuel tanks of cars, special equipment and traction composition of railway transport. The weighing installation for liquefied natural gas and liquefied nitrogen contains a cryogenic tank and a support platform with a weighing module. The unit is equipped with a cryogenic tank suspension equipped with a platform for installing standard replacement weights, a thrust screw, the lower end of which interacts with a weight measuring module and quick-detachable connections for fastening the cryogenic tank. The weighing module contains platform scales mounted above the cryogenic tank. The utility model allows to increase the accuracy of measuring the mass of LNG and liquefied nitrogen. 8 s.p. f-ly.

Description

The utility model relates to high-precision weighing devices, namely, to weighing systems for liquefied natural gas (LNG) and liquefied nitrogen in a cryogenic tank and can be used as a standard measuring instrument for testing, calibration and verification of LNG dispensers (further LNG LNG) used for filling LNG of cryogenic fuel tanks of automobiles, special equipment and traction train composition.

In the prior art, a weighing device for lifting machines containing a support platform, a suspension with a ball bearing and a weighing module located above the load is known (see AS SU711372, class G01G 19/12, publ. 25.01.1980). The main disadvantages of the known device are the complexity of the operation of unloading the weighing module and the inability to use for weighing LNG.

Closest to the technical nature of the proposed utility model is a weight measuring unit for liquefied natural gas containing a cryogenic tank and a support platform with a weight measuring module based on strain gauges (see patent RU2668642, class G01G 17/04, publ. 02.10.2018). The main disadvantage of the known installation is the relatively high error in measuring the weight of LNG, due to the presence of bellows expansion joints on the pipelines of the cryogenic tank, uneven load distribution between the load cells during filling of the cryogenic tank and the lack of technical ability to weigh the cryogenic tank by replacing reference weights.

The technical problem is the creation of a reference measuring installation, which can be used in testing, calibration and calibration of LNG fuel dispensing columns. The technical result consists in increasing the accuracy of measuring the weight of LNG. The problem is solved, and the technical result is achieved by the fact that the weighing installation for liquefied natural gas and liquefied nitrogen, containing a cryogenic tank and a support platform with a weighing module, is equipped with a suspension of a cryogenic tank equipped with a stop screw, the lower end of which interacts with a weighing module containing platform scales mounted over a cryogenic tank. The lower end of the thrust screw is preferably equipped with an end spherical stop, and the weighing module is equipped with a response hemispherical support mounted on a platform scale. The suspension of the cryogenic tank is preferably made in the form of a U-shaped frame, the upper part of which forms a beam, and the stop screw is fixed in the central part of the beam, and the beam is equipped with adjusting weights with threaded holes mounted on threaded rods located on both sides of the stop screw. The suspension is preferably provided with a platform for installing reference weights. The stop screw is preferably equipped with a helm. The support platform is preferably equipped with cryogenic tank tool holders, swivel wheels and height-adjustable screw supports.

Figure 1 presents the proposed installation, side view;

figure 2 is a schematic diagram of an installation with an unloaded weight measuring module, front view;

figure 3 is the same with a loaded weighing module;

in Fig.4-5 - the inclination of the tank in the process of filling LNG.

The proposed weighing installation essentially consists of a support platform 1 for placing equipment, a weighing module based on electronic platform scales 2, a set of reference weights 3, a cryogenic tank 4 and a suspension for it.

The support platform 1 is a rigid metal structure of a frame type, on which a weight table 5 is mounted above the tank 4. The platform 1 has screw supports 6 that are adjustable in height to ensure a stable position when weighing the cryogenic tank 4 and adjust the horizontal position of the weight table 5. On the platform 1 two lodges 7 are placed, which serve as supports for the cryogenic tank 4. The platform can be equipped with swivel wheels 8 to move the unit across the territory of gas filling stations th (gas stations) or CNG filling stations (CNG filling stations) (hereinafter - plant) the operator forces. Electronic platform scales 2 are mounted on the weighing table 5.

As the tank 4 can be used cryogenic fuel tanks installed on vehicles and special equipment equipped with gas-diesel power units or power units adapted to operate on natural gas. The cryogenic tank 4 is made in the form of a tank with double walls made of stainless steel. To ensure the least heat transfer with the environment from the inter-wall space of the cryogenic tank 4, air is pumped out. The cryogenic tank 4 is equipped with valves 9: nozzles with shut-off valves and quick-disconnect connections for connecting the standard sleeves of the gas supply lines of the gas phase and the steam return line of the gas distribution system of the LNG, a dial gauge for the presence of overpressure of the vapor phase of the gas and a pressure relief valve for gas overpressure when the pressure is 1.8 MPa . A cryogenic tank 4 has a built-in level sensor for the separation of the liquid and gas phases of LNG or liquefied nitrogen. The level sensor is made in explosion-proof execution. As part of the installation, cryogenic fuel tanks with an internal useful volume for LNG from 0.16 m ³ to 0.57 m ³ can be used.

Electronic platform scales 2 and the level sensor of the phase separation in the cryogenic tank 4 have independent power supply from sets of lithium batteries.

The suspension for the cryogenic tank 4 is designed to transfer the load created by the total weight of the tank 4 and the suspension or a set of reference replacement weights 3 and the suspension on the load platform of the electronic balance 2 when measuring the mass of liquefied gas in the cryogenic tank 4 by the method of replacing the mass of reference weights. The design of the suspension 10 is made in the form of a metal frame of a U-shape, to the lower part of which a cryogenic tank 4 is attached by means of quick-detachable threaded joints. A mechanism for loading the scales is built into the upper forming (hereinafter, rocker 11) of the suspension, by which the total weight of the equipment is transferred to the load-receiving platform weights 2. The loading mechanism is made in the form of a freely rotatable stop screw 12 and a nut 13 rigidly fixed to the rocker arm of the suspension. The lower end of the stop screw 12 is equipped with an end ball joint ohm 14. The upper end of the stop screw 12 is equipped with a steering wheel 15. A counter-hemispherical support 16 with a seat for the ball stop 14 is mounted on the load platform of the scales 2. The suspension 10 is additionally equipped with a platform 17 rigidly fixed to the suspension for installing reference replacement weights 3. The suspension design allows carry out separate weighing of the cryogenic tank 4 without a set of reference replacement weights 3 or a set of reference replacement weights 3 without a cryogenic tank 4.

Depending on the capacity of the cryogenic tank 4 used in the installation, the installation is equipped with 2 platform-type electronic scales with the highest weighing limit from 300 kg to 800 kg, with a division price from 5 g to 15 g and a set of 3 reference weights with a nominal total weight of 40 kg up to 260 kg of accuracy class M1 in accordance with GOST OIML R 111-1-2009 GSI. Weights of classes E1, E2, F1, M1, M1-2, M2, M2-3, and M3. Part 1. Metrological and technical requirements.

The attachment points of the quick-detachable threaded joints 20 of the suspension to the cryogenic tank 4 are distributed in such a way that when weighing an empty tank, the axis of the tank takes a horizontal position (Fig. 4). However, in the process of filling the tank with liquefied gas, the center of mass is shifted, which causes the suspension to tilt with the tank when weighing in the opposite direction from the valve 9 (Fig. 5). In this case, the lower generatrix of the surface of the tank 4 deviates from the horizontal, which makes it difficult to get out of contact with one of the base lodges 7 when loading the balance 2. To reduce the effect of this harmful effect, two adjusting weights 18 are provided in the beam 11 in the form of metal cylinders with threaded holes along the axes rotation. When the goods rotate around the axes, they move in a horizontal plane along the beam 11 along the threaded rods 19. Moving the goods along the beam 11, the operator compensates for the displacement of the center of mass when filling the cryogenic tank, achieving a horizontal position of the longitudinal axis of the cryogenic tank 4.

The proposed installation works as follows.

In the unloaded state of the load measuring module, the cryogenic tank 4 rests on the tool holders 7, the ball stop 14 does not touch the surface of the seat of the hemispherical support 16. The total weight of the equipment is perceived by tool holders 7 and is not transferred to the load-receiving platform of the scales 2. To load the load measuring module, the operator rotates the steering wheel 15 the stop screw 12 clockwise, thereby moving the stop screw 12 downward relative to the nut 13. The ball stop 14 comes into contact with the hemispherical surface With the seat of the support 16 and with a further rotation of the steering wheel 7, the suspension starts to move up.

When weighing the cryogenic tank 4 (empty or with liquefied gas), the cryogenic tank 4 is mounted on the suspension using quick-release couplings 20, while the suspension 10 is moving up, the lower generatrix of the cryogenic tank 4 comes out of contact with lodges 7 and the total weight of the suspension 10, tank 4 and sites for weights 17 (without replacement weights) begins to act on the load-receiving platform of weights 2.

When weighing the replacement set of weights, the cryogenic tank 4 is not fixed on the suspension, when the suspension 10 moves upward, the quick-release couplings 20 disengage from the cryogenic tank 4, the cryogenic tank 4 remains resting on lodgements 7 and the total weight of the suspension 10 and the platform for weights 17 with the set installed replacement weights begins to act on the load-receiving platform of the scales 2.

The principle of operation of the installation is based on measuring the mass of LNG or liquefied nitrogen released through the LNG of the LNG into the cryogenic tank 4 of the installation by replacing the total mass of a set of reference weights and comparing the result with the readings of the LNG of the LNG.

The design of the installation allows you to simulate various conditions for filling the tank 4, similar to the actual conditions that arise when filling LNG cryogenic fuel tanks of motor vehicles, locomotives and special equipment, namely:

a) refueling of a new (after repair) empty, not previously refrigerated cryogenic tank;

b) refueling a cryogenic tank partially filled with LNG;

c) refueling a cryogenic tank to the maximum level of LNG;

d) partial refueling of the cryogenic tank with a given mass of LNG.

The procedure for measuring the mass of LNG or liquefied nitrogen released through LNG to the cryogenic tank 4 is as follows.

During testing / verification / calibration, the installation is located in the immediate vicinity of LNG.

The measurement of the mass of liquefied gas discharged through LNG to the cryogenic tank of the balance is carried out in five stages:

I. Weighing the cryogenic tank until the tank is filled with a given mass of liquefied gas;

II. Weighing the 1st set of replacement reference weights;

III. Filling a cryogenic tank with a given mass of liquefied gas;

IV. Weighing the cryogenic tank after filling with a mass of liquefied gas released through the LNG;

V. Weighing of the 2nd set of replacement reference weights;

Stage I. Weighing the cryogenic tank until the tank is filled with a given mass of liquefied gas.

Before weighing the cryogenic tank, the scales are calibrated when loading the loading platform with a suspension weight of 10 with a weighing table for weights without an installed set of weights and a disconnected cryogenic tank 4.

To load the load receiving platform of the scale with the weight of a cryogenic tank, the operator fastens the tank to the suspension, and then rotates the load mechanism control wheel clockwise until the ball of the lower end of the stop screw comes into contact with the spherical surface of the bearing seat on the load receiving platform of the scale and the lower the generatrix of the cryogenic tank body does not rise above the lodgments of the rack base to a height of 15-20 mm. After stabilizing the balance readings, the operator records the weighing result W1 _te (readings of the weight of the cryogenic tank for stage I) and unloads the weighing platform of the balance by rotating the control wheel of the loading mechanism counterclockwise.

Stage II. Weighing the 1st set of replacement reference weights.

The operator disconnects the mounts of the cryogenic tank from the suspension.

Depending on the result of weighing the cryogenic tank in stage I, the operator installs on the suspension weighing table a set of reference weights with a total nominal weight determined by the formula:

, кг (1)

kg (1)

where M2 _gs is the nominal total conditional mass of the set of weights for replacing the weight of the cryogenic tank in stage II, kg;

W1 _te - weighing readings when weighing a cryogenic tank at stage I, kg.

The operator loads the weighing platform of the balance with a total suspension weight of 10 with a weighing table for weights with an installed set of weights of mass M2 _gs and a detached cryogenic tank 4. After stabilizing the readings of the scales, the operator fixes the readings of the weights for the 1st set of replacement weights WII _gs for stage II, kg .

Stage III. Filling a cryogenic tank with a given mass of liquefied gas.

The operator unloads the load receiving platform of the scale by turning the load mechanism control wheel counterclockwise until the lower generatrix lies on the seats on the upper generatrix of the cryogenic tank and the ball of the lower end of the stop screw comes out of contact with the spherical surface of the bearing seat on the load platform of the scales, then mounts the cryogenic tank to the suspension. In this case, the load-receiving platform of the balance should be unloaded and the lower generatrix of the cryogenic tank should rest on the lodgements of the base of the rack.

The operator connects the supply hose of the liquid gas phase supply line and the sleeve of the steam return line of the LNG gas distribution system to the quick couplings of the cryogenic tank and opens the shut-off valves in accordance with the technological scheme of the piping of the cryogenic tank. After that, depending on the given simulation option, the cryogenic tank is refilled with a given portion of liquefied gas, (option c) or refueling to the maximum possible level of liquefied gas in the cryogenic tank (option g). After refueling, the operator closes the shut-off valves of the cryogenic tank and disconnects the supply sleeve of the liquid phase supply line of the liquefied gas and the sleeve of the steam return line of the LNG gas distribution system from the quick disconnect connections of the cryogenic tank.

Stage IV. Weighing the cryogenic tank after filling with a mass of liquefied gas released through the LNG.

Before weighing the cryogenic tank filled with liquefied gas, it is necessary to remove ice crystals and liquid condensate from the surfaces of the external pipe fittings in the same way as in Step I.

Weighing the cryogenic tank filled with liquefied gas is carried out similarly to the procedure for weighing a cryogenic tank until the tank is filled with the specified mass of liquefied gas for Stage I. After stabilizing the balance readings, the operator fixes the weighing result WIV _tf (cryogenic tank weight readings for stage I) and unloads the weighing platform of the scales by rotating the steering wheel loading mechanism counterclockwise.

Stage V. Weighing of the 2nd set of replacement reference weights.

The operator disconnects the mounts of the cryogenic tank from the suspension and places the nuts of the mounting bolts on the weighing table of the suspension.

Depending on the result of weighing the cryogenic tank in stage IV, the operator installs on the suspension weighing table the 2nd set of reference weights with a total nominal weight determined by the formula:

, кг (2)

kg (2)

where M2 _gs is the nominal total mass of the 2nd set of reference weights to replace the weight of the cryogenic tank at stage V, kg;

WIV _tf - weight reading when weighing the filled cryogenic tank in stage IV, kg

Weighing the 2nd set of reference weights to replace the cryogenic tank filled with liquefied gas is performed similarly to the weighing procedure of the 1st set of weights for Stage II. After stabilizing the readings of the scales, the operator fixes the weighing result WV _gs (readings of the weight of the 2nd set of standard weights) and unloads the load-receiving platform of the scales by rotating the loading mechanism counterclockwise.

Calculation of the mass of the batch of LNG released into the cryogenic tank of the LNG group of companies is carried out according to the formula:

The mass of a batch of liquefied gas released into the cryogenic tank of the balance is calculated by the formula:

, кг (3)

kg (3)

where M _LG - the result of measurements of the mass of liquefied gas in the cryogenic tank of the balance, kg;

WIV _tf - weighing readings when weighing a cryogenic tank filled with liquefied gas in stage IV, kg;

WV _gs - weight reading when weighing the 2nd set of replacement weights at stage V, kg;

M2 _{gs -} total conditional mass of the 2nd set of weights, kg;

WI _te - readings of scales when weighing a cryogenic tank at stage I, kg;

WII _gs - weight reading when weighing the 1st set of replacement weights in stage II, kg;

M1 _gs - total conditional mass of the 1st set of replacement weights, kg;

e is the density of atmospheric air during weighing, kg / m ³ .

Thus, in the proposed design due to the low position of the center of mass, despite the fact that the force created by the weight of the equipment is applied to the load-receiving platform of the scales 2, the weighing process is similar to the weighing process “under the scales”. The suspension design of the cryogenic tank 4 allows you to implement the weighing method "under the scales" for any type of platform scales 2, in the design of which this is not provided. The design of the installation ensures the position of the center of mass of the suspension with the cryogenic tank 4 is always on the same vertical axis with the geometric center of the seat of the support 16, which coincides with the center of application of the load to the load-receiving platform of the balance 2. This eliminates the additional component of the weighing error associated with the different position of the application point load on the loading platform of the scale 2 when weighing the cryogenic tank 4 before and after filling with LNG or liquefied nitrogen. The design of the installation makes it possible to implement both the direct weighing method and weighing by the method of mass replacement of a set of reference weights. Thus, the proposed utility model can significantly improve the accuracy of measuring the weight of LNG.

Claims (9)

1. A weighing installation for liquefied natural gas and liquefied nitrogen, containing a cryogenic tank and a support platform with a weighing module, characterized in that it is equipped with a suspension of a cryogenic tank equipped with a stop screw, the lower end of which interacts with a weighing module containing a platform scale mounted above the cryogenic a tank. 2. The weighing installation according to claim 1, characterized in that the lower end of the thrust screw is equipped with an end spherical stop, and the weighing module is equipped with a hemispherical counter support mounted on a platform scale. 3. The weighing installation according to claim 1, characterized in that the suspension of the cryogenic tank is made in the form of a U-shaped frame, the upper part of which forms a beam, and the stop screw is fixed in the central part of the specified beam. 4. The weighing installation according to claim 3, characterized in that the beam is equipped with adjusting weights with threaded holes mounted on threaded rods located on both sides of the thrust screw. 5. The weighing installation according to claim 1, characterized in that the suspension is equipped with a platform for installing reference weights. 6. The weighing installation according to claim 1, characterized in that the thrust screw is equipped with a helm. 7. The weighing installation according to claim 1, characterized in that the suspension is equipped with quick-detachable connections for mounting a cryogenic tank. 8. The weighing installation according to claim 1, characterized in that the supporting platform is equipped with lodges for the cryogenic tank. 9. The weighing installation according to claim 1, characterized in that the supporting platform is equipped with swivel wheels and height-adjustable screw supports.

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