RU207395U1 - Tank container - Google Patents

Abstract

The utility model relates to devices for the safe transportation and storage of liquid cryoproducts, including liquefied natural gas, by road, rail and water transport, namely, to the design of supporting and fixing elements. A tank container containing a casing with bottoms, an inner vessel located in the casing, low-thermal conductivity supports located between the casing and the inner vessel, as well as tensioner assemblies that protect the inner vessel from displacement, each tensioner assembly includes a kinematic link, a bolt with nuts, disc springs , while the kinematic link on one side is connected to the casing, and on the other side - to the inner vessel, the tensioner assemblies are located at the ends of the tank container on both sides, characterized in that in each tensioner assembly the eyelet is rigidly attached to the stiffener and through the kinematic link is connected to the end of the bolt, while the stiffener is made of a domed, protruding dome into the inner cavity of the inner vessel through an opening made in the inner vessel, the stiffener is rigidly and hermetically connected to the inner vessel, and the eyelet is attached to the inner surface of the stiffener, disc springs installed on the other bolt between the stoppers, with the upper stopper fixed relative to the casing, and the lower stopper fixed with respect to the bolt. The technical result of the claimed utility model is to increase the reliability of the tank container by ensuring the rigidity and strength of the tensioner assembly, as well as by reducing the likelihood of damage or deformation of the inner vessel. 17 p.p. f-ly, 3 dwg

Description

The utility model relates to devices for the safe transportation and storage of liquid cryoproducts, including liquefied natural gas, by road, rail and water transport, namely, to the design of supporting and fixing elements.

Known tank for liquefied gases, which contains a shell, a vessel in it, supported at the ends on two pairs of low-thermal conductivity supports. The supports are located at an angle to the vertical axis of the tank. The vessel is fixed against longitudinal loads in both directions by one rigid rod. The rod has spatial hinges at its ends, one of which is fixed to the vessel, the other to the shell. The vessel is pressed against the supports and secured against rotation around the longitudinal axis by a spring-loaded stop. The stop is fixed on the vessel, supported on the shell through the adapter piece and has a key placed in the longitudinal groove of the said adapter piece, fixed on the shell. Each of the supports is mounted on the supporting surface of the vessel and is supported on a transition piece mounted on the support and fixed to the shell in place during installation (patent RU 2032848 C1, IPC F17C 13/08, F17C 3/00, publ. 10.04.1995).

The disadvantage of this solution is the complexity of the design of the supports, the rod and the spring-loaded stop, the complexity of the assembly, the possibility of damage to the low-heat-conducting supports when performing the assembly seam of welding transition parts.

Known tank for cryogenic liquid, related to devices for storage and transportation of cryogenic products, namely to the design of supporting elements that serve to fasten the inner heat-insulated vessels in hermetically sealed outer casings (shells) of tanks and protect the inner vessel from longitudinal movements during the transportation of cryogenic products and compensation of thermal deformations (patent RU 2709 750 C1, IPC F17C 13/08, F17C 3/00, publ. 19.12.2019).

The disadvantage of the known solution is that when a truncated cone is used as a support, fixed with a small diameter on the cylindrical part of the vessel, a large thermal bridge arises on the force belt of the outer casing with a large diameter, since the metal has a high thermal conductivity coefficient and because of this the process of vaporization of the cryogenic product is faster. Also, the disadvantages include possible deformations of this support unit due to thermal expansion of the vessel material when it is filled with a cryogenic liquid.

Known container-tank related to containers for storing and transporting liquids, which can be used in rail, road and water transport. The container - the tank contains a shell and a vessel in it, supported on two pairs of low-heat-conducting supports, located at an angle to the vertical axis of the tank. The unit for fixing the vessel from transport loads in the longitudinal direction is made in the form of one rigid rod having spatial hinges at the ends and is installed on the central axis of the tank. One spatial hinge is fixed on the bottom and placed inside the vessel in a cavity communicated with the insulating space of the tank, and the other on the bottom of the shell. The vessel is held from vertical movements by four spring-loaded chains (link and bolt in the claimed solution), one end of which is fixed to vessel 3, and the other to shell 2 (patent RU 2259312 C1, IPC B65D 88/12, publ. 27.08.2005).

The disadvantage of the known solution, taken as a prototype, is the lack of rigidity and strength of the tensioner assembly.

The technical problem to be eliminated by the claimed utility model is to ensure the rigidity and strength of the tensioner assembly.

The technical result of the claimed utility model is to increase the reliability of the tank container by ensuring the rigidity and strength of the tensioner assembly, as well as by reducing the likelihood of damage or deformation of the inner vessel.

The technical result is achieved by the fact that in a tank container containing a casing with bottoms, an inner vessel located in the casing, low heat-conducting supports located between the casing and the inner vessel, as well as tensioner assemblies that protect the inner vessel from displacement, each tensioner assembly includes a kinematic link , bolt with nuts, Belleville springs, while the kinematic link on one side is connected to the casing, and on the other hand - to the inner vessel, the tensioner assemblies are located at the ends of the tank container on both sides, according to the utility model, in each tensioner assembly there is an eyelet is rigidly attached to the stiffener and through a kinematic link is connected to the end of the bolt, while the stiffener is dome-shaped, with a dome protruding into the inner cavity of the inner vessel through an opening made in the inner vessel, the stiffener is rigidly and hermetically connected to the inner vessel, and the eyelet is attached to inner surface of a rigid element springs, Belleville springs are installed at the other end of the bolt between the stoppers, while the upper stopper is fixed relative to the casing, and the lower stopper is fixed relative to the bolt.

Tensioner assemblies can be arranged symmetrically about the vertical axis of the tank container.

The cross section of the domed stiffener can be circular.

The cross section of the domed stiffener can be oval.

The upper limiter can be made in the form of a washer.

The tensioner assembly may contain an additional washer installed between the upper washer and the springs, with spacers of low heat-conducting material located between the washers.

The gasket located between the washers in the tensioner assembly can be made of fiberglass.

In the tensioner assembly, the tab can be welded to the stiffener.

In the tensioner assembly, the stiffener can be welded to the inner vessel.

The kinematic link can be made in the form of a ring.

The kinematic link can be made in the form of a free-form ring.

The kinematic link can be made in the form of an oval ring.

The kinematic link can be made in the form of a ring of irregular shape.

The upper washer can be fixed relative to the casing by means of a stop rigidly connected to the casing and installed in the groove of the upper washer.

The tensioner assembly can be partially placed in a pipe rigidly connected to the casing, with the inner cavity of the pipe communicating with the cavity between the casing and the inner vessel.

The stop can be rigidly connected to the branch pipe.

The branch pipe can be connected to the casing by welding.

The stop can be connected to the branch pipe by welding.

The essence of the invention is described below on the basis of the presented drawings, where FIG. 1 is a perspective view of the container, FIG. 2 is a front view of a tank container, FIG. 3 - section A-A in Fig. 2, which shows a cross-section of the tank container at the location of the tensioner assemblies, FIG. 4 - remote element B in Fig. 3, FIG. 5 is a perspective view of the tensioner.

The tank container (Fig. 1-2) consists of a casing 1 with bottoms 2 rigidly fastened to two end frames 3 by means of transitional power shells 4, and reinforced with frames 5, an inner vessel 6 having a screen-vacuum insulation 7, and resting on the inner side of the casing 1 by installing two rows of support elements, consisting of supports 8 (Fig. 3, view A-A) made of a low heat-conducting material, for example, fiberglass. Supports 8 are located at an angle to the vertical axis of the container. To prevent vertical movement and axial rotation of the inner vessel 6, there are tensioner assemblies 9 located in the transverse direction at the same level with the supports 8. Tensioner assemblies 9 are located at both ends of the tank container on both sides symmetrically relative to the vertical axis of the tank container, so that to ensure the equilibrium position of the inner vessel and to ensure an even distribution of loads on the inner vessel 6. The space 10 between the casing 1 and the inner vessel 6 is filled with vacuum. The installed shut-off and safety valves of the tank container are closed with an armature compartment 11. The tank container has a unit for rigid fixation of the inner vessel 6 (not indicated in the drawings). The inner vessel 6 is located in the casing 1. The design of each tensioner assembly 9 (Fig. 4, remote element B) contains a stiffener 12 having a domed shape. The stiffening element 12 emerges with its dome into the inner cavity of the vessel 6 through an opening made in the inner vessel. In a particular case, the stiffener 12 may be in the form of a hemisphere. The stiffener 12 is rigidly and hermetically connected to the inner vessel 6, for example, by welding along the perimeter of the hole in which the stiffening element 12 is located. To the inner surface of the stiffening element 12, an eyelet 13 is rigidly attached, for example by welding. To the eyelet 13 through a kinematic link 14, a bolt 15 is attached, which serves to tension a set of disc springs 16 with a guide sleeve 21. A set of springs 16 in the upper part abuts against a set of washers 17, 18, between which a gasket 19 of low heat-conducting materials, for example, fiberglass, is located. The set of washers 17 and 18, in turn, abuts against stops 20 rigidly fixed to the branch pipe 24 of the casing 1, for example, by welding. In this case, the stops 20 are placed in the groove of the upper washer 17.

In the lower part, the Belleville springs 16 are pressed by the guide sleeve 21, provided at the bottom with a flat disc - the stop 25, and tightened with the nuts 23.

The claimed technical solution works as follows. Stiffeners 12 are welded into the vessel 6 through the holes so that their domes are located in the inner cavity of the vessel 6. Lugs 13 are welded to the inner surfaces of the stiffeners 12. After rolling the inner vessel 6 into the casing 1, a bolt 15 is put on the kinematic link 14 through the branch pipe 22 of the tensioners 9, then a set of washers 17, 18 is installed, between which a gasket 19 of low heat-conducting materials, for example, fiberglass, is located, and which abut against the stops 20. Next, a set of Belleville springs 16 is installed, which are compressed and fixed by means of a guide sleeve 21 and nuts 23. After that, the closing seam of welding the plug 24 to the nozzle 22 is performed. The inner vessel 6 is constantly pressed through the supports 8 to the inner surface of the casing 1 due to the work of the Belleville springs 16 and bolts 15 (Fig. 4), excluding overturning of the vessel. Also, the travel of the Belleville springs 16 compensates for the decrease in the diameter of the inner vessel 6 under the influence of the cryogenic liquid. The applied unit for rigid fixation of the vessel 6 helps to prevent its overturning during the transportation of cryogenic products. The presence of a domed stiffener 12 ensures the safety of the inner vessel 6 from deformations in the event of dynamic loads, since the dynamic loads will be perceived, first of all, by the stiffening element 12 (in contrast to the closest analogue, in which the dynamic loads from the tensioner assembly are perceived directly by the inner vessel, which can lead to its deformations). The implementation of the stiffening element 12 domed is due to the need for a more uniform distribution of loads from the tensioner assembly on the inner vessel 6, which will reduce the point stresses on the vessel 6 (which is the case in the construction of the closest analogue). The dome-shaped stiffener can be, for example, a part of a ball - a hemisphere, or it can have a different dome shape.

The tensioner assemblies proposed in this technical solution prevent vertical movement and axial rotation of the inner vessel and its overturning during transportation of liquid cryogenic products. In this case, the prevention of axial rotation of the inner vessel (along with the prevention of vertical movement, as in the closest analogue) is ensured by making the tensioner assembly more rigid than the closest analogue, since as a kinematic link, one ring is used, connected with the bolt and with the eye, there is no long chain, which causes a softer kinematic connection.

The technical documentation for the declared tank container using distinctive features has been approved by the Main Directorate of the Russian Maritime Register of Shipping.

Claims (18)

1. A tank container containing a casing with bottoms, an inner vessel located in the casing, low heat-conducting supports located between the casing and the inner vessel, as well as tensioner assemblies that protect the inner vessel from displacement, each tensioner assembly includes a kinematic link, a bolt with nuts, Belleville springs, with the kinematic link on one side connected to the casing, and on the other side to the inner vessel, the tensioner assemblies are located at the ends of the tank container on both sides, characterized in that in each tensioner assembly the eyelet is rigidly attached to the stiffener and through the kinematic link is connected to the end of the bolt, while the stiffener is made with a domed, dome-shaped protruding dome into the inner cavity of the inner vessel through an opening made in the inner vessel, the stiffener is rigidly and hermetically connected to the inner vessel, and the eyelet is attached to the inner surface of the stiffener, Belleville springs mounted on the other end of the bolt between the stoppers, while the upper stopper is fixed relative to the casing, and the lower stopper is fixed relative to the bolt. 2. A tank container according to claim 1, characterized in that the tensioner assemblies are arranged symmetrically relative to the vertical axis of the tank container. 3. A tank container according to claim 1, characterized in that the cross-section of the domed stiffener is made in the form of a circle. 4. A tank container according to claim 1, characterized in that the cross-section of the domed stiffener is made in the form of an oval. 5. A tank container according to claim 1, characterized in that the upper limiter is made in the form of a washer. 6. A tank container according to claim 2, characterized in that the tensioner assembly contains an additional washer installed between the upper washer and the springs, with spacers made of low heat-conducting material between the washers. 7. A tank container according to claim 3, characterized in that the gasket located between the washers in the tensioner assembly is made of fiberglass. 8. A tank container according to claim 1, characterized in that in the tensioner assembly the tab is attached to the stiffener by welding. 9. A tank container according to claim 1, characterized in that the stiffener is connected to the inner vessel by welding in the tensioner assembly. 10. A tank container according to claim 1, characterized in that the kinematic link is made in the form of a ring. 11. A tank container according to claim 1, characterized in that the kinematic link is made in the form of a free-form ring. 12. The tank container according to claim 1, characterized in that the kinematic link is made in the form of an oval ring. 13. Tank container according to claim 1, characterized in that the kinematic link is made in the form of a ring of irregular shape. 14. A tank container according to claim 1, characterized in that the upper washer is fixed relative to the casing by means of a stop rigidly connected to the casing and installed in the groove of the upper washer. 15. A tank container according to claim 1, characterized in that the tensioner assembly is partially located in a pipe rigidly connected to the casing, while the inner cavity of the pipe is in communication with the cavity between the casing and the inner vessel. 16. A tank container according to claim 11, characterized in that the stop is rigidly connected to the branch pipe. 17. A tank container according to claim 12, characterized in that the branch pipe is connected to the casing by means of welding. 18. A tank container according to claim 13, characterized in that the stop is connected to the branch pipe by welding.

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