RU2822334C1 - Method for installation of inner vessel into outer casing of cryogenic tank container - Google Patents

Abstract

FIELD: packaging; storage.

SUBSTANCE: invention relates to a method of mounting an inner vessel into an outer casing of a cryogenic tank container. Method of internal vessel installation into external casing of cryogenic tank container consists in the following. Inner vessel and the outer casing are connected. Wherein inner vessel is displaced to outer casing arranged on tilters using load grippers attached to it, so that outer casing and inner vessel are arranged sequentially in one line. Then, the inner vessel is moved towards the outer casing until the movable support fixed on the inner vessel enters the outer casing, and the inner vessel is pulled into the outer casing by means of a winch. Presence of gaps between the wall of the inner vessel and the wall of the outer casing is monitored . Further, the inner vessel is fixed inside the outer casing and the inner vessel is disconnected from the support, winch and load grippers.

EFFECT: possibility of installation of internal vessel into external casing of tank container, which is pre-assembled and has round shape in its cross-section.

27 cl, 2 dwg

Description

The present invention relates to a method for installing an inner vessel in the outer casing of a cryogenic tank container used in multimodal transport, for example, by rail, road and sea.

In the prior art, there is an invention that relates to a low temperature liquefied gas tank container using a two-tank design, which can improve the efficiency of liquefied gas storage by providing a low-temperature liquefied gas storage tank installed in accordance with a prescribed standard in a two-tank design. tanks consisting of an inner tank and an outer tank, and separately supports and fixes the inner tank and the outer tank. A tank container for low temperature liquefied gas using a double tank structure includes: a container frame unit forming a cube-shaped outer frame; and a storage tank unit, which is installed in the container frame block and includes an inner tank of a cylindrical shape for storing low-temperature liquefied gas therein, and an outer tank separated and mounted to surround an outer peripheral surface of the inner tank. The side support block is installed on both sides of the bottom of the storage tank block and is inclined downwards towards the container frame block about the center axis line to individually support the inner tank and the outer tank. The present invention forms a storage tank block in a double structure consisting of an inner tank and an outer tank, and individually supports the inner tank and the outer tank with a side support block installed on both sides of the bottom of the storage tank block to prevent damage when the outer the circumferential surface of the outer tank is pressed down by the weight of the storage tank assembly or an external force. The outer reservoir is preferably divided into a semicircular upper casing portion and a lower casing portion to facilitate assembly on the outer peripheral surface of the inner reservoir.

The prototype describes a method for installing a vessel into the casing of a tank container. The prototype states the following. The outer tank is mounted at a distance from the outer peripheral surface of the inner tank. That is, by installing the outer tank to surround the outer peripheral surface of the inner tank, the cooling efficiency of the liquefied gas stored in the inner tank can be improved. In addition, it can prevent the internal tank from being damaged by external force. In this case, the upper part of the casing and the lower part of the casing can be assembled so as to be located at a distance from each other on the outer peripheral surface of the inner tank, and then fixed as a single unit using a fastening method such as welding (invention patent No. KR101933058 "Containers - tanks for low-temperature liquefied gas”, IPC F17C 13/08, F17C 3/02). This solution was adopted as a prototype.

The disadvantage of the prototype is the presence of longitudinal welds formed when fixing the upper part of the casing and the lower part of the casing, which increase the complexity of the invention. In addition, welds made in one line on both sides along the entire length of the casing are stress concentrators, which reduces the quality of the final product. When making longitudinal seams, there is a high probability of damaging the insulation of the internal vessel by burning it. Another disadvantage of this method is the low probability of obtaining a round casing cross-section due to the fact that each part of the casing (upper and lower) does not have sufficient rigidity, and making two longitudinal seams along the entire length of the casing will most likely also lead to thermal deformations.

The technical problem is to develop a method that is devoid of the above disadvantages, namely, reducing the labor intensity of the method for installing an internal vessel into the outer casing of a cryogenic tank container and improving the quality of the final product.

The technical result of the proposed invention is the possibility of installing an internal vessel into the outer casing of a cryogenic tank container, which is pre-assembled and has a round cross-section.

The technical result is achieved by the fact that the method of installing the inner vessel into the outer casing of a cryogenic tank container includes connecting the inner vessel and the outer casing, while the inner vessel is moved to the outer casing mounted on the tilters using lifting devices attached to it so that the outer the casing and the inner vessel were positioned sequentially in one line, then the inner vessel is moved towards the outer casing until the movable support attached to the inner vessel goes inside the casing and, using a winch, the inner vessel is pulled into the outer casing, while controlling the presence of gaps between the wall of the inner vessel and the wall of the outer casing, then fix the inner vessel inside the outer casing and disconnect the inner vessel from the movable support, winch and load-handling devices.

In this case, the load-handling devices can be secured to the flanges of the inner vessel, which have threaded holes, by means of bolted connections.

In this case, the movement of the inner vessel to the outer casing can be carried out using slings hooked to load-handling devices.

In this case, the tilter can be configured with height adjustment.

In this case, additional support can be used.

In this case, the additional support can be made with the possibility of height adjustment.

In this case, the supports can be made with rollers.

In this case, the supports can be made with wheels.

In this case, the additional support can be moved along the rails.

In this case, the movable support inside the outer casing can be moved along the guides.

In this case, the additional support can be connected to an additional winch.

In this case, an additional winch can be mounted on an additional rack.

In this case, an additional rack can be fixed to the floor surface.

In this case, an additional winch can be equipped with a cable.

In this case, the additional winch can be manually controlled.

In this case, the additional winch can be equipped with automatic control.

In this case, the winch can be equipped with a cable.

In this case, the winch can be manually controlled.

In this case, the winch can be equipped with automatic control.

In this case, the cables can be secured in lugs made on supports.

In this case, the winch can be secured to a stand.

In this case, after seaming, the inner vessel can be installed on supports in the outer casing and secured with the help of tensioners and technological stops.

In this case, the movable support can exit from the outer casing onto a lifting table.

In this case, the lifting table can be made with the ability to adjust the height.

In this case, the lifting table can be installed on a stand.

In this case, the cabinet can be rigidly fixed to the floor surface.

In this case, the stand can be installed on a cabinet.

The essence of the invention is illustrated by figures.

In fig. 1 shows the inner vessel and the outer casing.

In fig. 2 shows view A.

Positions on the figures:

1 – movable support;

2 – additional support;

3 – lifting table;

4 – cabinet;

5 – rails;

6 – internal vessel;

7 – outer casing;

8 – additional rack;

9 – winch;

10 – additional winch;

11 – tilter;

12 – cable;

13 – cable;

14 – stand;

15 – load-handling device;

16 – load-handling device;

17 – bottom of inner vessel 6.

The method of installing the inner vessel 6 into the outer casing 7 of a cryogenic tank container involves moving the inner vessel 6 and the outer casing 7 to the location where the inner vessel 6 is installed in the outer casing 7, for example, to a specially prepared position. The inner vessel 6 is moved to the outer casing 7, installed on the tilters 11, using load-handling devices 15 and 16 attached to it so that the outer casing 7 and the inner vessel 6 are arranged sequentially in one line.

Internal vessels 6 that have passed all the necessary tests, are cleaned and have been insulated are allowed for installation (“rolling”). Slinging of the inner 6 vessel into the installation zone (“rolling in”) is carried out using load-handling devices 15 and 16, to which, for example, slings can be attached, in particular tape slings (position not shown). Due to the fact that the inner vessel 6 is covered with insulation and there is a high risk of its destruction when slinging the inner vessel 6, the flanges of the inner vessel may, for example, contain threaded holes to which lifting devices 15 and 16 can be attached, for example by means of bolted connections. 6 has two bottoms 17, on each of which a flange is installed, to which, for example, two load-handling devices 15 and 16 can be attached. Thus, with the help of tape slings and load-handling devices 15 and 16, in a particular version, the inner vessel 6 can be moved to the place its installation in the outer casing 7. The outer casing 7 is installed on tilters 11, which are placed in a specially equipped place - in the place where the internal vessel 6 is installed in the outer casing 7 of the tank container.

Then the inner vessel 6 is moved towards the outer casing 7 until the movable support 1, fixed to the inner vessel 6, goes inside the outer casing 7. They can in a particular version, attach an additional support 2, designed to move along rails 5 and adjustable in height. Through another load-handling device 16, closest to the outer casing 7, the movable support 1 is secured. During fastening, the inner vessel 6 can, for example, be held with slings by the load-handling devices 15 and 16. By rotating the rollers of the tilters 11, you can change the position of the outer casing 7 relative to the inner vessel 6. Instead of additional support 2, various types of slings attached to the load-handling device 15 can also be used.

Using the vertical movement of the tilters 11 and adjusting the height of the additional support 2 and support 1, the inner vessel 6 and the casing 7 are positioned so that the horizontal axis of symmetry of the inner vessel 6 either coincides with the horizontal axis of symmetry of the outer casing 7, or the horizontal axis of symmetry of the inner vessel 6 is slightly above the horizontal axis of symmetry of the outer casing 7 (so that when dragging the inner vessel 6 it does not touch the surface of the outer casing 7 with the standard supports that are installed on the inner vessel 6). In this case, for example, the rollers or wheels of the support 1 will rest on the inner surface of the wall of the outer casing 7. Thus, the inner vessel 6 will have two points of support. When using tape slings, it is possible to remove the tape sling from the load-handling device 16 after the movable support 1, attached to the inner vessel 6, enters the outer casing 7.

Next, support 1, for example using a cable 12, is connected to a winch 19 fixed to a stand 14. Next, using a winch 9, the inner vessel 6 is smoothly pulled into the outer casing 7. In a particular embodiment, when tightening the inner vessel 6, for example, the rollers of the support 1 move along the inner surface of the outer casing 7, and the additional support 2 moves smoothly, for example, along the rails 5. When tightening the inner vessel 6 into the outer casing 7, the presence of gaps between the inner vessel 6 and the outer casing 7 is monitored. The tightening of the inner vessel 6 is stopped after the support 1 comes out the outer casing 7 and the outlet of the bottom 17 of the inner vessel 6 from the outer casing 7, for example, at a distance specified by the technical documentation. In this case, the support 1, after leaving the outer casing 7, can continue to move, for example, along the lifting table 3, set at the level of the outer casing 7.

If necessary, the possibility of reverse movement of the inner vessel 6 can be provided using an additional winch 10 installed on an additional rack 8. The cable 13, attached to the additional winch 10, is also secured to the load-handling device 15. The internal vessel 6 carries out the reverse movement, moving together with additional support 2, for example moving on rails 5.

Next, fix the inner vessel 6 inside the outer casing 7. After completing the rolling of the inner vessel 6, reduce the height of the support 1 until the inner vessel 6 is installed on standard supports (or supports) (position not shown) and secure the inner vessel 6 using tensioners (positions not shown ) and technological stops (positions not shown) in order to eliminate vertical movements and overturning of the inner vessel 6. The inner vessel 6 through the supports will be constantly pressed against the inner surface of the wall of the outer casing 7 due to the operation of the tensioners. The free fit of the standard supports to the inner surface of the wall of the outer casing 7 allows the standard supports to slide along the inner surface of the wall of the outer casing 7 with possible changes in the dimensions of the internal vessel 6 as a result of exposure to the temperature of cryogenic liquids (the so-called thermal expansion of structural elements). This makes it possible to prevent deformation of the outer casing 7 and the inner vessel 6, while ensuring that the inner vessel 6 is constantly supported on the outer casing 7 to ensure its stability and prevent it from tipping over.

Then the winch 9 is disconnected from the support 1, for example connected to the cable 12, and if there is an additional support 2 with an additional winch 10, the additional winch 10 is disconnected from the additional support 2, for example also connected to the cable 13. Next, the inner vessel 6 is disconnected from the support 1 , in the presence of additional support 2 and load-handling devices 15 and 16.

Further, it is allowed to carry out further assembly of the tank container, including installation of: the bottoms of the outer casing (positions not shown), ring band rims (positions not shown) and end frames (positions not shown).

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the fastening of load-handling devices 15 and 16 to the flanges of the inner vessel 6, which have threaded holes, using bolted connections.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the movement of the inner vessel 6 to the outer casing 7 using slings hooked to the load-handling devices 15 and 16.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the design of the tilter 11 with the ability to adjust the height.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the use of additional support 2.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the implementation of an additional support 2 with the possibility of height adjustment.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the implementation of supports 1 and 2 with rollers.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the implementation of supports 1 and 2 with wheels.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the movement of an additional support 2 along rails 5.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the movement of the movable support 1 inside the outer casing 7 along the guides.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the connection of an additional support 2 with an additional winch 10.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the attachment of an additional winch 10 to an additional rack 8.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the rigid fastening of an additional rack 8 to the floor surface.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the installation of an additional winch 10 with a cable 13.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the implementation of an additional winch 10 with manual control.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the implementation of an additional winch 10 with automatic control.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is to equip the winch 9 with a cable 14.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the implementation of a winch 9 with manual control.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the implementation of a winch 9 with automatic control.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the fastening of cables 12 and 13 in lugs made on supports 1 and 2.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is securing the winch 9 to the rack 14.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the installation, after rolling, of the inner vessel 6 on supports in the outer casing 7 and securing it using tensioners and technological stops.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the exit of the movable support 1 from the outer casing 7 onto the lifting table 3.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the implementation of a lifting table 3 with the ability to adjust the height.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the installation of a lifting table 3 on a stand 4.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the rigid fastening of the cabinet 4 to the floor surface.

One of the most technologically advanced implementations of the method, which is confirmed experimentally, is the installation of rack 14 on pedestal 4.

This method was implemented at the applicant's enterprise. The use of this method has confirmed its advantages.

Example implementation.

A method for installing an inner vessel into an outer casing of a cryogenic tank container, including connecting the inner vessel and the outer casing. In this case, the inner vessel is moved to the outer casing mounted on the tilters along the rails with the help of an additional support, load-handling devices and slings attached to the inner vessel so that the outer casing and the inner vessel are arranged sequentially in one line. Then the inner vessel is moved towards the outer casing until the movable support with rollers, also attached to the inner vessel, goes inside the outer casing and, using a winch, the inner vessel is pulled into the outer casing, while monitoring the presence of gaps between the wall of the inner vessel and wall of the outer casing. Next, the inner vessel is fixed inside the outer casing using tensioners and technological stops, after which the inner vessel is disconnected from the movable support, winch and load-handling devices, as well as from the additional support.

Claims (27)

1. A method for installing an inner vessel into the outer casing of a cryogenic tank container, including connecting the inner vessel and the outer casing, characterized in that the inner vessel is moved to the outer casing mounted on tilters using load-handling devices attached to it so that the outer casing and the inner vessel were positioned sequentially in one line, then move the inner vessel towards the outer casing until the movable support attached to the inner vessel goes inside the outer casing, and using a winch, pull the inner vessel into the outer casing, while controlling the presence of gaps between the wall of the inner vessel and the wall of the outer casing, then fix the inner vessel inside the outer casing and disconnect the inner vessel from the movable support, winch and load-handling devices. 2. The method according to claim 1, characterized in that the load-handling devices are secured to the flanges of the inner vessel having threaded holes using bolted connections. 3. The method according to claim 1, characterized in that the movement of the inner vessel to the outer casing is carried out using slings hooked to load-handling devices. 4. The method according to claim 1, characterized in that the tilter is designed with the ability to adjust the height. 5. Method according to claim 1, characterized in that additional support is used. 6. The method according to claim 5, characterized in that the additional support is adjustable in height. 7. Method according to paragraphs. 1, 5, characterized in that the supports are made with rollers. 8. Method according to paragraphs. 1, 5, characterized in that the supports are made with wheels. 9. The method according to claim 5, characterized in that the additional support is moved along the rails. 10. The method according to claim 1, characterized in that the movable support inside the outer casing is moved along guides. 11. The method according to claim 5, characterized in that the additional support is connected to an additional winch. 12. The method according to claim 11, characterized in that the additional winch is fixed to an additional rack. 13. The method according to claim 12, characterized in that the additional stand is rigidly fixed to the floor surface. 14. The method according to claim 11, characterized in that an additional winch is equipped with a cable. 15. The method according to claim 11, characterized in that the additional winch is manually controlled. 16. The method according to claim 11, characterized in that the additional winch is automatically controlled. 17. The method according to claim 1, characterized in that the winch is equipped with a cable. 18. The method according to claim 1, characterized in that the winch is manually controlled. 19. The method according to claim 1, characterized in that the winch is automatically controlled. 20. Method according to paragraphs. 14, 17, characterized in that the cables are secured in lugs made on supports. 21. The method according to claim 1, characterized in that the winch is fixed to a stand. 22. The method according to claim 1, characterized in that after rolling, the inner vessel is installed on supports in the outer casing and secured with the help of tensioners and technological stops. 23. The method according to claim 1, characterized in that the movable support exits the outer casing onto the lifting table. 24. The method according to claim 23, characterized in that the lifting table is made with the ability to adjust the height. 25. The method according to claim 23, characterized in that the lifting table is installed on a stand. 26. The method according to claim 25, characterized in that the cabinet is rigidly fixed to the floor surface. 27. The method according to claim 21, characterized in that the stand is installed on a stand.