RU215957U1 - CONTAINER WITH PUMP - Google Patents

Abstract

The utility model relates to the field of scientific research of laboratory equipment and test equipment, in particular, relates to a device for explosive experiments in a vacuum and the method of its use. The evacuation container contains a body, a lid, a tray, at least one valve, a stand, and high-voltage feed-through connectors. The housing is made in the form of a hollow cylinder, on one end of which a tray is hermetically fixed by a detachable connection, and on the other end a lid is hermetically fixed. The stand is located in the center in the inner cavity of the case. The container is equipped with electrical connectors and optical harnesses. The pallet is made in the form of a glass, in the side surface of which high-voltage feed-through connectors, electrical connectors and optical bundles are hermetically installed. The stand is made in the form of a frame fixed on a pallet. The technical result, which the claimed utility model is aimed at, is to create a deep vacuum in an inert medium while increasing the measurement accuracy.

Description

The utility model relates to the field of scientific research of laboratory equipment and test equipment, in particular, relates to a device for explosive experiments in vacuum and the method of its use.

To improve the quality of registration by optical methods of fast processes in a container, it is necessary to create a deep vacuum in an inert medium. When conducting experiments without vacuum, the quality of the signal recorded by optical sensors decreases. To improve the signal and reduce the amount of noise recorded by optical sensors, it is necessary to create a deep vacuum and use an inert medium. The existing designs of containers do not allow creating a deep vacuum in an inert medium with given optical parameters and pressure.

Known vacuum explosion chamber, described in the invention called "Vacuum explosive complex" [RF patent for invention No. 2698372, IPC (2006.01) F42D 5/04, prior. October 29, 2018, publ. 08/26/2019], containing a housing, covers (lid and tray), a fitting (valve), an element for placing explosive elements (stand) and electrodes (high-voltage feed-through connector), while the housing is made in the form of a hollow cylinder, on one edge of which the lid (tray) is fixed by a detachable connection, and the element for placing the detonation object is located in the internal cavity of the housing. The covers are pivotally connected to the body. The body is equipped with a technological hatch and a pressure and vacuum gauge. The electrodes are placed in the technological hatch.

The disadvantage of this device is the presence of a large number of connections, due to which the probability of air leakage into the chamber increases significantly, which does not allow creating a deep vacuum and reduces the measurement accuracy, as well as small size, which reduces its scope.

This device is taken as a prototype, as the closest in technical essence to the claimed utility model.

The technical result, which the claimed utility model is aimed at, is to create a deep vacuum in an inert medium while increasing the measurement accuracy.

The specified technical result is achieved in that the container with pumping out contains a body, a lid, a pallet, valves, a stand and high-voltage feed-through connectors, while the body is made in the form of a hollow cylinder, on one edge of which the pallet is hermetically fixed by a detachable connection, and the lid is hermetically fixed on the other , and the stand is located in the center in the inner cavity of the housing, according to the utility model, it is equipped with electrical connectors and optical harnesses, while the pallet is made in the form of a glass, in the side surface of which high-voltage feed-through connectors, electrical connectors and optical harnesses are hermetically installed, and the stand is made in the form of a frame fixed on a pallet.

Thus, equipping the container with electrical connectors and optical bundles hermetically installed together with high-voltage feed-through connectors in the side surface of the pallet made in the form of a glass, and making the stand in the form of a frame fixed on the pallet, allows you to create a deep vacuum in an inert environment while increasing the accuracy of measurement, due to the small number of connections that ensure the tightness of the internal volume of the chamber.

In addition, in order to improve the tightness of the internal volume of the container, the lid is fixed on the second edge of the body through the sealing ring by welding.

In addition, in order to increase the strength of the container when creating a vacuum, high-voltage feed-through connectors are installed evenly along the entire length of the side surface of the cup in one row, and electrical connectors and optical harnesses, alternating, are installed evenly along the entire length of the side surface of the cup in another row.

The presence in the claimed utility model of features that distinguish it from the prototype, allows us to consider it as corresponding to the condition of "novelty".

The utility model is illustrated by the drawings:

in fig. 1 shows a general view of the container with pumping;

in fig. 2 - longitudinal section of the body with a lid;

in fig. 3 is a general view of the container pallet.

The evacuation container contains a body 1, a lid 2, a tray 3, two valves 4, a stand 5 for placing an object, and high-voltage feed-through connectors 6. The body 1 is made in the form of a hollow cylinder, on one edge of which a flange 7 is rigidly fixed by welding. Outside, on the side surface bodies 1 are rigidly fixed by welding eyelets 8 for fixing the container and lifting it, as well as for removing and installing body 1 on pallet 3.

The lid 2 is rigidly fixed on the second edge of the body 1 through a sealing ring (not shown) by welding to seal the inner cavity of the container. Valves 4 are installed in the center of the cover 2 for pumping inert gas and creating a vacuum inside the container. Outside, the valves 4 are closed by a casing 9 fixed on the cover 2 by a detachable connection in the form of bolts with washers. The inner surface of the lid 2 is reinforced with stiffeners 10 to ensure strength and prevent plastic deformation of the lid 2 under the influence of external pressure when creating a vacuum inside the container (Fig. 1, 2).

The pallet 3 is made in the form of a cup 11 with holes in the side surface and with a flange 12 rigidly fixed by welding on the free end of the cup 11. A rubber ring (not shown) is installed in the flange 12 to ensure the tightness of the connection of the body 1 with the pallet 3, and, accordingly, the tightness of the container. The flange 12 of the pallet 3 is connected to the flange 7 of the housing 1 by a detachable connection made in the form of bolts with washers. Holes in the side surface of the cup 11 are made in two rows evenly along the entire length of its side surface. In the holes of the side surface of the cup 11, high-voltage connectors 6 are hermetically installed in one row for supplying an explosive impulse, and in the second row, alternating, electrical connectors 13 and optical bundles 14 for recording product parameters during explosive loading. Electrical connectors 13 and high-voltage feed-through connectors 6 outside the tray 3 are covered with covers, and to secure the optical bundles 14 outside the tray 3, pads are installed. Uniform arrangement of high-voltage connectors 6, electrical connectors 13 and optical harnesses 14 allows you to evenly distribute the static load of external pressure, which increases the strength of the container when creating a vacuum (Fig. 1, 3).

Stand 5 is made in the form of a frame consisting of four stands 15 fixed between two flanges 16, one of which stand 5 is attached by a detachable connection to the pallet 3 from the side of the flange 12, and a flange 17 is attached to the second detachable connection to install the test sample. Detachable connections are made in the form of bolts with washers. Stand 5 is installed in such a way that the test sample fixed on it (not shown) is located in the center of the internal cavity of housing 1 (Fig. 3).

The device works as follows.

The test sample (not shown) is fixed on the flange 17, which is fixed on the second flange 16 of the stand 5. High-voltage feed-through connectors 6 are connected to the demolition system (not shown) located outside the container for supplying an explosive impulse. Electrical connectors 13 and optical bundles 14 are connected to a measuring system (not shown) located outside the container to obtain experimental data on the speed of flight of the free surface of the test sample during fast processes. Then the body 1 is installed on the pallet 3, moving it by the eyes 8. The flange 7 of the body 1 is fixed with bolts and washers to the flange 12 of the pallet 3. A gas pipeline (not shown) is connected to the valves 4 and the internal volume of the container is filled with an inert gas, after which the gas pipeline is turned off. Then, a gas pipeline of a vacuum pump (not shown) is connected to the valves 4 and a vacuum is remotely created inside the container. Having received the set vacuum value, the valves 4 close and disconnect the gas pipeline of the vacuum pump and close the valves 4 with a casing 9, which is fixed on the cover 2. Through the high-voltage connectors 6, a subversive impulse is applied to the test sample. After undermining the sample, the data obtained by the measuring system are transmitted to the operator.

Thus, the above information testifies to the fulfillment of the following set of conditions when using the claimed utility model:

The tool that embodies the claimed utility model in its implementation refers to test equipment and is intended for scientific research of laboratory equipment;

For the claimed device in the form as it is described in the claim of the utility model, the possibility of its implementation is confirmed;

The tool that embodies the claimed utility model in the implementation is capable of creating a deep vacuum in an inert environment while increasing the accuracy of measurements.

Therefore, the claimed invention meets the condition "Industrial applicability".

Claims (3)

1. A container with pumping out, containing a body, a lid, a pallet, valves, a stand and high-voltage feed-through connectors, while the body is made in the form of a hollow cylinder, on one edge of which the pallet is hermetically fixed by a detachable connection, and on the other the cover is hermetically fixed, and the stand is located in the center in the inner cavity of the housing, characterized in that it is equipped with electrical connectors and optical bundles, while the tray is made in the form of a glass, in the side surface of which high-voltage feed-through connectors, electrical connectors and optical bundles are hermetically installed, and the stand is made in the form of a frame, fixed on the pallet. 2. The container according to claim 1, characterized in that the lid is fixed on the second edge of the body through the sealing ring by welding. 3. The container according to claim 1, characterized in that the high-voltage feed-through connectors are installed evenly along the entire length of the side surface of the cup in one row, and the electrical connectors and optical bundles, alternating, are installed evenly along the entire length of the side surface of the cup in another row.

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