RU170956U1 - PISTON CRYOGENIC PUMP - Google Patents

Abstract

The utility model relates to the technique of pumping liquefied gases from containers with their subsequent compression and can find application in gas filling stations, medical equipment, the oil industry, fire extinguishing systems. The technical problem solved by the claimed utility model is to eliminate the excess supply pipe and leak pipe. The technical problem is achieved by the fact that it is proposed to report the volume of the cylinder and the cooling jacket through the holes in the cylinder. The technical result of the claimed A useful model is to simplify operation by reducing the number of pipelines.

Description

The invention relates to the technique of pumping liquefied gases from containers with their subsequent compression and can be used in gas filling stations, medical equipment, the oil industry, and fire fighting systems.

A known installation for pumping liquefied gas [SU 1539446, publ. 01/30/1990], containing interconnected isothermal capacity with liquefied gas and a piston pump, a discharge pipe and a drain pipe, the latter being connected to the discharge pipe through a non-return valve, normally open towards the discharge pipe.

Closest to the proposed is an installation for pumping cryogenic liquid from tanks [SU 1208400, publ. 01/30/1986], which contains emptied tanks, a piston pump with a cooling jacket connected to them by a supply pipe, a discharge pipe, pump and cooling jacket drain pipes connected to an additional tank.

The disadvantages of the known design is its complexity associated with the presence of an extra supply pipe and an extra leak pipe.

The technical problem solved by the claimed utility model is to eliminate excess supply pipe and leak pipe.

The technical problem is achieved by the fact that it is proposed to report the volume of the cylinder and the cooling jacket through the holes in the cylinder.

Cryogenic liquids for which the proposed utility model is intended are liquefied gases.

The figure shows a piston cryogenic pump for pumping liquefied gas.

The piston cryogenic pump consists of a cylinder 1 and a piston 2 with a rod 3. At least part of the cylinder 1 is located inside the cooling jacket case 4, most of which, in turn, is inside the vacuum jacket 5. The cooling jacket case 4 is connected to the free end of the case the supply pipe 6, through which the pumped liquefied gas is supplied inside the body of the cooling jacket 4 and through the inlet valve 7 into the working cavity of the cylinder 1. The discharge pipe 8 is connected using the exhaust valve 9 to the side howl of cylinder 1 in the region of the working cavity. The leak pipe 10 is connected to the side of the cooling jacket body 4. In the side of the cylinder 1 there are holes 11 communicating its rod cavity with the cooling jacket, with valves 12 normally open towards the cooling jacket. In the side of the vacuum casing 5 there is an opening for pumping air closed by a plug 13, which can be used as a vacuum gauge (for example, capacitive).

Under the working cavity of the cylinder 1 is meant its internal volume bounded by the side walls, the piston 2 and the end wall with the inlet valve 7.

Under the rod cavity of the cylinder 1 is meant its internal volume bounded by the side walls, the piston 2 and the end wall containing the hole for the rod 3.

The volumes of the working and stock cavities vary depending on the position of the piston 2.

The proposed piston cryogenic pump operates as follows. Cryogenic liquid (liquefied gas) is directed through the supply pipe 6 to the body of the cooling jacket 4 and, when the piston 2 is sucked in, enters the working cavity of cylinder 1 through the inlet valve 7. When the piston 2 is forced to move, the liquefied gas flows through the exhaust valve 9 into the discharge pipe 8 Liquefied gas leaks enter the rod cavity of cylinder 1, from where they are removed into the cooling jacket through openings 11 with valves 12, after which they are connected to the volume of liquefied gas in the cooling jacket and discharged through a pipe leakage 10. When using a vacuum gauge 13 as a stopper, it is possible to continuously evaluate the pressure inside the vacuum casing 5 and determine the serviceability of the leak pipe 10. With a sharp increase in pressure, it will be possible to detect a breakdown of the closed circuit of the vacuum casing 5, for example, due to damage to the leak pipe 10 or the pipeline injection 8.

The technical result of the claimed utility model is to simplify operation by reducing the number of pipelines.

Claims (3)

1. A piston cryogenic pump comprising a cylinder, a piston with a rod, a cooling jacket, supply, discharge and leak pipes, characterized in that the rod region of the cylinder communicates with the cooling jacket through openings with valves normally open to the side of the cooling jacket. 2. The piston cryogenic pump according to claim 1, characterized in that a vacuum gauge is used as the stopper of the vacuum casing. 3. The piston cryogenic pump according to claim 2, characterized in that the vacuum gauge is capacitive.

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