RU2213264C2 - Cryogenic pump test stand - Google Patents

Abstract

FIELD: cryogenic engineering. SUBSTANCE: proposed stand contains loading device arranged in pressure main line. Stand is furnished also with auxiliary reservoir and gas burner. Drain systems of service and auxiliary reservoirs are connected with gas burner. Pressure main line is furnished with pipeline communicating with gas space of auxiliary reservoir. Heat exchanger is installed in pressure main line. Heat exchanger is arranged before pipeline. EFFECT: reduced cost of testing. 2 cl, 1 dwg

Description

 The invention relates to stands for testing pumps on a liquid cryogenic working fluid and can be used primarily for life tests of pumps using liquefied natural gas.

 A well-known universal installation for testing pumps, containing a tank with fuel and connected to it a suction and discharge lines connected to the pump under test (E.L. Solokhin. Tests of aircraft jet engines. M.: Engineering. - 1975. S. 210, Fig. 5.21).

 The disadvantage of this installation is the low cost-effectiveness of testing due to the loss of a large amount of the working fluid and the clogging of the environment by the vapor of the working fluid.

 The closest to the described stand by technical essence is a stand for testing pumps with a closed hydraulic system for circulating the working fluid, containing a supply tank, a suction and pressure lines connected to it, connected to the test pump and a heat exchanger (SU 979701 A, IPC F 04 V 51/00 , 1981).

 The disadvantage of this stand is also the low cost of testing due to the loss of a large amount of the working fluid and clogging of the environment by the vapor of the working fluid.

 The objective of this technical solution is to increase the cost-effectiveness of testing cryogenic pumps at the bench by making better use of the energy of the working fluid.

 The problem is solved in that the well-known test bench for pumps, containing a supply tank, connected to it a suction and pressure lines connected to the pump under test, and a heat exchanger, further comprises a loading device, an auxiliary tank and a gas burner, while the drainage system of the supply and auxiliary tanks communicated with the gas burner, the pressure line is equipped with a pipeline in communication with the gas volume of the auxiliary tank, the heat exchanger and the loading device are placed in the pressure line, and in that the heat exchanger is placed in front of the conduit.

 In known technical solutions, features similar to the features. distinguishing the claimed technical solution from the prototype, not found.

 The drawing shows a simplified schematic diagram of the proposed stand for testing cryogenic pumps.

 The stand contains a supply tank 1, a suction 2 and pressure 3 pipes connected to it, connected to a test pump 4, a heat exchanger 5, a loading device 6, an auxiliary tank 7 and a gas burner 8.

 The supply tank 1 has a pipeline 9 with a shut-off element 10 for filling it with a working fluid from the store through a pipe 11 with a shut-off element 12 and supplying it to the suction line 2 when the stand is operating, a gas pressurization system 13 with a shut-off element 14 and a working fluid vapor drainage system 15 and boost gas, equipped with a shut-off 16 and safety 17 bodies. The suction line 2 has a shut-off body 18, a flow meter 19 for determining the flow characteristics of the test pump 4, a continuity flow sensor 20, a working fluid cleaning filter 21, and instrumentation 22 for monitoring and measuring the working fluid parameters. The pressure line 3 has a locking element 23 and 24, a sensor 25 for the continuity of the flow of the working fluid. a flow meter 26 for determining the flow characteristics of the test pump 4 and instrumentation 27, 28 for monitoring and measuring the parameters of the working fluid. It is equipped with a pipe 29 in communication with the gas volume of the auxiliary tank 7. The pipe 29 has a shut-off element 30. The heat exchanger 5 and the loading device 6 are placed in the pressure line 3 in front of the pipe 29. The auxiliary tank 7 has a pipe 31 with a shut-off element 32 for moving the working fluid in storage through a pipeline 33, a gas pressurization system 34 with a shutoff member 35 and a system 36 for drainage of the vapor of the working fluid and pressurization gas, equipped with a shutoff 37 and a safety 38 bodies.

 The stand works as follows. In the initial position of the stand, all locking and safety organs are closed, and the loading device is open. At the command of the control panel, the locking elements 10, 12 and 16 are opened, as a result of which a liquid cryogenic working fluid, for example, liquefied natural gas, from the storage through pipelines 11 and 9 starts to flow into the supply tank 1. Part of the working fluid evaporates in it, giving off cold her. Vapors of the working fluid from its gas volume through the open valve of the shut-off member 16 and the pipeline 39 enter the gas burner 8 and burn. After filling the supply tank 1 with the working fluid, the locking elements 10, 12 and 16 are closed. Then, upon a command from the control panel, the locking bodies 10, 14, 18, 23, 30 and 37 are opened, as a result of which the working fluid from the supply tank 1 under gas pressure the charge entering through the pipe 13 and the open valve of the shut-off element 14 begins to flow into the suction line 2, and from there through the test pump 4 to the pressure line 3. Part of the working fluid evaporates in them, taking heat from them. The mixture of liquid and gaseous phases of the working fluid through the open valve of the shut-off element 30 through the pipe 29 enters the auxiliary tank 7. In it, the liquid phase of the working fluid is separated from its gaseous phase and remains in its liquid volume, and the gaseous phase through the open valve of the shut-off element 37 enters into a gas burner 8 and burns out. After the cooling of the design of the suction 2 and pressure 3 lines and the test pump 4, that is, when lowering the temperature of their internal cavities to a control value, the shut-off element 24 opens, the test pump 4 starts, the heat exchanger 5 and the loading device 6 are turned on. As a result, the working fluid begins to cool in the heat exchanger 5 with a liquid cryogenic refrigerant, for example liquid nitrogen, and enter the suction line 2. Changing the operating modes of the test pump 4 is carried out by loading by the device 6. After the test of the test pump 4 is completed, the shut-off bodies 10, 14, 18, 23, 24, 30 and 37 are closed. Then the shut-off bodies 32 and 35 are opened, as a result of which the working fluid from the auxiliary tank 7 is pressurized with boost gas supplied through the open valve of the locking member 35, merges through the open valve of the locking member 32 in the store. After emptying the auxiliary tank 7, the shut-off bodies 32 and 35 are closed. Then the shut-off bodies 16 and 37 are opened, as a result of which the boost gas from the supply 1 and auxiliary 7 containers is vented to the atmosphere through the open valves of the shut-off bodies 16 and 37 and the gas burner 8. After that locking elements 16 and 37 are closed.

 Using the proposed test bench for cryogenic pumps using liquefied cryogenic fuel reduces the cost of testing, which, for example, when used to refine new samples of components and assemblies of aircraft engines, reduces fuel and energy costs and eliminates atmospheric pollution by cryogenic fuel.

Claims (2)

 1. A test bench for cryogenic pumps, comprising a supply tank, a suction and pressure line connected to it, connected to the pump under test, and a heat exchanger, characterized in that it further comprises a loading device, an auxiliary tank and a gas burner, while the drainage system of the consumable and auxiliary the tanks are connected to the gas burner, the pressure line is equipped with a pipeline in communication with the gas volume of the auxiliary tank, the heat exchanger and the loading device are placed in the pressure head th line.  2. The stand under item 1, characterized in that the heat exchanger is placed in front of the pipeline.