RU205557U1 - STAND FOR STUDYING THE WORK OF THE HYDRAULIC DRIVE - Google Patents

Abstract

The utility model refers to devices for testing hydraulic mechanisms, namely hydraulic drives. The purpose of the claimed utility model is to develop a stand for the study of closed hydraulic transmissions, which allows testing the ejector and pneumatic accumulator as part of this scheme. which is a closed hydrostatic circuit containing a hydraulic pump with a drive motor connected to the filter, a safety valve communicating a pressure hydraulic line connected to the hydraulic pump, with a drain hydraulic line connected to the hydraulic tank, a throttle connected to the inlet of the hydraulic distributor, to the working outlets of which the hydraulic cylinder is connected, in the drain hydraulic line is a pneumatic accumulator with a filling device, pressure sensors, a temperature sensor, characterized in that it additionally contains an ejector pump located after the pneumatic accumulator and connected to the hydraulic a tank, made sealed, and additionally contains a flow regulator with a flow meter connected to it, located at the filter outlet. The declared stand for studying the operation of a hydraulic drive can be used in research and educational laboratories studying hydraulic mechanisms. In particular, using the proposed stand, it is possible to study the operation of hydraulic transmissions described in patents RU 195329 and RU 195330, as well as others, similar to them, made separated from the atmosphere.

Description

The utility model relates to devices for testing hydraulic mechanisms, namely hydraulic drives.

A known stand for testing hydraulic transmissions (copyright certificate SU 1094942, dated 05/30/1984), containing the tested hydraulic transmission, the input and output shafts of which are connected to one of the ends of the through shafts, respectively, of the drive and brake balancing machines with torque sensors. The stand is equipped with additional drive and brake machines with torque sensors connected to the other ends of the through shafts of the balancing machines. However, the known stand does not allow testing a closed hydraulic transmission containing an ejector and a pneumatic accumulator, as well as a hydraulic motor in the form of a hydraulic cylinder.

The closest is a stand for studying the operation of a hydraulic drive (RF patent 128262, dated 05/20/2013), including a tank, a filter, an adjustable hydraulic pump with a drive motor, pressure and drain lines, a hydraulic valve, a loading device and a measuring system including pressure, flow and temperature sensors ... The loading device is made of three independent devices: a hydraulic motor for rotary movement, a hydraulic motor for translational movement and a brake hydraulic system, an "or" valve is included in the pressure line, which separates the work of hydraulic motors and a brake pneumatic hydraulic system, while each hydraulic motor at the input has its own hydraulic valve and throttle regulating the operation of these engines. However, the well-known stand also does not allow testing a closed hydraulic transmission, which includes an ejector and a pneumatic accumulator.

The purpose of the claimed utility model is to develop a stand for the study of closed hydraulic transmissions, which allows testing the ejector and pneumatic hydroaccumulator as part of this scheme.

This goal is solved by the fact that a stand for studying the operation of a hydraulic drive, which is a closed hydrostatic circuit containing a hydraulic pump with a drive motor connected to the filter, a safety valve that communicates a pressure hydraulic line connected to the hydraulic pump, with a drain line connected to the hydraulic tank, a throttle connected with the inlet of the hydraulic valve, to the working outlets of which the hydraulic cylinder is connected, in the drain line there is a pneumatic accumulator with a filling device, pressure sensors, a temperature sensor, characterized in that it additionally contains an ejector pump located after the pneumatic accumulator and connected to the hydraulic tank, made sealed, and also contains a flow regulator with a flow meter connected to it, located at the filter outlet.

The stand in particular can be characterized in that it additionally contains a microcontroller.

The stand in particular can be characterized in that it further comprises a thermostat in communication with a heat exchanger.

The stand in particular can be characterized in that it additionally contains a measuring container located downstream of the flow regulator.

The stand, in particular, can be characterized in that it additionally contains pressure gauges, which can be located after the hydraulic pump, before the hydraulic pump, or after the flow regulator, the pneumatic accumulator can be equipped with a pressure gauge.

The stand can in particular be characterized in that it further comprises valves.

FIG. 1 shows the hydraulic diagram of the stand for studying the operation of the hydraulic drive, where the numbers indicate: hydraulic pump (1), engine (2), filter (3), safety valve (4), pressure line (5), drain line (6), hydraulic tank (7 ), throttle (8), hydraulic valve (9), hydraulic cylinder (10), pneumatic accumulator (11), filling device (12), pressure sensors (13, 14, 15), temperature sensor (16), ejector pump (17), flow regulator (18), flow meter (19), thermostat (20), heat exchanger (21), measuring vessel (22), manometers (23, 24, 25, 26), valves (27, 28, 29, 30, 31 , 32), microcontroller (33).

The stand for studying the operation of a hydraulic drive is designed as follows: a hydraulic pump (1) with a drive motor (2) creates pressure in the pressure head line (5). The drive motor is connected to a filter (3), at the outlet of which there is a flow regulator (18) with a flow meter (19) connected to it. The safety valve (4) connects the pressure line with a return line (6) connected to the hydraulic tank (7). The throttle (8) supplies the working fluid to the inlet of the hydraulic valve (9), to the working outlets of which the hydraulic cylinder (10) is connected. A pneumatic accumulator (11) with a filling device (12) is located in the drain line. After the pneumatic accumulator, the liquid passes the ejector pump (17), which is connected to the hydraulic tank. Also in the drain line, up to the pneumatic accumulator, there is a thermostat (20) connected to the heat exchanger (21).

The stand for studying the operation of the hydraulic drive contains a number of measuring instruments: a pressure sensor (13) located before the hydraulic pump; a pressure sensor (14) located after the flow meter (19) connected to the flow regulator; and a pressure sensor (15) connected to the pneumatic accumulator. Electrical signals from the pressure sensors and the flow meter are fed to the microcontroller inputs (33). The temperature sensor (16) is located in the drain line, before the hydraulic pump. After the flow regulator, with the valve (27) closed and the valve (28) open, the working fluid enters the measuring container (22). Also in the circuit there is a pressure gauge (23) located after the hydraulic pump; pressure gauge (24) located downstream of the flow regulator; the pressure gauge (25) of the pneumatic accumulator and the pressure gauge (26) located before the hydraulic pump. The hydraulic tank inlet contains a valve (30), the hydraulic tank outlet contains a valve (32), the hydraulic tank outlet contains a valve (29), and a valve (31) is located in the hydraulic tank bypass line.

The stand for studying the operation of the hydraulic drive works as follows: when power is supplied to the engine, the hydraulic pump converts the motion energy of the input link (electric motor shaft) into the energy of the compressed fluid flow. The working fluid goes through the hydraulic line through the filter and passes the throttle, which creates resistance to provide the required pressure and increase the temperature in the pressure hydraulic line. Pressure control in the pressure head line can be carried out using a pressure gauge (23). After the throttle, the working fluid enters the hydraulic valve, which controls the change in the direction of the fluid flow for the purpose of switching on, off and reversing the hydraulic motor-hydraulic cylinder. The hydraulic cylinder converts the energy of the working fluid flow under pressure into the translational movement of the output link (rod). After the hydraulic cylinder, the working fluid flows through the thermostat, and when the temperature rises above the optimum, it passes through the heat exchange apparatus necessary for cooling the fluid, since the temperature effect of the fluid can introduce errors in the operation of the instruments that make up the stand. Further, the liquid flow enters the tank, made in the form of a pneumatic hydroaccumulator. It is necessary to accommodate the difference in the volumes of the piston and rod cavities of the hydraulic cylinder ΔV _Hz , temperature increments of the volumes of the working fluid V ' _gp and maintain the required back pressure in the drain line. The creation of a minimum overpressure in the pneumatic accumulator, which can be controlled by a pressure gauge (25), is carried out using a compressor or a pump through a filling device. The pneumatic accumulator is used with membrane separation of media, since the membrane separates the gas and liquid cavities, therefore, when pressure arises on the gas cavity, the gas does not dissolve in the liquid. The working fluid after the pneumatic accumulator enters the ejector pump. With the help of an ejector pump, drainage leaks from the pump and hydraulic motor are returned to the hydraulic line, which is under excess pressure. The stand simulates drainage leaks using a flow regulator. The presence of a flow regulator makes it possible to regulate the flow rate of a fluid that simulates leaks, which makes it possible to check the operation of a hydraulic drive with pumps of varying degrees of wear and different volumetric efficiency. After the flow regulator, with the valve (27) closed and the valve (28) open, the volumetric flow rate of the liquid is monitored by a flow meter and a measuring container, and the pressure is checked using a pressure gauge (24). The use of valves makes it possible to check various components of the circuit (or their layout) by disconnecting certain parts of it in order to direct the flow of the working fluid through the tested components of the hydraulic drive.

In the ejector pump, using the kinetic energy of the flow (working), the liquid (passive) is sucked from the drainage hydraulic lines into the hydraulic drive circuit, which is under pressure exceeding the pressure in the drainage simulation line.

It is advisable to install an ejector pump after the pneumatic accumulator, which makes it possible to ensure the stable operation of the ejector pump, since the flow rate differences are absorbed by the pneumatic accumulator. Flow differences arise due to the difference in the volumes of the rod and piston cavities of the hydraulic cylinder: when extending the rod, the difference is maximum, when retracted, it is minimal.

Also, the stand for studying the operation of the hydraulic drive provides for the shutdown of the hydraulic tank to check the operation of the hydraulic drive without it. In this case, the valve (32) and the valve (30) are closed, and the valve (31) opens, and the working fluid circulates in a closed loop, bypassing the hydraulic tank.

To ensure the process of testing closed hydraulic transmissions, the stand may include a microcontroller, for example, of the ATmega328P type. The microcontroller collects signals from pressure sensors and a flow meter and processes them by sending data to a personal computer. Thus, it is possible to carry out not only testing, but also the collection and accumulation of data, for the purpose, for example, of their subsequent analysis, to determine the most optimal parameters of the test bench components, including such as an ejector pump and a pneumatic accumulator.

The use of a research stand as a study of the operation of a closed hydraulic drive allows you to create an efficient hydraulic transmission isolated from the atmosphere and, using pressure gauges, pressure and temperature sensors, and other measuring devices, to investigate the processes during its operation. The creation of a closed hydraulic transmission is achieved through the use of a hydraulic tank separated from the atmosphere; for this, an ejector pump is included in the circuit, working in tandem with a pneumatic hydraulic accumulator and ensuring its operability. The study of the ejector operation is achieved through the use of a flow meter connected to a flow regulator to simulate leaks standing in the drain line. Also, the operation of the ejector pump is tested using pressure sensors and manometers in front of the ejector pump, in the drain line that goes to the ejector pump and at the outlet of the ejector pump, in the suction line of the hydraulic pump.

Thus, the use in the stand for studying the operation of a hydraulic drive, an ejector pump located after a pneumatic hydroaccumulator and connected to a pressure-tight hydraulic tank, as well as measuring instruments, in particular, a flow meter, makes it possible to achieve the claimed technical result, namely, the development of a stand for the study of closed hydraulic transmission, which allows testing the ejector and pneumatic hydroaccumulator.

Industrial applicability.

The claimed stand for studying the operation of a hydraulic drive can be used in research and educational laboratories studying hydraulic mechanisms. In particular, using the proposed stand, it is possible to study the operation of hydraulic transmissions described in patents RU 195329 and RU 195330, as well as others, similar to them, made disconnected from the atmosphere.

Claims (10)

1. A stand for studying the operation of a hydraulic drive, which is a closed hydrostatic circuit containing a hydraulic pump with a drive motor connected to a filter, a safety valve communicating a pressure hydraulic line connected to the hydraulic pump, with a drain hydraulic line connected to the hydraulic tank, a throttle connected to the inlet of the hydraulic distributor, a hydraulic cylinder is connected to the working outlets of which a hydraulic cylinder is connected, in the drain hydraulic line there is a pneumatic accumulator with a filling device, pressure sensors, a temperature sensor, characterized in that it additionally contains an ejector pump located after the pneumatic accumulator and connected to a hydraulic tank, made sealed, and also additionally contains a flow regulator with a connected to it with a flow meter located at the filter outlet. 2. The stand according to claim 1, characterized in that it further comprises a microcontroller. 3. The stand according to claim 1, characterized in that it further comprises a thermostat in communication with the heat exchanger. 4. The stand according to claim 1, characterized in that it further comprises a measuring container located after the flow regulator. 5. The stand according to claim 1, characterized in that it additionally contains pressure gauges. 6. The stand according to claim 5, characterized in that the pressure gauge is located after the hydraulic pump. 7. The stand according to claim 5, characterized in that the pressure gauge is located before the hydraulic pump. 8. The stand according to claim 5, characterized in that the pressure gauge is located after the flow regulator. 9. The stand according to claim 5, characterized in that the pneumatic accumulator is equipped with a pressure gauge. 10. The stand according to claim 1, further comprising valves.

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