RU2329414C1 - Testing stand for hydraulic machines of fluid power drive - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: stand is intended for testing in production, operation and repair of hydraulic machines of fluid power drive. Stand consists of rotary drive, for instance, hydraulic, mechanically connected with regulated reversible loading hydraulic machine. This hydraulic machine is mechanically and hydraulically connected with tested hydraulic machine. Mechanical connection of rotary drive with loading hydraulic machine is arranged in the form of toothed gear, the free ends of shafts of which are equipped with couplings for connection with tested hydraulic machine. In hydraulic connection between tested and loading hydraulic machines, in parallel to the latter, at least one controlled throttle and hydraulic valve equipped with loading form setting device are installed, at that, hydraulic line of hydraulic valve control is supplied from head hydraulic line of rotary hydraulic valve, and drain is connected to non-loaded hydraulic line, which connects tested and loaded hydraulic machines.

EFFECT: reduction of production and operation costs.

4 cl, 4 dwg

Description

The invention relates to the field of mechanical engineering, in particular to technological equipment intended for use in the manufacture, operation and repair of hydraulic machines of volume hydraulic drive.

One of the most important stages in the production and repair of hydraulic machines, which consists in confirming the main characteristics of hydraulic machines, are tests carried out on special equipment - stands. The latter should satisfy a variety of requirements, for example, to allow them to retune their work for testing in various modes. As a rule, at one stand it is not possible to test volumetric hydraulic machines of various design and purpose. This circumstance leads to the creation of a number of specialized stands, for example, only for testing pumps or hydraulic motors. Separate test benches are required for testing axial hydraulic machines and radial type hydraulic machines, etc. So, for testing self-priming pumps, as a rule, stands with a throttle loading scheme are used [GOST 14658-86, p.9-10]. For testing hydraulic motors, stands are usually used using a hydraulic motor of a similar displacement with a regenerative loading scheme [GOST 20719-83, p.17].

The main disadvantage of the stands described above is that for testing hydraulic machines of various design and purpose, each time a specific narrow application stands are created, in particular, separate stands are created for testing pumps and hydraulic motors, axial and radial hydraulic machines, etc.

For the prototype, a stand with a regenerative loading circuit designed for testing adjustable hydraulic machines was selected. The shafts of the two tested hydraulic machines (pump and hydraulic motor) are interconnected. Their pressure and drain lines are respectively interconnected. The low-pressure make-up pump through the check valves delivers fluid to the drain line and thereby compensate for leaks. The pressure in the drain line is determined by the setting of the valve, which drains the excess working fluid into the tank. The rotation of the tandem of hydraulic machines is provided by a rotation drive rigidly connected with it, made in the form of an electric motor. Depending on which of the hydraulic machines is being tested, the other hydraulic machine is loading. In general, the loading of hydraulic machines is carried out by regulating the working volumes of these hydraulic machines [Yu.F. Ponomarenko, “Test of hydraulic transmissions,” M., Mechanical Engineering, 1969, p. 153].

The disadvantage of a stand with a recuperative loading scheme is a narrow area of use for the sizes of hydraulic machines, for the constructive type of machines, as well as for the type of tests performed.

The objective of the invention is the creation of a universal stand that allows you to experience volumetric hydraulic machines, both in design and purpose, regardless of whether these hydraulic machines are low or high speed, the use of a minimum number of hydraulic equipment and devices, simplifying reconfiguration for different loading modes and different types of tests.

A test bench is proposed for testing hydraulic machines of a volume hydraulic drive, which includes a rotation drive, for example, a hydraulic drive, mechanically connected to an adjustable reversible loading hydraulic machine. This hydraulic machine is mechanically and hydraulically connected to the tested hydraulic machine. The mechanical connection of the rotation drive with the loading hydraulic machine is made in the form of a gear transmission, the free ends of the shafts of which are equipped with couplings for connection with the tested hydraulic machine. At least one adjustable throttle and a control valve are provided in hydraulic communication between the test and the loading hydraulic machines, parallel to the latter, equipped with a setter for the loading law, while the control valve of the hydraulic control valve is powered from the pressure hydraulic control line of the hydraulic drive of rotation, and its discharge is connected to an unloaded hydraulic line connecting tested and loading hydraulic machines.

The gear transmission can be multistage, for example, in the form of an adjustable gearbox or in the form of a closed single-stage cylindrical gearbox, the high-speed shaft of which is connected with the loading hydraulic machine, and the low-speed one is connected with a rotation drive. In this case, the free ends of both shafts are equipped with couplings for connection with the tested hydraulic machine.

The unloaded hydraulic line of the tested hydraulic machine can be connected to the drain by means of a ball valve and a pressure valve installed parallel to each other.

The tested hydraulic machines are various pumps and hydraulic motors of domestic and foreign production.

The essential features are:

- firstly, the presence of a gear allows you to have at least two output shafts for connecting the shafts of the tested hydraulic machines - high-speed (low-torque) and low-speed (high-torque), which in turn allows you to test various types of hydraulic machines;

- secondly, installed in a hydraulic connection between the test and loading hydraulic machines, parallel to the latter, an adjustable throttle allows you to test hydraulic machines with high volumetric losses;

- thirdly, the installation of a hydraulic distributor between the loading and the tested hydraulic machines, equipped with a setter of the loading law, allows loading to be reversed without re-mounting the hydraulic lines, and also provides the required dynamic load characteristic with discrete switching on of the hydraulic distributor, which also helps to simplify reconfiguration;

- fourthly, the connection of an unloaded hydraulic line to the drain through a ball valve and pressure valve makes it possible to test both self-priming pumps and hydraulic motors requiring back-up on the drain.

Figure 1 - schematic diagram of a bench for testing hydraulic machines volumetric hydraulic actuator;

figure 2 is a schematic illustration of a gear transmission between a rotation drive and a loading hydraulic machine, made in the form of an adjustable gearbox;

figure 3 is an example of connecting a hydraulic machine - self-priming pump for testing;

figure 4 is an example of connecting a hydraulic machine - high-torque hydraulic motor for testing.

The test bench for volumetric hydraulic drive hydraulic machines consists of an adjustable hydraulic drive, including an adjustable hydraulic pump 1 connected through a pressure line 2, a filter 3, a check valve 4 and a distributor 5 with a hydraulic motor 6, which in turn is mechanically connected to a loading hydraulic machine 7, which is an adjustable hydraulic motor ( figure 1). The mechanical connection of the rotation drive 6 and the loading hydraulic machine 7 is made in the form of a gear transmission 8 (figure 2). The latter is a closed single-stage cylindrical gearbox, the high-speed shaft of which is connected to the shaft of the loading hydraulic machine 7, and the low-speed shaft is connected to the shaft of the hydraulic motor of the rotation drive 6. The free ends of both shafts of the gearbox are equipped with couplings 9 for connecting to the shaft of the tested machine 10. An adjustable throttle 11 is introduced into the hydraulic connection between the test and the loading hydraulic machines 10 and 7, parallel to the latter. In addition, a hydraulic distributor 12 is installed in the hydraulic connection between the said hydraulic machines. a setter of the law of loading, made in the form of a throttle block for adjusting the switching time (not shown), providing the required characteristic of the dynamic load with discrete on The hydraulic control line of the latter is supplied from the pressure hydraulic line 2 of the rotary actuator 6, and the drain is connected to an unloaded hydraulic line connecting the test and loading hydraulic machines 10 and 7. The unloaded hydraulic line of the tested hydraulic machine 10 is connected to the drain by means of a ball valve 13 installed in parallel to each other and a valve pressure 14. The pressure line of the pump 1 is connected to the drain through the safety valve 15, installed between the filter 3 and the pump 1.

The work of the stand showed on the example of testing a self-priming pump (figure 3).

The shaft of the pump under test 10 is connected via a coupling 9 to the high-speed shaft of the gearbox 8, which is directly connected to the hydraulic loading 7. The pressure hydraulic line of the pump 10 is connected to the high pressure hydraulic line of the loading circuit, and the suction hydraulic line of the pump 10 is connected to the low pressure hydraulic circuit of this circuit. The valve 13 is opened by connecting the suction pump hydraulic line directly to the hydraulic tank. Such a scheme allows testing the pump both in the self-priming mode and in the non-reversible hydraulic motor mode. In this case, in the first case (self-priming mode), the working volume of the loading hydraulic machine is set to be less than the working volume of the pump under test. In the second (non-reversible hydraulic motor mode) case, the working volume of the loading hydraulic machine must exceed the working volume of the pump under test.

In the first case, the tested hydraulic machine - pump 10, operates in a self-priming pump mode, the loading hydraulic machine 7 operates in the hydraulic motor mode. In this case, the load is created by reducing the working volume of the hydraulic machine 7 compared to the working volume of the pump 10. In the second case, the loading hydraulic machine 7 operates in the pump mode, and the pump 10 in the motor mode with minimal back up on the drain. Moreover, to create a load, the working volume of hydraulic machine 7 must exceed the working volume of pump 10. If the tested hydraulic machine - pump 10 has unstable operating characteristics, then to ensure stable loading of such hydraulic machines it is necessary to install an adjustable choke 11 in a special way, which opens by the amount necessary for load stabilization.

In contrast to the above, when testing high-torque hydraulic machines, for example, hydraulic motor 10, the tests are carried out with the valve 13 closed with a back-up on the drain of the hydraulic motor 10, determined by the setting of the pressure valve 14 (Fig. 4).

The proposed stand is universal, allows you to test volumetric hydraulic machines, both in design and purpose, regardless of whether these hydraulic machines are low or high-speed, allows you to use a minimum number of hydraulic equipment and devices, simplifies reconfiguration to different loading modes and different types tests.

Claims (4)

1. A test bench for volumetric hydraulic drive hydraulic machines, including a rotation drive, for example, hydraulic, mechanically connected to an adjustable reversible loading hydraulic machine, which is mechanically and hydraulically connected to the tested hydraulic machine, characterized in that the mechanical connection of the rotation drive is made in the form of a gear transmission, free ends the shafts of which are equipped with couplings for connection with the test hydraulic machine, and in hydraulic communication between the test and loading hydraulic machines, parallel to the last, At least one adjustable throttle and a control valve equipped with a master of the loading law have been installed, while the control valve of the control valve is powered from the pressure hydraulic control line of the hydraulic actuator, and the drain of the hydraulic actuator is connected to an unloaded hydraulic line connecting the test and loading hydraulic machines. 2. The stand according to claim 1, characterized in that the gear train is made in the form of a closed single-stage cylindrical gearbox, the high-speed shaft of which is connected with a loading hydraulic machine, and the low-speed one is connected with a rotation drive, while the free ends of both shafts are equipped with couplings for connection to the tested hydraulic machine . 3. The stand according to claim 1, characterized in that the gear transmission is multi-stage, for example, in the form of an adjustable gearbox. 4. The stand according to claim 1, characterized in that the unloaded hydraulic line of the tested hydraulic machine is connected to the drain by means of, installed parallel to each other, a ball valve and a pressure valve.

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