SU574554A1 - Volumetric hydraulic drive - Google Patents

Description

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The invention relates to volumetric hydraulic actuators of traction machines.

A volumetric hydraulic drive is known, comprising a main unregulated pump and a hydraulic motor connected in a closed circuit for circulating the working fluid, a two-stage safety hydraulic valve consisting of a main valve, control valve and throttles, and a make-up system consisting of a subpoint pump, tank and overflow valve connected by hydrolines 1.

In the known volumetric hydraulic actuator, when operating in stop mode, i.e., when the overpressure level in the pressure hydraulic line of the closed loop is reached above the level determined by the setting of the safety valve, the flow of the pump from the hydraulic line to the drain is throttled.

Thus, in the stop mode, all the energy supplied to the closed-circuit pump is transferred to heat due to throttling of the fluid flow through the safety valve, which creates the danger of overheating of the hydraulic system of the drive.

The aim of the invention is to prevent overheating of the hydraulic system when the hydraulic motor stalls.

This is achieved by connecting a normally-open hydraulic valve to the drainage of a closed loop, the control cavities of which are connected to the control cavities of the two-stage safety valve, and an additional hydraulic overflow valve to communicate with the tank of the closed-loop drain line connected between the hydraulic motor and the normally open hydraulic valve.

The drawing shows the principle hydraulic scheme of the described volumetric hydraulic drive.

The volumetric hydraulic drive contains an unregulated pump 1, the pressure main line of which is connected by hydraulic lines 2-4 with a safety valve 5 of indirect action, as well as a hydraulic motor 6. The hydraulic line 6 of the hydraulic motor 6 is connected with a normally open hydraulic valve 8. Hydroline 9 hydraulic valve 8 is connected pump suction mains 1.

The hydraulic lines 10 and the control cavities of the hydraulic valve 8 are connected to the inlet and the outlet of the throttles 12 of the control of the safety hydraulic valve 5.

By hydraulic line 13, the drain line of the safety valve 5 is connected to the suction main line of the pump 1. R

As a result of this connection, the pump 1, the hydraulic motor 6 and the hydraulic valve 5 are provided with their parallel connection, creating a closed loop of the working fluid flow. In order to replenish the closed circuit with the working fluid, a feed pump 15 is connected to the suction main 9 of pump 1 via hydraulic line I, the suction line of which is connected to the hydraulic tank 16.

Hydraulic lines 9 and 13 with hydraulic lines 17 are connected to an overflow hydraulic valve 18, which is adjusted to maintain a given level of overpressure from pump 15 in hydraulic lines 9 and 13, and this pressure level is set equal to the setting value of the safety hydraulic valve 5. To hydraulic line 7 by hydraulic line 19 an overflow hydrovalve 20 is connected, which is tuned to maintain in hydrolines 7, 9, 13 and 14 the minimum back pressure necessary for normal operation of the pump 1 and the hydraulic motor 6.

The hydraulic pump 15, the overflow hydraulic valves 18, 20 and the hydroline and 14 and 17 form a system for feeding the closed circuit of the hydraulic drive.

The hydraulic drive works in the following sequence: preparation for start-up, start-up, work in nominal mode, stop mode.

Preparation of the hydraulic drive for start-up consists in starting from the individual motor of the makeup pump 15, which, taking the working fluid from the hydraulic tank 16, forces it in the hydraulic lines 9, 7, 13, 19 to the level of overpressure determined by setting the overflow hydraulic valve 20.

After the make-up pump 15 reaches the overpressure level, the tray of said pump will be returned to the hydraulic tank 16 via valves 8 and 18. This completes the preparation for starting the hydraulic drive.

Upon completion of the preparation, the hydraulic drive is started up, for which the pump 1 of the closed circuit is activated from the individual engine, which, taking the working fluid from the hydraulic line 9, pumps it into the hydraulic line 2-4 and thereby supplies it to the input of the hydraulic motor 6.

The level of overpressure developed by pump 1 is determined by the load on the hydraulic motor 6. So, if the resistance moment on the hydraulic motor 6 does not exceed the torque developed by the hydraulic motor determined by its displacement and maximum differential pressure in hydraulic lines 4 and 7, then all the power supplied from the pump 1 to the hydraulic motor 6 is used to perform external work — the operating mode of the hydraulic drive begins.

The maximum differential on hydromotor 6 is determined by the difference in the settings of the hydraulic valves 5 and 20.

If the resistance moment on the hydraulic motor exceeds its maximum torque, determined by the difference in settings of the hydraulic valves 5 and 18, the hydraulic motor 6 stops and the hydraulic drive goes into stop mode.

The operation of the hydraulic drive in the stoneware mode is as follows. Upon reaching overpressure in hydroline 3 to the level of setting valve 21 of the first stage of safety valve 5

the latter opens and the flow appears through the choke 12 and, consequently, the pressure drop across it.

The differential pressure on the throttle 12 causes the opening of the valve 22 of the second stage

hydrovalve 5, as a result of which hydrolines 2, 3 and 13 are combined, and the hydrovalve 8 is closed, as its cavities communicate with the inlet and outlet of throttles 12 with hydrolines 10 and 11. As a result of closing the hydrovalve 8, the make-up pump 15 raises the overpressure to determined by the setting of the overflow valve 18, and since its level of adjustment is equal to the level set up by the valve 5,

pressure in hydrolines 2, 3, 13, 9, 14, 17 is equalized.

The absence of pressure difference between the outlet and the inlet in pump 1 leads to a reduction in power consumption from the drive motor of pump 1 to the level due to the efficiency of pump 1 and losses in the hydraulic system consisting of hydraulic lines 2, 3.13 and hydraulic valve 5. Hydraulic motor 6 in the stop the mode will be

develop a maximum moment, and the power of the make-up pump 15 can be realized on it, and its operation will be carried out according to the open circuit of circulation of the working fluid, i.e. with circulation through the hydraulic tank 16. After the moment of resistance on the hydraulic motor 6 falls to a value below maximum, due to a decrease in pressure in the hydrolines 4, 3, 2 below the setting level of the hydraulic valve 5, the valve 21 is closed, on

throttle 12 pressure equalizes due to the absence of flow on it. At the same time, the hydraulic valve 21 is closed, and the hydraulic valve 8 is opened, and the hydraulic drive switches to the nominal mode of operation.

Claims (1)

Invention Formula A volumetric hydraulic drive containing a main unregulated pump and a hydraulic motor connected to a closed circulation contour a working fluid, a two-stage safety valve, consisting of a main valve, a control valve and throttles, as well as a make-up system, consisting of a make-up pump, a tank and an overflow hydraulically connected valves, which are tactile, in order to prevent hydraulic system from overheating when the hydraulic motor is stopped, a normal-open hydraulic valve is connected in series to the hydraulic drainage of the closed valve, the control cavities of which are connected to the control cavity of the two-stage safety valve, and additional hydroclan overflow for communication with the tank closed loop lines connected between a hydraulic motor and a normally open hydrovalve. Itotochnnknn information used in the examination during the examination 1. Rogov A. Ya. And others. Hydraulic drives of rotary motion for mining machines, L, TsIPE.Mugol, 1972, p. 15, 5.