RU2088814C1 - Hydraulic system - Google Patents

Abstract

FIELD: mechanical engineering. SUBSTANCE: hydraulic system has pump connected with the tank through a coarse filter and with the hydraulic distributor through a fine filter, hydraulic cylinder with throttles, and drain and discharging pipe lines connected with the inlet of the cooling system, the sucking pipe line of which is positioned at 2/3 of the height of the tank. Heated fluid is sucked with an oil sucker through an oil pipe line. EFFECT: enhanced efficiency. 1 dwg

Description

 The invention relates to mechanical engineering, namely to hydraulic drives with closed circulation.

 A hydraulic system of a vehicle is known, comprising two hydraulic circuits, each of which is equipped with a pump, and a common tank, wherein the drain line of the high temperature circuit is connected to the inlet of the pump of the low temperature circuit through a throttle device and a heat exchanger installed in the drain line of the circuit.

 A disadvantage of the known hydraulic system is its high energy intensity, which consists in the fact that this system has two hydraulic circuits, each of which is equipped with a pump. Its other disadvantage is the complexity of execution and low reliability (ed. USSR N 1178972, class F 15 B 21/04, 1985). The closest in technical essence to the claimed hydraulic system is the hydraulic control circuit 5mm 107-62, the catalog of the cecast company, which has two hydraulic circuits, a pump system connected to a common tank through primary filters, and the working circuit pump delivers cooled hydraulic fluid through a fine filter purification, connected through a pressure line to the valve, and the throttle to the working body, and the spent hydraulic fluid enters the tank through the throttle and the valve, is connected with a drain line, which is equipped with a backup valve, and the cooling circuit pump is connected by its outlet to the inlet of the heat exchanger, the discharge of cooled hydraulic fluid from which is carried out through the backup check valve into a common tank.

 A disadvantage of the known hydraulic system is its high energy intensity, complexity of execution and low reliability during operation, which is due to the presence of two hydraulic circuits in the system, each of which is equipped with a pump, as well as the fact that the spent hydraulic heated fluid flows directly into the tank, from where it is taken by the cooling pump passes through the heat exchanger and then enters the tank.

 The technical problem to which this invention is directed is to increase the reliability and reduce the power consumption of the hydraulic system by simplifying the cooling system.

 This problem is solved in such a way that a hydraulic system containing a pump connected through a coarse filter with a tank, and through a fine filter with a hydraulic distributor, throttles with a hydraulic cylinder, a heat exchanger, a check valve and a drain line installed in series, contains one hydraulic circuit, and the drain and the drainage line is connected to the entrance to the cooling system, the intake line of which is located at 2/3 of the height of the tank, while the intake of the heated hydraulic fluid from the tank is carried out by a float oil intake through the oil line.

 The following features are new in the claimed technical solution: the hydraulic system contains one hydraulic circuit, the drain and drain lines are connected to the entrance to the cooling system, the intake line of the cooling system is located at 2/3 of the tank height, the presence of a float oil intake with an oil pipe.

 The use of a single hydraulic circuit in the hydraulic system can significantly simplify the cooling system, since this eliminates the electric pump from its design. The connection of the drain and drain lines with the inlet to the cooling system makes it possible to supply the exhausted heated fluid to the tank only through a heat exchanger.

 The presence of a float-operated oil intake with an oil pipe ensures the circulation of the hydraulic fluid in an inoperative state, due to which it is forcedly cooled.

 With the installation of the cooling system at a level 2/3 of the tank height, there is no need to install a backup valve in the drain line of this system, which controls the filling of the hydraulic system. In addition, this arrangement of the cooling system in the hydraulic system eliminates the need for an electric pump from the design.

 Thus, all of the above features can significantly simplify the cooling system, which generally increases the reliability and reduces the energy consumption of the claimed hydraulic system and meets the criteria of the invention of "novelty."

 The invention is illustrated in the drawing, which shows a diagram of a hydraulic system.

 The hydraulic system consists of a pump 1 connected through a coarse filter 2 to a tank 3, and through a fine filter 4, a pressure line 5, a check valve 6, a control valve 7 with a hydraulic cylinder 8. Depending on the position of the control valve 7, the hydraulic fluid is supplied to the hydraulic cylinder 8 through throttles 9 or 10. The spent fluid through the drain line 11, the non-return valve 12, the heat exchanger 13 or through the non-return valve 14 is discharged into the tank 3. The drain from the valve 7 and from the pump 1 is discharged through the drain lines 15 and 16. The cooling system The refrigeration system has a coolant 17 supply line to the heat exchanger 13 and its discharge line 18. To collect the heated hydraulic fluid from the tank 3, the cooling system is equipped with a float oil intake 19, an oil pipe 20 and a intake line 21, and the cooled hydraulic fluid is drained from the heat exchanger 13 through the drain line 22.

 The hydraulic system works as follows.

 The pump 1 through the coarse filter 2 picks up the hydraulic fluid from the tank 3 and through the fine filter 4 delivers it to the pressure line 5, the check valve 6 in the valve 7, and from there through the throttles 9 or 10 (depending on the position of the valve in the valve 7) it enters the hydraulic cylinder 8. Next, the spent fluid passes through the drain line 11 and through the check valve 12 enters the heat exchanger 13, from where it drains into the tank 3 through the drain line 22. During the operation of the hydraulic system, the drainage hydraulic fluid from pump 1 and the hydraulic distribution The unit 7 is discharged through the drain lines 15 and 16 into the cooling system.

 During the shutdown of the hydraulic system, the fluid continues to cool due to convection. Using the float oil intake 19, the hydraulic fluid enters the heat exchanger 13 through the oil line 20, and then again through the line 22 to the tank 3. Thus, the hydraulic fluid is constantly circulated and cooled. Moreover, the higher the temperature of the fluid, the more intense the circulation. When the temperature of the liquid and refrigerant are equalized, the circulation stops. To drain excess fluid in emergency cases, the heat exchange system is equipped with a check valve 14 with a spring.

 The heat exchanger 13 is installed near the tank 3 so that the intake line 21 is located at 2/3 of the height of the tank (the standard minimum permissible level of hydraulic fluid in the tank), and the drain line 22 is at a level that drains the hydraulic fluid from the heat exchanger 13 into the tank 3 by gravity.

Claims (1)

 A hydraulic system comprising a pump connected through a coarse filter to a tank, and through a fine filter to a control valve, throttles with a hydraulic cylinder, a drain and drain line connected to a cooling system, characterized in that the drain and drain line are connected to the entrance to the cooling system, the intake line of which is located at 2/3 of the height of the tank, while the intake of the heated hydraulic fluid is carried out by a float oil intake through the oil pipe.