SU1613711A1 - Automatic device for charging hydraulic accumulator - Google Patents

Abstract

The invention relates to mechanical engineering hydraulic drive and can be used in pumping stations of constant pressure hydraulic systems and in steering systems of vehicles. The aim of the invention was to increase efficiency by reducing leakages from the hydraulic accumulator when unloading the power source. The hydroaccumulator charging machine contains a spring-loaded hydraulically controlled overflow valve 1, connected by input 2 to power supply 3 and output 4 to drain line 5, and control unit 6, having control input 7, communicated with accumulator 8 and charging level limiting device 9 dki gidroakkumul torus. The device 9 for limiting charging levels of the hydroaccumulator is provided with a ball locking element 19 placed between the first 20 and second 21 seats mounted coaxially with the spool 12. The opening cross section of the opening 24 of the first saddle 20 is larger than the cross sectional area of the spool 12, which, in turn, is larger than the through passage sections of the hole 23 of the second saddle 21. When the pressure in the pressure hydraulic line 26 is exceeded, the spool 12 switches to a position that allows the cavity 18 of the overflow valve 1 to communicate with the drain pipe 5, and the power source 3 discharged. When the pressure in the pressure line 26 drops below a certain level, the spool 12 is switched to a position that stops the communication of the cavity 18 of the overflow valve 1 with the drain line 5 and connects the power source 3 to the pressure line 26. The invention provides more efficient control of the overflow valve 1, and fewer locking elements - greater tightness. 1 il.

Description

The invention relates to mechanical engineering hydraulic drive and can be used in pumping stations of constant pressure hydraulic systems and in steering systems of vehicles.

The purpose of the invention is to increase the efficiency of operation by reducing leakages from the hydroaccumulator during unloading of the power source.

The drawing shows the structure of the proposed hydroaccumulator charging machine.

The hydroaccumulator charging machine contains a spring-loaded hydraulically controlled overflow valve 1, connected by input 2 to power supply 3 and output 4 to drain line 5, and control unit 6. The latter has a control input 7 communicated with the Vis hydroaccumulator by the device 9 limiting the hydroaccumulator charging levels.

In the cylindrical hole 10 of the housing 11 is placed a spool 12 having a radial 13 and axial 14 channels, the last of which communicates with the spring cavity 15 of the spool 12. The spool 12 is also placed in the housing 11 to form the hydraulic cavity 16. The cylindrical hole 10 of the housing 11 the bore 17 is connected to the spring cavity 18 controlling the overflow valve 1, and the spool 12 is installed in the cylindrical bore 10 of the housing 11 with the possibility of connecting the radial channel 13 to the bore 17 of the housing 11. The device 9 limits the charging levels the hydroaccumulator of the torus is equipped with a ball locking element 19 placed between the first 20 and second 21 seats installed in the housing 11 coaxially to the spool 12. The locking element 19 through the spool 12 spring 22 is pressed to the second saddle 21. The hole 23 of the second saddle 21 is reported to the input 7 of the control unit 6 controls Spring cavity 15 of spool 12 is connected to drain hydroline 5, and the flow area of the opening 24 of the first saddle 20 is larger than the cross section of the spool 12 that is larger than the flow section of the opening 23 of the second saddle 21. The power supply 3 is connected through a non-return valve 25 to the hydraulic accumulator 8, connected to the pressure line 26 of the system.

0 Automatic charging of the hydroaccumulator of the torus works as follows.

When the system is inoperative, the automatic charging device under pressure of the spring 22 ensures that the spool 12 and the locking element 19 are in the extreme right position, which corresponds to the closure of the overflow valve 1.

When the power source 3 is put into operation, the working fluid is supplied to the pressure hydroline 26 and the hydraulic Q battery 8. The overflow valve 1 is in the closed position until the pressure in the pressure hydraulic line 26 reaches the limit value due to the setting of the control unit 6.

Upon reaching the pressure line

5 26 and in the hydroaccumulator 8 of the limiting pressure, the locking element 19 opens. When opened, due to the setting of the spring 22, the spool 12 moves to the left, and the locking element 19 moves to the left until it goes down to the first saddle 20. At the same time, the spool 12 is displaced and its radial channel 13 is connected to the bore 17. This leads to the connection of the spring cavity 18 of the overflow valve 1 with the drainage line 5 of the system, which opens the overflow valve 1 and unloads the power supply source 3, and Stem provided powered torus pressure reservoir 8. By reducing the pressure in napor0

The hydraulic line 26 and the accumulator 8 to a certain level switch the spool 12 to the previous position, and the locking element 19 sits on the second seat 21. The drain from the spring cavity 18 of the overflow valve 1 stops and the valve 1 disconnects the power source 3 from the drain hydraulic line 5 The power source 3 begins to supply the working fluid under pressure to the pressure line 26.

Since the bore 24 of the first saddle 20 is larger than the cross-sectional area of the spool 12, which is larger than the bore of the 23 second bore 21, opening the locking element 19 when it is pressed against the second saddle 21 causes the spool 12 to move automatically to the left, since the area of the spool 12 is larger than the area of the hole 23 of the second seat 21, and the movement will continue until the locking element 19 is not with the children on the first seat 20.

When opening the passage 24 of the first saddle 20 by the locking element 19, which is caused by a decrease in pressure in the pressure line 26 of the system (discharge of the hydroaccumulator 8), there is a sharp movement of the spool 12 to the right, since the pressure on the spool 12 is caused by the cross-sectional area of the spool 12. Availability different areas when opening and closing the device 9 limiting the levels of charging of the hydroaccumulator to ensure reliable and fast switching of the modes of operation of the charging pump.

The invention provides more efficient control of the pressure valve, and a smaller number of closures - greater tightness.

Claims (1)

Invention Formula A hydroaccumulator charging machine containing a spring-loaded hydraulically controlled overflow valve connected by an input to a power source and an outlet to a drainage line, and a control unit including a housing with a control input communicated with the hydroaccumulator and with a device for charging the hydroaccumulator of the accumulator, and a spool mounted in the cylindrical bore of the housing with the formation of a hydraulic cavity, having radial and axial channels, the last of which is in communication with the spring cavity of the spool, while The cylinder housing bore is provided with a bore communicated with a spring cavity controlling the overflow valve, the valve being installed in the cylindrical bore of the housing with the possibility of connecting its radial channel with the bore of the housing, characterized in that, in order to increase the efficiency by reducing leakage from the accumulator when the source is unloaded power limiting device The hydroaccumulator charging levels are provided with first and second saddles with holes installed coaxially with the valve in the housing and a ball locking element placed between the saddles and spring loaded together with the valve to the second saddle, the valve being placed in the first saddle hole, the second saddle hole is reported the control input of the control unit, and the spring cavity of the spool is in communication with the drain, and the cross section of the spool is larger than the opening section of the second seat and less than the opening section holes in the first saddle.