SU754003A1 - Hydraulic twin-circuit drive of single-bucket excavator - Google Patents

Description

(54) HYDRAULIC 2-PERFORMANCE DRIVE

SINGLE BUCKET EXCAVATOR

one

The invention relates to hydraulic drives of single-bucket excavators.

A two-stream hydraulic drive of a single-bucket excavator is known, which includes a pump, sections of which are equipped with a common displacement regulator associated with pressure lines of sections, primary safety valves in pressure lines of each pump section, blocks of distributors of hydraulic motors of an excavator and including a hydraulic motor turning the platform, The remote control valves of these distributors are powered from a low-pressure discharge line 1.

Its disadvantage is the overhead cost of power due to the maximum working volume of the pump at the neutral position of the distributors and the operation of the safety valves of the motor turning the platform during acceleration of the turntable.

A two-stream hydraulic drive of a single-bucket excavator is known, including a pump, each of two sections of which contains a displacement regulator associated with the pressure lines of the sections and having an additional low-pressure hydraulic cylinder with a loading and unloading control cavities, and the unloading cavity is connected with pressure line of low pressure, primary safety valves in pressure lines of each section of the pump, blocks of distributors of excavator hydraulic motors, including hydraulic motor platform openings, remote control valves for these distributors, powered from the specified low pressure discharge line, logic valve blocks associated with the working lines of the specified remote control valves and the specified control cavities for additional hydraulic cylinders of the displacement controllers of pump sections, drain line 2 .

The disadvantage of this drive is the overhead cost of power, because when starting the drive motor, the pump does not guarantee the minimum performance due to the operation of the safety valves of the motor turning the platform during acceleration of the turntable.

The purpose of the invention is a comprehensive reduction of energy waste.

The purpose of the invention is achieved due to the fact that in the supply lines of the load cavities for controlling the additional hydraulic cylinders of the displacement regulators of the pump sections there are pressure valves connected by the lines of their taps to the drain line, and the control lines to the pressure lines of the corresponding sections of the pump, as well as due to the fact that the pressure valve of the pump section of the platform feeding hydraulic motor is made with a hydraulically variable setting and in the control line a change of setting related to the pressure head On the low pressure line, a pressure valve is installed, the control line of which is connected to the operating lines of the remote control valves of the platform rotary motor distributor.

FIG. 1 is a diagram of a hydraulic drive without remote control; in fig. 2 is a remote control circuit; in fig. 3 shows a variant of the pump with indirect control of the working volume of the sections and the option of feeding the low pressure discharge line through the reduction unit from the pressure lines of the pump sections.

The hydraulic drive includes a pump 1 (Fig. 1) with sections 2 and 3, each of which is equipped with a regulator 4 and 5 of its working volume. Each direct action regulator is a two-stage plunger with equal active areas of steps, which, through the throttle openings, are connected to the corresponding pressure lines 6 and 7 of the sections. This device provides automatic synchronous regulation of the working volumes of sections depending on the total pressure in both pressure lines 6 and 7. The characteristics of the springs in the regulators are adjusted so that within the range of adjustment of the working volume the value of the power consumed by the pump is constant. engine excavator. Each regulator is equipped with an additional two-cylinder control hydraulic cylinder 8 and 9. The cavities 10 and 11 of the hydraulic cylinders 8 and 9, the effect of which reduces the working volume of the sections 2 and 3 of the pump 1, are called relief and are associated with the low-pressure pressure line 12. The opposing cavities 13 and 14 of additional hydraulic cylinders 8 and 9 are called load and are connected by lines 15 and 16 through a system of logic valves of blocks 17 and 18 with working lines 19 of remote control valves 20, which are enclosed in blocks 21. Valves 20 with their working lines 19 (A1, A2, B1, B2, etc.) are connected to blocks 22 and 23. In addition to the working lines, valves 20 have a pressure 24 and a drain line 25 to the drain.

Discharge line 24 is connected to a low pressure pressure line 12.

The distributors (not shown) of blocks 22 and 23 are associated with the working lines of the excavator hydraulic motors. For example, the distributor unit 22, controlled from the operating lines B1 and 52 of the corresponding remote control valves 20 of the unit 21, is connected to the working lines 26 and 27 of the hydraulic motor 28 of the turn of the excavator platform. The remaining hydraulic motors and their working lines are not shown in the drawing.

In lines 15 and 16 of power supply cavities 13 and 14 of additional hydraulic cylinders 8 and 9, two-position three-way pressure valves 29 and 30 are installed, lines 31 and 32 of which are connected to pressure lines 6 and 7 of sections 2 and 3 of pump 1. Third discharge of valves 26 and 27 is connected to the drainage. The cavities of the springs of these pressure valves 26 and 27 are connected to the drainage, and the springs themselves are set to 0 to a pressure corresponding to the setting of the safety valves (not shown in the Fig.).

The pressure valve spring 29 is hydraulically controlled by tuning from line 33. It is possible to change the setting from high to low and vice versa. Adjusting the upper value of the setting corresponds to the setting of the primary safety valve (not shown in Fig.), Limiting the pressure in the pressure line 6 of section 2 of pump 1. Adjusting the lower setting value corresponds to the setting of the secondary safety valves (not shown in the figure) limiting the pressure in workers lines of hydraulic motor turning when accelerating the turning part.

The spring of the pressure valve 30 is set to a constant pressure value corresponding to the setting of the primary safety valve (not shown in the figure), 0 limiting the pressure in the pressure line 7 of the section 3 pump 1.

The control line 33 for adjusting the pressure valve 29 is connected to the low pressure pressure line 12 via a third two-position three-way pressure valve 34, the third outlet of which is connected to the drainage. The valve control line 35 is connected via a logic valve or 36 to the operating lines 51 and 52 of the valves for remote control of the valve distributor of the platform pivoting hydromotor 28. The spring cavity is connected to the drainage, and the spring itself is set to a small pressure, corresponding to the beginning of movement to one of the extreme positions of the spool of the distributor hydraulic motor 28 of the platform rotation. In order to achieve the ability to autonomously control the unloading of pumps, to the control line of the unloading cavities 10 and 11 additional hydraulic cylinders

through the logic valve "or 36 (connected to an autonomous pump 37).

The pressure in the pressure line 12 of low pressure is maintained by any system. However, a system with a hydroaccumulator, the pressure in which is maintained after the primary engine is stopped, is predominantly present, in order to ensure that the pump restarts with a minimum displacement without using an autonomous pump 37.

FIG. 3 shows one of the possible variants of such a power supply system. Line 12 is powered here from pressure lines 6 and 7 sections through a reduction-battery unit.

A variant of the pump with indirect regulation of the working volume of the sections differs in the sense of connecting the pressure valves 29, 30, 34 and the core pump 37, only in that the pressure line of the pump 37 is connected via check valves 38 and 39 also with pressure lines 40 and 41 the servo-systems for controlling the working volumes of sections 2 and 3 of pump 1. The reduction-accumulator unit 42 includes a logic valve or, a hydroaccumulator 43, as well as a reduction and safety valve.

The primary and secondary safety and make-up valves, distributors and hydraulic motors (except for the platform turning motor) of the excavator, filters, coolants for the working fluid are not shown for simplicity. The working fluid tank and the drainage line are depicted by one symbol.

The drive works as follows.

Before starting the prime mover, an autonomous pump 37 is driven, and a low operating pressure through a logic valve or 36 is supplied from it to the discharge cavities 10 and 11 of the regulators, outputting the pump section to the minimum displacement (Fig. 1). For the circuit of FIG. 3, in addition to the unloading cavities of the regulators, the pump also feeds through the check valves 38 and 39 the pressure lines 40 and 41 of the control servo systems, which ensures the withdrawal of the pump sections to the minimum displacement. The primary engine is started, and with it the pressure in line 12 rises, after which the external influence on the pump 37 is removed and its pressure line is closed by the logic valve 36. The hydraulic drive is ready for operation.

If there are no effects on the remote control valves 20, the pressure in their working lines 19 is equal to the drainage pressure. Therefore, the pressure in the lines H and M, as well as in the line L, is also equal to the drainage, that is, the loading cavities 13 and 14 are connected to the drainage. Regulators 4 and 5 of sections 2 and 3 of pump 1 under the action of pressure in the pressure line 12 of low pressure output sections to the minimum displacement,

there is a power consumption at the neutral position of the distributors minimized.

When any remote control valve 20 is turned on, the pressure in its 5 working line (for example, A1) corresponds to the position of the control knob and, depending on the latter, can increase to the value of pressure in the low-pressure pressure line 12. Accordingly, the distributor with control lines A1,

0 A2, located in block 22, begins to shift from the neutral position to the right extreme position, occupying a number of intermediate ones. At the same time, the working pressure increasing in line A1 through logical valves or blocks 17 and 18 is transmitted along lines H and M to loading cavities 13 and 14 of the regulators, partially or fully compensating for the effect of discharge cavities 10 and 11. The working volume of sections 2 and 3 increases as the pressure increases in line A1. In this case, small displacement of the distributor will correspond to small flows of the sections, and maximum displacements will correspond to the maximum flow (with small

J external loads).

As the external load increases and, consequently, the pressures in the pressure lines 6 and 7 of sections 2 and 3, the working volume will decrease under the action of the stepped pistons of the regulators, the pressure to which

0 is supplied from pressure lines 6 and 7. At the same time, the required power consumption will be maintained within the specified limits of displacement adjustment.

This will happen until the pressure increases in any of the lines 6 and 7 until the safety valve is adjusted. Then, under the action of this pressure, the corresponding pressure valve 29 or 30 will move and connect the loading cavity of the regulator with the drainage, as a result of which the minimum working volume of the section will be established, i.e. the overhead energy will be reduced.

When one of the remote control valves is turned on, the distributors of the hydraulic rotator 28 of the platform turn the pressure from the working line of this valve through the logic valve or 36 will flow along the line L to the control line 35 to the pressure valve 34 and move it to the operating position. Then, the control line 33 by setting the valve 29 is connected to the drainage, and the setting of the valve 29 is reduced to the setting of the secondary safety valves of the pivoting motor 28, as a result of which the displacement of the pump section 2 decreases and will increase as the rotating platform accelerates at a constant pressure determined by the reduced setting valve 29. Thus, throttling of the working fluid through

the rotation motor safety valve, while maintaining optimum rigid performance, i.e., energy overhead is optimally reduced.

The use of the invention leads to a decrease in primary engine fuel consumption when primary safety valves are triggered, secondary safety valves, partial disengagement or neutral position of the valves, lower fuel consumption for the drive of the working fluid cooling devices, increase pump durability due to reduced load on the elements of the swing sections and durability prime mover due to reduced load from. pumps.

Claims (2)

1. A hydraulic double-flow drive of a single-bucket excavator, comprising a pump, each of two sections of which contains a displacement regulator associated with the discharge lines of the sections and having an additional low-pressure hydrocyllium with the unloading and loading control cavities, and the unloading cavity is connected to low pressure pressure line, primary safety valves in the pressure lines of each pump section, blocks of distributors for excavator hydraulic motors, including the motor for turning the boards molds, remote control valves for these valves, supplied from a specified low-pressure pressure line, logic valve blocks associated with the working lines of these remote control valves and the specified control cavities for additional hydraulic cylinders of displacement regulators of pump sections, a different drain line the fact that, in order to comprehensively reduce energy overhead, in the supply lines of the load cavities control of additional hydraulic cylinders the displacement volume of the pump sections tori set pressure valves, lines associated with its laterals drain line, and control lines - with pressure lines corresponding pump sections. 2. Hydraulic double-flow drive according to claim 1, characterized in that, in order to reduce the overhead energy during acceleration of the turntable, the pressure valve of the pump section of the hydraulic motor for turning the platform is made with a hydraulically variable setting and in the control line the change of setting associated with a low pressure pressure line; a pressure valve is installed, the control line of which is connected to the working lines of the valves of the remote control of the platform rotary motor distributor. Sources of information taken into account in the examination 1. Excavator EO-4321, prospect 1975, TsNIITEStroymash. 2. An IS-2800 hydraulic excavator manufactured by Simitomo Dzunikai, Sumitomo Dzunikai Giho magazine, 1971, No. 54, p. 90-96, translation TSNIITEStroymash BP-72-6029 (prototype). 28 25 20 KI I kg. HI ig - (5