JPH06117402A - Load-sensitive hydraulic control device - Google Patents

Abstract

(57) [Summary] [PROBLEMS] An object of the present invention is to provide a load-sensitive hydraulic control device that does not change the steering feeling when the actuator 10 is slowly moved or when the load pressure of the actuator 10 rises. That is. In a hydraulic circuit that controls the discharge amount of the variable discharge pump P according to the pressure in the neutral passage 1 downstream of the center-open type switching valve 14, meter-in throttles 15 and 16 are provided at the switching position of the switching valve 14. A pressure detector 18 connected to the controller 13 is provided downstream thereof. Further, a variable throttle valve 19 connected to the controller 13 is provided downstream of the switching valve 14, and a pressure detector 22 connected to the controller 13 is provided downstream thereof, and the controller 13 is connected to the variable discharge pump P.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hydraulic control device which is used for construction machines such as power shovels and operates an actuator regardless of the magnitude of load pressure.

[0002]

2. Description of the Related Art As a hydraulic control device for controlling an actuator of a construction machine such as a power shovel, there is a conventional device as shown in FIG. In this device, a variable discharge pump P connected to an engine E as a drive source and a tank T are communicated with each other via a neutral passage 1. A center open type switching valve 2 is provided on the neutral passage 1, and a throttle 3 is provided upstream of the tank T. A pilot passage 4 branches from upstream of the throttle 3, and the pilot passage 4 is connected to a regulator 5 that controls the discharge amount of the variable discharge pump P. By connecting like this,
The regulator 5 is actuated by the pressure acting through the pilot passage 4, and the variable discharge pump P is actuated according to the actuation amount.
The discharge amount of changes.

The regulator 5 is also connected to a pressure control valve 7 connected to a setting input device 6 such as a switch, and the pressure control valve 7 generates pressure in response to switching of the setting input device 6. , The pressure is applied to the regulator 5. Further, the engine E is also connected to the setting input device 6 and changes the rotation speed of the engine E according to the switching. In this case, the regulator 5
When a high pressure is applied to the variable discharge pump P, the discharge amount of the variable discharge pump P decreases, and when the pressure is low, the discharge amount of the variable discharge pump P increases. The pressure control valve 7 controls the flow rate from the pump P ₁ to generate pressure.

A branch passage 9 provided with a check valve 8 is provided in the neutral passage 1 upstream of the switching valve 2 and is connected in parallel with the neutral passage 1, and the downstream thereof is the bottom side of a cylinder serving as an actuator 10. 10a and the rod side 10b, respectively. The switching valve 2 is a center open type that returns the total flow rate of the variable discharge pump P to the tank T via the neutral passage 1 when the switching positions are 2a to 2c and is in the neutral position 2b. During the switching process, the neutral passage 1 is always connected. The switching valve 2 is switched by an operating lever 11 such as a hydraulic joystick. Reference numeral 12 is a relief valve.

In the hydraulic control circuit having such a configuration, when the switching valve 2 is at the neutral position 2b, the total flow rate returns to the tank T through the neutral passage 1, but at this time, pressure is generated upstream of the throttle 3. This pressure acts on the regulator 5 via the pilot passage 4 to minimize the discharge amount of the variable discharge pump P. Then, for example, the actuator 10
When extending, the operating lever 11 is switched in the direction of arrow a so that the switching valve 2 is switched from the neutral position 2b to the switching position 2a.

When the switching valve 2 is switched in this way, the communication opening degree to the neutral passage 1 is narrowed according to the switching amount. As a result, pressure is generated upstream of the switching valve 2, and this pressure causes the check valve 8 to be pushed open. By opening the check valve 8, communication with the actuator 10 becomes possible, and the discharge flow rate from the variable discharge pump P is supplied to the bottom side 10a of the actuator 10.

Thus, from the neutral position 2b to the switching position 2
The supply flow rate to the actuator 10 increases and the flow rate flowing to the neutral passage 1 decreases as the switching to a is performed. That is, when the operation amount of the operation lever 11 is small, the switching amount is also small, so the flow rate supplied to the actuator 10 is small and the flow rate returning from the neutral passage 1 to the tank T is large, but as the switching amount increases, The supply flow rate to the actuator 10 increases and the return flow rate to the tank T decreases.

Thus, as the switching amount of the switching valve 2 increases, the flow rate passing through the neutral passage 1 decreases,
The pressure upstream of the throttle 3 becomes low, and this lowered pressure acts on the regulator 5 via the pilot passage 4. Since the regulator 5 controls the variable discharge pump P according to this low pressure, the variable discharge pump P operates to increase its discharge amount. And finally, the neutral passage 1
When the flow rate to the throttle 3 decreases and the pressure upstream of the throttle 3 becomes smaller than the set pressure of the regulator 5, the variable discharge pump P
Will discharge the maximum discharge amount.

When the pressure upstream of the throttle 3 increases according to the switching amount of the switching valve 2, the discharge flow rate of the variable discharge pump P decreases, and when the pressure upstream of the throttle 3 decreases, the variable discharge pump P changes. A circuit in which the discharge amount of the throttle 3 and the variable discharge pump P has a negative relationship such that the discharge flow rate increases is called a negative control system or a negative control system. In other words, this negative control system is also called surplus flow control for controlling the discharge signal pressure of the variable discharge pump P, that is, the pressure upstream of the throttle 3 in accordance with the switching amount of the switching valve 2. The pressure acting on the regulator 5 upstream of the throttle 3 is called the negative control signal pressure.

Further, in this hydraulic control circuit, for example, when the load pressure of the actuator 10 is constant, the actuator 1
When 0 is to be moved slowly, the setting input device 6 connected to the engine E connected to the variable discharge pump P and the pressure control valve 7 connected to the regulator 5 is set to the fine operation mode. be able to. By setting the setting input device 6 in the fine operation mode, the rotation of the engine E that drives the variable discharge pump P is reduced, and the discharge flow rate of the variable discharge pump P is reduced.

In this way, the supply flow rate to the actuator 10 is reduced and the operation speed thereof is slowed down. However, in general, this alone cannot sufficiently reduce the operation speed of the actuator 10. Therefore, the maximum discharge flow rate of the variable discharge pump P is The pressure control valve 7 connected to the setting input device 6 and the regulator 5 connected to this pressure control valve 7 are controlling. That is, by switching the setting input device 6, the rotation speed of the engine E is reduced to reduce the discharge amount of the variable discharge pump P, and the maximum discharge amount of the variable discharge pump P itself is limited, so that the supply flow rate to the actuator 10 is reduced. To reduce the operation speed.

[0012]

In such a conventional hydraulic control circuit, as shown in FIG. 4, the rotation of the engine E is lowered, the discharge amount of the variable discharge pump P is reduced, and further, the variable discharge pump P itself. The maximum discharge amount of is limited. Further, since the switching operation of the switching valve 2 is performed within the range where the maximum discharge amount is limited, the inching area of the operation lever 11 becomes narrow, and there is a problem that the operation feeling of the operator deteriorates. .

Further, for example, when the load pressure of the actuator 10 increases during excavation work with a power shovel, the flow rate through the neutral passage 1 increases correspondingly. Therefore, the pressure upstream of the throttle 3, that is, the negative control signal pressure increases, and the increased pressure acts on the regulator 5 to reduce the discharge flow rate of the variable discharge pump P. When the discharge flow rate of the variable discharge pump P is reduced in this way, the switching stroke region of the switching valve 2, that is, the inching region is narrowed, so that the operation feeling of the operator is increased by the increase of the load pressure of the actuator 10. There was a problem that it changed and it was difficult to operate. An object of the present invention is to provide a load-sensitive hydraulic control device that does not change the operation feeling when the actuator is operated slowly or when the load pressure of the actuator increases.

[0014]

In order to solve the above-mentioned problems, according to the present invention, a center-open type is provided on a neutral passage that connects a variable discharge pump connected to a drive source and a tank, and a switching process is performed. In a hydraulic control circuit in which a switching valve that is always in communication with the neutral passage is provided, the switching valve is connected to an actuator, and a throttle is provided upstream of the tank, a meter-in throttle provided at the switching position of the switching valve, A first pressure detector downstream of the meter-in throttle and connected to the controller, a variable throttle valve downstream of the throttle whose opening is controlled by the controller, and between the variable throttle and the throttle A second pressure detector provided and connected to the controller, a regulator for controlling the discharge amount of the variable discharge pump, and a controller for controlling this regulator. The controller is provided with a control means for controlling with a signal from a controller, an operating lever for controlling a switching amount of the switching valve which is connected to the controller, and a setting input device such as a switch connected to the controller. It is characterized in that it is connected to the control means and controls the number of rotations thereof, and controls the control means according to the number of rotations of the drive source.

[0015]

The controller controls the rotation speed of the drive source to a preset rotation speed according to the input signal from the setting input device. The discharge amount of the variable discharge pump is set by the change in the rotation speed of the drive source. At the same time, the controller controls the control means to a preset pressure set according to the rotational speed of the drive source, and sets the maximum discharge amount of the variable discharge pump via the regulator. In this way, the controller sets the rotation speed of the drive source in accordance with the input signal of the setting input device, and sets the maximum discharge amount of the variable discharge pump in accordance with this rotation speed.

When the operation lever connected to the controller is operated to operate the actuator, information on the stroke amount of the operation lever is sent to the controller and the switching valve is switched according to the operation amount. When the switching valve is switched, the switching valve that is always in communication with the neutral passage is switched to the switching position during the switching process, and the hydraulic oil that has passed through the meter-in throttle provided at the switching position becomes
Supplied to the actuator. At this time, the pressure downstream of the meter-in throttle is equal to the load pressure of the actuator. The pressure downstream of the meter-in throttle is detected by the first pressure detector, and the information is sent to the controller.

From this information, the controller controls the opening degree of the variable throttle valve provided in the neutral passage, and controls the flow rate passing through the throttle provided downstream thereof. Pressure is generated upstream of the throttle whose flow rate is controlled in this way.
It is detected by the second pressure detector and sent to the controller.
The controller calculates the required discharge amount of the variable discharge pump from this information and the stroke amount information of the operating lever, and controls the discharge amount of the variable discharge pump via the regulator and the control means.

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows an embodiment of the present invention. The same reference numerals are used for the same components as in the conventional example, and detailed description thereof is omitted. In this embodiment, the variable discharge pump P is driven by the engine E as a drive source. The discharge amount of the variable discharge pump P is controlled by the regulator 5, and the regulator 5 changes the discharge amount according to the pressure acting on the variable discharge pump P.
The flow rate of is controlled. The pressure acting on the regulator 5 is generated by the pressure control valve 7, and the pressure control valve 7 is controlled by the solenoid 27 connected to the controller 13. The engine E is connected to the controller 13. Further, the hydraulic oil is supplied to the pressure control valve 7 by the pump P ₁ , and the pressure control valve 7 and the pump P ₁ serve as control means.

The switching valve 14 provided in the neutral passage 1 that connects the variable discharge pump P and the tank T is a center open type, is connected to the actuator 10, and has switching positions 14a and 14c. Meter-in diaphragms 15 and 16 are provided. This meter-in diaphragm 1
A pressure detection passage 17 is provided downstream of 5 and 16 and is connected to the first pressure detector 18. The first pressure detector 18 is connected to the controller 13 and sends the detected information to the controller 13. Further, a variable throttle valve 19 is provided on the neutral passage 1 between the downstream of the switching valve 14 and the throttle 3 upstream of the tank T. The opening of the variable throttle valve 19 is controlled by a solenoid 20 connected to the controller 13. The opening of the variable throttle valve 19 is fully opened at the normal position shown in the figure, and the opening is reduced according to the control of the controller 13. It is a thing.

The downstream side of the variable throttle valve 19 and the throttle 3
A pressure detection passage 21 is provided between the second pressure detector 2 and
Although the second pressure detector 22 is connected to the controller 13, the second pressure detector 22 is also connected to the controller 13. Thus, the controller 13 connected to the first and second pressure detectors 18 and 22, the pressure control valve 7, and the engine E is also connected to the operation lever 23 and the setting input device 6 such as a switch. Operation lever 2
3 is connected to the switching valve 14 to control the switching amount. A third pressure detector 24 is provided in the middle of connection with the controller 13. This third pressure detector 24
Detects the operation amount of the operation lever 23 as pressure and sends the information to the controller 13. In addition, the setting input device 6 is a mode set in the controller 13,
For example, it is an input switch for selecting a fine operation mode for slowly moving the actuator 10. Note that reference numeral 2
Reference numerals 5 and 26 are meter-out diaphragms at the switching positions 14a and 14c.

According to this structure, when the switching valve 14 is in the neutral position 14b, the pressure upstream of the throttle 3 is the second pressure.
Is detected by the pressure detector 22 and sent to the controller 13. Based on this information, the controller 13 calculates the pressure applied to the regulator 5 and controls the pressure control valve 7. In this way, the pressure control valve 7 controls the working pressure on the regulator 5, and the flow rate of the variable discharge pump P is controlled by this pressure. In this case, if the pressure upstream of the throttle 3 is high, the high pressure acts on the regulator 5 to reduce the discharge amount of the variable discharge pump P. Conversely, if the pressure upstream of the throttle 3 is low, the discharge amount will be large.

When the switching valve 14 is switched from the neutral position 14b to the switching position 14a in order to operate the actuator 10, the flow rate of the actuator 10 and the neutral passage 1 is determined according to the switching amount. . In this case, the flow rate supplied to the actuator 10 is controlled by the meter-in throttles 15 and 16. The pressure downstream of the meter-in throttles 15 and 16 is, as is clear from the figure,
It is the same as the load pressure of the actuator 10, and this pressure is detected by the first pressure detector 18, and the information thereof is sent to the controller 13.

Based on this information, the controller 13 controls the variable throttle valve 1 according to the change of the load pressure of the actuator 10.
The opening degree of 9 is controlled. For example, when the load pressure of the actuator 10 becomes large, the controller 13 causes the pressure in the meter-in throttles 15 and 16 downstream, that is, the actuator 1
In order to supply the variable discharge pump P with a flow rate corresponding to a load pressure of 0, the opening of the variable throttle valve 19 is throttled, the flow rate upstream of the throttle 3 on the neutral passage 1 is controlled, and the pressure generated there is reduced. To do. The reduced pressure upstream of the throttle 3 is detected by the second pressure detector 22 and sent to the controller 13.
Based on the information, the controller 13 controls the pressure control valve 7 so as to lower the pressure applied to the regulator 5. The discharge amount of the variable discharge pump P is increased by this control.

As described above, when the controller 13 narrows the opening of the variable throttle valve 19 in accordance with the increase of the load pressure, the flow rate passing through the neutral passage 1 downstream thereof decreases. Therefore, the pressure generated upstream of the throttle 3 also decreases according to the flow rate. At this time, the pressure upstream of the throttle 3 is detected by the first pressure detector 18, the detected pressure is arithmetically processed by the controller 13, and the pressure applied to the regulator 5 is lowered by the pressure control valve 7 according to the processing result. The variable discharge pump P is controlled to increase the discharge amount.

Therefore, even if the load pressure of the actuator 10 rises, the flow rate passing through the neutral passage 1 and the pressure upstream of the throttle 3 are controlled by the controller 13 and the variable throttle valve 19 according to the rise. The discharge amount of the variable discharge pump P does not decrease, and the switching valve 14 due to the decrease in flow rate
There is no reduction in the switching stroke area. As a result, since the inching area of the operation lever 23 connected to the switching valve 14 does not become tight due to the increase in load pressure, the operation feeling does not change.

Further, when the load pressure is constant, the actuator 1
When 0 is moved slowly, the flow rate supplied to the actuator 10 may be reduced. In this case, the setting input device 6 connected to the controller 13 is switched to set the fine operation mode. With such a setting, first, the rotation speed of the engine E is reduced by the controller 13 to reduce the discharge amount of the variable discharge pump P, but there is a limit to reducing the discharge amount by reducing the rotation of the engine E. Therefore, the maximum discharge amount of the variable discharge pump P itself is further controlled. In this case, the maximum discharge amount of the variable discharge pump P itself is
The pressure is set in advance by the controller 13, and the pressure control valve 7 and the regulator 5 control according to the setting.
Then, the discharge amount of the variable discharge pump P up to the maximum discharge amount is controlled according to the rotation speed of the engine E and the operation amount of the operation lever 23. As a result, as shown in FIG. 2, even if the rotation of the engine E changes, the position of the operating lever 23 corresponding to the maximum speed of the actuator 10 becomes constant, so that the inching area does not become narrow, and the operating feel is reduced. Ring does not change.

Thus, according to the number of revolutions of the engine E,
Since the maximum discharge amount of the variable discharge pump P is set and the operation lever 23 is operated within the set range to operate the actuator 10, even if the operation is performed in the fine operation mode, the operation lever 23 is operated as in the conventional case. The inching area does not become narrow and the operation feeling does not change.

[0028]

[Effect] The maximum discharge amount of the variable discharge pump is reduced by setting the maximum discharge amount of the variable discharge pump according to the rotation speed of the drive source and operating the actuator within the set range. Even if the amount is limited, for example, the inching area of the operation lever does not become narrow as in the conventional case and the operation feeling does not change. Also, the load pressure of the actuator is detected downstream of the meter-in throttle, and the flow rate through the neutral passage downstream of the switching valve is controlled according to this increase in load pressure. There is no decrease. Therefore, the inching area of the operation lever changes due to the increase of the load pressure of the actuator, and therefore the operation feeling does not change.

[Brief description of drawings]

FIG. 1 is a circuit diagram as an embodiment of the invention.

FIG. 2 is a diagram showing a relationship between a flow rate and a stroke of an operation lever when a rotation speed of a drive source and a maximum discharge amount of a variable discharge pump are set in the circuit of FIG.

FIG. 3 is a conventional circuit diagram.

4 is a diagram showing the state of FIG. 2 in the circuit of FIG.

[Explanation of symbols]

 1 Neutral passage 3 Throttle 5 Regulator 6 Setting input device 7 Pressure control valve 10 Actuator 13 Controller 14 Switching valve 15, 16 Meter-in throttle 18, 22 Pressure detector 19 Variable throttle valve

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Atsushi Fujii 8-7-24 Tsuji, Urawa-shi, Saitama Kayaba Industrial Co., Ltd. Urawa factory (72) Inventor Haruhiko Kawasaki 1-12-1, Asamizodai, Sagamihara-shi, Kanagawa Kayaba Industry Co., Ltd. Sagami Plant (72) Inventor Haruki Igata 1-12-1, Asamizodai, Sagamihara City, Kanagawa Prefecture Kayaba Industry Co., Ltd. Sagami Plant

Claims (1)

[Claims] 1. A switching valve of a center open type, which is always in communication with a neutral passage in a switching process, is provided on a neutral passage which connects a variable discharge pump connected to a drive source and a tank. In the hydraulic control circuit having a throttle upstream of the tank and a meter-in throttle provided at the switching position of the switching valve, and a first pressure downstream of the meter-in throttle and connected to the controller. A detector, a variable throttle valve downstream of the throttle, the opening of which is controlled by a controller; a second pressure detector provided between the variable throttle and the throttle and connected to the controller; A regulator that controls the discharge amount of the variable discharge pump, a control unit that controls this regulator with a signal from the controller,
An operating lever that is connected to the controller and that controls the switching amount of the switching valve, and a setting input device such as a switch that is connected to the controller are provided, and the controller is connected to the drive source and controls the rotation speed thereof. A load-sensitive hydraulic control device configured to control the control means according to the rotation speed of a drive source.