JP4685542B2 - Hydraulic drive - Google Patents

Description

  The present invention relates to a hydraulic drive device used in a construction machine such as a hydraulic excavator, and in particular, a load sensing control method for controlling a discharge pressure of a hydraulic pump to be higher by a target differential pressure than a maximum load pressure of a plurality of actuators. The present invention relates to a hydraulic drive device.

  As this type of hydraulic drive device, for example, there is one described in Japanese Patent Laid-Open No. 2001-193705 (Patent Document 1). In this prior art, a main relief valve and an unload valve are connected to a hydraulic pressure supply circuit to which discharge of a hydraulic pump (main pump) is guided. The main relief valve is a kind of safety valve that operates when the load pressure of the actuator is high and the pressure of the hydraulic supply circuit (discharge pressure of the hydraulic pump) reaches the relief set pressure (for example, 25 Mpa) when the flow control valve operates. Prevents pressure from rising further. The unload valve mainly operates under the condition that the flow control valve is not operating (at neutral), and the pressure of the hydraulic supply circuit (discharge pressure of the hydraulic pump) is lower than the relief set pressure (for example, 2.0 Mpa). To reduce energy loss when neutral.

JP 2001-193705 A

  In a load sensing control type hydraulic drive device, two valves, a main relief valve and an unload valve, are provided as valves for limiting the pressure of the hydraulic supply circuit (discharge pressure of the hydraulic pump). The main relief valve operates during operation of the flow control valve to protect the hydraulic circuit, and the unload valve operates during neutralization (non-operation) of the flow control valve to avoid energy loss. That is, both do not operate simultaneously.

  Focusing on the fact that the main relief valve and the unloading valve do not operate at the same time, it is conceivable that the functions of the main relief valve and the unloading valve can be integrated by providing the function of the main relief valve. In this way, the main relief valve is not necessary, and the circuit configuration can be simplified. Further, since the number of valves in the main circuit is reduced, the manufacturing cost is also reduced. However, if the main relief valve is deleted from the hydraulic circuit, the fail-safe safety valve function in the event of a failure of a part provided to give the unload valve the function of the main relief valve will be lost.

  An object of the present invention is to provide a hydraulic drive device capable of maintaining a fail-safe safety valve function while an unload valve functions as a main relief valve in a hydraulic circuit for load sensing control.

In order to achieve the above object, the present invention provides a variable displacement hydraulic pump, a plurality of actuators driven by pressure oil discharged from the hydraulic pump, and a pressure supplied from the hydraulic pump to the plurality of actuators. A plurality of flow rate control valves for controlling the flow rate of oil, a horsepower control means for reducing a discharge amount (tilt) of the hydraulic pump when a discharge pressure of the hydraulic pump increases, and a discharge pressure of the hydraulic pump of the plurality of actuators. Pump discharge having a load sensing control valve for controlling the discharge amount (tilt) of the hydraulic pump so as to be higher than the maximum load pressure by a target load sensing differential pressure, and load sensing means having a load sensing control (tilt) actuator A hydraulic control system that opens at a neutral position of the quantity control mechanism and the plurality of flow control valves and guides the oil discharged from the hydraulic pump. An unloading valve for discharging the discharge oil of the circuit to the tank and controlling the discharge pressure of the hydraulic supply circuit to a target unload differential pressure, and the load sensing control valve is guided by the hydraulic pump discharge pressure and the hydraulic pressure A pressure receiving portion that causes the pump discharge amount (tilting) to decrease, a pressure receiving portion that guides the maximum load pressure of the plurality of actuators and causes the hydraulic pump discharge amount (tilting) to increase, and And an urging means for increasing the discharge amount (inclination) of the hydraulic pump for setting a target load sensing differential pressure, and the unload valve is configured such that the discharge pressure of the hydraulic pump is guided and the unload is performed. A first pressure receiving portion that operates the valve in the opening direction; a second pressure receiving portion that guides a maximum load pressure of the plurality of actuators to act on the unload valve in the closing direction; and the target unload differential pressure In the hydraulic drive device having an urging means that acts in the closing direction of the unload valve to be set, a signal pressure oil passage that guides the maximum load pressure to a second pressure receiving portion of the unload valve, and the signal pressure oil passage And a signal pressure relief valve provided between the throttle portion and the second pressure receiving portion of the signal pressure oil passage, and the hydraulic pressure is supplied to the set pressure of the signal pressure relief valve. The rated pressure of the hydraulic circuit including the oil passage is set, the area of the first pressure receiving portion of the unload valve is set larger than the area of the second pressure receiving portion, and the unload valve is activated when the signal pressure relief valve is out of order due to a failure. The maximum load pressure that functions as a safety valve is set, and the state immediately before the signal pressure relief valve of the unload valve is relieved at a set pressure and the state of the maximum load pressure at which the unload valve functions as a safety valve, Anro It is assumed that the ratio of the area of the first pressure receiving part and the area of the second pressure receiving part of the unload valve is set so that an equivalent stroke (opening area) can be obtained in the door valve .

  As a result, when the maximum load pressure reaches the set pressure of the signal pressure relief valve, the pressure in the signal pressure oil passage downstream of the throttle is limited to that set pressure, and the pressure in the pressure oil supply oil passage becomes the set pressure. When the pressure exceeds the sum of the target control differential pressures, the unload valve opens and the pressure oil in the pressure oil supply oil passage is drained into the tank. With this function, when the actuator (hydraulic cylinder) reaches the stroke end, the pressure of the hydraulic circuit including the hydraulic oil supply oil passage (hydraulic pump discharge pressure) matches the maximum load pressure, and the circuit pressure is It is limited to a pressure obtained by adding the target control differential pressure of the unload valve to the set pressure of the pressure relief valve.

On the other hand, if the signal pressure relief valve does not operate for some reason (such as a stick), the unload valve sets the area of the first pressure receiving part to be larger than the area of the second pressure receiving part, and the signal pressure relief valve Set the maximum load pressure at which the unload valve functions as a safety valve when it is not operating due to a failure, and the state immediately before the signal pressure relief valve of the unload valve is relieved with the set pressure and the unload valve as the safety valve By setting the area ratio of the first pressure receiving part and the second pressure receiving part of the unload valve so that an equivalent stroke (opening area) can be obtained in the state of the maximum load pressure that functions. , tank pressure oil of the pressure oil supply oil passage (discharge oil of the hydraulic pump) load the dependent characteristic operating in its own spool thrust reaches a maximum load pressure of said based on the area ratio It is possible to drain, unloading valve will be able to function as a safety valve.

  According to the present invention, in the hydraulic circuit for load sensing control, the unload valve has a function of a main relief valve, and includes a pressure oil supply oil passage even when the signal pressure relief valve becomes inoperable due to a failure or the like. It is possible to limit an extreme increase in the pressure of the hydraulic circuit, and the fail-safe safety valve function can be maintained.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a view showing a hydraulic drive apparatus according to an embodiment of the present invention.

  In FIG. 1, a hydraulic drive apparatus according to the present embodiment includes an engine 1, a variable displacement hydraulic pump 2 as a main pump driven by the engine 1, and a fixed displacement pilot pump 3 as a pilot pump. , A plurality of actuators 5a, 5b, 5c driven by the pressure oil discharged from the main hydraulic pump 2, a control valve 4, and a pump tilt control mechanism 12 for controlling the tilt (capacity) of the hydraulic pump 2. It has.

  A pilot relief valve (signal pressure relief valve) 15 is provided in the discharge oil passage 3a of the pilot pump 3, and the discharge pressure of the pilot pump 3 (pressure in the discharge oil passage 4a) is kept constant.

  The pump tilt control mechanism 12 includes a horsepower control tilt actuator 12a that reduces the tilt of the hydraulic pump 2 when the discharge pressure of the hydraulic pump 2 is increased, and the discharge pressure of the hydraulic pump 2 is the highest of the plurality of actuators 5a, 5b, and 5c. An LS control valve 14 and an LS control tilt actuator 12b that control the tilt of the hydraulic pump 2 (load sensing control) so as to be higher than the load pressure by the target differential pressure are provided.

  The LS control valve 14 has a hydraulic pressure source port 14 x connected to the discharge oil passage 13 a of the pilot pump 3, an output port 14 y connected to the LS control tilt actuator 12 b, and a discharge port 14 z connected to the tank T. The LS control valve 14 includes a pressure receiving portion 14a located on the side that increases the pressure of the actuator 12b and reduces the tilt of the hydraulic pump 2, and a pressure receiving portion 14b located on the side that reduces the pressure of the actuator 12b and increases the tilt of the hydraulic pump 2. The discharge pressure of the hydraulic pump 2 is guided to the pressure receiving portion 14a, and the maximum load pressure of the actuators 5a, 5b, 5c is guided to the pressure receiving portion 14b. The spring 14c sets a target differential pressure (target load sensing differential pressure) for load sensing control.

  The actuators 5a, 5b, and 5c are, for example, a boom cylinder, an arm cylinder, and a turning motor of a hydraulic excavator. The hydraulic excavator is equipped with left and right traveling cylinders, bucket cylinders and the like as other actuators. In FIG. 1, those actuators and corresponding portions of the control valve 3 are not shown.

  The control valve 4 includes valve sections 4a, 4b, 4c for controlling the flow of pressure oil supplied from the hydraulic pump 2 to the actuators 5a, 5b, 5c, and an inlet / outlet section 4d.

  Each of the valve sections 4a, 4b, and 4c includes a plurality of closed center type flow control valves (main spools) 42a, 42b, and 42c, and differential pressures before and after the meter-in throttle portions of the plurality of flow control valves 42a, 42b, and 42c. The valve section 4a further includes a load pressure taken out from the load port of the flow control valves 42a, 42b, 42c when the actuators 5a, 5b, 5c are driven. The valve section 4b further includes a shuttle valve 6a that detects and outputs the highest pressure (highest load pressure) to the signal pressure oil passage 7, and the valve section 4b further includes the flow control valves 42b and 42c when the actuators 5b and 5c are driven. A shuttle that detects the pressure on the high pressure side of the load pressure taken out from the load port and outputs it to the shuttle valve 6a It contains 6b.

  The flow rate control valves 42a, 42b, and 42c are switched by operating an operation lever (not shown), and the opening area of the meter-in restrictor is determined according to the operation amount of the operation lever.

  The plurality of pressure compensation valves 41, 41b, 41c are each a front type (before-orifice type) installed upstream of the meter-in throttle portions of the flow control valves 42a, 42b, 42c, and the pressure compensation valve 41a is a pair of pressure compensation valves 41a. There are opposed pressure receiving portions 31a, 31b and another pair of opposed pressure receiving portions 31c, 31d, and pressures on the upstream side and downstream side of the meter-in throttle portion of the flow control valve 42a are respectively guided to the pressure receiving portions 31a, 31b. The discharge pressure of the hydraulic pump 2 and the maximum load pressure detected by the signal pressure oil passage 7 are respectively guided to the pressure receiving portions 31c and 31d, and the differential pressure between the discharge pressure of the hydraulic pump and the maximum load pressure is set as the target compensation differential pressure. To control the differential pressure across the flow control valve 42a. The pressure compensation valves 41b and 41c are similarly configured. Thus, the differential pressures before and after the meter-in throttle portions of the flow control valves 42a, 42b, and 42c are all controlled to be the same value, and the meter-in throttle portions of the flow control valves 42a, 42b, and 42c are controlled regardless of the magnitude of the load pressure. Pressure oil can be supplied at a ratio corresponding to the opening area. Even if the discharge flow rate of the hydraulic pump 2 is in a saturation state where the required flow rate is less than the required flow rate, the pressure oil can be supplied at a ratio corresponding to the opening area of the meter-in throttle portions of the flow control valves 42a, 42b, 42c.

  The inlet / outlet section 4d of the control valve 4 is connected to a pipe leading to the discharge oil passage of the hydraulic pump 2, and a pressure oil supply oil passage 8a for guiding the pressure oil of the hydraulic pump 2 to the valve sections 4a, 4b, 4c, and a tank A pressure oil discharge oil path 8b for discharging return oil from the valve sections 4a, 4b and 4c to the tank T and a control pressure port 9x are connected to the pressure oil supply oil path 8a 9y is connected to the pressure oil discharge oil passage 8b to control the pressure of the pressure oil supply oil passage 8a (the discharge pressure of the hydraulic pump 2), and to make the unload valve 9 function as a main relief valve. The relief cut valve 13 is provided.

  The unloading valve 9 includes a pressure receiving portion 9a that acts in the closing direction, a pressure receiving portion 9b that acts in the opening direction, and a spring 9c that acts in the closing direction. The pressure receiving portion 9a is connected to the signal pressure oil passage 7 via the signal pressure oil passage 10a, and the pressure receiving portion 9b is connected to the control pressure port 9x (pressure oil supply oil passage 8a) via the signal pressure oil passage 10b. . The throttle part 11 is installed in the signal pressure oil path 10a. The maximum load pressure detected by the shuttle valve 6a is guided to the pressure receiving part 9a of the unload valve 9 via the throttle part 11, and the pressure (9) of the control pressure port 9x via the signal pressure oil path 10b ( The pressure of the pressure oil supply oil passage 8a, that is, the discharge pressure of the hydraulic pump 2) is guided. The spring 9c sets a target control differential pressure (target unload differential pressure) of the unload valve. In the relief cut valve 13, the control pressure port 13x is connected between the throttle portion 11 and the pressure receiving portion 9a of the signal pressure oil passage 10a via the signal pressure oil passage 12, and the discharge port 13y is connected to the pressure oil discharge oil passage 8b. It is connected. The relief cut valve 13 includes a spring 13a that operates in the closing direction and a pressure receiving portion 13b that operates in the opening direction. The spring 13a sets a target relief cut pressure, and the pressure receiving portion 13b is controlled via a signal pressure oil passage 13c. The pressure of the pressure port 13x (the pressure of the signal pressure oil passage 10a; normally, the maximum load pressure) is introduced.

  The area of the pressure receiving portion 9b to which the pump discharge pressure of the unload valve 9 is guided is set to be larger than the area of the pressure receiving portion 9a to which the maximum load pressure is guided, and the unload valve 9 has load dependent characteristics.

  FIG. 2 is a cross-sectional view showing the valve structure of the unload valve 9. The unload valve 9 has a valve housing 50 and a valve spool 51, and the valve spool 51 is slidably inserted into the valve housing 50. The valve spool 51 includes left and right land portions 51a and 51b, an intermediate shaft portion 51c, and left and right control spool portions 51d and 51e, and a notch for forming a variable throttle portion on the left land portion 51a in the drawing. A notch 51f is formed. The valve housing 50 is formed with the control pressure port 9x and the discharge port 9y. The control pressure port 9x opens into the inlet chamber 51g where the intermediate shaft portion 51c is located, and the discharge port 9y slides on the left land portion 51a. The moving surface is opened close to the notch 51f. The valve housing 50 is formed with annular drain chambers 51h and 51i, pressure receiving chambers 51j and 51k, and the control pressure oil passages 10a and 10b. The drain chamber 51h on the left side of the figure has an end face of the land portion 51a and a control spool. 51d is located, the end surface of the land portion 51b and the control spool portion 51e are located in the drain chamber 51i on the right side of the drawing, and the end surface of the control spool portion 51d is located in the pressure receiving chamber 51j on the left side of the drawing. The end surface of the control spool portion 51e is located in the chamber 51k, and the signal pressure oil passages 10a and 10b open to the pressure receiving chambers 51j and 51k. The end surface of the control spool portion 51d and the pressure receiving chamber 51j constitute a pressure receiving portion 9a, and the end surface of the control spool portion 51e and the pressure receiving chamber 51k constitute a pressure receiving portion 9b. The end surface of the control spool portion 51d defines the area of the pressure receiving portion 9a, and the end surface of the control spool portion 51e defines the area of the pressure receiving portion 9b. As described above, the area of the end surface of the control spool portion 51d (area of the pressure receiving portion 9b) is set larger than the area of the end surface of the control spool portion 51e (area of the pressure receiving portion 9a). A spring 9c for setting a target control differential pressure (target unload differential pressure) of the unload valve 9 is disposed in the pressure receiving chamber 51j.

  FIG. 3 is a view similar to FIG. 1 showing a hydraulic drive apparatus when a load dependent characteristic is not given to an unload valve as a comparative example. In the figure, parts that are the same as the parts shown in FIG. In the comparative example shown in FIG. 3, an unload valve 9A is provided in the inlet / outlet section 4Ad of the control valve 4A, and the area of the pressure receiving portion 9Ab of the unload valve 9A is the same as the area of the pressure receiving portion 9Aa. Other parts of the comparative example are the same as those shown in FIG.

  Next, the operation of the present embodiment will be described in comparison with a comparative example.

  In the LS control valve 14, the hydraulic pump 2 so that the differential pressure between the discharge pressure of the hydraulic pump 2 guided to the opposing pressure receiving portions 14 a and 14 b and the maximum load pressure is equal to the target load sensing differential pressure set by the spring 14. Is controlled (load sensing control).

  When the flow control valves 42a, 42b, and 42c are all in a neutral state (during non-operation), the maximum load pressure detected by the shuttle valve 6a is the tank pressure, and the unload valve 9 is guided to the pressure receiving portion 9a. Since the pressure becomes the tank pressure, the discharge pressure of the hydraulic pump 2 guided to the pressure receiving portion 9b is controlled to a pressure (target unload differential pressure) set by the override characteristic of the unload valve 9 by the spring 9c. This pressure is adjusted to be a value much lower than the pressure set by the spring 13a of the relief cut valve 13, which is the relief pressure of the hydraulic circuit including the pressure oil supply oil passage 8a. Here, if the target unload differential pressure at this time is Pun and the relief pressure of the hydraulic circuit (the set pressure of the spring 13a of the relief cut valve 13) is Pr, then Pun <0.15Pr, for example.

  When one of the flow control valves 42a, 42b, 42c is operated, the maximum load pressure detected by the shuttle valve 6a becomes the load pressure of the actuator related to the operated flow control valve in the single operation, and in the combined operation. The load pressure on the high-pressure side (or highest) of the actuators related to the operated flow control valve is set, the unload valve 9 operates in the closing direction, and is fully closed or throttled (described later) during the operation of the actuator.

In this state, the pressure in the pressure oil supply oil passage 8a is controlled to be higher than the maximum load pressure by the target load sensing differential pressure of the spring 14c of the LS control valve 14 by load sensing control. That is, if the pressure of the pressure oil supply oil passage 8a (discharge pressure of the hydraulic pump 2) is Ps, the maximum load pressure is Plmax, and the target load sensing differential pressure of the spring 14c is Pls-ref,
Ps = Plmax + Pls-ref
Further, when the maximum load pressure Plmax reaches the relief pressure Pr set by the relief cut valve 13, the pressure in the signal pressure oil passage 10a downstream of the throttle portion 11 is limited to Pr. When the pressure of the pressure oil supply oil passage 8a is to be equal to or higher than the pressure obtained by adding the target control differential pressure of the unload valve 9 to the Pr, the unload valve 9 opens and the pressure oil in the pressure oil supply oil passage 8a is supplied to the tank T. To drain. With this function, when the hydraulic cylinder of the actuator reaches the stroke end, the pressure of the hydraulic circuit including the pressure oil supply oil passage 8a (discharge pressure of the hydraulic pump 2) becomes Ps = Plmax, and the circuit pressure is released. The pressure is limited to a pressure obtained by adding the target control differential pressure of the unload valve 9 to the relieving pressure Pr set by the cut valve 13.

  The above operation is the same in this embodiment and the comparative example. When the relief cut valve 13 does not operate for some reason (such as a stick), the comparative example operates as follows.

  If the relief cut valve 13 does not operate for some reason (such as a stick), the pressure (maximum load pressure) in the signal pressure oil passage 10a will rise without restriction in the comparative example shown in FIG. In this state, the unloading valve 9A does not open, and the pressure in the pressure oil supply oil passage 8a (discharge pressure of the hydraulic pump 2) rises to a pressure higher than the relief pressure Pr set by the relief cut valve 13, which may damage the hydraulic equipment. is there.

  In the present embodiment, the pressure receiving chambers 9a and 9b of the unload valve 9 are set as Aa <Ab, where the pressure receiving areas are Aa and Ab, respectively. As a result, the balance of the forces acting on the unload valve 9 is as follows when the force by the spring 9c is Fsp.

Fsp = Ab * Ps-Aa * Plsmax
When the difference in pressure receiving area between the pressure receiving chambers 9a and 9b is ΔA,
Ab = Aa + ΔA
From Ps = Plsmax,
Fsp = (Aa + ΔA) × Ps−Aa × Plsmax
= ΔA × Plsmax (= ΔA × Ps)
As shown in the above equation, the unload valve 9 has an oil pressure obtained by multiplying the area difference ΔA between the pressure receiving portions 9 a and 9 b by the pressure of the pressure oil supply oil passage 8 a (discharge pressure of the hydraulic pump 2). 9 acts in the direction of opening. This force balances with the spring force Fsp of the spring 9c. Here, when the discharge pressure of the hydraulic pump 2 increases, the oil pressure due to the area difference ΔA increases accordingly, so that the spring displacement at which the spring force Fsp of the spring 9c corresponding to the oil pressure is obtained also increases, and the unload valve 9 operates with the displacement. That is, the notch 51f of FIG. 2 opens according to the displacement of the spring 9c. Thereby, the pressure oil of the flow volume according to the opening area of the notch 51f and the discharge pressure of the hydraulic pump 2 drains to the tank T, and an excessive increase in the discharge pressure of the hydraulic pump 2 can be prevented.

  Next, the operation of the unload valve 9 is verified.

  First, the change in the target control differential pressure (target unload differential pressure) due to the load-dependent characteristics of the unload valve 9 is verified.

Various quantities related to the unload valve 9 are expressed as follows.

F: force acting on the spool of the unload valve 9 x: spool stroke of the unload valve 9 k: spring constant of the spring 9c Aa: pressure receiving area of the pressure receiving portion 9a Ab: pressure receiving area of the pressure receiving portion 9b ΔA: pressure receiving portion 9a Area difference of pressure receiving portion 9b (ΔA = Ab−Aa)
ΔP: differential pressure between pump discharge pressure and maximum load pressure (ΔP = Ps−Plmax)
The relational expression of the behavior of the unload valve 9 can be expressed as follows.

F = kx = AbPs-AaPlmax
Here, since Ab = ΔA + Aa and Ps = Plmax + ΔP,
kx = (ΔA + Aa) (Plmax + ΔP) −AaPlmax
Expand this expression
kx = ΔAPlmax + (ΔA + Aa) ΔP (1)
Originally, in an unload valve that does not have load dependent characteristics, ΔA = 0 in the above equation (1).
kx = AaΔP
The differential pressure ΔP is controlled by the spring constant k. On the other hand, in the present invention, the differential pressure ΔP is obtained from the equation (1):
ΔP = (1 / ΔA + Aa) (kx−ΔAPlmax)
Is defined as This means that the control differential pressure ΔP of the unload valve 9 changes according to the maximum load pressure Plmax, and the spring constant of the spring 9c that sets the apparent unload valve control differential pressure is increased by the increase of the maximum load pressure Plmax. It will be lowered.

  Next, the influence on the control function as the unloading valve due to the load-dependent characteristics of the unloading valve 9 will be examined.

  Condition 1 when the relief cut valve 13 is immediately before the relief, condition 2 when the relief cut valve 13 does not operate for some reason and the unload valve 9 functions as a safety valve, and unloading in each state Consider the behavior of the valve.

<Condition 1>
Assuming that the relief set pressure by the spring 13a of the relief cut valve 13 is PR, since Plmax≈PR immediately before the relief, the above equation (1) is as follows.

F1 = kx1 = ΔAPR + (ΔA + Aa) ΔP (2)
<Condition 2>
For example, when the hydraulic actuators 5a and 5b reach the stroke end, the flow rate of the flow rate control valves 42a and 42b disappears, and the pressure loss at the meter-in throttle becomes 0, so Ps = Plmax. Therefore, since ΔP = 0, the above equation (1) is as follows.

F2 = kx2 = ΔAPlmax + (ΔA + Aa) × 0
= ΔAPlmax (3)
Assuming that the same opening area (= stroke) is obtained for the unload valve 9 under conditions 1 and 2, F1 = F2,
ΔAPR + (ΔA + Aa) ΔP = ΔAPlmax
ΔA (Plmax−PR) = (ΔA + Aa) ΔP
(ΔA + Aa) / ΔA = (Plmax−PR) / ΔP (4)
Here, specific numerical values are given as follows.

ΔP = PGR (target load sensing differential pressure) = 20 (kgf / cm ² )
PR = 230 (kgf / cm ² )
Plmax = 500 (kgf / cm ² )
Plmax = 500 (kgf / cm ² ) is the maximum load pressure (≈discharge pressure of the hydraulic pump 2) when the relief cut valve 13 does not operate for some reason and the unload valve 9 functions as a safety valve. Substituting these numbers into the right side of equation (4) above,
(ΔA + Aa) / ΔA = (Plmax−PR) / ΔP
= (500-230) /20=13.5
Therefore, the following relationship is obtained.

Aa: Ab = 12.5: 13.5 = 25: 27
That is, if the ratio of the pressure receiving area Aa of the pressure receiving part 9a and the pressure receiving area Ab of the pressure receiving part 9b is 25:27, even if the relief cut valve 13 does not operate for some reason, it depends on the load of the unloading valve 9. Due to the characteristics, the upper limit of the discharge pressure of the hydraulic pump 2 is limited to 500 kgf / cm ² .

  FIG. 4 is a diagram showing the flow characteristics of the unload valve 9 in the opening area assumed in the conditions 1 and 2. The horizontal axis in FIG. 4 is the flow rate (unload flow rate) flowing from the unload valve 9 to the tank T, and the vertical axis is the discharge pressure of the hydraulic pump 2. In conditions 1 and 2, it is assumed that the maximum discharge flow rate of the hydraulic pump 2 is limited to, for example, 30 L / min and 15 L / min, respectively, for horsepower control by the horsepower control tilt actuator 12a.

In condition 1, the maximum load pressure PLmax is ^{Plmax ≒ PR = 230kgf / cm 2} , because it is [Delta] P = 20 kgf / cm ^2, discharge pressure of the hydraulic pump 2 is ^{250kgf / cm 2 (= 25.0Mpa)} , The unload flow rate at this time is 10.6 L / min. Under condition 2, the discharge pressure of the hydraulic pump 2 is 500 kgf / cm ² (50.0 Mpa), and the unload flow rate at this time is 15 L / min. That is, in condition 1, about 1/3 of the discharge flow rate of the hydraulic pump 2 is unloaded, and in condition 2, the entire discharge flow rate of the hydraulic pump 2 is unloaded.

  Under condition 1, that about 1/3 of the discharge flow rate of the hydraulic pump 2 unloads means that that amount is wasted. However, when working in a high load region, force is often required rather than speed, and if about 2/3 of the discharge flow rate of the hydraulic pump 2 is supplied to the actuator, the work in the high load region is performed without any problem. It is thought that there are many cases where it is possible.

  On the other hand, the unload valve 9 has a load-dependent characteristic, and that part of the discharge flow rate of the hydraulic pump 2 unloads means that the unload valve 9 functions as a bleed valve. That is, when the area ratio is set to 25:27, the opening area of the unload valve 9 and the unload flow rate change as follows due to the load-dependent characteristics of the unload valve. When the discharge pressure Ps of the hydraulic pump 2 is low, the unload valve 9 is fully closed, and when the pump discharge pressure Ps rises to a certain pressure, the unload valve 9 starts to open, and then the unload valve with the rise of the pump discharge pressure Ps. The opening area of 9 increases, and the opening area of Condition 1 is obtained at Ps = 25 Mpa. Further, the unload flow rate also changes correspondingly, and when the discharge pressure Ps of the hydraulic pump 2 is low, the unload flow rate is 0, and when the unload valve 9 starts to open, the unload flow rate starts flowing, and then As the pump discharge pressure Ps increases, the unload flow rate increases. Under condition 1 where Ps = 25 Mpa, the unload flow rate becomes 10.6 L / min.

As a result of the operation of the unload valve 9 as described above, the unload valve 9 performs a function similar to the bleed function of the center bypass throttle in the open center type flow control valve, and this function allows pressure fluctuations during load sensing control. In addition, an additional effect that operability can be improved can be obtained.

  The present invention is not limited to the above embodiment, and various modifications and applications are possible. For example, in the above-described embodiment, the pressure compensation valves 41, 41b, 41c are the front type (before-orifice type) installed upstream of the meter-in throttle portions of the flow control valves 42a, 42b, 42c, respectively. Installed on the downstream side of the meter-in throttle part of the control valves 42a, 42b, and 42c, and the differential pressure across the meter-in throttle part is made the same by controlling the pressure on the downstream side of the meter-in throttle part to be the same as the maximum load pressure. A post-position type (after orifice type) to be controlled may be used. The pump tilt control mechanism 12 is hydraulically configured by the LS control valve 14 and the LS control tilt actuator 12b. However, the pump tilt control mechanism 12 may be configured electrohydraulic by a pressure sensor, a controller, and an electromagnetic valve. In this case, the discharge pressure and the maximum load pressure of the hydraulic pump are detected by a pressure sensor, the detected values are input to the controller, and the solenoid valve is controlled by the controller, whereby the discharge pressure of the hydraulic pump 2 and the plurality of actuators 5a, The tilt amount of the hydraulic pump 2 can be controlled so that the differential pressure between the maximum load pressure of 5b and 5c is maintained at the target load sensing differential pressure.

1 is a diagram showing a hydraulic drive device according to an embodiment of the present invention. It is sectional drawing which shows the structure of the unload valve with a load dependence characteristic. FIG. 2 is a view similar to FIG. 1 showing a hydraulic drive device when a load dependent characteristic is not given to an unload valve as a comparative example. It is a figure which shows the flow volume characteristic of the unload valve 9 in the opening area assumed on the conditions 1 and 2 conditions.

Explanation of symbols

1 Engine 2 Hydraulic pump (Main pump)
3 Hydraulic pump (pilot pump)
4 Control valve 4a, 4b, 4c Valve section 4d Inlet / outlet section 5a, 5b, 5c Actuator 6a, 6b Shuttle valve 7 Signal line 8a Pressure oil supply oil passage 9 Unload valve 9a, 9b Pressure receiving portion 9c Spring 9x Control pressure port 9y Discharge ports 10a and 10b Signal pressure oil passage 11 Restriction portion 12 Pump tilt control mechanism 12a Horsepower control tilt actuator 12b LS control tilt actuator 13 Relief cut valve (signal pressure relief valve)
13a Spring 13b Pressure receiving portion 13c Signal pressure oil passage 13x Control pressure port 13y Discharge port 14 LS control valve 15 Relief valve 41a, 41b, 41c Pressure compensation valve 42a, 42b, 42c Flow rate control valve

Claims (1)

A variable displacement hydraulic pump, a plurality of actuators driven by pressure oil discharged from the hydraulic pump, and a plurality of flow control valves for controlling the flow rate of the pressure oil supplied from the hydraulic pump to the plurality of actuators; ,
When the discharge pressure of the hydraulic pump becomes high, the horsepower control means for reducing the discharge amount (tilt) of the hydraulic pump and the discharge pressure of the hydraulic pump become higher by the target load sensing differential pressure than the maximum load pressure of the plurality of actuators. A pump discharge amount control mechanism having a load sensing control valve for controlling a discharge amount (tilt) of the hydraulic pump and a load sensing means including a load sensing control (tilt) actuator;
The discharge oil of the hydraulic supply circuit that opens when the plurality of flow control valves are neutral and guides the discharge oil of the hydraulic pump is discharged to a tank, and the discharge pressure of the hydraulic supply circuit is controlled to a target unload differential pressure. With a load valve,
The load sensing control valve receives the hydraulic pump discharge pressure and acts on the hydraulic pump discharge amount (inclination) in a decreasing direction, and the maximum load pressure of the plurality of actuators is guided to discharge the hydraulic pump A pressure receiving portion that causes the amount (tilt) to act in an increasing direction; and an urging means that acts on the hydraulic pump discharge amount (tilt) that sets the target load sensing differential pressure in an increasing direction;
The unload valve includes a first pressure receiving portion that guides a discharge pressure of the hydraulic pump to act on the unload valve in an opening direction, and closes the unload valve by guiding a maximum load pressure of the plurality of actuators. A hydraulic drive device comprising: a second pressure receiving portion that acts in a direction; and an urging means that acts in a closing direction of the unload valve that sets the target unload differential pressure.
A signal pressure oil passage that guides the maximum load pressure to the second pressure receiving portion of the unload valve, a throttle portion provided in the signal pressure oil passage, the throttle portion and the second pressure receiving portion of the signal pressure oil passage And a signal pressure relief valve provided between
The set pressure of the signal pressure relief valve is a rated pressure of a hydraulic circuit including the hydraulic supply oil passage,
Setting the area of the first pressure receiving portion of the unload valve to be larger than the area of the second pressure receiving portion, and setting the maximum load pressure at which the unload valve functions as a safety valve when the signal pressure relief valve fails and is inoperative; In addition, the stroke (opening area) equivalent to that of the unloading valve in the state immediately before the signal pressure relief valve of the unloading valve is relieved at a set pressure and the state of the maximum load pressure at which the unloading valve functions as a safety valve. The hydraulic drive device is characterized in that the ratio of the area of the first pressure receiving portion and the area of the second pressure receiving portion of the unload valve is set so that

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