JP2015059591A - Hydraulic drive device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hydraulic drive device capable of preventing a bleed-off valve from failing to function.SOLUTION: A hydraulic drive device 1 drives actuators 7, 9 by supplying a working fluid discharged from a hydraulic pump 11 to the actuators 7, 9. The hydraulic drive device 1 has: operation valves 13, 14; a flow rate control mechanism 12; a back pressure output mechanism 25; and a bleed-off valve 15. The operation valves 13, 14 output an output pressure of the pressure according to an inclination angle of operation levers 13a, 14a. The flow rate control mechanism 12 adjusts an opening according to the output pressure of the operation valves 13, 14 and supplies the working fluid of the flow rate according to the opening to the actuators 7, 9. The back pressure output mechanism 25 outputs a back pressure Paccording to an operation state. The bleed-off valve 15 is arranged parallel with the flow rate control mechanism 12 and discharges a pressure liquid of the flow rate according to a differential pressure Δp between a pilot pressure pfor bleed-off and the back pressure Pof the back pressure output mechanism to a tank.

Description

  The present invention relates to a hydraulic pressure drive device that supplies pressure liquid discharged from a hydraulic pressure pump to an actuator to drive the actuator.

  A construction machine such as a hydraulic excavator includes a plurality of hydraulic actuators, and by driving the hydraulic actuators, various components such as a boom, an arm, a bucket, a turning device, and a traveling device are moved to perform various operations. Be able to. The construction machine is provided with a hydraulic drive device as disclosed in Patent Document 1, for example, in order to drive these hydraulic actuators.

  The hydraulic drive device described in Patent Document 1 has a hydraulic pump, and drives the actuator by supplying pressure oil discharged from the hydraulic pump to the actuator. In the hydraulic drive device, a direction switching valve is provided in association with each actuator, and the direction switching valve switches the flow of pressure oil flowing through the corresponding actuator and adjusts the flow rate thereof. Further, the hydraulic drive device is provided with a bleed-off valve, and the bleed-off valve is adapted to discharge the pressure oil discharged from the hydraulic pump to the tank and adjust the flow rate flowing to each actuator. Further, in the hydraulic drive device, an operation device is provided in association with each actuator, and the operation device outputs an operation signal to the control device. The control device controls the opening areas of the direction switching valve and the bleed-off valve in accordance with an operation signal transmitted from the operation device, and supplies pressure oil having a direction and a flow rate in accordance with the operation signal to the actuator. .

JP-A-7-63203

  The bleed-off valve of the hydraulic drive device described in Patent Document 1 is configured by a so-called electromagnetic control valve, and is electrically connected to the control device via a signal line. A drive signal is transmitted from the control device to the bleed-off valve via this signal line, and the bleed-off valve adjusts its opening area in accordance with this drive signal. Therefore, when an electrical failure (such as a short circuit or disconnection) occurs in the signal line, the discharge amount of the pressure oil discharged from the hydraulic pump to the tank cannot be controlled, and the bleed-off valve does not function. As a result, the discharge pressure rises abnormally or a shock occurs when the actuator is operated.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a hydraulic drive device that can prevent a bleed-off valve from functioning.

  The hydraulic drive device of the present invention is a hydraulic drive device for driving the actuator by supplying the hydraulic fluid discharged from the hydraulic pump to the actuator, and when the operation lever is operated, An operation valve that outputs an output pressure corresponding to an operation amount, an opening degree is adjusted according to the output pressure of the operation valve, and a hydraulic fluid having a flow rate according to the opening degree and the load of the actuator is A flow rate according to an opening area based on a differential pressure between an output pressure of the operation valve and a back pressure of the back pressure output mechanism, a flow rate control mechanism supplied from the pump to the actuator, a back pressure output mechanism that outputs back pressure And a bleed-off valve that discharges the pressurized fluid from the hydraulic pump to the tank.

  According to the present invention, since the bleed-off valve moves according to the differential pressure between the back pressure of the back pressure output mechanism and the output pressure of the operation valve, it is possible to output the back pressure by appropriately setting the maximum pressure of the back pressure output mechanism. Even if the back pressure cannot be adjusted due to a mechanism failure or the like, the bleed-off valve can be operated according to the output pressure of the operation valve. Therefore, it is possible to prevent the bleed-off valve from functioning due to a failure or the like.

  In the above invention, the back pressure output mechanism outputs a back pressure corresponding to an operating state, and the operating state includes an operating state of the operating lever, an engine speed for driving the hydraulic pump, At least one state of the temperature of the pressure fluid and the load acting on the actuator may be included.

  If the said structure is followed, the efficient driving | operation according to the operation state is realizable.

  In the above invention, the back pressure output mechanism includes a control device and an electromagnetic control valve, the control device outputs a command signal corresponding to the operating state to the electromagnetic control valve, and the electromagnetic control valve The back pressure having a pressure corresponding to the input command signal may be output.

  According to the above configuration, since the electromagnetic control valve is employed, the setting can be made finely according to the operating state, and the operability can be finely tuned. Further, since the operability tuning operation can be performed only by setting the control device, the tuning operation of the hydraulic pressure driving device is facilitated, and the development time of the hydraulic pressure driving device can be shortened.

  In the above invention, the operation valve depressurizes the pressure liquid discharged from the first pilot pump to a pressure corresponding to the operation amount of the operation lever and outputs the pressure as the output pressure, and the electromagnetic control valve includes the first control valve. The pressure liquid discharged from the second pilot pump whose discharge pressure is lower than the discharge pressure of the pilot pump may be reduced and output as the back pressure.

  If the said structure is followed, it can prevent that the maximum value of the back pressure output from an electromagnetic control valve becomes higher than the maximum value of the output pressure output from an operating valve. As a result, even if a malfunction occurs in the electromagnetic control valve and the back pressure is constantly output, the bleed-off valve can be operated within a predetermined range by the output pressure from the operation valve. This prevents the bleed-off valve from becoming uncontrollable.

  In the above invention, the electromagnetic control valve may reduce the pressure of the pilot oil output from the operation valve and output it as the back pressure.

  If the said structure is followed, a 1st pilot pump will be used as a pressure source of an electromagnetic control valve, a 2nd pilot pump will become unnecessary and the hydraulic drive device of this invention will be obtained cheaply.

  In the above invention, the electromagnetic control valve may be configured such that the maximum output pressure is lower than the maximum output pressure of the first pilot pump.

  According to the above configuration, the output pressure from the operation valve can be made higher than the output pressure of the electromagnetic control valve even if the electromagnetic control valve continues to operate at the maximum opening or the minimum opening. The pressure liquid can be supplied to the actuator. Thereby, the situation where a hydraulic drive device does not operate | move by failure of an electromagnetic control valve can be prevented.

  In the above invention, comprising a plurality of the operation valves provided corresponding to the plurality of actuators respectively, and an output pressure selection mechanism for selecting the highest output pressure among the output pressures output from the plurality of operation valves, When the operation valve is operated and an output pressure is output, the flow control mechanism supplies a pressure fluid having a flow rate corresponding to the output pressure to an actuator corresponding to the operated valve. The bleed-off valve is configured to supply a hydraulic fluid having a flow rate corresponding to an opening area based on a differential pressure between an output pressure selected by the output pressure selection mechanism and a back pressure of the back pressure output mechanism from the hydraulic pump to the tank. The discharge amount may be reduced as the output pressure selected by the output pressure selection mechanism increases.

  If the said structure is followed, the discharge amount of the hydraulic fluid discharged | emitted from a hydraulic pump to a tank will be adjusted according to the largest output pressure, and discharge amount will become small, so that the said output pressure becomes large. Thereby, when a plurality of operation levers are operated, a flow rate corresponding to the largest operation amount among the operation amounts of these operation levers can be supplied to the actuator side.

  According to the present invention, it is possible to prevent the bleed-off valve from functioning.

It is a side view showing a hydraulic excavator provided with a fluid pressure drive of an embodiment of the present invention. It is a circuit diagram which shows the hydraulic circuit of the hydraulic drive apparatus of 1st Embodiment. It is a graph which shows the relationship between the lever stroke amount of the operation valve of a hydraulic-pressure drive device, and a variable bleed opening area. It is a circuit diagram which shows the hydraulic circuit of the hydraulic drive apparatus of 2nd Embodiment.

  Hereinafter, hydraulic drive units 1 and 1A and hydraulic excavators 2 including the hydraulic drive units 1 and 1A according to first and second embodiments of the present invention will be described with reference to the aforementioned drawings. In addition, the concept of the direction used in the following description is used for convenience in description, and does not limit the direction of the configuration of the invention in that direction. Further, the hydraulic drive devices 1 and 1A described below are only one embodiment of the present invention. Therefore, the present invention is not limited to the embodiments, and additions, deletions, and changes can be made without departing from the spirit of the invention.

<First Embodiment>
[Hydraulic excavator]
As shown in FIG. 1, a hydraulic excavator 2, which is an example of a construction machine, can perform various operations such as excavation and transportation with an attachment, for example, a bucket 3, attached to a tip portion. The excavator 2 has a traveling device 4 such as a crawler, and a revolving body 5 is placed on the traveling device 4 so as to be capable of turning. The swivel body 5 is configured to be capable of being swiveled by a swivel motor (not shown), and the swivel body 5 is formed with a driver seat 5a for a driver to board.

  The revolving body 5 is provided with a boom 6 that can swing in the vertical direction. The boom 6 extends obliquely upward and forward from the swing body 5, and a boom cylinder 7 is installed on the boom 6 and the swing body 5. The boom 6 swings upward or downward with respect to the revolving body 5 by expanding and contracting the boom cylinder 7. An arm 8 is provided at the tip of the boom 6 so as to be swingable in the front-rear direction. The arm 8 extends obliquely downward and forward from the tip of the boom 6, and an arm cylinder 9 is installed between the boom 6 and the arm 8. The arm 8 swings backward or forward with respect to the boom 6 by expanding and contracting the arm cylinder 9. Further, a bucket 3 is provided at the tip of the arm 8 so as to be swingable in the front-rear direction. A bucket cylinder 10 is provided on the bucket 3 and the arm 8, and the bucket 3 swings in the front-rear direction by expanding and contracting the bucket cylinder 10.

  The boom cylinder 7, the arm cylinder 9, the bucket cylinder 10, and the turning motor are hydraulic actuators, and are driven by supplying pressure liquid (operating oil in the present embodiment) to them. ing. The hydraulic excavator 2 includes a hydraulic drive device 1 that supplies hydraulic oil to the actuators 7, 9, 10 including a turning motor. The hydraulic drive device 1 supplies hydraulic oil to the actuators 7, 9, 10. To supply. Below, the structure of the hydraulic-pressure drive device 1 is demonstrated, referring FIG.

[Hydraulic drive]
The hydraulic drive device 1 includes a hydraulic pump 11, a flow rate control mechanism 12, a plurality of operation valves 13 and 14, and a bleed-off valve 15. The hydraulic pump 11 is connected to the engine E, and discharges the hydraulic fluid (operating oil or water, in this embodiment, operating oil) when the engine E rotates. The hydraulic pump 11 is a so-called variable displacement hydraulic pump and includes a swash plate 11a. The swash plate 11a changes the inclination angle according to the flow rate required for driving the actuator, and the hydraulic pump 11 discharges hydraulic fluid at a flow rate according to the angle of the swash plate 11a from the discharge port. The inclination angle of the swash plate 11a is controlled by, for example, negative control or positive control method. A main passage 16 is connected to the discharge port, and the main passage 16 is connected to the flow rate control mechanism 12. The hydraulic oil discharged from the hydraulic pump 11 is guided to the flow rate control mechanism 12 through the main passage 16.

  The flow control mechanism 12 is connected to actuators such as a boom cylinder 7, an arm cylinder 9, a bucket cylinder 10, and a turning motor, and the hydraulic oil from the hydraulic pump 11 is supplied to each actuator 7 including the turning motor. 9 and 10 can be supplied. In FIG. 2, for convenience of explanation, only the boom cylinder 7 and the arm cylinder 9 are shown, and the bucket cylinder 10 and the turning motor are not shown. The configuration of the flow control mechanism 12 will be described in more detail. The flow control mechanism 12 has a direction switching valve (not shown) provided for each of the actuators 7, 9, and 10. The directional switching valves are respectively connected to two ports of the corresponding actuators 7, 9, and 10 (in the case of the boom cylinder 7 and the arm cylinder 9, the cylinder head side ports 7a and 9a and the rod side ports 7b and 9b), respectively. It is connected so that the port of the hydraulic oil supply destination can be switched by switching the flow direction of the hydraulic oil. Further, the direction switching valve adjusts the opening degree of the opening so that the flow rate of hydraulic oil corresponding to the load of the actuators 7, 9, 10 corresponding to the opening degree flows to the corresponding actuators 7, 9, 10. It has become. A plurality of operation valves 13 and 14 are connected to the flow rate control mechanism 12 configured as described above.

  The operation valves 13 and 14 are associated with each direction switching valve (that is, for each of the actuators 7, 9 and 10), and are provided in the driver's seat 5 a. In the following, for convenience of explanation, only the operation valves 13 and 14 associated with the boom cylinder 7 and the arm cylinder 9 will be described with reference to FIG. The illustration and description of are omitted. The operation valves 13 and 14 have operation levers 13a and 14a, respectively. The operation levers 13a and 14a can be tilted in the first and second directions with respect to the neutral position. Moreover, the 1st pilot pump 20 is connected to the operation valves 13 and 14, respectively. The first pilot pump 20 is a so-called fixed displacement hydraulic pump, and a fixed amount of pilot oil is discharged. The pilot oil discharged from the first pilot pump 20 is guided to the operation valves 13 and 14, respectively. The operation valves 13 and 14 direct the guided pilot oil in a direction corresponding to the tilting direction of the operation levers 13a and 14a. The pressure is reduced to a pressure corresponding to the operation amount (that is, the tilt angle) and output.

More specifically, two pilot passages 17a and 17b are connected to the boom operation valve 13, and two pilot passages 18a and 18b are connected to the arm operation valve 14, respectively. Boom control valve 13, the operation lever 13a is a first direction (e.g., forward) when operated, the pilot oil of the output pressure p ₁ in accordance with the tilt angle of the operating lever 13a in one of the pilot passage 17a It is designed to output. On the other hand, the operating lever 13a is the second direction (e.g., rearward) when operated, the operation valve 13 for boom, the other pilot passage 17b to the pilot oil output pressure p ₂ in accordance with the tilt angle of the operating lever 13a To output. The pilot oil output to the pilot passages 17a and 17b is input to the flow rate control mechanism 12, and the direction switching valve associated with the boom cylinder 7 in the flow rate control mechanism 12 changes the tilt direction and tilt angle of the operation lever 13a. Moves accordingly. That is, the direction of the hydraulic oil flowing through the boom cylinder 7 is switched to the direction corresponding to the tilt direction, and the opening degree of the direction switching valve is adjusted to the opening degree corresponding to the tilt angle. As a result, hydraulic fluid is supplied from the hydraulic pump 11 to the boom cylinder 7 via the flow rate control mechanism 12.

It operated valve 14 for the arm, also when the operating lever 14a is operated in the first direction, and outputs the pilot oil output pressure p ₃ in accordance with the tilt amount in one of the pilot passage 18a, the operation lever 14a is first When operated in two directions, and outputs a pilot oil output pressure p ₄ in accordance with the tilt amount in the other pilot passage 18b. The pilot oil output to the pilot passages 18a and 18b is input to the flow rate control mechanism 12, and the direction switching valve associated with the arm cylinder 9 in the flow rate control mechanism 12 changes the tilt direction and tilt angle of the operation lever 14a. Moves accordingly. That is, the direction of the hydraulic oil flowing through the arm cylinder 9 is switched to the direction corresponding to the forward tilt direction, and the opening degree of the direction switching valve is adjusted to the opening degree corresponding to the tilt angle. As a result, hydraulic fluid is supplied from the hydraulic pump 11 to the arm cylinder 9 via the flow rate control mechanism 12.

A high pressure selection mechanism 19 is connected to the pilot passages 17a, 17b, 18a, 18b of the operation valves 13, 14 configured as described above. The high pressure selection mechanism 19 selects and outputs the highest output pressure among the output pressures p _{1 to} p ₄ output from the operation valves 13 and 14. More specifically, the high-pressure selection mechanism 19 has three shuttle valves 21, 22, and 23, and the first shuttle valve 21 is connected to the two pilot passages 17 a and 17 b of the operation valve 13. The higher hydraulic pressure of the pilot passages 17a and 17b is selected and output to the downstream side. The second shuttle valve 22 is connected to the two pilot passages 18a and 18b of the operation valve 14, so that the higher one of the hydraulic pressures in the pilot passages 18a and 18b is selected and output to the downstream side. It has become. Further, the third shuttle valve 23 selects the higher one of the two hydraulic pressures output from the first and second shuttle valves 21 and 22, respectively. The third shuttle valve 23 is connected to the bleed-off valve 15, and outputs it to the bleed-off valve 15 the hydraulic pressure selected as the pilot pressure p _b for bleed-off.

The bleed-off valve 15 is connected to the main passage 16 and connects the main passage 16 and the tank 24. The bleed-off valve 15 is configured to discharge the hydraulic oil flowing through the main passage 16 to the tank 24 and adjust the flow rate of the hydraulic oil flowing from the hydraulic pump 11 to the flow rate control mechanism 12. Bleed-off valve 15 is a so-called normal-open spool valve, the bleed-off pilot pressure p _b from the third shuttle valve 23 of the high pressure selection mechanism 19 is adapted to act on the spool 15a. Further, the bleed-off valve 15, the spring member 28 to urge the spool 15a is provided against the bleed-off pilot pressure p _b. Further, the spool 15a, and acts back pressure p _a against the bleed-off pilot pressure p _b, bleed-off valve 15, the differential pressure between the pilot pressure p _b and the back pressure p _a a bleed-off The opening degree of the opening is adjusted according to Δp. By adjusting the opening degree of the thus opening the bleed-off valve 15, a tank discharge amount of hydraulic oil from the hydraulic pump 11 in accordance with the pressure difference Δp between the pilot pressure p _b and the back pressure p _a a bleed-off It is discharged into the tank 24. This is the bleed-off valve 15 that is configured to, and back pressure output mechanism 25 is connected, so that the back pressure p _a dorsal pressure output mechanism 25 to bleed-off valve 15 is output.

The back pressure output mechanism 25 has a second pilot pump 26 and an electromagnetic proportional control valve 27. The second pilot pump 26 is a so-called fixed displacement hydraulic pump, and a fixed amount of pilot oil is discharged. The discharge pressure of the second pilot pump 26 is set lower than the discharge pressure of the first pilot pump 20, and is set to about 20% to 80%, for example. The discharge port 26 a of the second pilot pump 26 is connected to the bleed-off valve 15 via an electromagnetic proportional control valve 27. The electromagnetic proportional control valve 27 is a normally closed electromagnetic proportional control valve, and may be configured to increase the opening of the opening in proportion to an input signal (current value). It may be a normally open electromagnetic proportional control valve that is characteristic. Hereinafter, the electromagnetic proportional control valve 27 will be described as a normally closed type. Electromagnetic proportional control valve 27 configured in this way, the pressure was reduced to a pressure corresponding to the current input the discharge pressure of the second pilot pump 26, the spool of the bleed-off valve 15 to its output as a back pressure p _a It is made to act on 15a.

The hydraulic pressure driving device 1 includes a rotation speed sensor 31, an oil temperature sensor 32, a plurality of pilot pressure sensors PS1 to PS4, and a plurality of hydraulic pressure sensors LS1 to LS4. The rotation speed sensor 31 detects the rotation speed of the engine E, and the oil temperature sensor 32 detects the temperature of the hydraulic oil flowing through the main passage 16. Further, the pilot sensor PS1~PS4, the pilot passage 17a of the operation valves 13, 14, 17b, 18a, provided respectively to 18b, the output pressure _p 1 ~p ₄ outputted from the operation valves 13 and 14 Each one is to be detected. The hydraulic sensors LS1 to LS4 are respectively provided in passages 33 to 36 that connect the flow control mechanism 12 and the actuators 7, 9, and 10, respectively, and flow from the flow control mechanism 12 to the actuators 7, 9, and 10, respectively. The hydraulic pressure of the hydraulic oil is detected. The various sensors 31, 32, PS 1 to PS 4, LS 1 to LS 4 configured in this way are electrically connected to the control device 30 and output detection results to the control device 30.

  The control device 30 is electrically connected to the electromagnetic proportional control valve 27 in addition to the various sensors 31, 32, PS1 to PS4, LS1 to LS4. The control device 30 determines whether or not the hydraulic drive device 1 satisfies predetermined operating conditions based on the detection results output from the various sensors 31, 32, PS1 to PS4, LS1 to LS4, When it is determined that a predetermined operating condition is satisfied, the current that flows through the electromagnetic proportional control valve 27 is determined according to the operating condition that is satisfied. That is, the control device 30 is configured to flow a current corresponding to the operating state of the hydraulic pressure driving device 1 to the electromagnetic proportional control valve 27. Here, the operating state includes, for example, the operating state of the operating valves 13 and 14 (that is, the tilted state of the operating levers 13a and 14a), the rotational speed of the engine E, the temperature of the operating oil, and the actuators 7, 9, and 10. Load to be included.

[Operation of hydraulic drive unit]
Below, operation | movement of the hydraulic-pressure drive device 1 is demonstrated. In the hydraulic drive device 1, the operating lever 13a, when any one of 14a is tilted, the tilting has been operating lever 13a, the output pressure _p 1 ~p ₄ in a direction corresponding to the tilting direction of 14a is output. For example, when the operation lever 13a is tilted forward, the first output pressure p ₁ is outputted to the pilot passage 17a. When the first output pressure _{p 1} is output, the first output pressure _{p 1} in the first and third shuttle valve 21 and 23 is selected, the first output pressure _{p 1} is the pilot pressure _{p b} for bleed-off It is input to the spool 15 a of the bleed-off valve 15.

Further, when the pressure detected by the first output pressure p ₁ is output pilot pressure sensor PS1, the control unit 30 determines that the operating valve 13 based on the detection result has been operated, the operating state are you satisfied the predetermined operating condition in order to output the back pressure p _b in accordance whether the judges. For example, the control device 30 determines whether or not the oil temperature satisfies a predetermined operating condition (specifically, a predetermined temperature or higher) based on the detection result of the oil temperature sensor 32. Based on the detection result of the rotational speed sensor 31, it is determined whether or not the rotational speed of the engine E satisfies a predetermined operating condition (specifically, a predetermined rotational speed or less), or the hydraulic pressure sensor LS1. Based on the detection result of LS4, it may be determined whether or not the load of the actuators 7 and 9 satisfies a predetermined operating condition (specifically, a predetermined load or less). The control device 30 adjusts the magnitude of the current flowing through the electromagnetic proportional control valve 27 according to whether or not the operating condition is satisfied (that is, according to the operating state). For example, the control device 30, if that satisfies the operating conditions, for channeling current larger than when not satisfy the operating conditions, when the back pressure p _a of the case of satisfying the operating conditions do not satisfy the operating conditions It has to be larger than that of the back pressure p _a. In addition, a current map is set for each of the actuators 7 and 9, and the magnitude of the current flowing from the control device 30 to the electromagnetic proportional control valve 27 is determined according to whether the operating conditions for each actuator 7 and 9 are satisfied. You may adjust. By current from this control unit 30 to the electromagnetic proportional control valve 27 is flowed, the discharge pressure of the second pilot pump 26 is reduced by the electromagnetic proportional control valve 27, the spool 15a of the bleed-off valve 15 as back pressure p _a It acts to resist bleed-off pilot pressure p _b in.

In this way bleed-off valve 15, the bleed-off pilot pressure p _b acts on the spool 15a, further biasing force and the back pressure p _a of the spring member 28 to resist the bleed-off pilot pressure p _b action doing. Then, the spool 15a is moved bleed-off pilot pressure _{p b,} the back pressure _{p a,} and to a position where the biasing force of the spring member 28 are balanced. Thus, the opening of the opening degree of the bleed-off valve 15 is adjusted to the opening degree corresponding to the pressure difference Δp between the pilot pressure p _b and the back pressure p _a a bleed-off, and is discharged from the hydraulic pump 11 to the tank 24 The amount of hydraulic oil discharged is adjusted. As a result, hydraulic fluid having a flow rate corresponding to the tilt angle of the operation lever 13a and the operating conditions is guided from the hydraulic pump 11 to the flow control mechanism 12.

The flow control mechanism 12 operates in response to the first output pressure p ₁ of the directional control valve is operated valves 13, that is, the direction switching valve is operated in accordance with the tilting direction and the tilting angle of the operating lever 13a. As a result, hydraulic oil having a flow rate corresponding to the tilt angle of the operation lever 13a is supplied from the hydraulic pump 11 to the rod side 7b of the boom cylinder 7, and at a speed corresponding to the tilt angle and in the tilt direction of the operation lever 13a. The boom 6 tilts in the corresponding direction (ie, downward).

In the hydraulic drive apparatus 1 operates in this manner, are allowed to act back pressure p _a to the spool 15a against the bleed-off pilot pressure p _b. Therefore, if the back pressure p _a is not acting on the spool 15a is not able to only adjusting the opening of the opening of the bleed-off valve 15 for tilting angle of the operating lever 13a on the thick line in FIG. 3, the back it is possible to adjust the pressure p _a of the opening of the aperture of the bleed-off valve 15 for tilting angle of the operating lever 13a by the action on the spool 15a within the shaded area of FIG. Thus, according to the operating state of the solenoid proportional control valve by adjusting the back pressure p _a by changing the current applied to the 27, hydraulic drive unit be tilted angle of the same operating lever 13a 1 in accordance with the operating state Thus, the opening degree of the bleed-off valve 15 can be adjusted. That is, fine bleed-off control can be performed by setting so as to change the current flowing through the electromagnetic proportional control valve 27 according to the operating state.

  For example, in a high-temperature environment where the oil temperature is equal to or higher than a predetermined temperature, the viscosity of the hydraulic oil is low, and a large amount of hydraulic fluid may be supplied to the boom cylinder 7 during the startup operation of the boom 6 to cause an impact. In the hydraulic pressure driving device 1, when the oil temperature is equal to or higher than a predetermined temperature and the operation condition is satisfied, the opening degree of the bleed-off valve 15 is increased and the amount discharged to the tank 24 is increased. As a result, the impact can be mitigated by suppressing the flow rate of the hydraulic oil flowing through the boom cylinder 7. Similarly, when the number of revolutions of the engine E increases and the discharge amount from the hydraulic pump 11 increases, the opening degree of the bleed-off valve 15 is increased to increase the discharge amount to the tank 24. Thus, the impact can be mitigated by suppressing the flow rate of the hydraulic oil flowing through the boom cylinder 7.

In thus constructed hydraulic drive device 1, it is possible that the back pressure p _a in accordance with the operating state by the output from the electromagnetic proportional control valve 27 for adjusting the opening degree of the opening of the bleed-off valve 15. Therefore, by setting the operating conditions, it is possible to alleviate the above-described impact and improve the operability, and conversely reduce the opening of the bleed-off valve 15 to save energy. Moreover, because it uses an electromagnetic proportional control valve to the electromagnetic proportional control valve 27, the back pressure p _a to the output can be accurately controlled. Thereby, the operability can be finely tuned. Furthermore, since the operability tuning work related to the bleed-off valve 15 can be performed only by setting the control device 30, the tuning work of the hydraulic pressure driving device 1 is facilitated, and the development time of the hydraulic pressure driving device 1 is shortened. be able to.

Further, the hydraulic drive apparatus 1, a high pressure even if it can not back pressure p _a and electrical faults in the signal line 37 connecting the electromagnetic proportional control valve 27 and the control unit 30 (the short and disconnection or the like) is generated the output The bleed-off valve 15 operates according to the bleed-off pilot pressure p _b output from the selection mechanism 19. Therefore, it is possible to prevent the bleed-off valve 15 from functioning even if an electrical failure occurs in the signal line 37. Further, the output pressure of the bleed-off valve 15 of the electromagnetic proportional control valve 27, so acts in a direction to counter the bleed-off pilot pressure P _b, the operating lever 13a, in the state of 14a are all neutral, event, the electromagnetic Even if the proportional control valve 27 malfunctions, the problem that the opening of the bleed-off valve 15 is closed can be prevented. In this way, the fail safe of the hydraulic pressure driving device 1 can be realized with respect to the malfunction related to the electromagnetic proportional valve 27.

In the hydraulic pressure driving device 1, the discharge pressure of the second pilot pump 26 that is the pressure source of the electromagnetic proportional control valve 27 is set lower than the discharge pressure of the first pilot pump 20 that is the pressure source of the operation valves 13 and 14. cage, never higher than the maximum value of the output pressure of the maximum value of the back pressure p _a which is output from the electromagnetic proportional control valve 27 is outputted from the operation valve 13. Thus, the operation lever 13a, 14a is despite being tilted, bleed-off valve 15 tall pressure p _a of the electromagnetic proportional control valve 27 can be prevented a situation where not operate. Specifically, even continuously output the electromagnetic proportional control valve 27 the back pressure p _a left valve body the opening is opened by the failure or the like is to stick operation lever 13a, the bleed-off by causing 14a is greatly tilted The valve 15 can be operated, and it is possible to prevent the bleed-off valve 15 from functioning.

Thus, since the bleed-off valve 15 is moved in accordance with the pressure difference between the output pressure p _b of the back pressure p _a and operating valve back pressure output mechanism 25, sets the maximum pressure of the back pressure output mechanism 25 appropriately it is possible to operate the bleed-off valve 15 in accordance with the output pressure p _b of the back pressure output mechanism 25 failure or the like to the back pressure P _a is also no longer possible to adjust the operating valve 13, 14 by. Therefore, it is possible to prevent the bleed-off valve 15 from functioning due to a failure or the like.

Moreover, the two operating levers 13a, when 14a is tilted at the same time, each output pressure _p 1 ~p ₄ is outputted from each of the operating valves 13, 14. For example, the operating lever 13a is the second direction (i.e., backward) is tilted, the operation lever 14a is a first direction (i.e., forward) when tilted to the second output pressure p ₂ is output to the pilot passage 17b, the third output pressure _{p 3} is outputted to the pilot passage 18a. When the second and third output pressures p ₂ and p ₃ are output, the first and second shuttle valves 21 and 22 select the second and third output pressures p ₂ and p ₃ , respectively, The third output pressures p ₂ and p ₃ are output to the third shuttle valve 23. The third shuttle valve 23 selects the higher one of the second and third output pressures p ₂ and p ₃ and applies the output pressure to the spool 15a as the bleed-off pilot pressure p _b . Thereby, the opening degree of the opening of the bleed-off valve 15 can be adjusted according to the higher one of the second and third output pressures p ₂ and p ₃ . As a result, a flow rate corresponding to the largest tilt angle of the two operated levers 13a and 14a can be supplied to the actuators 7 and 9 side, and the movement of the actuator is caused by the insufficient flow rate. This can be suppressed.

Second Embodiment
The hydraulic pressure driving device 1A of the second embodiment is similar in configuration to the hydraulic pressure driving device 1 of the first embodiment, and the maximum output pressure of the electromagnetic proportional control valve 27A is higher than the maximum discharge pressure of the first pilot pump 20. and a low point is also different from the point that the solenoid proportional control valve 27A is a pressure source bleed-off pilot pressure p _b is the output from the high pressure selection mechanism 19. Specifically, as shown in FIG. 4, the input port 27a of the electromagnetic proportional control valve 27A is connected to a passage 41 connecting the third shuttle valve 23 and the bleed-off valve 15, and the electromagnetic proportional control valve 27A is , and it outputs the back pressure p _a to depressurize the pilot pressure p _b for bleed-off.

In the thus configured to have a hydraulic drive apparatus 1A, it is not possible to back pressure p _a, which is reduced in pressure by the solenoid proportional control valve 27A is higher than the pilot pressure p _b for bleed-off. Therefore, the bleed-off valve 15 can be moved even when the opening of the electromagnetic proportional control valve 27A is not closed (for example, even if the opening is continued at the maximum opening or the minimum opening). Thereby, even if the electromagnetic proportional control valve 27A fails or the control device 30 fails, it is possible to prevent the bleed-off valve 15 from functioning.

Further, since the output pressure of the solenoid proportional control valve 27A acts in a direction against the pilot pressure p _b for bleed-off, the operating lever 13a of the operating valve 13, 14, in a neutral state in which 14a is not operated, the solenoid proportional control valve Even if 27A malfunctions, the bleed-off valve 15 does not close. Therefore, fail-safe is achieved in the hydraulic drive device 1A.

  The hydraulic drive device 1A of the second embodiment has the same operational effects as the hydraulic drive device 1 of the first embodiment.

[Other Embodiments]
In the hydraulic drive units 1 and 1A of the first and second embodiments, a normally closed electromagnetic proportional control valve is employed as the electromagnetic proportional control valve 27, but a normally open electromagnetic inverse proportional control valve is employed. May be. Further, in the hydraulic pressure drive device 1 of the first embodiment, the second pilot pump 26 is configured such that its discharge pressure is lower than the discharge pressure of the first pilot pump 20, but it is not necessarily configured as such. You don't have to. For example, it may be an electromagnetic proportional control valve 27 so that the maximum value of the output possible back pressure p _a is lower than the maximum value of the pilot pressure p _b a printable bleed-off. The actuators 7, 9, and 10 are not limited to those described above, and may be a steering cylinder or a travel drive motor. The hydraulic pump 11 does not necessarily need to be a variable displacement pump, and may be a fixed displacement pump. Furthermore, the pressure fluid used is not limited to hydraulic oil, and may be water or other liquid.

DESCRIPTION OF SYMBOLS 1,1A Hydraulic drive device 7 Boom cylinder 9 Arm cylinder 10 Bucket cylinder 11 Hydraulic pump 12 Flow control mechanism 13, 14 Operation valve 13a, 14a Operation lever 15 Bleed-off valve 19 High pressure selection mechanism 20 1st pilot pump 25 Back Pressure Output Mechanism 26 Second Pilot Pump 27 Proportional Control Valve 30 Control Device

Claims (7)

A hydraulic drive device for supplying the hydraulic fluid discharged from the hydraulic pump to the actuator to drive the actuator,
An operation valve provided with an operation lever that outputs an output pressure corresponding to the operation amount when the operation lever is operated;
A flow rate control mechanism that adjusts the opening according to the output pressure of the operation valve, and supplies the hydraulic fluid at a flow rate according to the opening and the load of the actuator from the hydraulic pump to the actuator;
A back pressure output mechanism that outputs back pressure;
A hydraulic pressure drive comprising: a bleed-off valve that discharges a hydraulic fluid having a flow rate corresponding to an opening area based on a differential pressure between an output pressure of the operation valve and a back pressure of the back pressure output mechanism from the hydraulic pump to the tank. apparatus. The back pressure output mechanism outputs a back pressure of a pressure according to an operating state,
The operation state includes at least one of an operation state of the operation lever, a rotational speed of an engine driving the hydraulic pump, a temperature of the hydraulic fluid, and a load acting on the actuator. 2. The hydraulic drive device according to 1. The back pressure output mechanism has a control device and an electromagnetic control valve,
The control device outputs a command signal corresponding to the operating state to the electromagnetic control valve,
The hydraulic drive device according to claim 2, wherein the electromagnetic control valve outputs the back pressure having a pressure corresponding to the input command signal. The operation valve reduces the pressure liquid discharged from the first pilot pump to a pressure corresponding to the operation amount of the operation lever, and outputs the pressure as the output pressure,
The said electromagnetic control valve pressure-reduces the hydraulic fluid discharged from the 2nd pilot pump whose discharge pressure is lower than the discharge pressure of the said 1st pilot pump, and outputs it as the said back pressure. Hydraulic drive device.   The hydraulic drive device according to claim 3, wherein the electromagnetic control valve is configured to reduce the pressure of pilot oil output from the operation valve and output the pressure as the back pressure.   The hydraulic drive apparatus according to claim 3 or 5, wherein the electromagnetic control valve is configured such that a maximum output pressure thereof is lower than a maximum output pressure of the first pilot pump. A plurality of the operation valves provided corresponding to the plurality of actuators, respectively;
An output pressure selection mechanism for selecting the highest output pressure among the output pressures output from the plurality of operation valves;
When the operation valve is operated and an output pressure is output, the flow control mechanism supplies a pressure fluid having a flow rate corresponding to the output pressure to an actuator corresponding to the operated valve. ,
The bleed-off valve discharges from the hydraulic pump to the tank a flow of pressure corresponding to the opening area based on the differential pressure between the output pressure selected by the output pressure selection mechanism and the back pressure of the back pressure output mechanism. The hydraulic pressure drive device according to any one of claims 1 to 6, wherein the discharge amount discharged to the tank is reduced as the output pressure selected by the output pressure selection mechanism increases.

Images