JP2012159123A - Hydraulic driving device of construction machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hydraulic driving device of a construction machine capable of suppressing the fluctuation of the moving speed of hydraulic actuators according to the variation of load pressure while reducing energy loss when driving the plurality of hydraulic actuators at the same time dividing the discharged oil of a hydraulic pump.SOLUTION: The control device 40 controls the torque needed for the rotation of a generator 65 or 66 corresponding to a low load cylinder in which load pressure is lower of the hydraulic cylinders 21, 22 using inverters 67 or 68 in the case the load pressures of the hydraulic cylinders 21, 22 (a plurality of hydraulic actuators) are detected by pressure sensors 71 to 74 and both the hydraulic cylinders 21, 22 are operated, the fluctuation of the differential pressure of the upstream and the downstream of a direction switching valve 24 or 25 is suppressed corresponding to the low load cylinder by raising the resistance of the rotation of the hydraulic motor 63 or 64 corresponding to the low load cylinder, a storage device 80 stores electric energy generated by the generator 65 or 66.

Description

  The present invention includes a hydraulic pump shared by a plurality of hydraulic actuators as a hydraulic source, and when driving the plurality of hydraulic actuators at the same time, the hydraulic pressure of a construction machine that distributes the discharged oil of the hydraulic pump to the hydraulic actuators The present invention relates to a driving device.

  A conventional hydraulic drive device of this type is provided between each of a plurality of hydraulic actuators and a hydraulic pump in association with each hydraulic actuator, and a throttle valve that adjusts the operating speed of the hydraulic actuator; Some of them include a pressure compensation valve that is provided in association with each hydraulic actuator and suppresses fluctuations in the operating speed of the hydraulic actuator as the load pressure of the hydraulic actuator fluctuates.

  In the conventional hydraulic drive apparatus configured as described above, during operation of a plurality of hydraulic actuators, load pressures of the hydraulic actuators are usually different from each other. The pressure compensation valve associated with each hydraulic actuator behaves according to the load pressure so that the pressure difference between the upstream and downstream of the throttle valve associated with the same hydraulic actuator as this pressure compensation valve is constant. Further, it is possible to prevent the flow rate of the hydraulic oil supplied to the hydraulic actuator from fluctuating with the fluctuation of the load pressure, that is, the fluctuation of the operating speed of the hydraulic actuator.

  For the conventional hydraulic drive apparatus described here, refer to Patent Document 1.

Special table 2007-505270

  In the conventional hydraulic drive unit described above, the load pressure lower than the maximum load pressure among the load pressures of multiple hydraulic actuators corresponds to the hydraulic actuator that the lower load pressure acts as the pressure difference from the maximum load pressure increases. The pressure loss at the attached pressure compensation valve, that is, the energy loss is increased.

  The present invention has been made in consideration of the above-described circumstances. The purpose of the present invention is to distribute hydraulic oil discharged from a hydraulic pump and drive a plurality of hydraulic actuators at the same time. It is an object of the present invention to provide a hydraulic drive device for a construction machine that can suppress fluctuations in operating speed while reducing energy loss.

  In order to achieve the above-described object, the hydraulic drive device for a construction machine according to the present invention is configured as follows.

[1] A hydraulic drive device for a construction machine according to the present invention is provided in association with each of a hydraulic pump, a plurality of hydraulic actuators that are driven by supply of the discharge oil of the hydraulic pump, and the plurality of hydraulic actuators. A directional control valve for controlling a flow of pressure oil supplied from the hydraulic pump to the associated hydraulic actuator, and a hydraulic drive device for a construction machine, wherein each upstream of the plurality of directional control valves A pressure compensation unit that suppresses a variation in downstream pressure difference; a plurality of load pressure detection units that detect respective load pressures of the plurality of hydraulic actuators; and a power storage device, wherein the pressure compensation unit includes the plurality of hydraulic pressures. A generator associated with each of the actuators and a plurality of power generation hydraulic motors that drive each of the generators. And a resistance adjusting means for adjusting the resistance of rotation of each of the power generating hydraulic motors, and a control means for controlling these resistance adjusting means, wherein the power generating hydraulic motor is one of the plurality of hydraulic actuators. It is driven by pressure oil supplied to a hydraulic actuator associated with the power generation hydraulic motor or pressure oil discharged from the hydraulic actuator, and the control means is one of the plurality of hydraulic actuators. The resistance adjusting means associated with a low load actuator which is a hydraulic actuator to which a load pressure lower than the maximum load pressure is applied when any two or more of them are operating. And the rotational resistance of the power generating hydraulic motor associated with the low load actuator is increased. By suppressing the fluctuation of the pressure difference upstream and downstream of the directional control valve associated with the low load actuator, the power storage device is generated by the generator associated with the low load actuator It is characterized by storing electrical energy.

  In the hydraulic drive system for a construction machine described in “[1]”, the control unit controls the resistance adjusting unit associated with the low load actuator, and the rotation of the power generation hydraulic motor associated with the low load actuator is performed. Increase the resistance. As a result, the load pressure of the low load actuator can be increased to the maximum load pressure, and fluctuations in the pressure difference between the upstream and downstream of the direction switching valve associated with the low load actuator can be suppressed. Therefore, when the discharge oil of the hydraulic pump is distributed and a plurality of hydraulic actuators are driven at the same time, fluctuations in the operating speed of the hydraulic actuators accompanying fluctuations in load pressure can be suppressed.

  Further, in the hydraulic drive device for a construction machine described in “[1]”, the power storage device stores electrical energy generated by a generator associated with the low load actuator. Thus, energy loss can be reduced when suppressing fluctuations in the operating speed of the hydraulic actuator accompanying fluctuations in load pressure.

[2] A hydraulic drive device for a construction machine according to the present invention is the hydraulic drive device for a construction machine according to “[1]”, wherein the power generation hydraulic motor of the pressure compensating means is associated with the hydraulic drive device. It is driven by pressure oil discharged from the hydraulic actuator.

  Some working devices included in construction machines include a boom that is turned up and down by a boom cylinder (hydraulic cylinder). The boom cylinder is subjected to the gravity of the working device, and the boom cylinder can be contracted by rotating the working device downward by the gravity, and the pressure oil is discharged along with the contraction. In the hydraulic drive device for a construction machine described in “[2]”, since the power generation hydraulic motor of the pressure compensation means is driven by the pressure oil discharged from the hydraulic actuator, the hydraulic actuator is used as a boom cylinder. When applied, when the boom cylinder contracts due to the gravity of the working device and the pressure oil is discharged, the hydraulic motor is driven by the pressure oil to cause the generator to generate power, and the power storage device can be charged. That is, a part of the potential energy of the work device can be converted into electrical energy and stored.

  According to the hydraulic drive device for a construction machine according to the present invention, as described above, when the hydraulic pump discharge oil is distributed and a plurality of hydraulic actuators are driven at the same time, the operation of the hydraulic actuator accompanying a change in load pressure is performed. Speed fluctuations can be suppressed while reducing energy loss.

1 is a left side view of a hydraulic excavator that is a construction machine in which a hydraulic drive device according to an embodiment of the present invention is employed. 1 is a hydraulic circuit diagram showing a hydraulic drive device according to an embodiment of the present invention. It is a block diagram which shows the pressure compensation function of the hydraulic drive unit shown in FIG.

  A hydraulic drive apparatus according to an embodiment of the present invention will be described with reference to FIGS.

  A hydraulic excavator 1 shown in FIG. 1 includes a traveling body 2 that travels by driving a crawler belt 2a, a revolving body 3 that is pivotably coupled to the traveling body 2, and a front work provided at a front portion of the revolving body 3. Device 4.

  The swing body 3 includes a cab 3a provided on the left side of the front working device 4, a machine room 3b provided behind the cab 3a, and a rear end of the swing body 3 provided behind the machine room 3b. Counterweight 3c. The swing body 3 uses a swing motor (not shown) as a drive source.

  The front work device 4 includes a boom 5 coupled to the front portion of the revolving structure 3 so as to be pivotable in the vertical direction, an arm 6 coupled to the boom 5 so as to be pivotable, and a pivot to the arm 6. Connected buckets 7. The boom 5, the arm 6 and the bucket 7 are each driven by a hydraulic cylinder composed of a single rod double acting cylinder, that is, a so-called boom cylinder 8, arm cylinder 9 and bucket cylinder 10, respectively.

  As shown in FIG. 2, the hydraulic drive device 20 according to the present embodiment includes a plurality of hydraulic actuators, for example, two hydraulic cylinders 21 and 22 (for example, applied to the boom cylinder 8 and the bucket cylinder 10), and these hydraulic cylinders. A hydraulic pump 23 that discharges the pressure oil supplied to the hydraulic cylinders 21 and 22 and a flow of the pressure oil that is provided in association with the hydraulic cylinder 21 and that is supplied from the hydraulic pump 23 to the hydraulic cylinder 21 (flow direction and flow rate) ) And a directional control valve for controlling the flow (flow direction and flow rate) of pressure oil supplied from the hydraulic pump 23 to the hydraulic cylinder 22. 25.

  The direction control valve 24 is a closed center type three-position valve and includes four ports, that is, an A port 24a, a B port 24b, a P port 24c, and an R port 24d. The A port 24 a is a port that communicates with the bottom chamber 21 a of the hydraulic cylinder 21, and the B port 24 b is a port that communicates with the rod chamber 21 b of the hydraulic cylinder 21. The P port 24d is a port for introducing the discharge oil of the hydraulic pump 23, and the R port 24d is a port that is discharged from the hydraulic cylinder 21 and guides the hydraulic oil, that is, the return oil to the hydraulic oil tank 26 side.

  Similar to the directional control valve 24, the directional control valve 25 is a closed center three-position valve, and includes four ports, that is, an A port 25a, a B port 25b, a P port 25c, and an R port 25d. The A port 25 a is a port that communicates with the bottom chamber 22 a of the hydraulic cylinder 22, and the B port 25 b is a port that communicates with the rod chamber 22 b of the hydraulic cylinder 22. The P portro 25c is a port for introducing the discharge oil of the hydraulic pump 23, and the R port 25d is a port for guiding the hydraulic oil discharged from the hydraulic cylinder 22, that is, the return oil to the hydraulic oil tank 26 side.

  The hydraulic pump 23 and the P port 24 c of the directional control valve 24 are connected to each other via a trunk line 27 through which the hydraulic pump 23 discharges pressure oil and a branch line 28 branched from the trunk line 27. The hydraulic pump 23 and the P port 25 c of the directional control valve 25 are connected via a trunk line 27 and a branch line 29 branched from the trunk line 27. That is, the oil discharged from the hydraulic pump 23 is distributed into the amount guided to the hydraulic cylinder 21 through the branch pipe 28 and the amount guided to the hydraulic cylinder 22 through the branch pipe 29.

  The hydraulic drive device 20 further includes a control device 40. The control device 40 includes a ROM in which a control program is written, a CPU that performs information processing in accordance with the control program, and a RAM that is a work area for information processing by the CPU. Information processing and control of various control objects are performed. The directional control valve 24 and the directional control valve 25 described above are objects to be controlled by the control device 40 and are operated by being supplied with electric power from the control device 40. An operation lever device 51 provided in association with the hydraulic cylinder 21 and an operation lever device 52 provided in association with the hydraulic cylinder 22 are electrically connected to the control device 40. The operation lever device 51 converts the tilting operation amount from the neutral position of the operation lever 51 a into a command signal (electric signal) corresponding to the valve position command of the direction control valve 24 and outputs the command signal to the control device 40. The operation lever device 52 converts the tilting operation amount from the neutral position of the operation lever 52a into a command signal (electric signal) corresponding to the command of the valve position of the direction control valve 25 and outputs the command signal to the control device 40. The control device 40 is set so as to convert the command signal from the operation lever device 51 into electric power and supply it to the direction control valve 24, and to convert the command signal from the operation lever device 52 into electric power and control the direction. The valve 25 is set to be supplied.

  The relationship between the command value of the command signal output by the operation lever device 51, the power supplied from the control device 40 to the direction control valve 24, and the opening of the direction control valve 24 is in the vicinity of the neutral position of the operation lever 51a. And the vicinity of the limit position of the tilting operation of the operating lever 51a, the opening degree of the first direction control valve is set to increase as the tilting operation amount of the operating lever 51a from the neutral position increases. Similarly, the relationship between the command value of the command signal output from the operation lever device 52, the electric power supplied from the control device 40 to the direction control valve 25, and the opening degree of the direction control valve 25 is determined by the operation lever 52a. Except for the vicinity of the neutral position and the vicinity of the limit position of the tilting operation of the operating lever 52a, the opening degree of the second direction control valve is set to increase as the tilting operation amount of the operating lever 52a from the neutral position increases. . Further, as the opening degree of the direction control valve 24 increases, the flow rate of the hydraulic oil supplied from the hydraulic pump 23 to the hydraulic cylinder 21 increases, and the operating speed of the hydraulic cylinder 21 increases. Similarly, as the opening degree of the directional control valve 25 increases, the flow rate of hydraulic oil supplied from the hydraulic pump 23 to the hydraulic cylinder 22 increases, and the operating speed of the hydraulic cylinder 22 increases.

  The hydraulic drive device 20 further includes power generation devices 61 and 62 provided in association with the hydraulic cylinders 21 and 22, respectively.

  The power generation device 61 is provided in the return line 31 extending from the R port 24d of the direction control valve 24 to the hydraulic oil tank 26, and is provided on the return line 31 and operated from the R port 24d of the direction control valve 24. A power generation hydraulic motor 63 driven by oil and a generator 65 coupled to the power generation hydraulic motor 63 so as to be capable of transmission are provided. That is, the power generation hydraulic motor 63 is driven by the pressure oil discharged from the hydraulic cylinder 21, and the generator 65 is driven by the power generation hydraulic motor 63 to generate power.

  The power generator 62 is provided in a return line 32 extending from the R port 25d of the direction control valve 25 to the hydraulic oil tank 26, and is provided on the return line 32 to operate from the R port 25d of the direction control valve 25. A power generation hydraulic motor 64 driven by oil and a generator 66 coupled to the power generation hydraulic motor 64 so as to be capable of transmission are provided. In other words, the power generation hydraulic motor 64 is driven by the pressure oil discharged from the hydraulic cylinder 22, and the generator 66 is driven by the power generation hydraulic motor 64 to generate power.

  The rotation resistance of the generator 65, that is, the torque T1 that becomes the rotation resistance of the power generation hydraulic motor 63 is controlled by an inverter 67. That is, the generator 65 and the inverter 67 constitute resistance adjusting means for adjusting the resistance of rotation of the power generating hydraulic motor 63. In the same manner, the torque T <b> 2 that is the resistance of rotation of the generator 66, that is, the resistance of rotation of the power generation hydraulic motor 64, is controlled by the inverter 67. That is, the generator 66 and the inverter 68 constitute resistance adjusting means for adjusting the resistance of rotation of the power generating hydraulic motor 64.

  The aforementioned control device 40 is a control means for controlling the inverters 67 and 68. The control device 40 is set to control the inverters 67 and 68 based on detection signals (electrical signals) from the bottom pressure sensor 71, the rod pressure sensor 72, the bottom pressure sensor 73, and the rod pressure sensor 74. The bottom pressure sensor 71 converts the pressure Pb1 in the bottom chamber 21a of the hydraulic cylinder 21 into a detection signal and outputs the detection signal to the control device 40. The rod pressure sensor 72 converts the pressure Pl1 in the rod chamber 21b of the hydraulic cylinder 21 into a detection signal and outputs the detection signal to the control device 40. The bottom pressure sensor 73 converts the pressure Pb2 in the bottom chamber 22a of the hydraulic cylinder 22 into a detection signal and outputs the detection signal to the control device 40. The rod pressure sensor 74 converts the pressure Pl2 in the rod chamber 22b of the hydraulic cylinder 22 into a detection signal and outputs the detection signal to the control device 40.

  The power generated by the generator 65 is charged in the power storage device 80 via the inverter 67, and the power generated by the generator 66 is charged in the power storage device 80 via the inverter 68. It has become.

  As shown in FIG. 3, the control device 40 includes a maximum load pressure determination means 41 and a target torque command means 42 as means set by the control program written in the ROM.

  When the command signal from the operating lever device 51 and the command signal from the operating lever device 52 are input at the same time, the maximum load pressure determining means 41 determines which chamber of each of the hydraulic cylinders 21 and 22 has the hydraulic pump 23. A bottom pressure sensor 71 indicating a pressure (load pressure) in each of the hydraulic cylinders 21 and 22 determined by the supply destination determination means 41a and the supply destination determination means 41a. , A load pressure acquisition means 41b for acquiring a detection value of a detection signal from any one of the rod pressure sensor 72, the bottom pressure sensor 73, and the rod pressure sensor 74, and two load pressures acquired by the load pressure acquisition means 41b. And a maximum load pressure determining means 41c for determining the higher one as the maximum load pressure. The bottom pressure sensor 71, the rod pressure sensor 72, the bottom pressure sensor 73, the rod pressure sensor 74, the supply destination determination means 41a, and the load pressure acquisition means 41b detect the respective load pressures of the hydraulic cylinders 21 and 22. A load pressure detecting means is configured.

  The target torque command means 42 calculates a command value Si1 of the target torque of the generator 65 and a command value Si2 of the target torque of the generator 66 based on the determination result by the maximum load pressure determination means 41, and these commands. A command signal indicating each of the values Si1 and Si2 is output to each of the inverters 67 and 68. Here, the hydraulic cylinder on which the maximum load pressure is applied is rephrased as the maximum load actuator, and the hydraulic cylinder on which the load pressure is lower than the maximum load pressure is rephrased as the low load actuator, and the target torque command value Si1, Explaining the specific control of Si2, the command value for the inverter associated with the highest load actuator is set to 0 (zero), and the command value for the inverter associated with the low load actuator is The load pressure of the low load actuator is set to a value that increases to the maximum load pressure.

  Further, the target torque command means 42 determines the detected value of the pressure sensor that has detected the maximum load pressure among the bottom pressure sensor 71, the rod pressure sensor 72, the bottom pressure sensor 73, and the rod pressure sensor 74 from the command value (> 0). The deviation is obtained by subtraction, and the command value of the target torque for eliminating the deviation is set. That is, the target torque command means 42 performs feedback control when raising the lower load pressure to the maximum load pressure.

  Bottom pressure sensor 71, rod pressure sensor 72, bottom pressure sensor 73 and rod pressure sensor 74, maximum load pressure determination means 41, target torque command means 42, inverter 67, power generator 61 (power generation hydraulic motor 63, The generator 65) is provided in association with the hydraulic cylinder 21, and constitutes pressure compensation means for suppressing fluctuations in the pressure difference between the upstream and downstream of the directional control valve 24 associated with the hydraulic cylinder 21. Bottom pressure sensor 71, rod pressure sensor 72, bottom pressure sensor 73 and rod pressure sensor 74, maximum load pressure determination means 41, target torque command means 42, inverter 68, power generator 62 (power generation hydraulic motor 64, The generator 66) constitutes a pressure compensation means that suppresses fluctuations in the pressure difference between the upstream and downstream of the direction control valves 24, 25.

  The operation lever devices 51 and 52 are provided in the above-described cab 3a and operated by an operator. The hydraulic pump 23, the direction control valves 24 and 25, the power generation devices 61 and 62, the inverters 67 and 68, and the power storage device 80 are accommodated in the machine room 3b of the revolving unit 3 described above.

  Regarding the pressure compensation function in the hydraulic drive device 20, that is, the function of suppressing the fluctuation of the flow rate of the hydraulic oil supplied to the hydraulic cylinders 21 and 22 with the fluctuation of the load pressure of the hydraulic cylinders 21 and 22, The operation of the hydraulic drive device 20 when both of the cylinders 22 extend at the same time and the load pressure of the hydraulic cylinder 21 is also high is described below as an example.

  The operation lever device 51 is tilted in the direction in which the hydraulic cylinder 21 is extended, and at the same time, the operation lever device 52 is tilted in the direction in which the hydraulic cylinder 22 is extended.

  At this time, in the maximum load pressure determination means 41 of the control device 40, first, the supply destination determination means 41a determines a chamber that is a supply destination of pressure oil for each of the hydraulic cylinders 21 and 22. This time, the hydraulic cylinder 21 is determined to be the bottom chamber 21a, and the hydraulic cylinder 22 is determined to be the bottom chamber 22a. Next, based on the determination results (bottom chambers 21a and 22a) of the supply destinations, the load pressure acquisition unit 41b detects the pressure Pb1 (load pressure of the hydraulic cylinder 21) in the bottom chamber 21a. And the detection value indicated by the detection signal from each of the bottom pressure sensor 73 that detects the pressure Pb2 in the bottom chamber 22a (load pressure of the hydraulic cylinder 22). Next, the maximum load pressure determining means 41c determines the higher one of the detected values of the two load pressures Pb1 and Pb2 acquired by the load pressure acquiring means 41b as the maximum load pressure. This time, the load pressure Pb1 is determined as the maximum load pressure. In other words, the hydraulic cylinder 21 is determined as the highest load actuator on which the maximum load pressure is applied, and the hydraulic cylinder 22 on which the load pressure lower than the maximum load pressure is applied is determined as the low load actuator.

  Next, the target torque command means 42, based on the maximum load pressure Pb1 determined by the maximum load pressure determination means 41, the command value Si1 of the target torque of the generator 65 and the command value Si2 of the target torque of the generator 66 And command signals indicating the command values Si1 and Si2 are output to the inverters 67 and 68, respectively. This time, the command value Si1 for the inverter 67 associated with the hydraulic cylinder 21 which is the highest load actuator is set to 0 (zero), and the command value Si2 for the inverter 68 associated with the hydraulic cylinder 22 which is the low load actuator. Is set to a value (> 0) that increases the load pressure Pb2 of the hydraulic cylinder 22 to the maximum load pressure (= pressure Pb1).

  The inverter 67 sets the generated current I1 generated by the generator 65 to 0 A (ampere) based on the command signal (command value Si1 = 0) from the target torque command means 42. Accordingly, the torque necessary for the rotation of the generator 65 is set to the minimum. That is, the power generation device 61 is controlled so as not to generate power. As a result, in the return line 31, the resistance that the power generation hydraulic motor 63 gives to the flow of return oil is in a minimum state. On the other hand, the inverter 68 sets the generated current I2 generated by the generator 66 to a value larger than 0A based on the command signal (command value Si2> 0) from the target torque command means 42. Accordingly, the torque necessary for the rotation of the generator 66, that is, the torque necessary for the rotation of the power generation hydraulic motor 64 is set larger than the minimum. That is, in the return pipe 32, the power generation hydraulic motor 64 gives resistance to the flow of return oil in the hydraulic cylinder 22, so that the load pressure Pb2 of the hydraulic cylinder 22 rises and finally reaches the load pressure Pb1.

  Further, the target torque command means 42 gives a command signal of the command value Si2 to the inverter 68, and then inputs a detection signal from the bottom pressure sensor 73. The detection value of this detection signal, that is, the bottom chamber 22a of the hydraulic cylinder 22 is input. The detected value of the pressure Pb2 is subtracted from the command value Si2 (> 0) to obtain a deviation, and the command value Si2 of the target torque is adjusted so that the deviation is eliminated. That is, feedback control of the resistance of rotation of the power generation hydraulic motor 64 is performed. That is, feedback control of the resistance of rotation of the power generation hydraulic motor 64 is performed.

  The pressure compensation function in the hydraulic drive device 20 will be described using an example of an operation different from the above. Another example of the operation is when the hydraulic cylinder 21 as a “boom cylinder” contracts due to the gravity of the front working device 4 and the hydraulic cylinder 22 (corresponding to the bucket cylinder 10) contracts at the same time. It is an example of operation.

  The operation lever device 51 is tilted in the direction in which the hydraulic cylinder 21 is contracted (the direction in which the boom 5 is lowered), and at the same time, the operation lever device 52 is tilted in the direction in which the hydraulic cylinder 22 is contracted.

  At this time, in the maximum load pressure determination means 41 of the control device 40, first, the supply destination determination means 41a determines a chamber that is a supply destination of pressure oil for each of the hydraulic cylinders 21 and 22. This time, the hydraulic cylinder 21 is determined to be the rod chamber 21b, and the hydraulic cylinder 22 is determined to be the rod chamber 22b. Next, based on the determination result of the supply destination, the load pressure acquisition unit 41b includes a rod pressure sensor 72 for detecting the pressure Pl1 of the rod chamber 21b (load pressure of the hydraulic cylinder 21), and a pressure Pl2 of the rod chamber 22b. The detection value indicated in the detection signal from each of the rod pressure sensor 74 that detects (load pressure of the hydraulic cylinder 22) is acquired. Next, the maximum load pressure determining unit 41c determines the higher one of the detected values of the two pressures Pl1 and Pl2 acquired by the load pressure acquiring unit 41b as the maximum load pressure. Since the hydraulic cylinder 21 (boom cylinder 8) is contracted due to the gravity of the front working device 4 this time, the detected value of the pressure Pl1 is 0 (zero). Therefore, if it is larger than the detected value 0 of the pressure Pl2, the load pressure Pl2 of the hydraulic cylinder 22 is determined as the maximum load pressure. This time, it is assumed that the load pressure Pl2 of the hydraulic cylinder 22 is determined as the maximum load pressure. That is, it is assumed that the hydraulic cylinder 22 is determined as the highest load actuator on which the maximum load pressure is applied, and the hydraulic cylinder 21 on which the load pressure lower than the maximum load pressure is applied is determined as the low load actuator.

  Next, the target torque command means 42, based on the maximum load pressure Pl2 determined by the maximum load pressure determination means 41, the command value Si1 of the target torque of the generator 65 and the command value Si2 of the target torque of the generator 66 And command signals indicating the command values Si1 and Si2 are output to the inverters 67 and 68, respectively. This time, the command value Si2 for the inverter 68 associated with the hydraulic cylinder 22 which is the highest load actuator is set to 0 (zero), and the command value Si1 for the inverter 67 associated with the hydraulic cylinder 21 which is the low load actuator. Is set to a value (> 0) that increases the load pressure Pl1 of the hydraulic cylinder 21 to the maximum load pressure (= pressure Pl2).

  As a result, the inverter 68 sets the generated current I2 generated by the generator 66 to 0 A (ampere). Along with this, the torque required for the rotation of the generator 66 is set to the minimum. That is, the power generator 62 is controlled so as not to generate power. As a result, in the return line 32, the resistance that the power generation hydraulic motor 64 gives to the flow of the return oil from the hydraulic cylinder 22 becomes a minimum state. On the other hand, the inverter 67 sets the generated current I1 from the generator 65 to a value larger than 0A based on the command value Si1. Accordingly, the torque necessary for the rotation of the generator 65, that is, the torque necessary for the rotation of the power generation hydraulic motor 63 is set larger than the minimum. That is, in the return pipe 31, the power generation hydraulic motor 63 gives resistance to the flow of return oil from the hydraulic cylinder 21, so that the load pressure Pl1 of the hydraulic cylinder 21 rises and finally reaches the load pressure P12.

  Further, the target torque command means 42 gives a command signal of the command value Si1 to the inverter 67, and then inputs a detection signal from the rod pressure sensor 72, and from this detection signal, the pressure Pl1 of the rod chamber 21b of the hydraulic cylinder 21 is input. A detected value is obtained, the detected value is subtracted from the command value Si1 (> 0) to obtain a deviation, and the target torque command value Si1 is adjusted so that the deviation is eliminated. That is, feedback control of the resistance of rotation of the power generation hydraulic motor 63 is performed.

  According to the hydraulic drive device 20 according to the present embodiment, the following effects can be obtained.

  In the hydraulic drive device 20 according to the present embodiment, the control device 40 is a resistance adjusting means (the inverter 67 and the generator 65 or the hydraulic cylinder 21 or 22 having the lower load pressure) associated with the low load actuator. The inverter 68 and the generator 66) are controlled to increase the rotation resistance of the power generation hydraulic motor 63 or 64 associated with the low load actuator. As a result, the load pressure of the low load actuator can be increased to the maximum load pressure, and fluctuations in the pressure difference between the upstream and downstream of the direction switching valve 24 or 25 associated with the low load actuator can be suppressed. Therefore, when the oil discharged from the hydraulic pump 23 is distributed and the hydraulic cylinders 21 and 22 are driven at the same time, fluctuations in the operating speed of the hydraulic cylinders 21 and 22 due to fluctuations in load pressure can be suppressed.

  In the hydraulic drive device 20 according to the present embodiment, the power storage device 80 stores electrical energy generated by the generator associated with the low load actuator. Thereby, when suppressing the fluctuation | variation of the operating speed of the hydraulic cylinders 21 and 22 accompanying the fluctuation | variation of load pressure, an energy loss can be reduced.

  The gravity of the front working device 4 acts on the boom cylinder 8 of the hydraulic cylinder 21, and the boom cylinder 8 can be contracted by this gravity, and the pressure oil is discharged along with the contraction. In the hydraulic drive device 20 according to the present embodiment, since the power generation hydraulic motor 63 is driven by the pressure oil discharged from the hydraulic cylinder 21, the hydraulic cylinder 21 is applied to the boom cylinder 8 as described above. In this case, when the boom cylinder 8 contracts due to the gravity of the front working device 4 and the pressure oil is discharged, the power generation hydraulic motor 63 is driven by the pressure oil to cause the generator 65 to generate power, and the power storage device 80 is charged. can do. That is, a part of the potential energy of the front working device 4 can be converted into electrical energy and stored.

  The hydraulic drive device 20 according to the above-described embodiment includes a power generation hydraulic motor 63 in the return line 31 of the hydraulic cylinder 21 and a power generation hydraulic motor 64 in the return line 32 of the hydraulic cylinder 22. In other words, the power generation hydraulic motor is driven by the pressure oil discharged from the hydraulic actuator, but the present invention may be configured such that the power generation hydraulic motor is driven by the pressure oil supplied to the hydraulic actuator. Good. In this case, referring to FIG. 2, the power generating hydraulic motors 63 and 64 are provided in the branch pipes 28 and 29, respectively.

  In the hydraulic drive device 20 according to the above-described embodiment, the resistance adjusting means adjusts the rotational resistance of the power generating hydraulic motors 63 and 64 and applies the torque required to rotate the generators 65 and 66 to the inverters 67 and 68. However, the resistance adjusting means in the present invention is not limited to this, and is performed by controlling the capacity of the power generation hydraulic motors 63 and 64 as variable displacement hydraulic motors. There may be. That is, a variable mechanism having a variable capacity in the variable displacement hydraulic motor may be used as the resistance adjusting means.

  In the hydraulic drive device 20 according to the above-described embodiment, the plurality of hydraulic actuators are the two hydraulic cylinders 21 and 22. However, the number of hydraulic actuators in the present invention is not limited to two, and from two There may be many. In this case, when any two or more of the plurality of hydraulic actuators are operating, the hydraulic actuator on which the highest load pressure is applied is treated as the highest load actuator among the hydraulic actuators in operation. A hydraulic actuator acting with a load pressure lower than the pressure is treated as a low load actuator.

  In the hydraulic drive device 20 according to the above-described embodiment, the plurality of hydraulic actuators are the two hydraulic cylinders 21 and 22. However, the plurality of hydraulic actuators in the present invention is not limited to the hydraulic cylinder, only the hydraulic motor. A mixture of a hydraulic cylinder and a hydraulic motor may be used.

DESCRIPTION OF SYMBOLS 1 Hydraulic excavator 2 Running body 2a Crawler belt 3 Revolving body 3a Cab 3b Machine room 3c Counterweight 4 Front work device 5 Boom 6 Arm 7 Bucket 8 Boom cylinder 9 Arm cylinder 10 Bucket cylinder 20 Hydraulic drive devices 21, 22 Hydraulic cylinders 21a, 22b Bottom chambers 21b, 22b Rod chamber 23 Hydraulic pumps 24, 25 Direction control valves 24a, 25a A ports 24b, 25b B ports 24c, 25c P ports 24d, 25d R ports 26 Hydraulic oil tank 27 Trunk lines 28, 29 Branch lines 31, 32 Return pipeline 40 Control device 41 Maximum load pressure determination means 41a Supply destination determination means 41b Load pressure acquisition means 41c Maximum load pressure determination means 42 Target torque command means 51, 52 Operation lever devices 51a, 52a Operation levers 61, 62 Power generation devices 63 and 64 Electric hydraulic motor 65, 66 the generator 67, 68 inverter 71 bottom pressure sensor 72 the rod pressure sensor 73 bottom pressure sensor 74 the rod pressure sensor 80 power storage device

Claims (2)

A hydraulic pump, a plurality of hydraulic actuators that are driven by being supplied with oil discharged from the hydraulic pump, and a plurality of hydraulic actuators that are associated with each other, and are supplied to the associated hydraulic actuators from the hydraulic pump A hydraulic control device for a construction machine comprising: a directional control valve that controls a flow of pressure oil that is
Pressure compensation means for suppressing fluctuations in the pressure difference between the upstream and downstream of each of the plurality of directional control valves, a plurality of load pressure detection means for detecting each load pressure of the plurality of hydraulic actuators, and a power storage device ,
The pressure compensation means includes a generator provided in association with each of the plurality of hydraulic actuators, a plurality of power generation hydraulic motors that drive each of the power generators, and each of the power generation hydraulic motors. A resistance adjusting means for adjusting the resistance of the rotation, and a control means for controlling these resistance adjusting means,
The power generation hydraulic motor is driven by pressure oil supplied to a hydraulic actuator associated with the power generation hydraulic motor among the plurality of hydraulic actuators or pressure oil discharged from the hydraulic actuator. ,
The control means is a hydraulic actuator in which a load pressure lower than a maximum load pressure is applied among hydraulic actuators in operation when any two or more of the plurality of hydraulic actuators are operating. By controlling the resistance adjusting means associated with a certain low load actuator and increasing the rotation resistance of the power generating hydraulic motor associated with the low load actuator, the resistance adjusting means is associated with the low load actuator. Suppresses the variation in pressure difference between the upstream and downstream of the directional valve
The power storage device stores hydraulic energy generated by the power generator associated with the low load actuator, and is a hydraulic drive device for a construction machine. The hydraulic drive device for a construction machine according to claim 1,
The hydraulic drive device for a construction machine, wherein the power generation hydraulic motor of the pressure compensation means is driven by pressure oil discharged from the hydraulic actuator associated therewith.

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