JP5292361B2 - Work machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a work machine capable of inhibiting the growth in size of a center joint. <P>SOLUTION: In the work machine, an actuator port 47c of a superstructure upper part control valve 30 provided in a upper revolving superstructure 3 and a main port 64 of a lower part control valve 50 provided in a lower structure 2 are connected through the center joint 6. And, the opening area of a flow control valve 31c for supplying pressure oil from the upper control valve 30 to the lower control valve 50 is configured to be controlled based on the load sensing differential pressure PLS1 of the lower control valve 50. Thereby, the growth in size of the center joint 6 can be inhibited, because the number of pipe lines in the center joint 6 can be inhibited. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to a work machine having an upper swing body that is turnable with respect to a lower traveling body.

  In order to respond to work on rough terrain, a work machine configured to be able to lift and lower each of the four wheels independently is known. In this work machine, one end is pivotally supported at the front and rear of a base frame (center frame) provided at the lower part of the upper structure, and wheel legs that can swing in the vertical direction are provided on the left and right, respectively. A wheel is attached to the other end. In this work machine, the height position of the wheel with respect to the base frame is adjusted by swinging the wheel leg vertically by extending and contracting the height adjusting cylinder (see Patent Document 1).

JP-A-6-257182

  In the working machine described in the above-mentioned patent document, the upper structure can be rotated with respect to the base frame. Therefore, the height disposed on the base frame from the upper structure via the hydraulic rotary transmission central stator (center joint). Supply pressure oil to the adjustment cylinder. However, since the work machine described in the above-mentioned patent document has four height adjustment cylinders arranged on the base frame, a control valve for controlling the pressure oil supplied to the height adjustment cylinder is provided in the upper structure. In this case, as the number of pipes of the center joint increases, the center joint itself increases in size, requiring a large mounting space and increasing manufacturing costs.

(1) A work machine according to a first aspect of the present invention includes a lower traveling body, an upper revolving body that is turnably provided on an upper portion of the lower traveling body, a cab provided in the upper revolving body, and a lower traveling body. Supplying pressure oil to the plurality of lower traveling body actuators provided, the plurality of upper turning body actuators provided in the upper revolving body, the plurality of lower traveling body actuators and the plurality of upper revolving body actuators, A hydraulic pump provided in the upper swing body, a center joint that connects the hydraulic circuit of the lower swing body and the hydraulic circuit of the upper swing body so that the upper swing body can swing with respect to the lower travel body, A plurality of undercarriage actuator operating devices for operating a plurality of undercarriage actuators, respectively, and a plurality of upper swing body actuators provided in the cab. A plurality of upper swing body actuator operating devices for operating the respective tutors, and a plurality of flow control valves (lower flow control valves) corresponding to the plurality of lower travel body actuators are provided on the lower travel body. A lower running body control valve, a plurality of flow control valves (upper flow control valves) corresponding to a plurality of upper swing body actuators, and an upper swing body control valve provided on the upper swing body, Opening control signal output means for outputting an opening control signal for controlling the opening of the plurality of upper flow control valves and the plurality of lower flow control valves, and travels in the lower part downstream of the upper flow control valve via the center joint. The pump port of the body control valve is connected, and the opening degree control signal output means is connected to the lower traveling body downstream based on the operation amount of the lower traveling body actuator operating device. And outputs an opening control signal to the upper flow control valve the pump port of the control valve is connected. (2) The invention according to claim 2 is the work machine according to claim 1, further comprising lower load sensing differential pressure detecting means for detecting a load sensing differential pressure (lower load sensing differential pressure) of the control valve for the lower traveling body. The opening control signal output means includes a lower traveling body control valve downstream based on an operation amount of the lower traveling body actuator operating device and a lower load sensing differential pressure detected by the lower load sensing differential pressure detecting means. An opening degree control signal is output to the upper flow rate control valve to which the pump port is connected.
(3) A work machine according to a third aspect of the present invention includes a lower traveling body, an upper swinging body provided on the upper portion of the lower traveling body, a cab provided in the upper swinging body, and a lower traveling body. Supplying pressure oil to the plurality of lower traveling body actuators provided, the plurality of upper turning body actuators provided in the upper revolving body, the plurality of lower traveling body actuators and the plurality of upper revolving body actuators, A hydraulic pump provided in the upper swing body, a center joint that connects the hydraulic circuit of the lower swing body and the hydraulic circuit of the upper swing body so that the upper swing body can swing with respect to the lower travel body, A plurality of undercarriage actuator operating devices for operating a plurality of undercarriage actuators, respectively, and a plurality of upper swing body actuators provided in the cab. A plurality of upper swing body actuator operating devices for operating the respective tutors, and a plurality of flow control valves (lower flow control valves) corresponding to the plurality of lower travel body actuators are provided on the lower travel body. A lower running body control valve, a plurality of flow control valves (upper flow control valves) corresponding to a plurality of upper swing body actuators, and an upper swing body control valve provided on the upper swing body, The opening control signal output means for outputting an opening control signal for controlling the opening of the plurality of upper flow control valves and the plurality of lower flow control valves, and the load sensing differential pressure (lower load sensing difference) of the lower traveling body control valve Lower load sensing differential pressure detecting means for detecting the pressure), and a controller for the lower traveling body downstream of the upper flow control valve via the center joint. The pump port of the valve is connected, and the opening control signal output means is connected to the pump port of the lower traveling body control valve downstream based on the lower load sensing differential pressure detected by the lower load sensing differential pressure detecting means. An opening control signal is output to the upper flow rate control valve.
(4) According to a fourth aspect of the present invention, in the work machine according to any one of the first to third aspects, the hydraulic pump is a variable displacement hydraulic pump, and a capacity changing means for changing a capacity of the hydraulic pump. And further comprising an upper load sensing differential pressure detecting means for detecting the load sensing differential pressure (upper load sensing differential pressure) of the upper swing body control valve, and the capacity changing means is detected by the upper load sensing differential pressure detecting means. The capacity of the hydraulic pump is changed based on the upper load sensing differential pressure.
(5) According to a fifth aspect of the present invention, in the work machine according to any one of the first to fourth aspects, the lower traveling body includes four independent traveling body units each having a traveling body frame, and one end of the traveling body. Four swing frames that are connected to the frame and whose other end is pivotally supported near the periphery of the center frame and can swing independently in the vertical direction, and are provided for each of the four swing frames. Including four drive cylinders as actuators for the lower traveling body that cause the traveling body unit to move up and down independently of the center frame by swinging the frame independently in the vertical direction with respect to the center frame. Features.

  According to the present invention, an increase in the size of the center joint can be suppressed.

1 is a schematic side view showing a work machine 1 according to the present invention. FIG. 3 is a schematic top view showing a lower traveling body 2 of the work machine 1. It is the schematic which shows the system configuration | structure of the working machine 1 of 1st Embodiment. It is a figure which shows the general | schematic hydraulic circuit of 1st Embodiment. It is a flowchart which shows the processing content of control of the flow control valve 31c of 1st Embodiment. It is a block diagram which shows the control content in step S402 of FIG. It is a block diagram which shows the control content in step S402 in 2nd Embodiment. It is a block diagram which shows the control content in step S402 in 3rd Embodiment.

--- First embodiment ---
With reference to FIGS. 1-6, 1st Embodiment of the working machine by this invention is described. FIG. 1 is a schematic side view showing a work machine 1 according to the present invention. In the work machine 1, an upper swing body 3 is pivotably attached to the lower traveling body 2, and the upper swing body 3 is driven by a swing motor (not shown). A driver's cab 4 and the like are attached to the upper swing body 3. A counterweight 8 is provided behind the upper swing body. The upper swing body 3 is provided with an engine 5, a pump unit 7, and an upper control valve (upper control valve) 30 shown in FIG.

---- Work front 6 ---
The upper swing body 3 is provided with a boom 10 that can swing up and down at a fulcrum 40, and the boom 10 is provided with an arm 12 that can swing up and down at a fulcrum 41. A bucket 23 is provided at a fulcrum 42 so as to be swingable in the vertical direction. The boom 10, the arm 12 and the bucket 23 constitute a work front 6. Reference numeral 11 denotes a boom cylinder that swings the boom 10, and is connected to the upper swing body 3 and the boom 10. Reference numeral 13 denotes an arm cylinder 13 that swings the arm 12, and is connected to the boom 10 and the arm 12. Reference numeral 15 denotes a work tool cylinder that swings the bucket 23, and a cylinder rod tip is connected to the bucket 23 via a link 16, and a bottom side end of the cylinder is connected to the arm 12. The bucket 23 can be arbitrarily replaced with any one of other work tools (not shown) such as grapples, cutters, and breakers.

---- Lower traveling body 2 ---
FIG. 2 is a schematic top view showing the lower traveling body 2 of the work machine 1. The structure of the lower traveling body 2 will be described with reference to FIGS. The center frame 201 of the lower traveling body 2 is provided with four independent leg units 202a to 202d at front, rear, left and right ends. In the following description, the left front leg unit 202a will be described. However, the remaining three leg units 202b to 202d have the same configuration as the leg unit 202a, and therefore the detailed description of the leg units 202b to 202d is as follows. Omitted. In addition, about the structure of each part of the leg unit 202b corresponding to the structure of each part of the leg unit 202a, the end of a code | symbol is described replacing a to b. The same applies to the leg units 202c and 202d.

  The name of the leg unit 202a is a general term for a portion from the leg base bracket 203a provided on the left front side of the center frame 201 to the front side frame 207a. The leg unit 202a includes a leg base bracket 203a, a leg frame 204a, a leg tip bracket 205a, and a side frame 207a.

  A leg base bracket 203a is provided so as to be swingable (rotatable) in a vertical direction at a fulcrum 208a with respect to the center frame 201 of the lower traveling body 2. The leg base bracket 203a swings in a horizontal direction at a fulcrum 209a. A leg frame 204a is freely provided, and a leg end bracket 205a is provided on the leg frame 204a so as to be rotatable at a fulcrum 210a. The leg base bracket 203a, the leg frame 204a, and the leg tip bracket 205a constitute a swing frame.

  The fulcrum 208a is swingable with a support portion provided at the lower portion of the left front portion, which is the outer peripheral portion of the center frame 201, and a support portion provided at the rear portion of the leg base bracket 203a supported by a pin. It is comprised by connecting to. The fulcrum 209a is supported by a pin between a support portion provided at the front portion of the leg base bracket 203a and a support portion provided at the rear end of the leg frame 204a extending in the front-rear direction on the left front side of the center frame 201. And is configured to be swingably connected. The fulcrum 210a is configured by pivotally supporting a support part provided at the front end of the leg frame 204a and a support part provided at the rear part of the leg tip bracket 205a so as to be swingable. Yes.

  A link rod 206a is provided between the leg base bracket 203a and the leg tip bracket 205a so as to keep the posture of the leg tip bracket 205a parallel to the posture of the leg base bracket 203a. That is, a parallel link is formed by the leg base bracket 203a, the leg frame 204a, the leg tip bracket 205a, and the link rod 206a.

  The leg base bracket 203a and the link rod 206a are engaged at a fulcrum 211a, and the leg tip bracket 205a and the link rod 206a are engaged at a fulcrum 212a. The fulcrum 211a is configured by a support part provided on the right side of the front part of the leg base bracket 203a, with the rear end of the link rod 206a being pivotally supported by a pin. The fulcrum 212a is configured such that the front end of the link rod 206a is pivotally supported by a pin at a support portion provided at the right portion of the leg tip bracket 205a.

  Reference numeral 214a denotes a leg vertical cylinder that swings the leg base bracket 203a in the vertical direction, and is connected to the center frame 201 and the leg base bracket 203a. 215a is a leg left / right cylinder for moving the above-mentioned parallel link to move the leg tip bracket 205a in the left / right direction with respect to the center frame 201, and is connected to the leg base bracket 203a and the leg frame 204a.

---- Traveler unit ---
The leg end bracket 205a is provided with a traveling body frame (side frame) 207a that can swing up and down at a fulcrum 213a. No actuator is provided between the leg tip bracket 205a and the side frame 207a, and the side frame 207a swings passively around the fulcrum 213a. Note that the fulcrum 213a is configured such that a support portion provided at the front portion of the leg tip bracket 205a and a support portion of the side frame 207 are pivotally supported by a pin and are swingably connected.

  Reference numeral 217a denotes an idler that is rotatably provided on the front end side of the side frame 207a. Reference numeral 218a denotes a lower roller that is rotatably provided on a lower portion of the side frame 207a. Reference numeral 219a denotes an upper portion of the side frame 207a. It is an upper roller provided rotatably.

  220a is a drive sprocket provided on the rear end side of the side frame 207a, and 222a is a crawler belt wound around the idler 217a, the lower roller 218a, the upper roller 219a, and the drive sprocket 220a, and the drive sprocket 220a. Is configured so that the crawler belt 222a rotates around the side frame 207a and travels the work machine 1 by rotating with respect to the side frame 207a by the operation of a traveling hydraulic motor (not shown). A traveling unit is configured by the side frame 207a, the idler 217a provided on the side frame 207a, the rollers 218a and 219a, the drive sprocket 220a, the crawler belt 222a, and the like.

--- Configuration of work machine 1 ---
FIG. 3 is a schematic diagram showing a system configuration of the work machine according to the present embodiment. As shown in FIG. 3, the hydraulic system of the work machine 1 includes an engine 5, a pump unit 7 driven by the engine 5, a variable capacity main pump 70 and a pilot pump 71 disposed in the pump unit 7, An upper control valve 30 provided on the downstream side of the main pump 70 and a plurality of upper swing body actuators 26 provided on the downstream side of the actuator oil passage 39 of the upper control valve 30 are provided. The hydraulic system includes a lower control valve (lower control valve) 50 connected to an actuator port 47c, which will be described later, which is a downstream port of the actuator oil passage 39 of the upper control valve 30, and an upper control valve 30. A center joint 6 provided between the lower control valves 50 and a plurality of lower traveling body actuators 27 (for example, leg upper and lower cylinders 214a to 214d) provided downstream of the actuator oil passage 59 of the lower control valve 50. And.

  Further, the hydraulic system of the work machine 1 includes an operating device 80 for the upper swing body provided in the cab 4 and an electromagnetic valve controller 85 that controls the electromagnetic proportional valve 82 based on an operation signal from the operating device 80. And an electromagnetic proportional valve 82 that operates the flow control valve of the upper control valve 30 based on the output current from the electromagnetic valve controller 85. This hydraulic system includes an operating device 81 for a lower traveling body provided in the cab 4 and a communication controller 84 for transmitting an operation signal from the operating device 81 to an electromagnetic valve controller 86 provided for the lower traveling body 2. And a slip ring 87 provided between the communication controller 84 and the electromagnetic valve controller 86. In this hydraulic system, an electromagnetic valve controller 86 that controls the electromagnetic valve 83 based on a signal from the communication controller 84, and an electromagnetic proportional that operates the flow control valve of the lower control valve 50 based on the output current from the electromagnetic valve controller 86. And a valve 83.

  The center joint 6 and the slip ring 87 are provided at a connection portion between the upper swing body 3 and the lower traveling body 2. Even when the upper swing body 3 rotates 360 degrees or more with respect to the lower traveling body 2, the center joint 6 An electric signal can be transmitted to the lower traveling body 2 by the slip ring 87 and the pressure oil, respectively.

---- Hydraulic circuit ---
FIG. 4 is a diagram showing a schematic hydraulic circuit in the present embodiment. In the present embodiment, there are two, the upper control valve 30 and the lower control valve 50, but these basic functions are equivalent. Therefore, the basic functions related to the control valve will be described in detail using the upper control valve 30 shown in FIG. The configuration of each control valve 30, 50 alone is equivalent to the configuration when the control valve is used alone for a certain work machine. In other words, there are no newly added components for the control valves 30 and 50 for the series connection of the control valves shown in the present embodiment.

--- Connection of upper control valve 30 ---
The upper control valve 30 is provided in the upper swing body 3, and includes a main pump port 44, a tank port 48, a pilot pump port 45, a load sensing differential pressure port 46, and a plurality of actuator ports 47a, 47b, 47c. And have. The main pump port 44 is connected to the main pump 70 via the main supply oil passage 441. The pilot pump port 45 is connected to the pilot pump 71 via a pilot oil passage 451. The tank port 48 is connected to a hydraulic oil tank (oil tank) 25 via a tank oil passage 481.

  The load sensing differential pressure port 46 is connected to the pump unit 7 via the load sensing differential pressure oil passage 43. The actuator ports 47a and 47b are connected to the upper swing body actuator 26 via actuator oil passages 39a and 39b, respectively. The actuator port 47 c is connected to the lower control valve 50 via the actuator oil passage 39 c, the center joint 6, and the main supply oil passage 641 for the lower control valve 50.

--- About the upper control valve 30 ---
The upper control valve 30 has a plurality of valve sections 30a, 30b, 30c corresponding to the plurality of actuator oil passages 39a, 39b, 39c, and a control section 30d. Although only three valve sections 30a, 30b, and 30c are shown in FIG. 4 for convenience of explanation, actually, the number of valve sections corresponding to a plurality of other upper swing body actuators is provided.

  The valve sections 30a, 30b, and 30c include closed center type flow control valves (main spools) 31a, 31b, and 31c that control the flow rate and direction of the pressure oil supplied to the actuator oil passages 39a, 39b, and 39c, respectively. And pressure compensation valves 32a, 32b, and 32c for controlling the differential pressure across the meter-in throttle portions of the flow control valves 31a, 31b, and 31c, respectively. Each valve section 30a, 30b, 30c is provided with a shuttle valve 34a, 34b, 34c for selecting the higher one of the load pressures of the actuator oil passages 39a, 39b, 39c.

---- About the operation of the actuator ---
As described above, the electromagnetic proportional valve 82 is connected to the electromagnetic valve controller 85. Specifically, the flow rate control valve 31a of the valve section 30a is provided with an electromagnetic proportional valve 49a, the flow rate control valve 31b of the valve section 30b is provided with an electromagnetic proportional valve 49b, and the flow rate of the valve section 30c. The control valve 31c is provided with an electromagnetic proportional valve 49c. The electromagnetic proportional valves 49a to 49c are connected to the electromagnetic valve controller 85 by wire harnesses 88a to 88c, respectively. As described above, the solenoid valve controller 85 is connected to the operating device 80 provided in the cab 4.

  For example, when the operator operates the operation device 80 related to the upper swing body actuator 26 connected downstream of the flow control valve 31 a, an operation signal corresponding to the operation amount is output from the operation device 80 and received by the electromagnetic valve controller 85. Is done. The electromagnetic valve controller 85 outputs an excitation current to the electromagnetic proportional valve 49a based on the received operation signal. As a result, the operating current rises, the flow control valve 31a moves, the opening area of the meter-in throttle portion changes, and the flow rate to the actuator oil passage 39a increases. In this way, the flow rate to the actuator oil passage 39a is determined according to the operation amount of the operating device 80. Although only the valve section 30a has been described here, the same applies to other valve sections.

  Each of the pressure compensation valves 32a, 32b, and 32c is of a front type (before-orifice type) installed upstream of the meter-in throttle portion of the flow control valves 31a, 31b, and 31c. The pressure compensation valve 32a has a pair of opposed pressure receiving portions 35a and 35b and a pressure receiving portion 35c for operating in the opening direction. The pressure receiving portions 35a and 35b are provided on the upstream side and the downstream side of the flow control valve 31a. Each pressure acts. The pressure compensation valve 32a controls the differential pressure across the flow control valve 31a using a load sensing differential pressure (described later) acting on the pressure receiving portion 35c as a target compensation differential pressure. The pressure compensation valves 32b and 32c are similarly configured. Thus, the differential pressures before and after the meter-in throttle parts of the flow control valves 31a, 31b, 31c are all controlled to be the same value, and the meter-in throttle parts of the flow control valves 31a, 31b, 31c are controlled regardless of the load pressure. Pressure oil can be supplied at a ratio corresponding to the opening area.

  The control section 30 d has a main relief valve 36, a pressure oil supply oil passage 37, and a pressure oil discharge oil passage 38. Discharged oil from the main pump 70 is supplied to the pressure compensation valves 32a, 32b, 32c and the flow rate control valves 31a, 31b, 31c via the pressure oil supply oil passage 37, and further from the flow rate control valves 31a, 31b, 31c. It is supplied to the oil passages 39a, 39b, 39c. The maximum pressure in the pressure oil supply oil passage 37 is limited to the set pressure by the main relief valve 36. The return oil from the actuator oil passages 39a, 39b, 39c through the flow control valves 31a, 31b, 31c and the relief oil from the main relief valve 36 are returned to the hydraulic oil tank 25 through the discharge oil passage 38.

--- About the unload valve 40 ---
An unload valve 40 is provided in the control section 30d. The unload valve 40 is a valve for limiting the differential pressure between the discharge pressure of the main pump 70 and the maximum load pressure to a value slightly larger than the target load sensing differential pressure, and is connected to the discharge oil passage 38. The unloading valve 40 has a pressure receiving part 40a for operating in the closing direction, a spring 40c for operating in the closing direction, and a pressure receiving part 40b for operating in the opening direction. In the unload valve 40, the pressure (maximum load pressure) of the maximum load pressure line 33 acts on the pressure receiving portion 40a, and the discharge pressure of the main pump 70 acts on the pressure receiving portion 40b. The biasing force of the spring 40c is set so that the differential pressure between the discharge pressure of the main pump 70 and the maximum load pressure is limited to a value slightly larger than the target load sensing differential pressure.

  The unload valve 40 operates as follows. In a state where the work machine 1 is not operated and no load pressure is generated, the discharge pressure of the main pump 70 acting on the pressure receiving portion 40b becomes high, so that the unload valve 40 resists the urging force of the spring 40c. Opened. As a result, the pressure oil from the main pump 70 is returned to the oil tank 25. Further, when load pressure is generated by performing work on the work machine 1, the resultant force of the force acting on the pressure receiving portion 40a by the urging force of the spring 70c and the maximum load pressure is the force acting on the pressure receiving portion 40b by the pump discharge pressure. As it becomes larger, the unload valve 40 is closed. Thereby, the discharge pressure of the main pump 70 can be increased to the set pressure of the main relief valve 36.

−−− Generation of load sensing differential pressure −−−
A differential pressure reducing valve 42 is provided in the control section 30d. The differential pressure reducing valve 42 includes a pressure receiving portion 42a and pressure receiving portions 42b and 42c. The discharge pressure of the main pump 70 acts on the pressure receiving part 42a. The maximum load pressure output from the shuttle valve 34a and its own output pressure act on the pressure receiving portions 42b and 42c, respectively. The differential pressure reducing valve 42 operates with a balance of these pressures, and generates and outputs an absolute pressure of a load sensing differential pressure that is a differential pressure between the discharge pressure of the main pump 70 and the maximum load pressure. When the pressure received by the pressure receiving part 42a increases, the output pressure from the differential pressure reducing valve 42, that is, the load sensing differential pressure increases. When the pressure received by the pressure receiving portions 42b and 42c increases, the output pressure from the differential pressure reducing valve 42 decreases.

  The load sensing differential pressure is introduced as a target compensation differential pressure to the pressure receiving portion 35c of the pressure compensation valve 32a and the pressure receiving portions of the pressure compensation valves 32b and 32c. As a result, the differential pressure across the meter-in throttle portion of each flow control valve 31a, 31b, 31c is controlled by each pressure compensation valve 32a, 32b, 32c with the load sensing differential pressure as the target compensation differential pressure. Therefore, even if the discharge flow rate of the main pump 70 is in a saturation state where the required flow rate is less than the required flow rate, the pressure oil is supplied to each actuator 26 at a ratio corresponding to the opening area of the meter-in throttle portion of each flow control valve 31a, 31b, 31c. Can supply. Further, the load sensing differential pressure that is the output pressure of the differential pressure reducing valve 42 is also introduced as a control differential pressure to the pump tilt control mechanism 72 of the main pump 70 via the load sensing differential pressure oil passage 43.

--- Pump unit 7 ---
The pump tilt control mechanism 72 of the pump unit 7 includes a horsepower control tilt regulator 72a, a load sensing control valve 73, and a load sensing control regulator 72b. The horsepower control tilt regulator 72 a is connected to the discharge port of the main pump 70, and when the discharge pressure of the main pump 70 increases, the amount of tilt of the main pump 70 is reduced so that the absorption torque of the main pump 70 is the output torque of the engine 5. The tilt of the main pump 70 is controlled so as not to exceed.

  The load sensing control tilt regulator 72b controls the tilt of the main pump 70 so that the discharge pressure of the main pump 70 is higher than the maximum load pressure of the plurality of actuators by a set pressure. The load sensing control valve 73 has a pressure receiving portion 73a and a spring 73b. A load sensing differential pressure, which is an output pressure of the differential pressure reducing valve 42, acts on the pressure receiving portion 73a as a control differential pressure. A spring 73b for defining a target load sensing differential pressure is provided at a position facing the pressure receiving portion 73a. As a result, the load sensing control valve 73 and the load sensing control tilt regulator 72b allow the main pump 70 to tilt so that the discharge pressure of the main pump 70 is higher than the maximum load pressure of the plurality of actuators by the target load sensing differential pressure ( (Push-off volume) is controlled.

--- About the lower control valve 50 ---
The basic configuration of the lower control valve 50 is the same as that of the upper control valve 30 except for the difference in the number of actuators to be driven. The lower control valve 50 includes a main pump port 64, a tank port 68, a pilot pump port 65, a load sensing differential pressure port 66, and actuator ports 67a, 67b, 67c.

  The main pump port 64 is provided in the lower traveling body 2, and is connected to the actuator port 47c of the upper control valve 30 via the main supply oil passage 641, the center joint 6, and the actuator oil passage 39c. The pilot pump port 65 is connected to the pilot pump 71 via the pilot oil passage 651, the center joint 6, and the pilot oil passage 451. The tank port 68 is connected to the oil tank 25 via the tank oil passage 681 and the center joint 6. The actuator ports 67a, 67b, and 67c are connected to the lower traveling body actuator 27 via actuator oil passages 59a, 59b, and 59c, respectively.

---- Center joint 6 ---
As shown in FIG. 4, the number of pipes of the center joint 6 includes a main supply oil passage 91 connecting the upper control valve 30 and the lower control valve 50, a tank oil passage 92 connecting the lower control valve 50 and the tank 25, and a lower portion. There are four pilot pipes 93 connecting the control valve 50 and the pilot pump 71 and a drain oil passage (not shown). Therefore, the size of the center joint 6 is the same as that of a center joint used in a general hydraulic excavator of the same class.

--- Relationship between upper control valve 30 and lower control valve 50 ---
In the present embodiment, as described above, the actuator port 47c of the upper control valve 30 and the main port 64 of the lower control valve 50 are connected. Hereinafter, the relationship between the upper control valve 30 and the lower control valve 50 will be described.

  First, the upper control valve 30 will be described. In the oil passage through which the pressure oil supplied to the actuator 26 flows, only the main pump 70 is connected upstream of the upper control valve 30. Therefore, there is no need to perform a special control regarding the control of the pump unit 7 due to the series connection of the upper and lower control valves 30 and 50. A lower control valve 50 is connected to the downstream side of the upper control valve 30. Here, when the lower control valve 50 is viewed from the upper control valve 30, the lower control valve 50 can be regarded as a part of the load actuator like the other upper swing body actuators 26. Therefore, in order to realize the serial connection of the upper and lower control valves 30 and 50, it is not necessary to perform special control on the upper control valve 30 except for the control of the opening area of the flow control valve 31 c described later.

  Next, the lower control valve 50 will be described. Only the actuator 27 of the lower traveling body is connected to the downstream side of the lower control valve 50. Therefore, there is no need to perform special control on the lower control valve 50 due to the series connection of the upper and lower control valves 50. Further, a pressure oil supply path from the main pump 70 is connected to the upstream side of the lower control valve 50 via the upper control valve 30. Therefore, in order to properly control the flow rate to the lower control valve 50, it is necessary to control the opening area of the flow control valve 31c of the upper control valve 30 as follows according to the request of the lower control valve 50. .

--- About control of the flow control valve 31c of the upper control valve 30 ---
The control of the flow rate control valve 31c that controls the pressure oil supplied to the lower control valve 50 in the upper control valve 30 will be described below.

(1) About basic principle The basic principle about control of the flow control valve 31c is demonstrated. In the flow control valve 31c, similarly to the upper control valve 30, control is performed so that the load sensing differential pressure PLS1 corresponding to the pressure difference between the upstream and downstream sides of the flow control valve in the lower control valve 50 becomes the target load sensing differential pressure PLS2. I do. That is, the opening area of the flow control valve 31c that supplies pressure oil from the upper control valve 30 to the lower control valve 50 is controlled based on the load sensing differential pressure PLS1 of the lower control valve 50.

  The load sensing system is a system in which the flow rate passing through the control valve can be controlled by the opening area of the main spool by keeping the differential pressure across the control valve constant. Therefore, a target value serving as a reference is set for the load sensing differential pressure, which is the differential pressure across the control valve, and the specifications of the flow rate of each spool are based on the target value. The target load sensing differential pressure PLS2 corresponds to the target value.

The operation of the flow control valve 31c will be specifically described.
i) When the load sensing differential pressure PLS1 of the lower control valve 50 is higher than the target load sensing differential pressure PLS2, the lower control valve 50 is caused by the flow of pressure oil at a flow rate higher than the lower control valve 50 requires. As a result, the load sensing differential pressure PLS1 becomes higher than the target load sensing differential pressure PLS2. Therefore, when the load sensing differential pressure PLS1 of the lower control valve 50 is higher than the target load sensing differential pressure PLS2, the opening area of the flow control valve 31c of the upper control valve 30 is reduced to reduce the pressure oil to the lower control valve 50. Reduce the flow rate. As a result, the load sensing differential pressure PLS1 decreases and becomes equal to the target load sensing differential pressure PLS2.

ii) When the load sensing differential pressure PLS1 of the lower control valve 50 is lower than the target load sensing differential pressure PLS2 The lower control valve 50 has no flow of pressure oil required by the lower control valve 50. As a result, the load sensing differential pressure PLS1 becomes lower than the target load sensing differential pressure PLS2. Therefore, when the load sensing differential pressure PLS1 of the lower control valve 50 is lower than the target load sensing differential pressure PLS2, the opening area of the flow control valve 31c of the upper control valve 30 is enlarged, so that the pressure oil to the lower control valve 50 is increased. The flow rate is increased and the load sensing differential pressure PLS1 is increased. As a result, the load sensing differential pressure PLS1 decreases and becomes equal to the target load sensing differential pressure PLS2.

(2) About control system Next, the structure of a control system is demonstrated. As shown in FIG. 4, the load sensing differential pressure port 65 of the lower control valve 50 is provided with a pressure sensor 150 for acquiring the load sensing differential pressure PLS1 of the lower control valve 50. The output signal from the pressure sensor 150 indicating the lower load sensing differential pressure PLS1 is transmitted to the upper rotating body electromagnetic valve controller 85 via the lower traveling body electromagnetic valve controller 86 and the slip ring 87. .

  The operating lever signal L1 acquired by the operating device 81 for the lower traveling body is transmitted to the electromagnetic valve controller 85 for the upper swing body via the communication controller 84.

  In the solenoid valve controller 85 of the upper swing body 3, the actual load sensing differential pressure PLS1 obtained as described above, the operation signal L1 of the lower traveling body 2, and the target load sensing that the solenoid valve controller 85 has in advance. Based on the differential pressure PLS2, a current output value I1 to the flow control valve 31c of the upper control valve 30 is calculated. Then, the calculated current value I1 is caused to flow through the electromagnetic proportional valve 49c that drives the flow control valve 31c, so that the opening area of the flow control valve 31c changes, and the pressure oil of the desired flow rate is transferred from the upper control valve 30 to the lower portion. Flows to control valve 50.

(3) Flowchart Control contents in the solenoid valve controller 85 of the upper swing body 30 will be described. FIG. 5 is a flowchart showing the processing contents of the control of the flow rate control valve 31c of the present embodiment. When an ignition switch (not shown) of the work machine 1 is turned on, a program for performing this process is started and executed by the solenoid valve controller 85. In step S400, various sensor information such as load sensing differential pressure PLS1 is read and the process proceeds to step S401. In step S401, it is determined whether or not the operating device 81 of the lower traveling body 3 is operated, that is, whether or not there is an operation input of the operating device 81.

  When there is no input signal from the operating device 81, it is not necessary to supply hydraulic oil to the lower control valve 50. Therefore, the process proceeds to step S403, and the current value I1 of the drive current that flows to the electromagnetic proportional valve 49c is calculated so that the flow control valve 31c of the upper control valve 30 is fully closed, and the process proceeds to step S404.

  If there is an input signal from the operating device 81 of the lower traveling body 3, the process proceeds to step S402. In step S402, the actual load sensing differential pressure PLS1 of the lower control valve 50 and the target load sensing differential pressure PLS2 are compared, and an output current value I1 to the flow control valve 31c is calculated according to the difference, and step S404 is performed. Proceed to In step S404, an exciting current is output to the electromagnetic proportional valve 49c so as to have the current value I1 calculated in step S402 or step S403. When step S404 is executed, the process returns to step S400, and thereafter the above processing is periodically repeated.

(4) Block Diagram Detailed control contents in step S402 of the flowchart shown in FIG. 5 described above will be described. FIG. 6 is a block diagram showing the control contents in step S402. As shown in FIG. 6, the actual load sensing differential pressure PLS1 is subtracted from the target load sensing differential pressure PLS2 that the electromagnetic valve controller 85 has in advance to calculate a difference ΔPLS of the load sensing differential pressure.

  In block 405, the load sensing differential pressure difference ΔPLS is multiplied by a preset conversion coefficient K between the load sensing differential pressure and the electromagnetic proportional valve output current value, thereby increasing or decreasing the command current value of the electromagnetic proportional valve 31c. ΔI1 is calculated. Finally, a new command current value I1 of the electromagnetic proportional valve 31c is calculated by adding the increase / decrease value ΔI1 of the command current value to the current command current value I2 of the electromagnetic proportional valve 31c.

--- About the main relief valve 56 of the lower control valve 50 ---
In the present embodiment, since the upper and lower control valves 30 and 50 are connected in series, when the lower control valve 50 is driven, the main relief valve 36 of the upper control valve 30 exists in the middle of the hydraulic oil path. It becomes. That is, when the driving pressure of the lower control valve 50 increases, the pressure oil can be relieved from the relief valve 36 of the upper control valve 30. Therefore, the main relief valve 56 may not be provided in the lower control valve 50.

The work machine 1 according to the first embodiment described above has the following operational effects.
(1) Via the center joint 6, the actuator port 47 c of the upper swing body upper control valve 30 provided in the upper swing body 3 and the main port 64 of the lower control valve 50 provided in the lower travel body 2 Configured to connect. The opening area of the flow control valve 31c that supplies pressure oil from the upper control valve 30 to the lower control valve 50 is controlled based on the load sensing differential pressure PLS1 of the lower control valve 50. As a result, the number of pipes of the center joint 6 can be suppressed, so that the center joint has the same size as the center joint used in a general hydraulic excavator of the same class as the work machine 1 in terms of size and work capacity. This is advantageous in terms of mounting space and manufacturing cost.

  In addition, it is possible to configure a hydraulic circuit that drives a plurality of control valves with a single pump by using a control valve that is normally used alone, so that the configuration of the hydraulic circuit can be simplified. Further, since the flow rate of the pressure oil supplied to the lower control valve 50 can be appropriately controlled, energy consumption can be reduced.

(2) Via the center joint 6, the actuator port 47 c of the upper swing body upper control valve 30 provided in the upper swing body 3, and the main port 64 of the lower control valve 50 provided in the lower travel body 2 Configured to connect. Then, the lower control valve 50 is regarded as a part of the load actuator in the same manner as the other upper swing body actuator 26, and based on the load sensing differential pressure that is the output pressure of the differential pressure reducing valve 42 of the upper control valve 30, The capacity of the main pump 70 was controlled. Thereby, it is not necessary to directly reflect the control signal from the lower control valve 50 in the capacity control of the main pump 70, and the system configuration of the work machine 1 can be simplified.

--- Second Embodiment ---
With reference to FIG. 7, a second embodiment of the work machine according to the present invention will be described. In the following description, the same components as those in the first embodiment are denoted by the same reference numerals, and different points will be mainly described. Points that are not particularly described are the same as those in the first embodiment. In the present embodiment, the first embodiment is mainly that the opening area control of the flow control valve 31c of the upper control valve 30 is performed based on the operation signal output from the operating device 81 for the lower traveling body. And different.

  That is, in the first embodiment described above, first, the opening area of the flow control valve 51 in the lower control valve 50 changes based on the operation signal output from the operation device 81, and pressure oil is applied to the actuator 27. Flow, load sensing differential pressure PLS1 changes. Next, the electromagnetic valve controller 85 controls the opening area of the flow control valve 31c in the upper control valve 30 in accordance with a change in the load sensing differential pressure PLS1. Therefore, in the above-described first embodiment, the opening area of the flow control valve 51 in the lower control valve 50 changes, pressure oil flows through the actuator 27, and the load sensing differential pressure PLS1 actually changes. During this time, the flow control of the pressure oil in the flow control valve 31c is not performed.

  Therefore, in the second embodiment, as described below, the opening area control of the flow control valve 31c of the upper control valve 30 is performed earlier based on the operation signal output from the operating device 81 for the lower traveling body. I'm trying to get started. Specifically, among the steps of the flowchart shown in FIG. 5 in the first embodiment described above, the control content in step S402 is changed as follows.

  FIG. 7 is a block diagram showing the contents of control in step S402 in the present embodiment. In block 407, the command current value of the electromagnetic proportional valve 31c is obtained from the acquired input value L1 of the operating device 81 by using a conversion formula between the input value L1 of the operating device 81 and the electromagnetic proportional valve output current value I1 set in advance. I1 is calculated.

  In the second embodiment, in addition to the operational effects in the first embodiment, as described above, by using the input value L1 of the operating device 81, the load sensing differential pressure as in the first embodiment. Compared with the case of using PLS1, it becomes possible to start driving the flow control valve 31c earlier. Therefore, the responsiveness of the system is improved. Further, similarly to the first embodiment, the flow rate of the pressure oil supplied to the lower control valve 50 can be appropriately controlled, so that energy consumption can be reduced.

  A third embodiment of the work machine according to the present invention will be described with reference to FIG. In the following description, the same components as those in the first and second embodiments are denoted by the same reference numerals, and different points will be mainly described. Points that are not particularly described are the same as those in the first and second embodiments. In the present embodiment, the opening area control of the flow control valve 31c of the upper control valve 30 is mainly performed based on both the load sensing differential pressure PLS1 and the operation signal output from the operating device 81 for the lower traveling body. It differs from the first and second embodiments in that it is performed.

  That is, in the first embodiment, as described above, the opening area of the flow control valve 51 in the lower control valve 50 changes, pressure oil flows through the actuator 27, and the load sensing differential pressure PLS1 actually changes. During this time, the flow control of the pressure oil in the flow control valve 31c is not performed. In the second embodiment, since the opening area of the flow rate control valve 31c is controlled using only the input value L1 of the operating device 81, there is a risk that the flow rate will be excessive or insufficient due to load fluctuations. is there.

  Therefore, in the third embodiment, as described below, the flow control valve 31c is controlled using both the load sensing differential pressure PLS1 of the lower control valve 50 and the input signal L1 of the operating device 81 of the lower traveling body. Control the opening area. Specifically, among the steps of the flowchart shown in FIG. 5 in the first embodiment described above, the control content in step S402 is changed as follows.

  FIG. 8 is a block diagram showing the contents of control in step S402 in the present embodiment. As shown in FIG. 8, the actual load sensing differential pressure PLS1 measured is subtracted from the target load sensing differential pressure PLS2 that the solenoid valve controller 85 has in advance to calculate the load sensing differential pressure difference ΔPLS.

  In block 405, the load sensing differential pressure difference ΔPLS is multiplied by a preset conversion coefficient K between the load sensing differential pressure and the electromagnetic proportional valve output current value, thereby increasing or decreasing the command current value of the electromagnetic proportional valve 31c. ΔI1 is calculated. Further, the current input value L1 of the measured operating device 81 is subtracted from the past input value L2 of the operating device 81 stored in a memory (not shown) of the solenoid valve controller 85, and the difference between the input values of the operating device 81 is subtracted. ΔL is calculated.

  In block 406, the command current of the electromagnetic proportional valve 31c is multiplied by multiplying the input value difference ΔL of the operating device 81 by a conversion coefficient K between the input value of the operating device 81 and the electromagnetic proportional valve output current value set in advance. The increase / decrease value ΔI2 of the value is calculated. Finally, with respect to the current command current value I2 of the electromagnetic proportional valve 31c, an increase / decrease value ΔI1 of the command current value due to a change in the load sensing differential pressure and an increase / decrease value ΔI2 of the command current value due to a change in the input signal of the operating device 81 are obtained. In addition, a new command current value I1 of the electromagnetic proportional valve 31c is calculated.

  In the third embodiment, the opening area of the flow control valve 31c is controlled by using both the load sensing differential pressure PLS1 of the lower control valve 50 and the input signal L1 of the operating device 81 for the lower traveling body. Thereby, at the initial stage when the operation input is changed, the opening area of the electromagnetic proportional valve 31c is determined based on the input signal L1 of the operation device 81, so that the responsiveness is improved. Further, when the load sensing differential pressure PLS1 of the lower control valve 50 starts to change, the opening area of the electromagnetic proportional valve 31c is determined based on the load sensing differential pressure PLS1, so that the flow rate of the pressure oil to the actuator 27 is optimized. it can. That is, both the optimization of the flow rate of the pressure oil to the actuator 27 and the improvement of the response of the actuator 27 to the operation of the operation device 81 can be achieved.

---- Modified example ---
(1) In the above description, the opening area of the flow control valve 31c of the upper control valve 30 is controlled based on the operation signal output from the load sensing differential pressure PLS1 and the operating device 81 for the lower traveling body. However, the present invention is not limited to this. For example, the flow control valve 31c of the upper control valve 30 may be simply turned on / off. That is, if it is determined that the operating device 81 is operated based on the operation signal output from the operating device 81 for the lower traveling body, the flow control valve 31c is fully opened and the operating device 81 is not operated. If determined, the flow control valve 31c may be fully closed.

(2) In the above description, as an example of the working machine, the hydraulic excavator provided with four independent crawler-type leg units 202a to 202d at the front, rear, left, and right ends has been described, but the present invention is not limited thereto. Not. For example, you may apply this invention to the working machine comprised so that four wheels could be raised / lowered independently, respectively. For example, the present invention may be applied to a general crawler type work machine having two crawler units.

(3) In the above description, it is not essential that the main pump 70 is a variable displacement type.
(4) You may combine each embodiment and modification which were mentioned above, respectively.

In addition, this invention is not limited to the thing of embodiment mentioned above at all, a lower traveling body, the upper revolving body provided in the upper part of the lower traveling body so that turning was possible, and the cab provided in the upper revolving body A plurality of lower traveling body actuators provided on the lower traveling body, a plurality of upper swing body actuators provided on the upper swing body, a plurality of lower traveling body actuators, and a plurality of upper swing body actuators. Connect the hydraulic circuit of the lower traveling body and the hydraulic circuit of the upper swinging body so that the upper swinging body can turn relative to the lower traveling body, and a hydraulic pump provided in the upper swinging body that supplies pressure oil A center joint, a plurality of undercarriage actuator operating devices for operating a plurality of undercarriage actuators provided in the cab, and a plurality of undercarriage actuator operating devices provided in the cab, respectively. A plurality of upper swing body actuator operating devices for operating the upper swing body actuators, and a plurality of flow control valves (lower flow control valves) corresponding to the plurality of lower travel body actuators. The upper swing body provided in the upper swing body has a control valve for the lower travel body provided in the travel body and a plurality of flow control valves (upper flow control valves) corresponding to the plurality of actuators for the upper swing body. Control valve and an opening control signal output means for outputting an opening control signal for controlling the opening of a plurality of upper flow control valves and a plurality of lower flow control valves, and an upper flow control valve via a center joint Is connected to the pump port of the control valve for the lower traveling body, and the opening control signal output means is based on the operation amount of the actuator operating device for the lower traveling body. It is intended to include working machine various structures and outputs the opening control signal to the upper flow control valve the pump port of the lower traveling-body control valves are connected downstream.
Further, the present invention is not limited to the above-described embodiment, and the lower traveling body, the upper swinging body that is turnable on the upper portion of the lower traveling body, and the cab provided in the upper swinging body. A plurality of lower traveling body actuators provided on the lower traveling body, a plurality of upper swing body actuators provided on the upper swing body, a plurality of lower traveling body actuators, and a plurality of upper swing body actuators. Connect the hydraulic circuit of the lower traveling body and the hydraulic circuit of the upper swinging body so that the upper swinging body can turn relative to the lower traveling body, and a hydraulic pump provided in the upper swinging body that supplies pressure oil A center joint, a plurality of undercarriage actuator operating devices for operating a plurality of undercarriage actuators provided in the cab, and a plurality of undercarriage actuator operating devices provided in the cab, respectively. A plurality of upper swing body actuator operating devices for operating the upper swing body actuators, and a plurality of flow control valves (lower flow control valves) corresponding to the plurality of lower travel body actuators. The upper swing body provided in the upper swing body has a control valve for the lower travel body provided in the travel body and a plurality of flow control valves (upper flow control valves) corresponding to the plurality of actuators for the upper swing body. Control valve, opening control signal output means for outputting an opening control signal for controlling the opening of the plurality of upper flow control valves and the plurality of lower flow control valves, and load sensing differential pressure of the lower traveling body control valve Lower load sensing differential pressure detecting means for detecting (lower load sensing differential pressure), and downstream of the upper flow control valve via the center joint The pump port of the control valve for the traveling body is connected, and the opening control signal output means is downstream of the pump port of the control valve for the lower traveling body based on the lower load sensing differential pressure detected by the lower load sensing differential pressure detection means. It includes a working machine having various structures, characterized in that it outputs an opening degree control signal to an upper flow rate control valve to which is connected.

DESCRIPTION OF SYMBOLS 1 Work machine 2 Lower traveling body 3 Upper turning body 5 Engine 6 Center joint 7 Pump unit 10 Boom 11 Boom cylinder 12 Arm 13 Arm cylinder 15 Work implement cylinder 23 Bucket 26 Upper turning body actuator 27 Lower traveling body actuator 30 Upper part Control valve (upper control valve)
30a, 30b, 30c Valve section 30d Control section 31a, 31b, 31c Flow control valve (main spool)
32a, 32b, 32c Pressure compensation valve 36 Main relief valve 40 Unload valve 42 Differential pressure reducing valve 49a, 49b, 49c Solenoid 50 Lower control valve (lower control valve)
70 Main pump 71 Pilot pump 72 Pump tilt control mechanism 72a Horsepower control tilt regulator 72b Load sensing control tilt regulator 73 Load sensing control valve 80 Operating device 81 Operating device 82 Electromagnetic proportional valve 83 Electromagnetic proportional valve 84 Communication controller 85 Electromagnetic Valve controller 86 Solenoid valve controller 87 Slip ring 150 Pressure sensor 201 Center frame 202a to 202d Leg unit

Claims (5)

A lower traveling body,
An upper swing body provided to be pivotable on an upper portion of the lower traveling body;
A cab provided in the upper swing body;
A plurality of lower traveling body actuators provided in the lower traveling body;
A plurality of upper swing body actuators provided in the upper swing body;
A hydraulic pump provided in the upper swing body for supplying pressure oil to the plurality of lower traveling body actuators and the plurality of upper swing body actuators;
A center joint that connects a hydraulic circuit of the lower traveling body and a hydraulic circuit of the upper rotating body so that the upper swinging body can turn with respect to the lower traveling body;
A plurality of undercarriage actuator actuators for operating the undercarriage actuators provided in the cab;
A plurality of upper swing body actuator operation devices for operating the plurality of upper swing body actuators provided in the cab;
A plurality of flow control valves (lower flow control valves) corresponding to the plurality of lower traveling body actuators, and a lower traveling body control valve provided in the lower traveling body;
A plurality of flow control valves (upper flow control valves) corresponding to the plurality of upper swing body actuators, and an upper swing body control valve provided on the upper swing body;
Opening control signal output means for outputting an opening control signal for controlling the opening of the plurality of upper flow control valves and the plurality of lower flow control valves,
A pump port of the lower traveling body control valve is connected to the downstream of the upper flow control valve via the center joint;
The opening degree control signal output means is based on the operation amount of the lower traveling body actuator operating device, and the opening degree control signal is sent to the upper flow control valve to which the pump port of the lower traveling body control valve is connected downstream. A working machine characterized by outputting The work machine according to claim 1,
A lower load sensing differential pressure detecting means for detecting a load sensing differential pressure (lower load sensing differential pressure) of the lower traveling body control valve;
The opening degree control signal output means is based on the amount of operation of the lower traveling body actuator operating device and the lower load sensing differential pressure detected by the lower load sensing differential pressure detecting means. A work machine that outputs an opening control signal to the upper flow control valve to which a pump port of a control valve is connected. A lower traveling body,
An upper swing body provided to be pivotable on an upper portion of the lower traveling body;
A cab provided in the upper swing body;
A plurality of lower traveling body actuators provided in the lower traveling body;
A plurality of upper swing body actuators provided in the upper swing body;
A hydraulic pump provided in the upper swing body for supplying pressure oil to the plurality of lower traveling body actuators and the plurality of upper swing body actuators;
A center joint that connects a hydraulic circuit of the lower traveling body and a hydraulic circuit of the upper rotating body so that the upper swinging body can turn with respect to the lower traveling body;
A plurality of undercarriage actuator actuators for operating the undercarriage actuators provided in the cab;
A plurality of upper swing body actuator operation devices for operating the plurality of upper swing body actuators provided in the cab;
A plurality of flow control valves (lower flow control valves) corresponding to the plurality of lower traveling body actuators, and a lower traveling body control valve provided in the lower traveling body;
A plurality of flow control valves (upper flow control valves) corresponding to the plurality of upper swing body actuators, and an upper swing body control valve provided on the upper swing body;
An opening control signal output means for outputting an opening control signal for controlling the opening of the plurality of upper flow control valves and the plurality of lower flow control valves;
A lower load sensing differential pressure detecting means for detecting a load sensing differential pressure (lower load sensing differential pressure) of the control valve for the lower traveling body,
A pump port of the lower traveling body control valve is connected to the downstream of the upper flow control valve via the center joint;
The opening degree control signal output means is configured to have the upper flow rate to which a pump port of the lower traveling body control valve is connected downstream based on the lower load sensing differential pressure detected by the lower load sensing differential pressure detecting means. A work machine that outputs an opening control signal to a control valve. In the work machine according to any one of claims 1 to 3,
The hydraulic pump is a variable displacement hydraulic pump,
Further comprising capacity changing means for changing the capacity of the hydraulic pump;
An upper load sensing differential pressure detecting means for detecting a load sensing differential pressure (upper load sensing differential pressure) of the upper swing body control valve;
The working machine characterized in that the capacity changing means changes the capacity of the hydraulic pump based on the upper load sensing differential pressure detected by the upper load sensing differential pressure detecting means. In the work machine according to any one of claims 1 to 4,
The lower traveling body is
Four independent traveling unit units having traveling unit frames;
Four swing frames having one end connected to the traveling body frame and the other end pivotally supported near the periphery of the center frame and capable of swinging independently in the vertical direction;
Provided for each of the four swing frames, and independently swing the traveling body unit with respect to the center frame by swinging the four swing frames independently with respect to the center frame. A work machine comprising: four drive cylinders as the actuator for the lower traveling body that move up and down.

Images