JP2016113878A - Work vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to reduce the pressure of pressure oil accumulated in an accumulator during operation of a parking brake to save energy.SOLUTION: A work vehicle includes: an accumulator 21 for accumulating pressure oil supplied from a hydraulic pump 3 to serve as a temporary hydraulic power source relative to a steering cylinder 11 and a parking brake 15; and a controller 23 for controlling operations of the parking brake 15 and the hydraulic pump 3 on the basis of signals from a parking brake switch 20 and a pressure sensor 22. The controller 23 changes the discharge amount of the pressure oil by the hydraulic pump 3 by tilting a capacity variable section 3A of the hydraulic pump 3 by a tilting actuator 4 so as to reduce a pressure value of the pressure oil accumulated in the accumulator 21 when the parking brake 15 is being operated, compared to when the parking brake 15 is being released.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a work vehicle configured to use an accumulator as a temporary hydraulic source for a parking brake and a steering cylinder.

  In general, a large transport work vehicle called a dump truck is equipped with a power steering device including a steering cylinder and the like so as to reduce the operating force during vehicle steering. The parking brake is equipped with a negative brake device that releases braking force when pressure oil is supplied from the outside and applies braking force to the vehicle while pressure oil is not supplied. In addition, an accumulator serving as a temporary hydraulic source for the steering cylinder and the parking brake is provided (see, for example, Patent Documents 1 and 2).

JP 2009-264456 A JP 2013-23105 A

  By the way, in the work vehicle according to the above-described prior art, the pressure value of the pressure oil accumulated in the accumulator is kept almost constant regardless of whether the parking brake is operated or not. For this reason, during operation of the parking brake, the pressure value of the accumulator is higher than necessary, and it is desired to save energy.

  The present invention has been made in view of the above-mentioned problems of the prior art, and an object of the present invention is to reduce the pressure value of the accumulator during operation of the parking brake and to save energy. It is to provide.

  In order to solve the above-described problems, the present invention relates to a variable displacement hydraulic pump having a displacement variable portion and driven to rotate by a prime mover, and a pressure oil discharged from the hydraulic pump by tilting the displacement variable portion. A tilt actuator that increases or decreases the discharge amount, a steering cylinder in which pressure oil from the hydraulic pump is supplied and discharged via a steering valve when the vehicle is steered, and a braking force that is always applied to the vehicle to supply the pressure oil A negative type parking brake for releasing the braking force, a parking brake operating device for commanding the operation and release of the parking brake, and pressure oil supplied from the hydraulic pump to accumulate temporary oil for the steering cylinder and the parking brake. An accumulator serving as a hydraulic pressure source, a pressure sensor for detecting the pressure of the pressure oil accumulated in the accumulator, and the parking brake Operating device and on the basis of a signal from the pressure sensor is applied to a working vehicle comprising a controller for controlling the operation of the parking brake and the hydraulic pump.

  A feature of the configuration adopted by the present invention is that the controller uses the tilt actuator to variably control the pressure of the pressure oil accumulated in the accumulator according to whether the parking brake is operated. Tilt actuator control means for tilting the displacement variable section to change the discharge amount of the pressure oil by the hydraulic pump, the tilt actuator control means is configured to compare the parking brake with that during the release of the parking brake. In order to reduce the pressure value of the pressure oil accumulated in the accumulator during the operation of the brake, a control signal for tilting the capacity variable portion of the hydraulic pump is output to the tilt actuator.

  By adopting the configuration as described above, during operation of the parking brake, it is possible to lower the pressure value of the accumulator by lowering the discharge amount of the hydraulic pump than when the brake is released, thereby reducing the load on the prime mover. Energy can be achieved.

It is a circuit block diagram of the dump truck by embodiment of this invention. It is a flowchart which shows the pressure control process of the accumulator by the controller in FIG. It is a characteristic diagram which shows the relationship between the pressure of an accumulator, the operation | movement of parking brake, cancellation | release, and the tilt angle of a hydraulic pump, respectively.

  Hereinafter, as a work vehicle according to an embodiment of the present invention, a dump truck that transports crushed stones mined in a mine or the like will be described as an example, and will be described in detail with reference to FIGS. 1 to 3 of the accompanying drawings.

  An engine 1 as a prime mover is mounted on a dump truck, which is a large transport work vehicle. The engine 1 rotates a variable displacement hydraulic pump 3 that constitutes a hydraulic pressure source together with a hydraulic oil tank 2. The hydraulic pump 3 includes a variable capacity portion 3A such as a swash plate or a valve plate. The displacement variable portion 3A is tilted by the tilt actuator 4, and increases or decreases the displacement volume (that is, the discharge amount of pressure oil) of the hydraulic pump 3 according to the tilt angle.

  For example, under normal operating conditions in which the engine 1 is rotated at a predetermined rotational speed, the discharge amount of the pressure oil discharged from the hydraulic pump 3 is increased by increasing the tilt angle of the displacement variable portion 3A by the tilt actuator 4. And the maximum discharge amount at the maximum tilt. On the other hand, when the tilt angle of the capacity variable portion 3A is reduced, the discharge amount of the hydraulic pump 3 decreases accordingly, and becomes the minimum discharge amount at the minimum tilt.

  First and second supply pipes 6 and 7 are connected to the discharge side of the hydraulic pump 3 via a direction control valve 5 called a priority valve. The direction control valve 5 is constituted by, for example, a hydraulic pilot type or electromagnetic type three-way switching valve. The directional control valve 5 is operated in the first position (A), the second position (B), and the third position (C) by an operator manually operating a remote control device (none of which is shown) in the cab of the dump truck. ).

  The directional control valve 5 allows the pressure oil discharged from the hydraulic pump 3 to flow only toward the first supply line 6 when being switched to the first position (A). When switched to the second position (B), the pressure oil from the hydraulic pump 3 is circulated toward both the first and second supply pipes 6 and 7. When the second position (B) is switched to the third position (C), the pressure oil from the hydraulic pump 3 is allowed to flow only toward the second supply line 7.

  A hoist cylinder 9 is connected to the second supply pipe line 7 via a control valve device 8. The control valve device 8 controls the supply and discharge of the pressure oil from the hydraulic pump 3 to the hoist cylinder 9. An operation lever (not shown) is provided in the cab of the dump truck, and the control valve device 8 is switched by this lever operation. The hoist cylinder 9 expands or contracts as follows when the pressure oil from the hydraulic pump 3 is supplied and discharged through the second supply pipe 7 and the control valve device 8.

  Here, the hoist cylinder 9 is configured by a multi-stage (for example, three-stage) hydraulic cylinder that is extendable and retractable between the body of the dump truck and a loading platform (both not shown). For example, the hoist cylinder 9 extends upward and downward in order to perform earth removal work, thereby tilting (turning) the loading platform obliquely rearward of the vehicle body. On the other hand, when the hoist cylinder 9 is contracted, the cargo bed lies down with respect to the vehicle body and is rotated to the load carrying position.

  The first supply pipeline 6 is provided with a pair of steering cylinders 11 (only one is shown) via a steering valve 10. Here, the steering valve 10 and each steering cylinder 11 constitute a power steering device for a dump truck, and reduce the operation force when the steering handle 12 is steered.

  When the operator of the dump truck steers the steering handle 12, the steering valve 10 is switched from the neutral position (D) to either the left or right switching position (E) or (F). At this time, the pressure oil discharged from the hydraulic pump 3 to the first supply pipe 6 is supplied to the steering cylinder 11 via the steering valve 10 to extend or contract the rod 11A of the steering cylinder 11. Thereby, the steering wheel (for example, the front wheel side) of the dump truck is steered according to the expansion and contraction operation of the steering cylinder 11. The tank line 13 returns the return oil from the steering cylinder 11 to the hydraulic oil tank 2.

  The brake pipe 14 is provided such that a base end side 14 </ b> A branches off from a middle portion of the first supply pipe 6. The distal end side of the brake conduit 14 is connected to a brake cylinder 16 (a hydraulic chamber 16C described later) of the parking brake 15. The parking brake 15 is a negative type brake device that releases braking force when pressure oil is supplied to the brake cylinder 16 from the outside, and applies braking force to the vehicle during normal times when pressure oil is not supplied.

  In the brake cylinder 16 of the parking brake 15, a piston 16A inserted so as to be slidably displaceable, a spring 16B that constantly urges the piston 16A toward the vehicle braking side, and the spring 16B sandwiches the piston 16A. And a hydraulic chamber 16C disposed on the opposite side. A friction brake plate 18 is pressed by a piston 16A to a disk 17 that rotates integrally with each wheel of the dump truck, and a braking force is applied by a spring 16B.

  A brake release valve 19 for supplying and releasing brake release pressure to and from the hydraulic chamber 16C of the brake cylinder 16 is provided in the middle of the brake conduit 14 (that is, a position between the brake cylinder 16 and the accumulator 21). The brake release valve 19 is constituted by an electromagnetic valve including an urging spring 19A and a solenoid 19B. Since the solenoid 19B is normally demagnetized, the brake release valve 19 is placed at the braking position (G) by the biasing spring 19A. To the release position (H).

  When the brake release valve 19 is switched from the brake position (G) to the release position (H), the pressure oil from the brake conduit 14 is supplied to the hydraulic chamber 16C of the brake cylinder 16 as a brake release pressure. For this reason, the piston 16 </ b> A of the brake cylinder 16 is pushed in the brake release direction against the spring 16 </ b> B to separate the brake plate 18 from the disk 17. As a result, the parking brake 15 releases the braking force of the vehicle and allows the dump truck to run.

  The parking brake switch 20 constitutes a parking brake operating device that commands activation and release of the parking brake 15. The parking brake switch 20 is provided in the cab of the dump truck and is manually operated by an operator. A command signal from the parking brake switch 20 is output to the controller 23 described later. The controller 23 outputs a brake control signal that excites or demagnetizes the brake release valve 19 based on the command signal at this time. The parking brake operating device that commands the operation and release of the parking brake 15 is not limited to the parking brake switch 20, and for example, the parking brake operating device may be configured using an operation lever or an operation dial (knob). Good.

  The brake line 14 is provided with an accumulator 21 located between the first supply line 6 and the brake release valve 19. The accumulator 21 accumulates the pressure oil discharged from the hydraulic pump 3 to the first supply pipe 6 and constitutes a temporary hydraulic source for the steering cylinder 11 and the parking brake 15, for example. In other words, when the hydraulic pump 3 is out of order and pressure oil is not supplied from the hydraulic pump 3 to the first supply pipe 6, the pressure oil accumulated in the accumulator 21 is supplied to the steering cylinder 11 and / or the parking brake 15. To do.

  When it is necessary to cancel the operation of the parking brake 15 or perform a power steering operation of the dump truck (vehicle) in such an abnormality, the pressure of the pressure oil accumulated in the accumulator 21 is used. By doing so, emergency measures can be taken appropriately. Note that the attachment position of the accumulator 21 is not limited to a position in the middle of the brake pipeline 14, and may be provided in the middle of the first supply pipeline 6, for example.

  In the middle of the first supply pipe 6, a pressure sensor 22 is provided at a position upstream of the steering valve 10. The pressure sensor 22 detects the pressure P (see FIGS. 2 and 3) of the pressure oil accumulated in the accumulator 21 and outputs a detection signal to the controller 23 described later. The pressure sensor 22 may be provided in the middle of the brake conduit 14. That is, the mounting position of the accumulator 21 and the pressure sensor 22 is not limited to the position shown in FIG. 1, and can be changed as appropriate according to the convenience of design. In short, it is only necessary that the pressure sensor 22 can detect the pressure P of the pressure oil accumulated in the accumulator 21.

  The controller 23 serving as a dump truck control device includes a microcomputer or the like, and includes a storage device (hereinafter referred to as a memory 23A) represented by, for example, a flash memory, a ROM, a RAM, and the like. On the input side of the controller 23, a parking brake switch 20 for commanding the operation and release of the parking brake 15 and the pressure sensor 22 are connected. The tilting actuator 4 of the hydraulic pump 3 and the solenoid 19B of the brake release valve 19 are connected to the output side of the controller 23.

  The controller 23 outputs an excitation or demagnetization control signal to the solenoid 19 </ b> B of the brake release valve 19 in order to control the operation and release of the parking brake 15 based on the command signal from the parking brake switch 20. A memory 23A of the controller 23 stores a program for pressure control processing of the accumulator 21 (see FIG. 2) and the like. The controller 23 controls the operation of the parking brake 15 and the tilting actuator 4 of the hydraulic pump 3 based on signals from the parking brake switch 20 and the pressure sensor 22.

  Specifically, as shown in FIG. 2, the controller 23 variably controls the pressure P of the pressure oil accumulated in the accumulator 21 depending on whether the parking brake 15 is activated or not. There is a tilt actuator control means (see, for example, step 2 and steps 4 to 7 in FIG. 2) that tilts the capacity variable portion 3A of the hydraulic pump 3 to change the discharge amount of the pressure oil by the hydraulic pump 3. Yes. This tilting actuator control means tilts a control signal for tilting the capacity variable portion 3A so that the pressure value of the pressure oil accumulated in the accumulator 21 is lowered during the operation of the parking brake 15 than when the brake is released. It is configured to output to the actuator 4.

  The tilting actuator control means by the controller 23 determines whether or not the parking brake 15 is operated based on a command signal from the parking brake operating device (that is, the parking brake switch 20). The tilt actuator control means is configured to feedback control the pressure P of the pressure oil accumulated in the accumulator 21 by controlling the operation of the tilt actuator 4 based on the detection signal from the pressure sensor 22. .

  Here, when the pressure P of the accumulator 21 is lowered by the control signal from the controller 23, the tilt actuator 4 tilts the capacity variable portion 3A of the hydraulic pump 3 in a direction in which the tilt angle becomes smaller. On the other hand, when the pressure P of the accumulator 21 is increased, the displacement variable portion 3A of the hydraulic pump 3 is tilted in the direction in which the tilt angle is increased.

  A characteristic line 24 shown in FIG. 3 represents the pressure characteristic of the pressure oil accumulated in the accumulator 21. The pressure P of the accumulator 21 varies as indicated by pressure values Pa, Pb, and Pc (Pa <Pb <Pc) as indicated by the characteristic line 24. Here, it is considered that the reason why the pressure P of the accumulator 21 is decreased, for example, from time t3 to t5 is due to leakage of pressure oil in the hydraulic circuit. Further, the reason why the pressure P decreases during the time t1 to t2, the time t6 to t8, and the time t9 to t11 is also due to the same reason.

  A characteristic line 25 indicates the operation and release characteristics of the parking brake 15 and corresponds to opening and closing (OFF, ON) operations of the parking brake switch 20. While the parking brake 15 is in operation, the vehicle is parked and stopped, and while the parking brake 15 is released, the vehicle is ready to travel. A characteristic line 26 represents characteristics when the displacement variable portion 3A of the hydraulic pump 3 is tilt-driven by the tilt actuator 4 between the minimum tilt and the maximum tilt.

  The work vehicle (that is, the dump truck) according to the present embodiment has the above-described configuration. Next, the operation thereof will be described.

  When the operator starts and operates the engine 1 in the cab of the dump truck, the hydraulic pump 3 is driven to rotate. The hydraulic pump 3 discharges the pressure oil from the discharge side while sucking the oil in the hydraulic oil tank 2. When the directional control valve 5 is switched to the first position (A), the pressure oil from the hydraulic pump 3 is supplied to the accumulator 21 through the first supply line 6 and the brake line 14, and enters the accumulator 21. The pressure oil is accumulated.

  When the operator of the dump truck operates the parking brake switch 20 to release the parking brake 15, a control signal is output from the controller 23 to the brake release valve 19 and the solenoid 19B is excited. As a result, the brake release valve 19 is switched from the brake position (G) to the release position (H), and the pressure oil introduced from the hydraulic pump 3 to the brake conduit 14 becomes the brake release pressure, and the brake cylinder 16 It is supplied to the hydraulic chamber 16C.

  For this reason, the piston 16 </ b> A of the brake cylinder 16 is pushed in the brake release direction against the spring 16 </ b> B to separate the brake plate 18 from the disk 17. As a result, the parking brake 15 releases the braking force of the vehicle and allows the traveling operation of the dump truck.

  In this state, when the operator in the driver's cab runs the dump truck and steers the steering handle 12, the steering valve 10 is moved from the neutral position (D) to the left and right switching positions (E) and (F). It can be switched to either. At this time, the pressure oil discharged from the hydraulic pump 3 to the supply pipe 6 is supplied to the steering cylinder 11 via the steering valve 10 to expand or contract the rod 11A of the steering cylinder 11. Thereby, the steering wheel of the dump truck is steered according to the expansion / contraction operation of the steering cylinder 11, and the operator can perform the steering operation of the vehicle with a relatively light force.

  Here, the accumulator 21 constitutes a temporary hydraulic source for the hydraulic pump 3. That is, even if the supply of pressure oil from the hydraulic pump 3 toward the first supply pipe 6 is temporarily interrupted, the pressure oil accumulated in the accumulator 21 is supplied to the steering cylinder 11 via the steering valve 10. So that a so-called power steering operation can be performed. Further, while the brake release valve 19 is switched from the braking position (G) to the release position (H), the pressure oil accumulated in the accumulator 21 can be supplied to the hydraulic chamber 16C of the brake cylinder 16 as a brake release pressure. The dump truck can be allowed to travel by releasing the braking force of the parking brake 15.

  When the directional control valve 5 is switched from the first position (A) to the second position (B), the pressure oil discharged from the hydraulic pump 3 is supplied to both the first and second supply pipelines 6 and 7. It is distributed toward. As a result, both the steering operation of the vehicle and the expansion / contraction operation of the hoist cylinder 9 can be performed in a state where the operation of the parking brake 15 is released. On the other hand, when the direction control valve 5 is switched from the second position (B) to the third position (C), the pressure oil from the hydraulic pump 3 is circulated only toward the second supply line 7. In this case, the hoist cylinder 9 can be expanded and contracted to raise and lower the cargo bed while the parking brake 15 is operated and the vehicle is stopped.

  By the way, a work vehicle represented by a dump truck has a substantially constant pressure oil pressure accumulated in the accumulator 21 regardless of whether the parking brake 15 is operated or not (for example, pressure values Pb to Pc shown in FIG. 3). Range). However, while the parking brake 15 is in operation, the brake release valve 19 is in the braking position (G), the vehicle is parked and stopped, the steering valve 12 is not steered, and the steering valve 10 is in the neutral position ( D).

  For this reason, during operation of the parking brake 15, for example, the pressure oil accumulated in the accumulator 21 is not consumed until the operator closes the parking brake switch 20 (ON operation). In other words, the pressure of the pressure oil to be accumulated in the accumulator 21 is higher than necessary during the operation of the parking brake 15, and there is room for improvement in order to save energy.

  Therefore, in the present embodiment, the controller 23 executes the control process shown in FIG. 2 to reduce the pressure value of the pressure oil accumulated in the accumulator 21 during the operation of the parking brake 15 to save the pressure. Energy can be achieved.

  That is, when the control process shown in FIG. 2 is started, it is determined whether or not the engine 1 is operating. If “YES” is determined, it is determined whether or not the parking brake 15 is operating in the next step 2. To do. Here, the controller 23 can determine whether the parking brake 15 is in operation or is released based on a command signal from the parking brake switch 20.

  When it is determined as “NO” in Step 2, the operation of the parking brake 15 is released, the vehicle is in a travelable state, and the steering operation is appropriately performed. Therefore, in the next step 3, normal control is performed as follows. For example, at time t2 to t7 in FIG. 3 and further after time t12, in a vehicle ready state where the parking brake 15 is released, sufficient pressure oil is applied to the accumulator 21 in order to always be prepared for the steering operation of the operator. Need to be accumulated.

  For this reason, when performing normal control, the pressure of the pressure oil accumulated in the accumulator 21 is controlled within a range of pressure values Pb to Pc (pressures higher by about 1 to 3 MPa than the pressure value Pa) shown in FIG. Specifically, a control signal for tilting is output from the controller 23 to the tilting actuator 4, and the displacement variable portion 3A of the hydraulic pump 3 is tilted by the tilting actuator 4 between the minimum tilt and the maximum tilt. To do.

  Thereby, the discharge amount (flow rate) of the pressure oil discharged from the hydraulic pump 3 is increased when the tilt angle is set to the maximum tilt, and the pressure P of the pressure oil accumulated in the accumulator 21 is, for example, the time t3. The pressure is increased to the pressure value Pc. On the other hand, from time t3 to time t4, the displacement variable portion 3A of the hydraulic pump 3 is tilted to the minimum by the tilting actuator 4 in order to prevent the pressure P of the accumulator 21 from becoming higher than the pressure value Pc. Driven, the discharge amount of the pressure oil by the hydraulic pump 3 is reduced so as to be the minimum flow rate.

  On the other hand, in the hydraulic circuit shown in FIG. 1, for example, pressure oil leaks from various hydraulic devices such as the directional control valve 5, the steering valve 10, and the brake release valve 19. Returned through the road 13 and the like. Therefore, for example, when the displacement variable portion 3A of the hydraulic pump 3 is driven to the minimum tilt side so as to reduce the tilt angle, as in the time t3 to t5 in FIG. 3, the pressure P of the accumulator 21 is leaked. It will gradually decrease under the influence of oil.

  Therefore, from time t5 to t6, the displacement variable portion 3A of the hydraulic pump 3 is driven to the maximum tilt side by the tilt actuator 4 so that the pressure P of the accumulator 21 does not drop below the pressure value Pb. The discharge amount of pressure oil due to is increased. When the pressure P of the accumulator 21 is increased again to the pressure value Pc at time t6, for example, after the time t6, the capacity variable portion 3A of the hydraulic pump 3 is set so that the pressure P of the accumulator 21 becomes equal to or less than the pressure value Pc. The actuator is driven to the minimum tilt side by the tilt actuator 4.

  Next, from time t7 to t12, the parking brake 15 is switched from the released state to the activated state. For this reason, in step 2 of FIG. 2, “YES” is determined. Thereby, in the next step 4, the pressure P of the accumulator 21 is read by the detection signal from the pressure sensor 22. In the next step 5, it is determined whether or not the pressure P of the accumulator 21 is equal to or higher than the control target value Pi.

  Here, the control target value Pi is set to a range of pressure values Pa to Pb (Pi = Pa to Pb) lower than the pressure value Pc by, for example, about 2 to 3 MPa. If “YES” is determined in the step 5, the pressure P of the accumulator 21 is equal to or higher than the control target value Pi, for example, after the time t7 in FIG. Therefore, in the next step 6, the tilt actuator 4 is controlled to reduce the pump tilt angle.

  That is, the displacement variable portion 3A of the hydraulic pump 3 is driven to the minimum tilt side by the tilt actuator 4 to reduce the discharge amount of the pressure oil by the hydraulic pump 3. As a result, from time t6 to t8, the pressure P of the accumulator 21 is reduced due to pressure oil leakage in the hydraulic circuit. In other words, since the discharge amount (supply amount) of the pressure oil from the hydraulic pump 3 is minimized, the leak amount of the pressure oil exceeds the supply amount, and the pressure P of the accumulator 21 gradually decreases.

  For example, when the pressure P of the accumulator 21 decreases to the pressure value Pa at time t8, it is determined as “NO” in step 5 in FIG. 2, and the pressure P of the accumulator 21 is lower than the control target value Pi. For this reason, in the next step 7, the tilt actuator 4 is controlled to increase the pump tilt angle. That is, as shown in time t8 to t9 in FIG. 3, the displacement variable portion 3A of the hydraulic pump 3 is driven to the maximum tilt side by the tilt actuator 4, and the discharge amount (supply amount) of the pressure oil by the hydraulic pump 3 is set. Increase.

  As a result, the pressure P of the pressure oil accumulated in the accumulator 21 is increased to the pressure value Pb at time t9, for example. Therefore, in step 5 in FIG. 2, it is determined that the pressure P is equal to or higher than the control target value Pi, and “YES” is determined, and in the next step 6, control is performed so as to reduce the pump tilt angle. That is, from time t9 to t10, the displacement variable portion 3A of the hydraulic pump 3 is driven by the tilt actuator 4 so as to be at the minimum tilt in order to prevent the pressure P of the accumulator 21 from becoming higher than the pressure value Pb. The discharge amount of the pressure oil by the hydraulic pump 3 is reduced so as to be the minimum flow rate. From time t9 to t11, the pressure P of the accumulator 21 is decreased due to pressure oil leakage in the hydraulic circuit.

  For example, when the pressure P of the accumulator 21 decreases to the pressure value Pa at time t11, “NO” is determined in step 5 in FIG. Thus, in the next step 7, control is performed to increase the pump tilt angle, and the discharge amount of the pressure oil from the hydraulic pump 3 is increased. As a result, the pressure P of the accumulator 21 rises so as to be higher than the pressure value Pa as at times t11 to t12 in FIG.

  In step 8 in FIG. 2, it is determined whether or not the engine 1 has been stopped. During the determination of “NO”, the processing over steps 2 to 8 is repeated, and “YES” is determined in step 8. When the engine 1 has been stopped, the control process is terminated because the engine 1 is stopped.

  Thus, according to the present embodiment, since the pressure of the pressure oil accumulated in the accumulator 21 is variably controlled according to whether the parking brake 15 is operated, the tilt actuator 4 is used for tilting. A control signal is output, and the displacement variable portion 3A of the hydraulic pump 3 is tilted by the tilt actuator 4 between the minimum tilt and the maximum tilt. Thus, the tilting actuator 4 tilts the capacity variable portion 3A so as to lower the pressure value of the pressure oil accumulated in the accumulator 21 during the operation of the parking brake 15 as compared to when the parking brake 15 is released. It is configured.

  For this reason, in the present embodiment, when the parking brake 15 is released, the pressure P of the pressure oil accumulated in the accumulator 21 is controlled in the range of pressure values Pb to Pc, and the parking brake 15 is in operation. The pressure P of the accumulator 21 can be controlled in the range of pressure values Pa to Pb lower than this.

  In this way, the discharge amount of the hydraulic pump 3 can be reduced and the pressure P of the accumulator 21 can be lowered to the pressure values Pa to Pb during the operation of the parking brake 15 compared to when the parking brake 15 is released. . Therefore, the rotational load that the engine 1 receives from the hydraulic pump 3 can be reduced, and the fuel consumption of the engine 1 can be reduced to save energy. Further, by reducing the pressure P of the accumulator 21 to the pressure values Pa to Pb, it is possible to suppress wear and damage of the component parts and to extend the life.

  In the above-described embodiment, among the steps 1 to 8 shown in FIG. 2, the processing of step 2 and steps 4 to 7 shows a specific example of the tilt actuator control means that is a constituent element of the present invention.

  Moreover, in the said embodiment, the dump truck was mentioned as an example and demonstrated as a working vehicle. However, the present invention is not limited to this, and can also be applied to a work vehicle including a parking brake and a power steering device, such as a wheeled hydraulic excavator, a wheeled hydraulic crane, and a hall loader.

  Furthermore, in the above-described embodiment, the case where the engine 1 is used as the prime mover of the work vehicle has been described as an example. However, the present invention is not limited to this. For example, an electric motor may be used as a prime mover, and the invention can also be applied to a hybrid work vehicle that uses an engine and an electric motor that also serves as a power generator as prime movers.

1 engine (motor)
DESCRIPTION OF SYMBOLS 2 Hydraulic oil tank 3 Variable displacement type hydraulic pump 3A Capacity variable part 4 Tilt actuator 10 Steering valve 11 Steering cylinder 12 Steering handle 15 Parking brake 16 Brake cylinder 19 Brake release valve 20 Parking brake switch (parking brake operation device)
21 Accumulator 22 Pressure sensor 23 Controller

Claims (3)

A variable displacement hydraulic pump having a displacement variable portion and driven to rotate by a prime mover;
A tilt actuator that tilts the capacity variable section to increase or decrease the discharge amount of the pressure oil discharged from the hydraulic pump;
A steering cylinder in which pressure oil from the hydraulic pump is supplied and discharged via a steering valve during steering of the vehicle;
A negative parking brake that constantly applies braking force to the vehicle and releases the braking force by supplying the pressure oil;
A parking brake operating device that commands activation and release of the parking brake;
An accumulator that accumulates pressure oil supplied from the hydraulic pump and serves as a temporary hydraulic source for the steering cylinder and parking brake;
A pressure sensor for detecting the pressure of the pressure oil accumulated in the accumulator;
In a work vehicle comprising a controller that controls the operation of the parking brake and the hydraulic pump based on signals from the parking brake operation device and a pressure sensor,
The controller tilts the displacement variable portion by the tilt actuator so as to variably control the pressure of the pressure oil accumulated in the accumulator according to whether the parking brake is activated or not. Tilt actuator control means for changing the discharge amount of pressure oil by
The tilt actuator control means tilts the capacity variable portion of the hydraulic pump to reduce the pressure value of the pressure oil accumulated in the accumulator during the operation of the parking brake compared to when the parking brake is released. A work vehicle characterized in that a control signal for rolling is output to the tilting actuator.   The controller determines whether the parking brake is activated or not based on a command signal from the parking brake operating device, and the pressure value of the pressure oil accumulated in the accumulator is based on a detection signal from the pressure sensor. The work vehicle according to claim 1, wherein the work vehicle is configured to be controlled.   The tilt actuator tilts the capacity variable portion of the hydraulic pump in a direction to reduce a tilt angle by the control signal when decreasing the pressure value of the accumulator, and increases the hydraulic pressure when increasing the pressure value of the accumulator. The work vehicle according to claim 1 or 2, wherein the capacity variable portion of the pump is configured to tilt in a direction in which a tilt angle increases.

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