JP3993413B2 - Boom working vehicle hydraulic oil supply device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
TECHNICAL FIELD The present invention relates to a hydraulic oil supply device for a boom working vehicle configured by providing a working device at the tip of a boom provided on a vehicle body that can freely move up and down, expand and contract, and more specifically, the boom is raised and lowered, expanded and contracted and turned. The present invention relates to a hydraulic oil supply device that can reduce drive power of a hydraulic pump that supplies hydraulic oil to each hydraulic actuator to be operated.
[0002]
[Prior art]
As an example of a boom work vehicle, in addition to a commonly known crane vehicle, a work board for operator boarding can be attached to the tip of the boom so that it can be swung freely so that work can be performed at a high place. There is an aerial work vehicle. Such a boom working vehicle can control the supply of hydraulic oil to each hydraulic actuator that moves the boom up and down, expands and contracts, and can move the working device at the tip of the boom as desired. In general, the hydraulic oil is supplied to these hydraulic actuators by driving a hydraulic pump provided in the vehicle body by an electric motor or a small engine.
[0003]
[Problems to be solved by the invention]
However, conventionally, this hydraulic oil supply hydraulic pump is always driven to rotate at a constant rotational speed, so that the flow rate of hydraulic oil fed to the hydraulic actuator is small, such as when the boom is moved slowly. However, most of the discharged hydraulic oil is returned to the oil tank as surplus oil, and there is a problem that the power loss of the hydraulic pump is large. In addition, there is a problem that the heat and noise generated during the work have a great influence on the surrounding environment.
[0004]
The present invention has been made in view of such a problem, and the hydraulic oil flow discharged from the hydraulic pump is set to a necessary minimum flow rate with a small surplus flow rate, thereby reducing the loss of driving power of the hydraulic pump. It is an object of the present invention to provide a hydraulic oil supply device for a boom working vehicle having a configuration capable of reducing the work cost.
[0005]
[Means for Solving the Problems]
In order to achieve such an object, a hydraulic fluid supply device for a boom working vehicle according to the present invention is provided with a working device (for example, the work in the embodiment) at the tip of a boom that is provided on a vehicle body and that can freely move up and down, extend and contract. The platform 40) is provided, and the boom is operated at a speed corresponding to the operation amount of each operation means (for example, the hoisting operation lever 51, the telescopic operation lever 52, and the turning operation lever 53 in the embodiment) corresponding to the hoisting, telescopic, and turning operations of the boom. Is a hydraulic oil supply device for a boom working vehicle (e.g., an aerial work vehicle 1 in the embodiment) configured to move up and down, extend and retract, and each hydraulic actuator (for example, The undulating cylinder 24, the telescopic cylinder 31, and the swing motor 23) in the embodiment, a hydraulic pump that supplies hydraulic oil to each hydraulic actuator, and each of the operating means Operation amount detection means (for example, first to third operation state detectors 81, 82, 83 in the embodiment) and position detection means for detecting the position of the work device relative to the vehicle body (for example, the embodiment) Undulation angle detector 85, length detector 86, turning angle detector 87 and position calculation circuit 62 of controller 60), and load detection means for detecting the load acting on the boom (for example, load detector 88 in the embodiment). And the overturning moment calculation circuit 63) of the controller 60, and the hydraulic fluid to each hydraulic actuator based on the position of the work device relative to the vehicle body detected by the position detection means and the operation amount of each operation means detected by the operation amount detection means. First flow rate setting means for obtaining the supply flow rate and setting the sum as the first flow rate (for example, the controller 6 in the embodiment) The first flow rate setting circuit 71) and the load acting on the boom detected by the load detection means and the operation oil supply flow rate to each hydraulic actuator based on the operation amount of each operation means detected by the operation amount detection means. The second flow rate setting means (for example, the second flow rate setting circuit 72 of the controller 60 in the embodiment) that sets the sum as the second flow rate, and the first flow rate and the first flow rate set by the first flow rate setting means. The main flow rate setting means (for example, the selection circuit 73 of the controller 60 in the embodiment) that sets the smaller one of the second flow rates set in the second flow rate setting means and the main flow rate setting means. Target flow rate setting means for setting the target flow rate based on the main flow rate (for example, the total flow rate calculation circuit 75 of the controller 60 and the target flow rate in the embodiment) Hydraulic pump control means for controlling the rotation of the hydraulic pump so that the flow rate of the hydraulic oil discharged from the hydraulic pump substantially coincides with the target flow rate set in the target flow rate setting means (for example, implementation) An electric motor drive control circuit 77 of the controller 60 and an electric motor M).
[0006]
Further, another working oil supply device for a boom working vehicle according to the present invention is provided with a working device at a tip end portion of a boom provided on a vehicle body that is freely movable up and down, extended and retracted, and operated to raise and lower the boom. Is a hydraulic power supply device for a boom working vehicle configured to raise, lower, extend, and turn the boom at a speed corresponding to the operation amount of each operation means corresponding to each hydraulic pressure that causes the boom to move up, down, extend, and turn An actuator, a hydraulic pump for supplying hydraulic oil to each hydraulic actuator, an operation amount detection means for detecting the operation amount of each operation means, a position detection means for detecting the position of the work device relative to the vehicle body, and a load acting on the boom Load detecting means for detecting the position of the working device detected by the position detecting means with respect to the vehicle body, a load acting on the boom detected by the load detecting means, and an operation amount detecting means Based on the detected operation amount of each operation means, the hydraulic fluid supply flow rate to each hydraulic actuator is obtained, and the sum is set as the main flow rate, and the main flow rate setting means sets the main flow rate to the main flow rate setting means. A target flow rate setting means for setting a target flow rate based on the hydraulic pump, and a hydraulic pump for controlling the rotation of the hydraulic pump so that the flow rate of the hydraulic oil discharged from the hydraulic pump substantially matches the target flow rate set in the target flow rate setting means Control means, The load acting on the boom is divided into multiple load classes, and for each load class, the relationship between the operation amount of the operating means at each work bench position and the hydraulic oil supply flow rate to the hydraulic actuator corresponding to the operation is specified. A small map group consisting of a plurality of maps is set, and the main flow rate setting means selects a small map group corresponding to this load class from the load detected by the load detection means, and the small map group thus selected A map corresponding to the position detected by the position detection means is selected from the above, and the hydraulic oil supply flow rate corresponding to the operation amount detected by the operation amount detection means is obtained using the map thus selected. .
[0007]
In these hydraulic oil supply devices for boom working vehicles according to the present invention, the hydraulic oil flow rate discharged from the hydraulic pump is the main flow rate of the hydraulic oil supply flow rate to each hydraulic actuator that causes the boom to move up, down, extend, and rotate. The rotation control (rotation speed or rotation speed control) of the hydraulic pump is performed so as to substantially match the target flow rate determined as follows. At this time, the hydraulic oil supply flow rate to each hydraulic actuator is determined by the operation amount of the operation means. In addition, the position is set depending on the position of the working device with respect to the vehicle body and the load acting on the boom (the load acting on the tip of the boom, the overturning moment acting on the vehicle body, etc.).
[0008]
For this reason, when control is performed to reduce the operating speed of the boom relative to the amount of operation of the operating means, such as when the position of the work device is far away from the vehicle body or when the load acting on the boom is large. Accordingly, since the discharge flow rate of the hydraulic pump can be reduced, the difference between the hydraulic oil flow rate actually required for the operation of the boom and the hydraulic oil flow rate discharged from the hydraulic pump is reduced to reduce the hydraulic pressure. The flow rate of hydraulic oil discharged from the pump can be set to a necessary minimum flow rate with a small surplus flow rate. As a result, it is possible to reduce the driving power loss of the hydraulic pump and reduce the work cost, and at the same time, it is possible to extend the service life of the hydraulic pump itself and the electric motor that drives the hydraulic pump. Furthermore, since the generation of heat and noise associated with the driving of the hydraulic pump is reduced, the influence on the surroundings during work can be reduced.
[0009]
Further, in the boom control, the boom control, the valve control means (for example, the valve control circuit 61 of the controller 60 in the embodiment) supplies and shuts off the hydraulic oil discharged from the hydraulic pump to each hydraulic actuator. The control valve is driven to perform the second target flow rate based on the sum of the hydraulic oil supply flow rates to the respective hydraulic actuators obtained according to the control valve drive signal output from the valve control means. The second target flow rate setting means for setting (for example, the second target flow rate setting circuit 78 of the controller 60 in the embodiment) is provided, and the hydraulic pump drive control means is configured such that the flow rate of the hydraulic oil discharged from the hydraulic pump is the target flow rate. The smaller one of the target flow rate set by the setting means and the second target flow rate set by the second target flow rate setting means. It is preferably adapted to control the rotation of the hydraulic pump so as pot match.
[0010]
In such a configuration, the hydraulic oil flow discharged from the hydraulic pump is output from the target flow rate (target flow rate set in the target flow rate setting circuit) set based on the operation amount of each operation unit and the valve control unit. The rotation control of the hydraulic pump is performed so as to coincide with the smaller one of the target flow rate set based on the drive signal of the control valve (second target flow rate set in the second target flow rate setting circuit). Therefore, the difference between the hydraulic oil flow rate actually required for the operation of the boom and the hydraulic oil flow rate discharged from the hydraulic pump can be further reduced, and the surplus flow rate can be further reduced.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. FIG. 2 shows an aerial work vehicle including a hydraulic oil supply device according to an embodiment of the present invention. The aerial work vehicle 1 includes a vehicle body 10 that includes tire wheels 11 and can travel on a road. A swivel base 20 provided at the rear of the vehicle body 10, a telescopic boom 30 coupled to a column 21 extending upward from the swivel base 20 with a foot pin 22, and a work table attached to the tip of the boom 30 40.
[0012]
The swivel base 20 swivels by a hydraulic drive of a swivel motor 23 provided in the vehicle body 10, and the boom 30 expands and contracts in the longitudinal direction by a hydraulic drive of a telescopic cylinder 31 incorporated therein. Further, a hoisting cylinder 24 is provided between the boom 30 and the support column 21, and the entire boom 30 moves up and down within the upper and lower surfaces by hydraulic driving of the hoisting cylinder 24.
[0013]
The work table 40 is rotatably attached to a vertical post 32 supported at the tip of the boom 30, and swings around the vertical post 32 by hydraulic drive of a swing motor 42 incorporated therein. Is possible. Here, the vertical post 32 is configured such that the vertical position is always maintained at the tip of the boom 30, and therefore the floor surface of the work table 40 is always maintained in the horizontal position regardless of the up-and-down position of the boom 30. Is done.
[0014]
Outrigger jacks 12 are provided at four positions on the vehicle body 10 in the front, rear, left and right directions. These outrigger jacks 12 extend downward to support the vehicle body 10, and can be used in a state of projecting to the side of the vehicle body 10.
[0015]
The work table 40 is provided with an upper operation device 50, and the upper operation device 50 is provided with a raising / lowering operation lever 51, an expansion / contraction operation lever 52, a turning operation lever 53, and a swing operation lever 54 (FIG. 1). reference). These operation levers 51, 52, 53, 54 can be tilted in the front-rear or left-right direction from the neutral position, and an operator who has boarded the work table 40 can tilt these operation levers 51, 52, 53, 54. By the operation, the boom 30 can be raised, retracted, swung, or the work table 40 can be swung. Here, the hoisting / unfolding / extending / turning operation direction of the boom 30 and the swinging operation direction of the work table 40 can be selected according to the operation directions of the corresponding operation levers 51, 52, 53, 54, respectively. It can be adjusted as desired according to the operation amount of 51, 52, 53, 54.
[0016]
FIG. 1 is a block diagram showing a signal transmission system in which the boom 30 is raised, retracted, turned, and turned by the operation of the operation levers 51, 52, 53, 54. The operation direction and the operation amount of each of the operation levers 51, 52, 53, 54 are the first to fourth operation state detectors (the operation direction detector and the operation amount detector) provided at the base end of each lever. The detection information is detected by 81, 82, 83, 84, for example, composed of a potentiometer, and the detected information is the valve control of the controller 60 provided on the vehicle body 10 as an operation signal of the boom 30 or the work table 40. Input to the circuit 61.
[0017]
An electric motor M that operates upon receiving power supply from the battery B is provided in the vehicle body 10, and the hydraulic pump P is driven by the electric motor M. Supply and shut-off of hydraulic oil discharged from the hydraulic pump P to the hoisting cylinder 24, the telescopic cylinder 31, the swing motor 23, and the swing motor 42 (hereinafter all or a part thereof are collectively referred to as a hydraulic actuator) The control valve (here, multiple type valve) V is driven by a valve control circuit 61 of the controller 60 (electromagnetic proportional drive). The drive control of the electric motor M is performed by a hydraulic pump discharge flow rate control circuit 70 of the controller 60 (this will be described later).
[0018]
The valve control circuit 61 of the controller 60 determines the operation direction and operation amount (operation signal) of the operation levers 51, 52, 53, 54 detected by the first to fourth operation state detectors 81, 82, 83, 84. A corresponding driving signal (driving voltage) is output, and thereby the control valve V is electromagnetically driven to control the direction and opening of the spool corresponding to each hydraulic actuator, and each hydraulic actuator 24, 31, 23, 42 is controlled. Operate. Therefore, the boom 30 moves up and down, expands and contracts in a direction corresponding to the operation direction of the operation levers 51, 52, and 53 at a speed corresponding to the operation amount, and the work table 40 moves in the operation direction of the swing operation lever 54. The head swings in the corresponding direction at a speed corresponding to the operation amount.
[0019]
Further, as shown in FIG. 2, the boom 30 is provided with a undulation angle detector 85 for detecting its own undulation angle and a length detector 86 for detecting its own length. A swivel angle detector 87 for detecting the swivel angle of the swivel base 20 (that is, the swivel angle of the boom 30) is provided in the vicinity of the swivel base 20. The information detected by these detectors 85, 86, 87 is input to the position calculation circuit 62 of the controller 60 as shown in FIG. 1, where the position of the tip of the boom 30, that is, the position of the work table 40 relative to the vehicle body 10 is determined. Calculated.
[0020]
As shown in FIG. 2, a load detector 88 that detects a load (axial force) acting on the hoisting cylinder 24 based on the pressure acting on the hoisting cylinder 24 is provided at the lower end of the hoisting cylinder 24. The information detected by the load detector 88 is input to the overturning moment calculation circuit 63 of the controller 60 as shown in FIG. The overturning moment calculation circuit 63 calculates the overturning moment that is a load acting on the boom 30 based on the input load information, and the valve control circuit 61 uses the overturning moment calculated in the overturning moment calculation circuit 63 as the boom. Compared with the allowable moment determined at any time according to various conditions such as the turning position (turning angle) of 30 and the amount of lateral extension of each outrigger jack 12, an operation command of the boom 30 that causes the overturning moment to exceed the allowable moment is issued. Ignoring (or rejecting the output of the drive signal of the control valve V in response to the operation command of the boom 30), moment limiter control for preventing the vehicle body 10 from overturning is performed.
[0021]
The valve control circuit 61 incorporates a shockless module that drives the control valve V so that the operating speed of the boom 30 gradually increases or decreases with sudden operation of the operation levers 51, 52, and 53. This shockless module operates by multiplying the drive signal of the control valve V output corresponding to the input operation signal by a shockless coefficient that changes stepwise (gradual increase or decrease) at each time step. It plays the role of a filter that causes a certain time delay until a predetermined boom operating speed corresponding to the signal is obtained. In addition, this shockless module drives the control valve V that is output in response to the input operation signal so that the boom 30 does not stop suddenly even when the boom 30 reaches the end of the undulating or telescopic region. The signal is multiplied by a shockless coefficient so that the operation speed of the boom 30 is gradually reduced and then stopped.
[0022]
As described above, the hydraulic pump discharge flow rate control circuit 70 that controls the drive of the electric motor M includes the first flow rate setting circuit 71, the second flow rate setting circuit 72, the selection circuit 73, and the third flow rate setting circuit 74 as shown in FIG. The total flow rate calculation circuit 75, the target flow rate setting circuit 76, and the motor drive control circuit 77 are configured.
[0023]
The first flow rate setting circuit 71 includes information on the position of the work table 40 with respect to the vehicle body 10 calculated by the position calculation circuit 62 and the operation levers 51 detected by the first to third operation state detectors 81, 82, 83. , 52, 53, the hydraulic fluid supply flow rates Qa, Qb, Qc to the hydraulic actuators 24, 31, 23 are determined based on the operation direction and operation amount information of the hydraulic flow rates, and the sum total is obtained as the first flow rate Q ₁ Set as. Further, the second flow rate setting circuit 72 includes information on the overturning moment calculated by the overturning moment calculating circuit 63 and the operation levers 51, 52, 52 detected by the first to third operation state detectors 81, 82, 83. The hydraulic fluid supply flow rates Qa, Qb, and Qc to the hydraulic actuators 24, 31 and 23 are obtained based on the operation direction and operation amount information of 53, and the sum is obtained as the first flow rate Q. ₂ Set as.
[0024]
In the first flow rate setting circuit 71, the first flow rate Q ₁ The procedure for setting is described with reference to FIGS. In the first storage circuit 71a (see FIG. 1) of the controller 60, each operation direction of the operation levers 51, 52, and 53 (that is, every operation direction of the hoisting cylinder 24, the telescopic cylinder 31, and the turning motor 23) For each position of the base 40 with respect to the vehicle body 10, data defining the relationship between the lever operation amount and the hydraulic oil supply flow rate to the hydraulic actuator that operates in response to the lever operation is stored in advance. As shown in FIG. 3, this data is composed of first to fifth map groups M1, M2, M3, M4, and M5 classified according to the operation directions of the operation levers 51, 52, and 53. The map groups M1, M2, M3, M4, and M5 include a plurality of maps that define the relationship between the lever operation amount and the flow rate for each position of the work table 40. In FIG. 3, the first and second map groups M1 and M2 show map groups corresponding to the boom raising and lowering operations of the raising and lowering operation lever 51, and the third and fourth map groups M3 and M4 are respectively shown. The map groups corresponding to the boom extending operation and boom retracting operation of the telescopic operation lever 52 are shown. The fifth map group M5 shows a map group corresponding to the boom turning operation of the turning operation lever 53.
[0025]
The first flow rate setting circuit 71 first detects which operation lever is operated in which direction based on detection information from the first to third operation state detectors 81, 82, 83, and responds to this. A map group is selected from the first to fifth map groups M1, M2, M3, M4, and M5 stored in the first storage circuit 71a (see FIG. 11). After selecting the corresponding map group, the map corresponding to the position is selected based on the position information of the work table 40 relative to the vehicle body 10 calculated by the position calculation circuit 62. The selected map shows a relationship in which the hydraulic oil supply flow rate is approximately proportional to the lever operation amount within a range equal to or less than the upper limit value determined according to the position of the work table 40 with respect to the vehicle body 10 and is detected. The hydraulic oil supply flow rate corresponding to the lever operation amount is read, and the flow rate values are defined as Qa, Qb, and Qc.
[0026]
Here, the upper limit value of the flow rate is set so that the operating lever 40 is smaller as the position of the operating platform 40 is further away from the center of the vehicle body 10 in any of the operation levers 51, 52, and 53. This is because when the boom 30 is operated at the same speed, the work table 40 is more distant from the center of the vehicle body 10 (the work radius or work table height is larger) and the work table 40 acts. This is because the inertial force is increased, and the posture of the worker on the work table 40 tends to become unstable.
[0027]
Further, the map is different for each hydraulic actuator 24, 31 and 23, and even for the same hydraulic actuator for each operation direction. If the hydraulic actuator and its operation direction are different, the map of the hydraulic pump P is different. Maximum load pressure differs (for example, 90kgf / cm when boom is raised ² , 140kgf / cm with boom contraction ² This is because, in order to optimize the hydraulic oil discharge flow rate characteristic of the hydraulic pump P, it is preferable to set a pressure map for each maximum load pressure. However, regarding the boom turning, the maximum load pressure of the hydraulic pump P is considered to be the same regardless of the operation direction of the turning operation lever 53 (the operation direction of the turning motor 23).
[0028]
FIG. 4 is an example of a map constituting the first map M1 corresponding to the boom raising / lowering operation of the hoisting operation lever 51. The map m1 in the case where the upper limit value of the flow rate is maximized and the upper limit value of the flow rate are minimized. The map m2 is superimposed and shown. Here, although the upper limit value of the flow rate is shown only as the maximum and the minimum value, for other maps, the upper limit value is set to be larger as the position of the work table 40 is closer to the vehicle body 10. The upper limit value is set smaller as the position moves away from the vehicle body 10. Here, when the position of the work table 40 is at a position corresponding to the map m1 (when the distance of the work table 40 from the vehicle body 10 is minimum), the flow rate is smaller than the upper limit value with respect to the operation amount a. b, but when the position of the work table 40 is at a position corresponding to the map m2 (when the distance of the work table 40 from the vehicle body 10 is the maximum), the flow rate is the upper limit c with respect to the operation amount a. (C <b), it can be seen that the hydraulic oil supply flow rate is different if the position of the work table 40 is different even with the same operation amount.
[0029]
When a plurality of operation levers 51, 52, and 53 are operated simultaneously, the flow rate is set for each operated lever, and the flow rate Qa (actuation to the undulation cylinder 24 corresponding to the operation of the undulation operation lever 51 is performed. The oil supply flow rate) corresponds to the operation of the expansion / contraction operation lever 52, the flow rate Qb (the hydraulic oil supply flow rate to the expansion / contraction cylinder 31), and the flow rate Qc (the supply of the rotation motor 23 to the rotation motor 23). The hydraulic oil supply flow rate) is obtained. Then, the sum of the flow rates Qa, Qb, Qc is calculated, and this is the first flow rate Q. ₁ Set as
[0030]
Subsequently, the second flow rate setting circuit 72 uses the second flow rate Q. ₂ The procedure for setting is described with reference to FIGS. In the second memory circuit 72a (see FIG. 1) of the controller 60, for each operating direction of the operating levers 51, 52, and 53 (for each operating direction of the hoisting cylinder 24, the telescopic cylinder 31, and the turning motor 23), the falling moment is also reduced. For each value, data defining the relationship between the lever operation amount and the hydraulic oil supply flow rate to the hydraulic actuator that operates in response to the lever operation is stored in advance. As shown in FIG. 5, this data is composed of first to fifth map groups M11, M12, M13, M14, and M15 classified according to the operation directions of the operation levers 51, 52, and 53. The map groups M11, M12, M13, M14, and M15 are composed of a plurality of maps that define the relationship between the lever operation amount and the flow rate for each value of the overturning moment. In FIG. 5, the first and second map groups M11 and M12 show map groups corresponding to the boom raising and lowering operations of the raising and lowering operation lever 51, respectively. The third and fourth map groups M13 and M14 are respectively shown in FIG. The map groups corresponding to the boom extending operation and boom retracting operation of the telescopic operation lever 52 are shown. The fifth map group M15 indicates a map group corresponding to the boom turning operation of the turning operation lever 53.
[0031]
The second flow rate setting circuit 72 first detects which operation lever is operated in which direction based on detection information from the first to third operation state detectors 81, 82, 83, and responds to this. A map group is selected from the first to fifth map groups M11, M12, M13, M14, and M15 stored in the second memory circuit 72a. When the corresponding map group is selected, a map corresponding to the value of the falling moment is selected based on the information on the falling moment calculated by the falling moment calculating circuit 63. The selected map shows the relationship that the hydraulic oil supply flow rate is almost proportional to the lever operation amount within the range below the upper limit value determined according to the value of the tipping moment. The corresponding flow rate is read, and the flow rate values are defined as Qa, Qb, and Qc.
[0032]
Here, the upper limit value of the flow rate is set so that the value of the operation levers 51, 52, and 53 becomes smaller as the value of the falling moment increases. This is because when the boom 30 is operated at the same speed, the vehicle body 10 is likely to become unstable as the value of the falling moment increases. In addition, the map is different for each hydraulic actuator 24, 31 and 23, and even for the same hydraulic actuator for each operation direction, as described above, the hydraulic actuator and its operation direction are different. This is because the maximum load pressure of the hydraulic pump P is different, and in order to optimize the hydraulic oil discharge flow rate characteristic of the hydraulic pump P, it is preferable to set a pressure map for each maximum load pressure.
[0033]
FIG. 6 is an example of a map constituting the first map M11 corresponding to the boom raising / lowering operation of the hoisting operation lever 51. The map m11 when the upper limit value of the flow rate is maximum and the upper limit value of the flow rate are minimum. The map m12 is superimposed and shown. Here, only the maximum and minimum flow rates are shown, but for other maps, the lower the fall moment value, the higher the upper limit value is set, and the greater the fall moment value is, The upper limit is set small.
[0034]
When a plurality of operation levers 51, 52, and 53 are operated simultaneously, the flow rate is set for each operated lever, and the flow rate Qa (actuation to the undulation cylinder 24 corresponding to the operation of the undulation operation lever 51 is performed. The oil supply flow rate) corresponds to the operation of the expansion / contraction operation lever 52, the flow rate Qb (the hydraulic oil supply flow rate to the expansion / contraction cylinder 31), and the flow rate Qc (the supply of the rotation motor 23 to the rotation motor 23). The hydraulic oil supply flow rate) is obtained. Then, the sum of the flow rates Qa, Qb, and Qc is calculated, and this is the second flow rate Q. ₂ Set as
[0035]
The selection circuit 73 has a first flow rate Q that is the sum of the flow rates Qa, Qb, and Qc set in the first flow rate setting circuit 71. ₁ And a second flow rate Q that is the sum of the flow rates Qa, Qb, and Qc set in the second flow rate setting circuit 72 ₂ The smaller value is selected, and the selected value is used as the main flow rate Q. ₀ Set as. Further, the third flow rate setting circuit 74 determines the hydraulic fluid supply flow rate Qd to the swing motor 42 corresponding to the detected operation direction and operation amount of the detected swing operation lever 54 as the additional flow rate Q. _Three Set as.
[0036]
The total flow rate calculation circuit 75 has a main flow rate Q set in the selection circuit 73. ₀ And the additional flow rate Q set in the third flow rate setting circuit 74 _Three And the total flow rate Q _Four Set as (Q _Four = Q ₀ + Q _Three ). Also, the hydraulic oil supply flow rate Q required for the operation of other hydraulic actuators ₃₁ , Q ₃₂ , ... are required, this is also the additional flow rate Q _Three (Q _Four = Q ₀ + (Q _Three + Q ₃₁ + Q ₃₂ + ...)).
[0037]
Examples of the other hydraulic actuators include a device that slides the work table 40 up and down relative to the mounting portion (vertical post 32) of the boom 30, a drive device for an attachment tool provided in the work table 40, and the work table 40. There is a booster device that is used by being attached to a booster outlet provided in the system. Here, unlike the above-described swing operation lever 54, the hydraulic oil supplied to the hydraulic actuator (swing motor 42) to be operated is not a type of lever that is determined according to the operation amount, but is supplied to the actuator. For levers of the type that commands whether or not to supply oil (ie, hydraulic oil supply on / off), it is detected whether or not the lever is being operated and that the lever is being operated. When detected, a known hydraulic oil supply flow rate required for driving the actuator may be added. On / off detectors 89, 90,... For detecting such an on / off state of the lever are shown in FIG.
[0038]
The target flow rate setting circuit 76 has a total flow rate Q calculated by the total flow rate calculation circuit 75. _Four Is set as the target flow rate Qt (Qt = K × Q). _Four ). This coefficient K is the total flow rate Q calculated by the total flow rate calculation circuit 75. _Four For each time step and this is the total flow rate Q _Four The hydraulic fluid flow finally discharged from the hydraulic pump P can be reduced stepwise in accordance with the shockless control performed by the valve control circuit 61, thereby avoiding unnecessary hydraulic fluid supply. (If excessive hydraulic oil is supplied relative to the spool opening of the control valve V, it becomes excess oil and is returned to the oil tank).
[0039]
The motor drive control circuit 77 controls the rotation of the hydraulic pump P (the number of revolutions or rotation) so that the flow rate of the hydraulic oil discharged from the hydraulic pump P substantially matches the target flow rate Qt set in the target flow rate setting circuit 76. Speed control). Specifically, a correspondence table between the target flow rate Qt and the rotation speed of the hydraulic pump P (that is, the rotation speed of the electric motor M) is stored in the third storage circuit 77a (see FIG. 1). The rotation speed of the hydraulic pump P is read by applying the obtained target flow rate Qt to the correspondence table, and the rotation of the electric motor M is controlled so that the hydraulic pump P is driven at the rotation speed (target rotation speed).
[0040]
Here, if the motor M is a DC motor, rotation control is performed by changing the drive voltage or changing the magnetic flux of the field. If the motor M is an AC motor, the DC current obtained from the battery B is changed. Inverted by pulse width modulation (PWM), the motor M is controlled to rotate at a speed corresponding to the duty ratio of the pulse width. Further, when the motor M is an AC motor, the duty ratio of the pulse width can be determined only by the target rotational speed if the hydraulic pump P has a constant rotation characteristic regardless of the load pressure. If the rotation characteristics change depending on the pressure, it is necessary to determine the duty ratio in consideration of not only the target rotation speed but also this load pressure (maximum load pressure).
[0041]
In the aerial work vehicle 1 having such a configuration, an operator on the work table 40 operates the operation levers 51, 52, 53 and the work table swing operation lever 54 from the work table 40. Thus, the boom 30 can be raised, retracted, swiveled, and the work table 40 can be swung, and can be moved to a desired position by operating its own lever. At this time, since the controller 60 performs the moment limiter control as described above, even when the overturning moment acting on the vehicle body 10 becomes large, a situation where the vehicle body 10 falls over is prevented.
[0042]
Further, in the hydraulic oil supply device provided in the aerial work platform 1, the hydraulic fluid flow discharged from the hydraulic pump P is supplied to the hydraulic actuators 24, 31, and 23 that cause the boom 30 to move up, down, extend, and turn. The rotation control of the hydraulic pump P is performed so that the sum of the hydraulic oil supply flow rates substantially coincides with the target flow rate determined as the main flow rate. At this time, hydraulic oil supply to the hydraulic actuators 24, 31 and 23 is performed. The flow rate is set depending not only on the operation amount of the operation levers 51, 52, 53 but also on the position of the work table 40 relative to the vehicle body 10 and the load acting on the boom 30 (in the above example, the falling moment). ing.
[0043]
Therefore, the operation of the boom 30 compared to the operation amount of the operation levers 51, 52, 53, such as when the position of the work table 40 is far away from the vehicle body 10 or when the load acting on the boom 30 is large. When the control for reducing the speed is performed, the discharge flow rate of the hydraulic pump P can be reduced accordingly, so that the hydraulic oil flow rate actually required for the operation of the boom 30 and the hydraulic pump P are discharged. It is possible to reduce the difference from the hydraulic oil flow rate so that the hydraulic oil flow rate discharged from the hydraulic pump P becomes a necessary minimum flow rate with a small surplus flow rate. As a result, it is possible to reduce the driving power loss of the hydraulic pump P to reduce the work cost, and to extend the service life of the hydraulic pump P itself and the electric motor M that drives the hydraulic pump P itself. Furthermore, since the generation of heat and noise associated with the driving of the hydraulic pump P is reduced, the influence on the surroundings during work can be reduced.
[0044]
Next, the configuration of another hydraulic oil supply device for a boom working vehicle according to the present invention will be described with reference to FIGS. 7 and 8. In addition, the boom working vehicle to which the hydraulic oil supply device in the present embodiment is applied is the above-described aerial work vehicle 1, and description of the configuration thereof is omitted here.
[0045]
FIG. 7 shows a signal transmission system in which the boom 30 is raised, retracted, turned, and turned by the operation of the operation levers 51, 52, 53, and 54 in the hydraulic oil supply apparatus according to the present embodiment. It is a block diagram. Also in the device according to the present embodiment, the operation direction and the operation amount of each operation lever 51, 52, 53, 54 are provided at the base end portion of each lever, as in the case of the device according to the above-described embodiment. The valve control circuit 61 of the controller 60 provided on the vehicle body 10 as an operation signal of the boom 30 or the work table 40 is detected by the first to fourth operation state detectors 81, 82, 83, 84 described above. Is input. Further, based on information detected by the undulation angle detector 85, the length detector 86, and the turning angle detector 87, the position calculation circuit 62 calculates the position of the tip portion (work table 40) of the boom 30 with respect to the vehicle body 10. In the same manner as in the above-described embodiment, the overturning moment calculation circuit 63 calculates the overturning moment that is a load acting on the boom 30 based on the information detected by the load detector 88.
[0046]
In the present embodiment, the hydraulic pump discharge flow rate control circuit 70 that performs drive control of the motor M includes a main flow rate setting circuit 271, an additional flow rate setting circuit 272, a total flow rate calculation circuit 273, a target flow rate setting circuit 276, and an electric motor drive control circuit. 277.
[0047]
The main flow rate setting circuit 271 includes information on the position of the work table 40 relative to the vehicle body 10 calculated in the position calculation circuit 62, information on the overturning moment calculated in the overturning moment calculation circuit 63, and first to third operation state detections. The hydraulic oil supply flow rates Qa, Qb, Qc to the hydraulic actuators 24, 31, 23 are determined based on the operation direction and operation amount information of the operation levers 51, 52, 53 detected by the devices 81, 82, 83. The main flow rate Q ₂₀ Set as.
[0048]
In the main flow rate setting circuit 271, the main flow rate Q ₂₀ The procedure for setting is described with reference to FIG. In the first storage circuit 271a (see FIG. 7) of the controller 60, each operation direction of the operation levers 51, 52, and 53 (that is, every operation direction of the hoisting cylinder 24, the telescopic cylinder 31, and the turning motor 23) Data defining the relationship between the lever operation amount and the hydraulic oil supply flow rate to the hydraulic actuator that operates in response to the lever operation is stored in advance for each position of the base 40 relative to the vehicle body 10 and the value of the overturning moment. . As shown in FIG. 8, this data is composed of first to fifth map groups M21, M22, M23, M24, and M25 classified according to the operation directions of the operation levers 51, 52, and 53. The map groups M21, M22, M23, M24, and M25 include a plurality of maps that define the relationship between the lever operation amount and the flow rate for each position of the work table 40 and the value of the overturning moment. In FIG. 8, the first and second map groups M21 and M22 show map groups corresponding to the boom raising and lowering operations of the raising and lowering operation lever 51, and the third and fourth map groups M23 and M24 are respectively shown. The map groups corresponding to the boom extending operation and boom retracting operation of the telescopic operation lever 52 are shown. The fifth map group M25 indicates a map group corresponding to the boom turning operation of the turning operation lever 53.
[0049]
The main flow rate setting circuit 271 first detects which operation lever is operated in which direction based on detection information from the first to third operation state detectors 81, 82, 83, and a map corresponding thereto. A group is selected from the first to fifth map groups M21, M22, M23, M24, and M25 stored in the first storage circuit 271a. After the corresponding map group is selected, a small map group for each load class corresponding to the overturning moment (load) calculated by the overturning moment calculating circuit 63 is selected. In the example shown in FIG. 8, the small map group includes the load classes 1 to N for the first map group M21. ₁ However, for the second map group M22, load classes 1 to N ₂ However, for the third map group M23, load classes 1 to N _Three However, for the fourth map group M24, load classes 1 to N _Four However, for the fifth map group M25, load classes 1 to N _Five Is prepared.
[0050]
After selecting a small map group for each load class corresponding to the overturning moment (load), this time based on the position information of the work table 40 relative to the vehicle body 10 calculated by the position calculation circuit 62 from the small map group, A map corresponding to the position is selected. The selected map shows a relationship in which the hydraulic oil supply flow rate is substantially proportional to the lever operation amount within a range equal to or less than the upper limit value determined according to the position of the work table 40 with respect to the vehicle body 10 (the map is As in the map shown in FIG. 4, the hydraulic oil supply flow rate corresponding to the detected lever operation amount is read, and the flow rate values are defined as Qa, Qb, and Qc.
[0051]
Here, when a plurality of operation levers 51, 52, and 53 are operated simultaneously, the setting of the flow rate is performed for each operated lever, and the flow rate Qa (to the undulation cylinder 24) corresponding to the operation of the undulation operation lever 51 is performed. The hydraulic fluid supply flow rate) corresponds to the operation of the telescopic operation lever 52, the flow rate Qb (the hydraulic fluid supply flow rate to the telescopic cylinder 31), and the flow rate Qc (to the swing motor 23) corresponding to the operation of the swing operation lever 53. The hydraulic oil supply flow rate) is obtained respectively. Then, the sum of these flow rates Qa, Qb, and Qc is calculated, and this is the main flow rate Q. ₂₀ Set as
[0052]
Further, the additional flow rate setting circuit 272 converts the hydraulic oil supply flow rate Qd to the swing motor 42 corresponding to the detected operation direction and operation amount of the swing operation lever 54 to the additional flow rate Q. _{twenty one} Set as.
[0053]
The total flow rate calculation circuit 273 is a main flow rate Q set in the main flow rate setting circuit 271. ₂₀ And the additional flow rate Q set in the additional flow rate setting circuit 272 _{twenty one} And the total flow rate Q _{twenty two} Set as (Q _{twenty two} = Q ₂₀ + Q _{twenty one} ). Also, the hydraulic oil supply flow rate Q required for the operation of other hydraulic actuators (described above) _{twenty three} , Q _{twenty four} , ... are required, this is also the additional flow rate Q _{twenty one} (Q _{twenty two} = Q ₂₀ + (Q _{twenty one} + Q _{twenty three} + Q _{twenty four} + ...)).
[0054]
The target flow rate setting circuit 276 has a total flow rate Q calculated by the total flow rate calculation circuit 273. _{twenty two} Is set as the target flow rate Qt (Qt = K × Q). _{twenty two} ). This coefficient K is the total flow rate Q calculated by the total flow rate calculation circuit 273. _{twenty two} For each time step and this is the total flow rate Q _{twenty two} The hydraulic fluid flow finally discharged from the hydraulic pump P can be reduced stepwise in accordance with the shockless control performed by the valve control circuit 61, thereby avoiding unnecessary hydraulic fluid supply. (As described above).
[0055]
The motor drive control circuit 277 controls the rotation (rotation speed or rotation) of the hydraulic pump P so that the flow rate of the hydraulic oil discharged from the hydraulic pump P substantially matches the target flow rate Qt set in the target flow rate setting circuit 276. Speed control). Specifically, a correspondence table between the target flow rate Qt and the rotational speed of the hydraulic pump P (that is, the rotational speed of the electric motor M) is stored in the second storage circuit 277a (see FIG. 7), and the target flow rate setting circuit 276 The rotation speed of the hydraulic pump P is read by applying the obtained target flow rate Qt to the correspondence table, and the rotation of the electric motor M is controlled so that the hydraulic pump P is driven at the rotation speed (target rotation speed). The contents of the rotation control are the same as in the above-described embodiment.
[0056]
In such another working oil supply device for a boom working vehicle according to the present invention, the position of the work table 40 is greatly separated from the vehicle body 10 as in the above-described working fluid supply device for a boom working vehicle according to the present invention. When control is performed to reduce the operating speed of the boom 30 relative to the amount of operation of the operation levers 51, 52, and 53, such as when the load acting on the boom 30 is large, the hydraulic pressure is adjusted accordingly. Since the discharge flow rate of the pump P can also be reduced, the difference between the hydraulic oil flow rate actually required for the operation of the boom 30 and the hydraulic oil flow rate discharged from the hydraulic pump P is made smaller than the hydraulic pump P. The discharged hydraulic fluid flow rate can be set to a necessary minimum flow rate with a small surplus flow rate. Accordingly, it is possible to reduce the driving power loss of the hydraulic pump P and thereby reduce the work cost, and to extend the service life of the hydraulic pump P itself and the electric motor M that drives the hydraulic pump P. Furthermore, since the generation of heat and noise associated with the driving of the hydraulic pump P is reduced, the influence on the surroundings during work can be reduced.
[0057]
Subsequently, other embodiments based on either of these two embodiments are shown. Here, an example based on the first embodiment is shown, but a configuration based on the later embodiment can be similarly implemented.
[0058]
FIG. 9 shows a configuration of a hydraulic oil supply device for a boom working vehicle according to another embodiment based on the first embodiment. As shown in this figure, in the hydraulic oil supply device according to this embodiment, the second target flow rate setting circuit 78 is added to the hydraulic oil supply device according to the first embodiment described above. The same components as those in the embodiment are denoted by the same reference numerals, and the description thereof is omitted.
[0059]
The second target flow rate setting circuit 78 corresponds to the drive signal of the control valve V output from the valve control circuit 61 of the controller 60 (this drive signal has already been filtered by the shock module as described above). The flow rate obtained based on the hydraulic oil supply flow rate to the hydraulic actuator (the hoisting cylinder 24, the telescopic cylinder 31, and the turning motor 23) is set as the second target flow rate Qt ′.
[0060]
The fourth storage circuit 78a (see FIG. 9) of the controller 60 stores the operation of the hoisting operation lever 51, the telescopic operation lever 52, and the turning operation lever 53 (that is, the operation of the hoisting cylinder 24, the telescopic cylinder 31, and the turning motor 23). For each direction, data defining the relationship between the drive signal (drive voltage) of the control valve V output by the lever operation and the hydraulic oil supply flow rate to the hydraulic actuator that operates in response to the lever operation is stored in advance. Has been. As shown in FIG. 10, this data is composed of first to fifth maps M31, M32, M33, M34, and M35 classified according to the operation directions of the operation levers 51, 52, and 53. In FIG. 10, the first and second maps M31 and M32 show maps corresponding to the boom raising and lowering operations of the raising and lowering operation lever 51, respectively, and the third and fourth maps M33 and M34 are respectively extended and retracted. The map corresponding to the boom extension operation and boom contraction operation of the lever 52 is shown. A fifth map M35 shows a map corresponding to the boom turning operation of the turning operation lever 53.
[0061]
Based on the drive signals of the hydraulic actuators 24, 31 and 23 output from the valve control circuit 61, the second target flow rate setting circuit 78 stores corresponding maps in the first to fifth maps stored in the fourth storage circuit 78a. Select from M31, M32, M33, M34, and M35. The selected map shows a relationship in which the hydraulic oil supply flow rate is substantially proportional to the drive signal (drive voltage) of the control valve V, and the hydraulic oil supply flow rate corresponding to the drive signal (drive voltage) is read, The flow rates are Qa, Qb, and Qc. Here, the graph selected in the map is defined so that the flow rate increases in proportion to the drive signal (drive voltage) of the control valve V. Note that the above-described map differs for each hydraulic actuator 24, 31 and 23, and even for the same hydraulic actuator, depending on the operation direction, as described above, if the hydraulic actuator and its operation direction are different, the hydraulic pump P This is because the maximum load pressure is different, and in order to optimize the hydraulic oil discharge flow rate characteristic of the hydraulic pump P, it is preferable to set a pressure map for each maximum load pressure. FIG. 11 shows a map m31 corresponding to the boom raising operation of the hoisting operation lever 51 as an example of such a map.
[0062]
Here, when a plurality of operation levers 51, 52, and 53 are operated simultaneously, the setting of the flow rate is performed for each operated lever, and the flow rate Qa (to the undulation cylinder 24) corresponding to the operation of the undulation operation lever 51 is performed. The hydraulic fluid supply flow rate) corresponds to the operation of the telescopic operation lever 52, the flow rate Qb (the hydraulic fluid supply flow rate to the telescopic cylinder 31), and the flow rate Qc (to the swing motor 23) corresponding to the operation of the swing operation lever 53. The hydraulic oil supply flow rate) is obtained respectively. Then, the sum of these flow rates Qa, Qb, and Qc is calculated, and this is added to the additional flow rate (the flow rate Q set in the third flow rate setting circuit 74). _Three ) Is set as the second target flow rate Qt ′.
[0063]
The motor drive control circuit 77 in this embodiment uses a smaller value between the target flow rate Qt set in the target flow rate setting circuit 76 and the second target flow rate Qt ′ set in the second target flow rate setting circuit 78. Select and set this as the true target flow rate. Then, the rotation control of the hydraulic pump P is performed so that the flow rate of the hydraulic oil discharged from the hydraulic pressure pump P substantially coincides with the true target flow rate. The specific method of this control is the same as that shown in the above-described embodiment.
[0064]
As described above, in the hydraulic oil supply device shown in the present embodiment, the target flow rate of the hydraulic oil discharged from the hydraulic pump P is set based on the operation amount of the operation levers 51, 52, 53. (Target flow rate set in the target flow rate setting circuit 77) and target flow rate set based on the drive signal that actually drives the control valve V (second target flow rate set in the second target flow rate setting circuit 78) ) Since the rotation control of the hydraulic pump P is performed so as to coincide with the smaller one of Qt ′, the hydraulic oil flow rate actually required for the operation of the boom 30 and the hydraulic pump P are discharged. The difference from the hydraulic oil flow rate can be further reduced, and the surplus flow rate can be further reduced.
[0065]
Although preferred embodiments of the present invention have been described so far, the scope of the present invention is not limited to the above. For example, in the above embodiment, the power source for driving the hydraulic pump P is the electric motor M, but this is a prime mover (for example, a small engine for driving the hydraulic pump P provided separately from the engine for driving the vehicle). There may be.
[0066]
In the above embodiment, the overturning moment is handled as a load acting on the boom 30, but this may be a load on the work table 40. In this case, in addition to the method of detecting the axial force of the hoisting cylinder 24 as shown in the above embodiment, a method of directly detecting the load of the work table 40 acting on the tip of the boom 30 is also employed. be able to.
[0067]
Further, the operation means for performing operation input of the hydraulic actuators (the hoisting cylinder 24, the telescopic cylinder 31 and the swing motor 23) for raising, lowering, extending and rotating the boom 30 is a lever (the operation lever 51, 52, 53), it may be a knob or a switch.
[0068]
Furthermore, in the above-described embodiment, the operation means is composed of three independent operation levers, that is, the raising / lowering operation lever 51, the telescopic operation lever 52, and the turning operation lever 53. However, two or three of these three levers are used. It is also possible to use a joystick lever that has all the functions in one lever. According to such a joystick lever, for example, the forward / backward direction operation is assigned to the boom 30 raising / lowering operation, the left / right direction operation is assigned to the boom 30 extending / contracting operation, and the boom 30 raising / lowering operation and the extending / contracting operation are simultaneously performed by the oblique operation. In this case, the operation in the oblique direction is not considered as an operation in one oblique direction, but the operation in the front-rear direction and the operation in the left-right direction are performed simultaneously. That is, it is necessary to apply the present invention as if the raising / lowering operation lever 51 and the telescopic operation lever 52 were operated simultaneously in the above-described embodiment.
[0069]
Moreover, in the said embodiment, although the aerial work vehicle which has a work bench | platform at the front-end | tip part of a boom was shown as an object to which this invention is applied, this invention is not restricted to such an aerial work vehicle, The present invention can also be applied to a crane vehicle having a lifting device at the tip.
[0070]
【The invention's effect】
As described above, according to the hydraulic oil supply device for a boom working vehicle according to the present invention, the operating means is used when the position of the working device is far away from the vehicle body or when the load acting on the boom is large. When the control is performed to keep the boom operating speed smaller than the operation amount, the discharge flow rate of the hydraulic pump can be reduced accordingly, so that the hydraulic oil flow rate actually required for boom operation can be reduced. The difference between the hydraulic oil flow rate discharged from the hydraulic pump can be reduced, and the hydraulic oil flow rate discharged from the hydraulic pump can be set to the minimum required flow rate with a small excess flow rate. As a result, it is possible to reduce the driving power loss of the hydraulic pump and reduce the work cost, and at the same time, it is possible to extend the service life of the hydraulic pump itself and the electric motor that drives the hydraulic pump. Furthermore, since the generation of heat and noise associated with the driving of the hydraulic pump is reduced, the influence on the surroundings during work can be reduced.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a signal transmission system of an aerial work vehicle equipped with a hydraulic oil supply control device according to the present invention.
FIG. 2 is a side view of the aerial work vehicle.
FIG. 3 is a block diagram showing a part of a controller constituting the hydraulic oil supply device.
FIG. 4 is a diagram illustrating an example of a map stored in a first storage circuit.
FIG. 5 is a block diagram showing a part of a controller constituting the hydraulic oil supply device.
FIG. 6 is a diagram illustrating an example of a map stored in a second storage circuit.
FIG. 7 is a block diagram showing a signal transmission system of an aerial work vehicle equipped with another hydraulic oil supply device according to the present invention.
FIG. 8 is a block diagram showing a part of a controller constituting the hydraulic oil supply apparatus according to another embodiment of the present invention.
FIG. 9 is a block diagram showing a signal transmission system of an aerial work vehicle including a hydraulic oil supply control device according to another embodiment based on the first embodiment.
FIG. 10 is a block diagram showing a part of a controller constituting a hydraulic oil supply device according to another embodiment based on the first embodiment.
FIG. 11 is a diagram illustrating an example of a map stored in a fourth storage circuit.
[Explanation of symbols]
1 High-altitude work vehicle (boom work vehicle)
10 body
20 swivel
23 Swing motor (hydraulic actuator)
24 Rolling cylinder (hydraulic actuator)
30 boom
31 Telescopic cylinder (hydraulic actuator)
40 Working table (working equipment)
51 Undulating operation lever (operating means)
52 Telescopic operation lever (operating means)
53 Turning control lever (operation means)
60 controller
61 Valve control circuit (valve control means)
62 Position calculation circuit (position detection means)
63 Falling moment calculation circuit (load detection means)
70 Hydraulic pump discharge flow rate control circuit
71 First flow rate setting circuit (first flow rate setting means)
72 Second flow rate setting circuit (second flow rate setting means)
73 Selection circuit (main flow rate setting means)
74 Third flow rate setting circuit (target flow rate setting means)
75 Total flow setting circuit (Target flow setting means)
76 Target flow rate setting circuit (Target flow rate setting means)
77 Electric motor drive control circuit (hydraulic pump control means)
81-83 1st-3rd operation state detector (operation amount detection means)
85 Relief angle detector (position detection means)
86 Length detector (position detection means)
87 Turning angle detector (position detection means)
88 Load detector (load detection means)
M motor (hydraulic pump control means)
P Hydraulic pump

Claims (3)

A working device is provided at the tip of the boom that can be raised, retracted, and swivel provided on the vehicle body, and the boom is raised and lowered at a speed corresponding to the operation amount of each operating means corresponding to the boom hoisting, telescoping, and turning operation. A boom working vehicle hydraulic oil supply device configured to expand and contract and turn.
Each hydraulic actuator for moving the boom up and down, expanding and contracting, and turning,
A hydraulic pump for supplying hydraulic oil to each of the hydraulic actuators;
An operation amount detection means for detecting an operation amount of each of the operation means;
Position detecting means for detecting the position of the working device relative to the vehicle body;
Load detecting means for detecting a load acting on the boom;
Based on the position of the working device with respect to the vehicle body detected by the position detection means and the operation amount of each operation means detected by the operation amount detection means, the hydraulic oil supply flow rate to each hydraulic actuator is obtained, First flow rate setting means for setting the sum as a first flow rate;
Based on the load acting on the boom detected by the load detection means and the operation amount of each operation means detected by the operation amount detection means, the hydraulic oil supply flow rate to each hydraulic actuator is obtained and the sum is obtained. Second flow rate setting means for setting the second flow rate;
Main flow rate setting means for setting the smaller value of the first flow rate set in the first flow rate setting means and the second flow rate set in the second flow rate setting means as a main flow rate;
Target flow rate setting means for setting a target flow rate based on the main flow rate set in the main flow rate setting means;
Hydraulic pump control means for controlling the rotation of the hydraulic pump so that the flow rate of the hydraulic oil discharged from the hydraulic pump substantially matches the target flow rate set by the target flow rate setting means. Hydraulic oil supply device for boom working vehicles. A working device is provided at the tip of the boom that can be raised, retracted, and swivel provided on the vehicle body, and the boom is raised and lowered at a speed corresponding to the operation amount of each operating means corresponding to the boom hoisting, telescoping, and turning operation. A boom working vehicle hydraulic oil supply device configured to expand and contract and turn.
Each hydraulic actuator for moving the boom up and down, expanding and contracting, and turning,
A hydraulic pump for supplying hydraulic oil to each of the hydraulic actuators;
An operation amount detection means for detecting an operation amount of each of the operation means;
Position detecting means for detecting the position of the working device relative to the vehicle body;
Load detecting means for detecting a load acting on the boom;
Based on the position of the working device with respect to the vehicle body detected by the position detection means, the load acting on the boom detected by the load detection means, and the operation amount of each operation means detected by the operation amount detection means. A main flow rate setting means for obtaining a hydraulic oil supply flow rate to each of the hydraulic actuators and setting the sum as a main flow rate;
Target flow rate setting means for setting a target flow rate based on the main flow rate set in the main flow rate setting means;
The flow rate of the hydraulic oil discharged from the hydraulic pump, e Bei a hydraulic pump control means for controlling the rotation of the hydraulic pump so as to substantially coincide with the target flow rate set in the target flow rate setting means,
The load acting on the boom is divided into a plurality of load classes, and for each of these load classes, the operation amount of the operation means at each position of the work table and the hydraulic oil supply flow rate to the hydraulic actuator corresponding to the operation A small map group consisting of multiple maps that prescribe the relationship between
The main flow rate setting means selects the small map group corresponding to the load class from the load detected by the load detection means, and corresponds to the position detected by the position detection means from the selected small map group. to select a map, thus the selected map boom work vehicle of the hydraulic oil supply device and obtaining the working oil supply flow rate corresponding to the operation amount detected by the prior SL operation amount detecting means with. The boom control of the boom is controlled by driving a control valve for supplying and shutting off the hydraulic oil discharged from the hydraulic pump to the hydraulic actuators. ,
Second target flow rate setting means for setting a second target flow rate based on a sum of hydraulic oil supply flow rates to the respective hydraulic actuators obtained according to the drive signal of the control valve output from the valve control means. Prepared,
The hydraulic pump drive control means is configured such that the flow rate of the hydraulic oil discharged from the hydraulic pump is the target flow rate set by the target flow rate setting means and the second target flow rate setting means set by the second target flow rate setting means. The hydraulic oil supply device for a boom working vehicle according to claim 1 or 2, wherein rotation control of the hydraulic pump is performed so as to substantially match a smaller one of the target flow rates.

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