Source: https://patents.google.com/patent/KR970000491B1/en
Timestamp: 2020-08-10 00:34:40
Document Index: 139535976

Matched Legal Cases: ['art 64', 'art 64', 'art 63', 'art 64', 'art 60', 'art 80', 'art 67', 'art 83', 'art 60', 'art 162', 'art 162']

KR970000491B1 - Hydraulic control system in hydraulic construction machine - Google Patents
KR970000491B1
KR970000491B1 KR92702343A KR920702343A KR970000491B1 KR 970000491 B1 KR970000491 B1 KR 970000491B1 KR 92702343 A KR92702343 A KR 92702343A KR 920702343 A KR920702343 A KR 920702343A KR 970000491 B1 KR970000491 B1 KR 970000491B1
KR92702343A
KR930700738A (en
아키라 다츠미
세이지 다무라
미츠오 기하라
가즈히로 이치무라
히로시 오노우에
시게타카 나카무라
오카다 하지메
히다치 겐키 가부시키가이샤
1991-01-28 Priority to JP91-26912 priority Critical
1991-01-28 Priority to JP2691291 priority
1991-07-24 Priority to JP91-184802 priority
1992-01-28 Application filed by 오카다 하지메, 히다치 겐키 가부시키가이샤 filed Critical 오카다 하지메
1993-03-16 Publication of KR930700738A publication Critical patent/KR930700738A/en
1997-01-13 Publication of KR970000491B1 publication Critical patent/KR970000491B1/en
238000010276 construction Methods 0.000 title claims description 36
Hydraulic Control System of Hydraulic Construction Machinery
BACKGROUND OF THE INVENTION As a hydraulic construction machine on which a hydraulic control device of this kind is conventionally mounted, there is, for example, a wheeled hydraulic excavator as shown in FIG.
In the figure, "4" is a traveling hydraulic motor, and the rear wheel 103 is driven through the transmission 101 and the propeller shaft 102 by the rotation of the hydraulic motor 4 so that the vehicle travels.
The expansion and contraction of the boom cylinder 21 raises and lowers the boom 104 which is part of the front attachment.
In the present specification, excavation or the like by front attachment without traveling is simply called work, and is distinguished from running.
Therefore, it is proposed to selectively perform the load sensing control and the input torque limit control in the above-mentioned hydraulic construction machine (for example, Japanese Patent Laid-Open No. 2-118203).
Hereinafter, these systems will be described with reference to FIG.
FIG. 11 is a diagram showing, for example, the hydraulic circuit for traveling and working of the hydraulic excavator, and "1" is a variable displacement hydraulic pump driven by the diesel engine 27. As shown in FIG.
The rotation speed of the engine 27 is caused by the governor lever 27b of the governor 27a being rotated by the pulse motor 28 in response to the operation amount of the fuel lever (not shown) or the stepping amount of the traveling pedal 6a. Is controlled by
The variable displacement hydraulic pump 1 discharges oil having a flow rate corresponding to the engine speed and the pushing volume, and the discharge oil is delivered to the hydraulic motor 4 through the driving control valve 2 and at the same time a working control valve ( It is guided to the boom driving hydraulic cylinder 21 through 20).
In the load sensing control, a pressure difference between the inlet pressure (pump pressure) and the outlet pressure (rod sensing pressure) of the control valve 2 or the work control valve 20, that is, the front and rear pressures of the control valve 2 and the work control valve 20 is constant. The pushing volume of the variable displacement hydraulic pump 1 (hereinafter also referred to as tilt angle) is controlled so as to be a value, and the pump pressure is kept higher than the load sensing pressure by a predetermined target value.
The load sensing pressure is the pressure on the high pressure side selected by the shuttle valve 29 among the load pressures of the hydraulic motor 4 and the hydraulic cylinder 21.
In the system shown in FIG. 11 which performs the load sensing control, the load sensing regulator 11 which switches in response to the differential pressure of a pump pressure and a load sensing pressure is provided, and the differential pressure between a pump pressure and a load sensing pressure is a spring 11a. When the pressure is equal to or greater than the pressure set in the above, the load sensing regulator 11 is switched in the direction of the b position in response to the pressure.
At this position b, the pump pressure is delivered to the servo cylinder 12, and the volume pushed out of the hydraulic pump 1 becomes smaller due to the expansion of the servo cylinder 12, thereby reducing the pump discharge flow rate.
On the contrary, when the pressure difference is less than the pressure set by the spring 11a, the load sensing regulator 11 is switched in the direction of the a position, and the servo cylinder 12 is connected to the tank.
As a result, the pushing volume is increased and the pump discharge flow rate is increased.
By the above operation, in the system which performs the load sensing control, the pump tilt angle is controlled so that the pump discharge flow rate is the required flow rate of the control valve 2 or 20, and waste due to loop loss can be avoided without discharging excess flow rate. Since it disappears, fuel economy improves and operability is also good.
Next, the operation of the traveling circuit will be described.
By operating the pedal 6a of the switching pilot valve 6 to the forward (E position) forward and backward switching valve 8, the discharge oil from the hydraulic pump 5 is pilot port of the pilot control valve (2). Guided by (2a), the control valve 2 switches to the stroke amount in response to the pilot hydraulic pressure.
Thus, the discharge oil from the variable displacement hydraulic pump 1 passes through the conduit 91, the pressure compensation valve 23, the control valve 2, the conduit 92 and the counterbalance valve 3. Supplied to the vehicle to drive.
It also depends on the amount of stepping on the running pedal 6a.
When the pedal 6a is released while traveling, the outlet port of the pilot valve 6 is blocked from the inlet port and communicates with the tank port connected to the tank 10.
As a result, the hydraulic pressure acting on the pilot port 2a returns to the tank 10 via the forward / backward switching valve 8, the throuuriton valve 7, and the pilot valve 6.
At this time, since the throttle is carried out by the throttle portion 7a of the throttle valve 7, the pilot control valve 2 gradually switches to the neutral position, and the vehicle gradually decelerates.
When the operation switching valve 20 is switched to the "b" position or the "c" position by the operation lever 20a, the discharge oil from the hydraulic pump 1 is the conduit 91, the pressure compensation valve 24, the conduit ( 94) and the boom driving hydraulic cylinder 21 through the control valve 20, and the boom 104 shown in FIG. 10 is lifted by the expansion and contraction of the hydraulic cylinder 21.
Here, the pressure compensation valves 23 and 24 supply pressure to the hydraulic motor 4 and the hydraulic cylinder 21 from the hydraulic pump 1 by a predetermined pressure higher than the respective load pressure. It makes the actuator work independently.
The hydraulic control apparatus of FIG. 11 further includes a torque control servovalve 25 for input torque limiting control, in which the discharge pressure of the hydraulic pump 1 is guided as a pilot pressure.
When the pilot pressure acting on the servovalve 25 becomes higher than the pressure set by the limiting torque setting spring 25a, the servovalve 25 switches from the c position shown to the d position.
As a result, the discharge pressure of the hydraulic pump 1 acts on the servo cylinder 12, and the discharge pressure of the hydraulic pump 1 acts on the servo cylinder 12 by the servo cylinder 12, and acts on the servo cylinder 12. As a result, the pushing volume of the hydraulic pump 1 is reduced, the torque of the hydraulic pump 1 is kept within the range of the output torque of the engine 27, and overloading of the engine 27 is prevented.
This is the input torque limit control.
According to the above configuration, the hydraulic pressure is set to be the smaller of the target pushing volume (the first target pushing volume) by the load sensing control and the target pushing volume (the second target pushing volume) by the input torque limiting control. The pushing volume of the pump is controlled, thereby improving fuel economy and operability and preventing overload of the engine 27.
In addition, "26" is an unload valve driven by the differential pressure of the said pump pressure and a load sensing pressure, "31a, 31b" is a crossover load relief valve, and CJ is a center joint.
In the hydraulic control device having the load sensing control and the input torque suggestion control of the hydraulic control device shown in FIG. 11, the pushing volume of the variable displacement hydraulic pump 1 is the servovalve 25 on the pressure torque limit control system side. The maximum value is limited to the value determined by), and within the range not exceeding this maximum value, the configuration is limited to the pushing volume determined by the load sensing regulator 11 on the side of the load sensing control system. Regardless of the contents of the operation or the operator's preference, one of the input torque limit control value or the load sensing control value is uniformly controlled due to the amount of brightness of the running pedal and the amount of operation lever or circuit pressure of the operating lever.
Therefore, there are two problems.
By operating the pedal 6a of the switching pilot valve 6 to the forward (E position) forward and backward switching valve 8, the discharge oil from the hydraulic pump 5 is pilot port of the pilot control valve (2). Guided to (2a), this control valve (2) switches to the stroke amount in response to the pilot hydraulic pressure.
As a result, the hydraulic pressure acting on the pilot port 2a returns to the tank 10 via the forward / backward switching valve 8, the throwuristic valve 7, and the pilot valve 6.
When the operation switching valve 20 is switched to the "b" position or the "c" position by the operating lever 20a, the discharge oil from the hydraulic pump 1 is the conduit 91, the pressure compensation valve 24, the conduit ( 94) and the boom driving hydraulic cylinder 21 through the control valve 20, and the boom 104 shown in FIG. 10 is lifted by the expansion and contraction of the hydraulic cylinder 21.
The hydraulic control apparatus of FIG. 11 further includes a torque control servovalve 25 for performing pressure torque limiting control, in which the discharge pressure of the hydraulic pump 1 is guided as a pilot pressure.
When the pilot pressure acting on the servovalve 25 becomes higher than the pressure set by the limiting torque setting spring 25a, the servovalve 25 switches from the illustrated c position to the d position.
In the hydraulic control device including the load sensing control and the input torque limiting control of the hydraulic control device shown in FIG. 11, the pushing volume of the variable displacement hydraulic pump 1 is the servovalve 25 on the pressure torque limiting control system side. The maximum value is limited to the value determined by), and within the range not exceeding this maximum value, the configuration is limited to the pushing volume determined by the load sensing regulator 11 on the side of the load sensing control system. Regardless of the contents of the operation or the operator's preference, one of the input torque limit control value or the load sensing control value is uniformly controlled due to the amount of brightness of the running pedal and the amount of operation lever or circuit pressure of the operating lever.
(1) In the neutral state where the operation lever 20a and the traveling pedal 6a are not operated, the load sensing regulator 11 is switched to the b position, and the servo valve 25 is switched to the c position so that the variable displacement hydraulic pump ( The pushing volume of 1) is controlled to the minimum value and the pump discharge flow rate is small.
Therefore, when the operating lever is operated in the neutral position, the pump pushing volume is significant in response to the operating lever operation amount, but there is a problem that the pushing welding corresponding to the operating lever position takes time to the earthenware and the responsiveness of the actuator is poor. .
In the present specification, the pump discharge flow rate when the control valves 2 and 20 are in the neutral position is called a standby flow rate.
(2) The present applicant proposes to Japanese Patent Application Laid-Open No. 3-234364 which allows the engine speed to be controlled in response to the operation of the traveling pedal 6a at the time of work.
When this proposal is adopted as the hydraulic control device shown in FIG. 11 in which the extrusion volume determined by the load sensing control and the extrusion volume determined by the input torque limiting control are alternatively selected and the extrusion volume is controlled, The following problems occur.
In the load sensing control which is kept constant at the front and rear pressure difference of the control valve 2 or 20, when the opening area of the control valve 2, that is, the operating lever and the stroke is constant, the engine speed is increased and the pump discharge flow rate is increased. Even if this increases, the pushing volume of the hydraulic pump 1 is automatically reduced so that the pressure difference does not become large, while the rotation speed of the engine 27 decreases and the hydraulic pressure pump 1 does not become small even when the pump discharge flow rate decreases. The pushing volume of is large.
For this reason, if the load sensing control is carried out when the engine speed is controlled by the running pedal 6a regardless of the opening area of the control valve 2 at the time of operation, the pump flow rate is constant and the front flows even if the engine speed is varied. The drive speed of the attachment (eg boom) does not change and the workability is poor.
The speed of the front actuator can be controlled by controlling the engine speed when the preset differential pressure does not occur even when the tilt angle of the hydraulic pump 1 increases to the maximum value or when the target flow rate exceeds the torque limit flow rate. It is when (saturation state) becomes.
The object of the present invention is not to select the target value of the pushing out volume by the load sensing control and the target value by the input torque limiting control uniformly, in particular to add a restriction and add a restriction to the target value by the load sensing control. When not added, the present invention is to provide a hydraulic control apparatus for a hydraulic construction machine with different target values selected even in the same operation contents.
Independent and dependent claims of claim 1
(1) The present invention is provided between a variable displacement hydraulic pump driven by a prime mover, a first hydraulic actuator driven by discharge oil from the hydraulic pump, and the hydraulic pump and the first hydraulic actuator. The first control valve for controlling the hydraulic oil supplied to the first hydraulic actuator and the first target pushing volume for maintaining the discharge pressure of the hydraulic pump higher than the load pressure of the first hydraulic actuator by a predetermined target value. First determining means for determining and second determining means for determining a second target pushing volume limiting the input torque due to the discharge pressure of the hydraulic pump, and at least the first and second target pushing volumes It is applied to a hydraulic construction machine having an extrusion volume control means for controlling the extrusion volume of the hydraulic pump so that any one value of.
The object is achieved by providing limiting means for adding a limit to a signal indicating the first target pushing volume determined and output by the first determining means.
The pushing volume of the variable displacement hydraulic pump is controlled to either at least the first target pushing volume determined by the first determining means and the second target pushing volume determined by the second means.
Then, the pushing volume of the variable displacement hydraulic pump is controlled to a value at which the first target pushing volume is limited by the state of the limiting means, or the pushing of the variable displacement hydraulic pump is not fully functional. The bet volume is always controlled to the second target pushing volume.
(2) The limiting means is preferably a limiting signal output means for outputting a limiting signal having a value greater than the minimum value of the first target pushing out volume outputted from the first determining means, and the limiting signal and the first determination. The limit operation command which outputs the limit operation command signal which operates the said limit signal output means by operating by the operator and the maximum value selection means which selects and outputs the larger one by comparing the magnitude of the 1st target pushing-out volume output from a means The pushing volume is controlled to include a signal output means so as to be the smaller of the target pushing volume and the second pushing volume selected by the maximum value selecting means.
For example, when the first target pushing volume represents a minimum value and the second target pushing volume represents an approximate maximum value, such as when the first control valve is neutral and the hydraulic actuator is stopped. When the limited operation command signal is output, the target pushing out volume represented by the limiting signal is selected as the maximum value selecting means and the minimum value selecting means so that the pushing volume of the variable displacement hydraulic pump is smaller than the second target pushing volume, It is set to a value larger than the target pushing out volume.
Therefore, it is possible to increase the discharge flow rate (hereinafter referred to as standby flow rate) from the hydraulic pump when the first control valve is in neutral, and to reach the required flow rate when suddenly operating the first control valve. Can shorten the time.
(3) The limited operation command signal output means preferably obtains the above-mentioned action by limiting the first target pushing out volume when the switch operated by the operator is preferable and the operator desires.
(4) The restriction operation command signal output means may output at least two kinds of restriction operation command signals, and output a target pushing volume of a value corresponding to the restriction operation command signal input from the restriction signal output means. The standby flow rate may be changed in response to the work.
(5) The restriction operation command signal output means may be configured to include an operation member for outputting two or more kinds of restriction operation command signals corresponding to the operation amount to be operated by the operator.
(6) said limiting means comprises: a minimum value selecting means for selecting a smaller one of a first target pushing volume output from said first determining means and a second target pushing volume output from said second determining means; The output of the minimum value selection means is selected as the target pushing volume selected by the minimum value selecting means and the second target pushing volume by the selecting means and the target pushing volume selected by the selecting means. A selection command signal output means for outputting a selection command signal for instructing whether to select a target pushing volume may be provided.
According to this configuration, the volume pushed to the minimum value of the first and second target pushing volumes is normally controlled and pushed to the second target pushing volume regardless of the first target pushing volume from which the selection command signal is output. The volume is controlled.
Therefore, it is preferable to control the volume pushed out to the input knob limit value rather than the volume pushed out to the load sensing control value, and the operation peeling is improved by outputting the selection command signal during operation.
(7) The limited operation command signal may be output when a specific operation member such as an operation lever and a traveling pedal is operated.
(8) The hydraulic construction machine furthermore, the first operation means operated to maintain the rotational speed of the prime mover and the initial low-speed position when the operating force is slowed down to control the rotational speed of the prime mover. Second control means for returning to the engine, rotation speed control means for controlling the prime mover speed in response to the first and second operation means, a second hydraulic actuator driven by the discharge oil from the hydraulic pump, and the hydraulic pressure. A second control valve may be provided between the pump and the second hydraulic actuator to control the pressurized oil supplied to the second hydraulic actuator.
In this case, the second target pushing volume is selected when the state of operating the first hydraulic actuator is continuously controlled by the second operation means as the limited operation command signal output means and the state of operating the first hydraulic actuator is determined. It is preferable to use discrimination means for outputting a selection command signal.
(9) The first means for determining the pressure difference between the pressure in the conduit connecting the hydraulic pump to the first control valve and the pressure in the conduit connecting the first hydraulic actuator to the first control valve. It is good also as a well-known load sensing control system which calculates the deviation of the detected target differential pressure and the detected differential pressure, and calculates the 1st target pushing-out volume based on this deviation.
(10) The second determining means detects a deviation between the actual athlete of the diesel engine as the prime mover and the control speed indicated at the governor lever position of the diesel engine, and detects the engine from the detected deviation. Well-known input torque limiting control which detects the target torque and detects the discharge pressure of the variable displacement hydraulic pump and detects the second target pushing volume based on the inverse of the detected discharge pressure and the target torque. You may use system.
Independent and dependent claims of claim 11
(11) The present invention, the first operation means operated to maintain the rotational speed of the prime mover, and the operation to control the rotational speed of the prime mover to return to the initial low speed position when the operating force is slowed down Second operating means, rotational speed control means for controlling the prime mover speed in response to the first and second operating means, a variable displacement hydraulic pump driven by the prime mover, and discharge oil from the hydraulic pump. A first hydraulic actuator driven by the first hydraulic actuator, a first hydraulic actuator driven by the discharge oil from the hydraulic pump, and the hydraulic pump and the first hydraulic actuator to be supplied to the first hydraulic actuator. A first control valve for controlling the pressurized oil to be provided; and a second for controlling the pressurized oil supplied between the hydraulic pump and the second hydraulic actuator and supplied to the second hydraulic actuator. Control valve and first determination means for determining a first target pushing volume for maintaining a discharge pressure of the hydraulic pump higher than a load pressure of the first and second hydraulic actuators by a predetermined target value; Second determination means for determining a second target pushing volume for limiting input torque based on the discharge pressure of the hydraulic pump, and at least one of at least one of the first and second target pushing volumes. It is applied to a hydraulic control device of a hydraulic construction machine having a pushing out volume control means for controlling the pushing out volume of the hydraulic pump.
And discriminating means for outputting a discrimination signal when the state of operating the first hydraulic actuator is determined by continuously controlling the prime mover rotation speed by the second operating means, and when the discrimination signal is output, The object is achieved by controlling the pushing volume of the variable displacement hydraulic pump to be controlled such that the second target pushing volume is controlled regardless of the value of the first target pushing volume.
The volume of the pushing out of the variable displacement hydraulic pump is controlled to control the prime mover speed by the second operating means and to determine the second target pushing volume when the state of operating the first hydraulic actuator is determined. .
In response to the driving situation, in the control device that performs the load sensing control and the input torque limiting control, for example, when the prime mover speed is controlled in response to the operation amount of the driving pedal due to a non-traveling operation, the input torque limiting control is forcibly performed. By this, the pushing volume of the variable displacement pump is controlled.
Therefore, at the time of operation, for example, by operating the driving pedal to control the prime mover speed, the speed of the front attachment such as the boom can be controlled in response to the pedal operation, and the operability can be improved.
(12) Preferably, the minimum value selecting means for selecting a small value among the first and second target pushing volumes, and the target pushing volume selected by the minimum value selecting means when the determination signal is not output, And a switching means for outputting the second target pushing out volume when the discriminating signal is being output.
(13) Further, the limit signal output means for outputting a limit signal having a value larger than the minimum value of the first target pushing out volume and the magnitude of the limit signal and the first target pushing out volume are compared to select the larger one. The limit signal outputting means is operated by an operator and a minimum value selecting means for selecting the smallest value among the maximum value selecting means and the target pushing volume output from the maximum value selecting means and the second target pushing volume. A limit operation command signal output means for outputting a limit operation command signal may be provided.
(14) The first hydraulic actuator is used as a front attachment hydraulic cylinder, the second hydraulic actuator is a traveling hydraulic motor, and the first operation means is a manual operation member, and the second operation member is used. It can also be set as a stepping-type operation member.
(15) As the manual operation member, a fuel lever for setting the prime mover speed in response to the operated position is most suitable, and the opening area of the second control valve can also be adjusted as the pedal operation member in response to the stepping amount. The driving pedal is most suitable. According to the present invention, when the prime mover speed control is performed by operating the fuel lever, either the load sensing control or the input torque limit control is performed in response to the situation, and the prime mover speed is controlled by operating the driving pedal during operation. In this case, input torque limit control is forcibly performed.
Therefore, the pump flow rate changes in response to the prime mover speed control by operation of the traveling pedal at the time of operation, and it is possible to control the front attachment such as the boom at the desired speed.
(16) When the discrimination signal is outputted, it is more preferable to provide a prohibition means for prohibiting the driving of the second hydraulic actuator because there is no fear that the wheel type hydraulic excavator or the like will start during operation.
(17) The rotation speed control means includes first target rotation speed setting means for setting a first target rotation speed of the prime mover in response to an operation amount of the first operation means, and an operation amount of the second operation means. Second target rotation speed setting means for setting the second target rotation speed of the prime mover, selection means for selecting any one of the first and second target rotation speeds, and a selected target rotation speed. It may include a rotation speed increasing means for increasing or decreasing the prime engine speed.
The present invention relates to a hydraulic control device of a hydraulic construction machine capable of load sensing control and input torque limit control.
1 is a block diagram showing a pump control system of a hydraulic control apparatus according to a first embodiment of the present invention.
2 is a diagram showing an overall configuration of the hydraulic control device.
3 is an enlarged view of a portion of FIG. 2;
4 is a block diagram showing a pump control system of the hydraulic control apparatus according to the second embodiment of the present invention.
5 is a block diagram showing a pump control system of a hydraulic control apparatus according to a third embodiment of the present invention.
6 is a block diagram showing an engine control system.
7 is a flowchart showing the procedure of engine speed control.
FIG. 8 is a block diagram showing details of an input torque control unit for the first to third embodiments. FIG.
FIG. 9 is a block diagram showing in detail an input torque control unit that solves a problem occurring in the input torque control unit of FIG.
10 is a side view of a wheeled hydraulic excavator.
11 is a view showing a conventional hydraulic control device.
1 to 3, a first embodiment of the present invention will be described.
In the embodiment of FIG. 1, the volume of pushing the first target pushing volume calculated by the load sensing control system and the second target pushing volume calculated by the input torque limiting control system to a smaller value is controlled more. If you want to get a fast response speed, the standby flow rate is increased so that the limit is added to the first target pushing volume, so that either the larger limit value or the second target pushing volume is smaller than the first target pushing volume. To control the pushing volume.
2 is a view showing the overall configuration of a hydraulic control device of a wheel-type hydraulic excavator to which the present invention is applied. FIG.
In this embodiment, the tilt angle, that is, the pushing volume of the variable displacement hydraulic pump 1 is controlled by the tilt angle control device 40.
The tilt angle control device 40 includes a hydraulic pump 41 driven by the engine 27, a pair of solenoid valves 42 and 43, and a hydraulic pump 41 in response to switching of the solenoid valves 42 and 43. From the servo cylinder 44 whose piston position is controlled by the hydraulic pressure from, the tilt angle of the hydraulic pump 1 is controlled in response to the piston position of the servo cylinder 44.
Here, the pair of solenoid valves 42 and 43 are controlled to be switched by the controller 50 mainly composed of microcomputers.
The forward and backward switching valve 8A uses an electronic valve and the forward and backward switching valve 8A moves to the N position in response to the switch from the N position to the F position and the R position of the forward and backward switching switch SW1 installed in the driver's seat. Switch to E position and R position respectively.
The working control valve 20A uses a hydraulic pilot valve, and the switching direction and stroke amount are controlled by the pilot pressure output from the pressure reducing valve 59 in response to the operation of the operation lever 58.
"SW2" is a brake switch and is turned on by the operator's operation during work, and turned off during driving.
"SW3" is a response speed selector switch, which will be turned ON when setting the quick mode with a higher standby flow rate as described below, and turned OFF when setting the standard mode that emphasizes fuel economy and noise.
The output signals of these switches SW2 and 3 are all input to the controller 50.
This embodiment is different from the example of FIG. 11 and electrically controls the pushing volume of the hydraulic pump by electrically detecting the operating state, and signals from the switch and the sensor group described later are input to the controller 50. By pushing various operations in the controller 50 to drive various actuators, the pushing out volume of the hydraulic pump is controlled.
"51" is a tilt angle sensor for detecting the tilt angle θs of the hydraulic pump 1, "52" is a pressure sensor for detecting the discharge input Pp of the hydraulic pump 1, "53" is for the engine 27 The rotation speed sensor "54" for detecting the rotation speed Nr is the greater of the discharge pressure of the hydraulic pump 1 and the maximum load pressure of the actuator (the load pressure of the hydraulic motor 4 and the load pressure of the hydraulic cylinder 21). It is a differential value sensor which detects the differential pressure (DELTA) PLS with the side value, and was selected by the shuttle valve 29).
"55" denotes a potentiometer for detecting the control speed Nθ from the displacement of the governor lever 27b, and "56" detects the pressure Pt of the pilot valve 6 in response to the operation amount of the traveling pedal 6a. The pressure sensor &quot; 95 &quot; is a pressure switch that is turned on when the working pilot pressure Pd is equal to or higher than a predetermined value.
The detection result of each sensor and the ON / OFF state of the pressure switch 95 are input to the controller 50.
"57" is a rotation speed setting device for commanding the target rotation speed X in response to the manual operation of the fuel lever 57a, and the command signal is also input to the controller 50.
The controller 50 has a first control circuit section 60 as shown in FIG. 1, which control circuit section 60 calculates and outputs a first target pushing volume θL (hereinafter, LS control unit 61, the torque control unit 62 that computes and outputs the second target pushing volume θA, and the first target pushing volume θL when the standby flow rate is increased. A standby flow rate control section 63 for outputting the third target pushing volume θO, and a first or third target pushing volume input through the standby flow rate control section 63 and a third input from the torque control section 62; The minimum value selection part 64 which selects the smaller one of the target pushing out volume of 2, and the volume control solenoid valve 42 which pushes out based on the target pushing out volume and the pushing out volume input from the minimum value selection part 64, 43 is a servo control unit 65 for controlling.
The LS controller 61 detects a deviation Δ (PLS) between the target differential pressure generator 61a for outputting a signal in response to the target differential pressure ΔPLSR, and the differential pressure ΔPLS detected by the target differential pressure ΔPLSR and the differential pressure sensor 54. The first target pushing volume (θL) for load sensing control by integrating the calculating deviation 61a, the calculating unit 61c calculating the change amount ΔθL of the target value from the deviation ΔPLS, and ΔθL. ) Is obtained from the integrator 61d for obtaining and outputting?
The torque control unit 62 provides a marginal torque from the deviation between the engine speed Nr detected by the rotation speed sensor 53 and the control speed Nθ represented by the governor lever displacement detected by the potentiometer 55. Deviator 62a for calculating ΔT, target torque operator 62b for calculating target torque Tpo for preventing engine stall from the spare torque ΔT, and pressure sensor 52 for detection The inverse operator 62c for calculating the inverse of the pump discharge pressure Pp thus obtained, the θps operator 62d for calculating the inclination angle θps by multiplying the target torque Tpo by the inverse 1 / Pp, and the inclination angle θps temporarily. The filter 62e outputs the second target pushing volume θA for the input torque limiting control through the filter of the delayed element.
The standby flow rate control unit 63 outputs a value corresponding to the third target pushing volume θO that is at least greater than the minimum value of the first target pushing volume θL calculated by the LS control unit 61. When the setter 63a and the response speed selector switch SW3 are turned on, the switch 63b closes and outputs the third target pushing volume θO, and the first target pushing volume θL and the third target pushing volume θO. It has the maximum value selection part 63c which selects and outputs larger one of the target pushing-out volume (theta) O.
The maximum value selector 63c inputs the larger of the first or third target pushing volume θL or θO to the minimum value selector 64, and the minimum value selector 64 enters the maximum value selector 63c. ) Selects the smaller one of the first or third target pushing volume θL or (θO) and the second target pushing volume θA and inputs it to the servo control unit 65 as a tilt angle command value θr. .
The servo controller 65 has a deviation 65d for calculating a deviation between the selected tilt angle command value θr and the tilt angle feedback value θs detected by the tilt angle sensor 51, and “θs” is insensitive. A tilting angle control device having a function generator 65b for outputting an ON signal to the solenoid valve 42 or 43 when the size is larger than the size of the table, so that the pump tilt angle? S coincides with the tilt angle command value? R. 40).
In the first control circuit section 60 of the controller 50 shown in FIG. 1, the following processing is performed.
(1) When the operation lever 58 and the traveling pedal 6A are not operated and the control valves 2 and 20A are in the neutral position, the standard speed is selected when the response speed selection switch SW3 is OFF. The selection signal SS output from SW3 is low level and the switch 63b is open.
In this way, the maximum value selecting section 63c selectively outputs the LS control value θL from the LS control section 61.
When the control valves 2 and 20A are in the neutral position, the first target pushing volume θL calculated by the LS control unit 61 is the smallest (θLmin) with respect to the engine speed at that time.
On the other hand, the pump discharge pressure Pp is the minimum value determined by the unload valve 26 and the second target pushing volume calculated by the input torque control unit 62 becomes the maximum value [theta] Amax.
Therefore, the minimum value selector 64 selects the first target pushing volume θLmin, which is the LS control value, and the standby flow rate of the hydraulic pump 1 is the first minimum target pushing volume θLmin and the engine speed. It is a relatively small flow rate Qs expressed as the product of.
In this state, when the operator operates the operation lever 58, the load sensing control for maintaining the pump pressure higher than the load pressure of the hydraulic actuator by the constant differential pressure ΔPLSR is performed, and the control valve 20A is proportional to the operation amount of the operation lever 58. The pushing volume of the hydraulic pump 1 increases in response to the increase in the opening area of the pump.
At this time, since the standby flow rate is a relatively small flow rate, the pump discharge flow rate gradually increases.
When the load pressure becomes high and the second target pushing volume θA calculated by the input torque control section 62 becomes smaller than the target pushing volume output from the maximum value selecting section 63c, the second value selecting section 64 causes the second value to drop. The target pushing volume θA of is selected.
Therefore, the pressure torque of the hydraulic pump 1 is controlled not to exceed the output torque of the engine 27 and generation of engine stall is prevented.
(2) When the operation mode 58 and the driving pedal 6A are not operated and the control valves 2 and 20A are in the neutral position, the quick mode is selected when the response speed selection switch SW3 is ON. The signal SS is high level and the switch 63b is closed.
In this way, the third target pushing volume θO and the LS control value θL from the LS control unit 61 are input to the maximum value selecting section 63c.
When the control valves 2 and 20A are in the neutral position, the first target pushing volume θL calculated by the LS control unit 61 becomes the smallest θLmin below the engine speed at that time.
Therefore, if the third target pushing volume θO is set to a value larger than θLmin, the maximum value selecting section 63c always selects and outputs the third target pushing volume θO at the time of no control valve operation.
On the other hand, the second target pushing out volume calculated by the input torque control unit 62 at the time of no operation of the control valve becomes the maximum value [theta] Amax as described above.
Therefore, the minimum value selector 64 selects the third target pushing volume θO set by the standby flow rate control section 63, and the standby flow rate of the hydraulic pump 1 is the third target pushing volume θO. And a relatively large flow rate Qq (Q, S), expressed as the product of the engine speed.
When the operator operates the operation lever 58 in this state, the LS control unit 61 performs the above-described load sensing control operation and the opening area of the control valve 20A in proportion to the operation amount of the operation lever 58. In response to the increase in the required flow rate, the first target pushing volume θL is increased.
At this time, the volume pushed out of the hydraulic pump 1 is independent of the operation of the operating lever 58 until the first target pushing volume θL becomes larger than the third target pushing volume θO. Is set to the third target pushing out volume value θO.
Therefore, if the quick mode is selected during the operation of rapidly operating the operating lever 58, since the standby flow rate is a relatively large flow rate, the pump discharge flow rate follows the operation of the operation lever 58 in a good response and increases.
Also in this case, when the 2nd target pushing volume (theta) A becomes larger than the 3rd target pushing volume (theta) O or the 1st target pushing volume (theta) L, the minimum value selection part 64 will push a 2nd target pushing. The pump input torque does not exceed the engine output torque because the inside selects the volume θA.
As described above, according to the first embodiment, the pushing volume of the hydraulic pump 1 when the control valves 2 and 20A are in the neutral position, that is, the standby flow rate, is changed by the operation of the response speed selector switch SW3. In the standard mode with low standby flow rate, the actuator operates in mild mode in response to the minute operation of the operating member, and in the quick mode with high standby flow rate, the actuator operates quickly in response to the rapid operation of the operating member. Improve.
In FIG. 1, when the third target pushing out volume θO is set to be larger than the maximum value θAmax output from the input torque control unit 62, the response torque selection switch SW3 is always turned on in the input torque control. The pump pushing volume is controlled, and when the switch SW3 is turned off, the pump pushing volume is controlled by either the load sensing control or the input torque control depending on the operating state.
Moreover, the response speed selector switch SW3, for example, a pressure switch for turning on the traveling pilot pressure above a predetermined value can be constituted.
According to this configuration, the standby flow rate increases during driving, and the oscillation response is improved.
In addition, a pressure switch to be turned on by the pilot pressure of the operation unit where other responsiveness is required may be provided instead of the response speed selection switch SW3.
4 shows a second embodiment.
In the first embodiment, the third target pushing volume θO for changing the standby flow rate was a fixed value, but in the second embodiment, the third target pushing volume θO was set in accordance with the operator's operation amount. It is set to a value.
The differences from the first embodiment will mainly be described.
In place of the response selection switch SW3, a response selection dial DI such as volume for outputting an electric signal corresponding to the rotational operation amount is provided, and at the same time, the standby flow control section 63A is provided with the setter 63a and the switch 63b. Instead, a function generator 63d for outputting the third target pushing volume θO in response to the output voltage from the dial DI is provided.
By such a configuration, it is possible to arbitrarily set the standby flow rate in accordance with the hobby and the operation state of the operator, and to provide a hydraulic construction machine with improved operability that is more welcomed by everyone and can cope with various operation states.
In addition, if the maximum output value of the function generator 63d is set larger than the maximum output value of the input torque control unit 62, it is possible to control the volume of pump pushing by only the input torque control as described above.
5 to 7 show a third embodiment.
The first and second embodiments are separate from the first target pushing volume θL output from the LS control unit 61 and the second target pushing volume θO output from the pressure torque control unit 62. In the third embodiment, the standby flow control unit is abolished, and the load sensing control is prohibited when detecting a specific operation state, although the standby flow control units 63 and 63A are provided to change the standby flow rate by an operator's operation. The limiting control is to control the pushing out volume of the hydraulic pump.
Further, in the third embodiment, the load sensing control and the input torque limit control are selectively performed during driving, and the engine is controlled by the driving pedal 6a to continue the engine speed control. It is to control input torque limit without control.
The main part of the whole circuit of the hydraulic construction machine is as shown in Figs. 2 and 3 and mainly explains the differences.
The controller 50 is provided with the 1st control circuit part 60B shown in FIG. 5, and the 2nd control circuit part 80 shown in FIG.
In the first control circuit section 60B of FIG. 5, the standby flow rate control section 63 of FIG. 1 is omitted, and the selection switch 66 is provided at the rear end of the minimum value selecting section 64, and the switch 66 The determination part 67 which is a switching control part is provided.
The judging section 67, the comparator 67a and the end gate circuit 67b are configured to continuously control the engine speed in the traveling pedal 6a and to output a high level signal during operation of operating the operation lever 58. have.
The comparator 67a outputs a high level signal when the pilot pressure Pt detected by the pressure sensor 56 is higher than a predetermined predetermined pressure (set to the standard power supply 67c). It is input to the gate circuit 67b.
A signal indicating the ON / OFF state of the brake switch SW2 and a signal indicating the switching state of the forward / backward switching switch SW1 are also input to the AND gate circuit 67b so that the brake switch SW2 is turned ON (high level signal). Is output), ② the forward and backward switching switch SW1 is at the N position (high level signal is output), ③ the pilot pressure Pt is higher than a predetermined value (the high level signal is output from the comparator 67a), (4) The AND gate circuit 67b is turned ON only when all four conditions of the working pilot pressure switch 95 are turned ON (high level signal is output).
When working while controlling the rotation speed of the engine 27 by the operation of the driving pedal 6a in the vehicle stopped state, all four conditions are satisfied and the high gate signal is output from the AND gate circuit 67b.
The selector switch 66 is switched to the contact a when the AND gate circuit 67b is OFF (when the low level signal is being output and when traveling), and selects the output of the minimum value selector 64.
That is, it selects as the volume command value (theta) r which pushes out the smaller one of the 1st target pushing out volume (theta) L and the 2nd target pushing out volume (theta) A.
When the AND gate circuit 67b is ON (when a high level signal is being output and at the specific operation), the selector switch 66 is switched to the b contact to select the output of the torque control unit 62.
That is, it selects as volume command value (theta) r which pushes out 2nd target pushing-out volume (theta) A.
The selected pushing volume command value [theta] r is input to the servo controller 66.
The controller 50 also has a second control circuit section 80 shown in FIG.
In the second control circuit section 80, &quot; 81 &quot; is the first target rotational speed calculating section, and a signal corresponding to the operation amount X of the fuel lever 57a of the rotation speed setting device 57 is input and the displacement amount ( The first target rotation speed Nx in accordance with X) is determined.
&Quot; 82 &quot; is a second target rotational speed calculating section and represents a manipulated amount of the traveling pedal 6a, and a pilot pressure Pt detected by the pressure sensor 56 is input to respond to the pilot pressure Pt. Determine the target speed Nt.
Here, in the first target rotation speed calculating unit 81, the displacement amount X and the first target rotation speed Nx are the idle rotation speed (Nx) as the displacement amount X increases. Ni) is set to increase linearly.
In the second target rotation speed calculating unit 82, the pilot pressure Pt and the second target rotation speed Nt are the second target rotation speed Nt as the pilot pressure Pt (pedal manipulation amount) increases. ) Is set to have a linear increase in idle rotation speed Ni.
Furthermore, the maximum value Nxmax of the first target rotational speed Nx is set lower than the maximum achievable rotational speed of the engine 1 and the maximum value Ntmax of the second target rotational speed Nt is the engine ( It is set almost equal to the maximum speed of 1).
Therefore, the maximum value Ntmax of the target rotation speed Nt is larger than the maximum value Nxmax of the target rotation speed Nx.
These target rotation speeds Nx and Nt are selected by the maximum value selection part 83, and become the target rotation speed command value Ny.
This target rotation speed command value Ny is compared with the control rotation speed Nθ indicated by the displacement of the governor lever 27b detected by the potentiometer 55 by the servo controller 84, and is shown in FIG. The pulse motor 28 is controlled so that the two coincide in the order shown.
In FIG. 7, the target rotation speed command value Ny and the control rotation speed Nθ indicated by the governor lever displacement amount are respectively read in step S21, and the flow advances to step S22.
In step "S22", the result of N? -Ny is stored in the memory as the rotation aberration A, and it is determined whether | A | ≥K using the reference rotation aberration K already determined in step "S23".
If it is affirmative, proceed to step "S24" and judge whether or not the rotation aberration A0. If A0, the control rotation speed Nθ indicated by the governor lever displacement amount is larger than the target rotation speed command value Ny. Since it is higher than that, a signal for commanding motor reversal is output to the pulse motor 28 in step S25 in order to lower the engine speed.
As a result, the rotation speed of the pulse motor 28 and the reverse electrolysis engine 27 decreases.
On the other hand, if A? 0, the control speed Nθ indicated by the governor lever displacement is smaller than the target speed command value Ny, that is, the control speed is lower than the target speed, so that the engine speed is increased. ”To output the motor command.
As a result, the pulse motor 28 rotates forward and the rotation speed of the engine 27 increases.
If step S23 is denied, the process proceeds to step S27 to output a motor stop signal, whereby the rotation speed of the engine 27 is maintained at a constant value.
Steps S25 to S27 return to the beginning.
Next, operation | movement of the 3rd Example comprised as mentioned above is demonstrated.
When the excavation work is performed by driving the front attachment, the brake switch SW2 is turned on and the forward and backward changeover switch SW1 is switched to the N position.
The engine speed can be controlled by the fuel lever 57a or by the traveling pedal 6a.
When it is not based on the traveling pedal 6a, the fuel lever 57a of the rotation speed setting device 57 is held at a suitable intermediate position of the maximum stroke position or less.
In this way, when the engine speed is controlled by the fuel lever 57a, the traveling pilot input Pt input to the second target speed calculating section 82 of the second control circuit section 80 is zero and the calculating section 82 is used. The second target rotation speed Nt calculated at) becomes the idle rotation speed Ni, and the fuel lever operation amount X inputted to the first target rotation speed calculating unit 81 is a large value other than zero, and this calculation unit ( The first target rotation speed Nx calculated in 81 is larger than the idle rotation speed Ni in response to the stroke position of the fuel lever 57a.
Therefore, in the selection unit 83, the target rotation speed Nx is selected as the target rotation speed command value Ny, and the engine 27 is controlled by the target rotation speed Nx.
As a result, the engine speed is controlled at a constant speed corresponding to the stoke position of the fuel lever 57a.
On the other hand, in the first control circuit section 60B of the controller 50 shown in FIG. 5, the following processing can be performed.
When the engine speed is controlled by the fuel lever 57a, the brake switch SW2 is turned ON, the forward and backward switching switch value SW1 is in the N position (neutral position), and the operation lever 58 is operated. Pressure switch 95 is ON.
However, since the driving pedal 6a is not operated, the pilot pressure Pt is less than the predetermined value (1 out of 3 out of 3) out of 3), but not up to 3), and the AND gate constituting the judging section 67 is not satisfied. The circuit 67b is off.
Therefore, the selector switch 66 selects the minimum value selector 64.
That is, the smaller one of the first and third target pushing volumes θL and θA is selected as the pushing out volume command value θr and the pushing out volume of the hydraulic pump 1 is the selected pushing out volume command value ( r).
As described above, when the engine speed is controlled by the fuel lever 57a, the discharge pressure of the hydraulic pump 1 is higher than the load pressure of the hydraulic motor 3 by the first target pushing out volume θL. The input torque of the hydraulic pump 1 is controlled not to exceed the target torque Tpo by controlling the target differential pressure ΔPLSR (load sensing control) and by the second target pushing out volume θA. )do.
In addition, the engine speed is controlled by the driving pedal 6a when the vehicle is running, but since the brake switch SW2 is turned off, the selector switch 66 is switched to the a-axis and the pump is turned to the smaller value of "θL" and "θA". The angle is controlled.
When the engine speed is controlled by the operation of the running pedal 6a at the time of operation, and the speed of the front attachment is controlled, the brake switch SW2 is turned on, and the forward and backward switch SW1 is switched to the neutral N position and the fuel is turned on. Hold the lever 57a at the minimum stroke position.
When the driving pedal 6a is pressed in this state, the fuel lever operation amount x = 0 is input to the first target rotational speed calculating section 81 of the second control circuit section 80, and the first calculation calculated by the calculating section 81 is performed. The target rotation speed Nx becomes the idle rotation speed Ni, and the driving pilot pressure Pt corresponding to the stepped amount of the travel pedal 6a is input to the second target rotation speed calculation unit 82, and this calculation unit 82 2nd target rotation speed Nt computed by () becomes a value responding to the stepping amount of the running pedal 6a larger than idle rotation speed Ni.
Therefore, in the selection unit 83, the target rotation speed Nt is selected as the target rotation speed command value Ny, and the rotation speed of the engine 27 is controlled by the target rotation speed Nt.
As a result, the engine speed is controlled in response to the operation amount of the travel pedal 6a, and increasing the operation amount of the travel pedal 6a increases the engine speed and decreases the number of engines by returning the travel pedal 6a.
On the other hand, the following process is performed in the 1st control circuit part 60B.
When the engine speed is controlled by the traveling pedal 6a, the brake switch SW2 is turned on, the forward and backward switching switch SW1 is in the N position (neutral position), and the pilot is operated by the driving pedal 6a. The pressure Pt becomes more than a predetermined value and the pressure switch 95 is turned ON by the operation of the work lever 58.
Therefore, since all four conditions ①②③④ are satisfied, the AND gate path 67b constituting the determination unit 67 is turned ON, whereby the selector switch 66 switches to the B contact point, whereby the The target pushing out volume [theta] A of 2 is selected as the volume command value [theta] r to push out.
The pushing volume of the hydraulic pump 1 is controlled to be the selected pushing volume command value [theta] r.
In other words, only the input torque limiting control is performed without the above-described load sensing control.
Therefore, in the region below the second target pushing out volume determined by the input torque control, the flow rate of the hydraulic pump 1 increases and decreases approximately in proportion to the increase / decrease control of the engine speed by the running pedal 6a, and the like. It is possible to drive control the front attachment at the required speed.
If the operator switches the selection switch 66 of FIG. 5 freely, the load sensing control and the input torque control can be divided and used at the operator's discretion.
In addition, as described in the first and second embodiments, the same method as in the third embodiment is used in the case where the load sensing control is prohibited at the operator's discretion and the pump pushing volume is controlled by the input torque control. The effect can be obtained.
In addition, although the example which used the existing traveling pedal 6A as the operation means for engine speed control was shown above, this operation means is not limited to the traveling pedal 6a but may be another operation member (preferably a pedal).
Moreover, although the example which installed the driving hydraulic motor 4 and the working hydraulic cylinder 20A was shown as a erector actuator, you may have a some working hydraulic cylinder 20A and a turning hydraulic motor.
On top of that, the working hydraulic cylinder 20A is not limited to the boom driving but may be, for example, the arm and the bucket driving.
FIG. 8 shows a more detailed block diagram of the torque control unit 62 of the first to third embodiments described above.
The control speed Nθ corresponding to the governor lever position detected by the potentiometer 55 is input to the reference speed calculation part 162a and the torque calculation part 162a.
The reference rotation calculating section 162a calculates the speed sensing reference rotation speed Ns from the characteristic shown in response to the input control rotation speed Nθ.
The reference rotation speed Ns is higher as the control rotation speed Nθ is higher.
Further, the torque calculating section 162b calculates the target torque Tro from the characteristics shown in response to the input control rotation speed Nθ.
The adder 162C calculates the deviation? N = (Nr-Ns) between the actual rotational speed Nr of the engine and the reference rotational speed Ns, and the correction torque calculating section 162d responds to the rotational speed deviation? N. The correction torque ΔT is obtained from the characteristics shown.
When the rotational deviation △ N is positive, the correction torque is also positive; when the rotational deviation △ N is negative, the correction torque is negative, and with the increase of | ΔN |, the correction torque | △ T | Is supposed to increase.
The function generator 162e outputs a signal indicating &quot; 1 &quot; when the control rotation speed Nθ is less than a predetermined value and is equal to or greater than &quot; 0 &quot;, and the signal is transmitted to the correction torque? Merge with each other.
That is, the correction torque DELTA T is effective only when the control rotation speed Nθ is equal to or greater than a predetermined value, and this DELTA T is added to the target torque Tro by the adder 162g, and the value is the target torque command value. It is output as (Tpo).
And the said target pushing-out volume (theta) A is calculated from this target torque command value Tpo.
According to such an input torque control unit, when the torque of the engine is sufficient, the correction torque (ΔT) becomes positive, the target torque command value (Tpo) increases, and when the torque is over, the correction torque (ΔT) sound becomes negative. Since the target torque command value Tpo is reduced, the target torque can be brought closer to the rated torque and the torque can be set effectively.
However, there is no problem in the case where the engine speed is maintained at a constant value by the fuel lever 57a, but there is no problem when the engine speed is controlled by the running pedal 6a.
When multiplying the running pedal 6a to the full throttle position, the governor lever 27a is operated by the pulse motor 28 directly to the full slot position, so that the control speed Nθ becomes large and the speed sensing reference speed ( Ns) also becomes a large value immediately.
However, even when the governor lever is at the maximum operating amount, there is a time lag until the actual rotation speed of the engine increases to the maximum value.
During this time lag, the rotational speed deviation ΔN becomes negative and the correction torque ΔT becomes negative.
Therefore, the target torque command value Tpo becomes small, the pushing volume of the hydraulic pump decreases, and the start of the rotation speed worsens.
Therefore, FIG. 9 shows an example in which the start characteristic of the engine speed is improved. 9 shows the input torque control unit 162 of the first control circuit unit 60 in the controller 50. As shown in FIG. The difference is mainly demonstrated by attaching the same code | symbol to the place like FIG.
The input torque control unit 162 includes a torque calculating unit 162k having different characteristics in parallel with the torque calculating unit 162d in FIG. 8, and an output value of each torque calculating unit is input to the selecting unit 162h.
The torque calculating section 162k has a positive correction torque DELTA T as in the case where the rotational speed deviation N is positive, and increases with increasing N, but DELTA T is zero when DELTA N is negative.
That is, only the control in which the input torque is increased is performed.
In addition, the input torque control unit 162 has an AND gate circuit 162i, and the AND gate circuit 162i includes a signal indicating an ON / OFF state of the brake switch SW2 and an operation position of the forward / backward switching switch SW1. The signal shown and the thrust of the function generator 162j are input.
The function generator 162j outputs "1" when the stepped amount of the running pedal 6a is greater than or equal to a predetermined value and zero when less than the predetermined value. A signal Pt indicating the amount of stepping on the pedal 6a is input.
Therefore, the AND gate circuit 162j turns ON when the following three conditions are satisfied, that is, when driving, and inputs a high level signal to the selection switch 162h, and the selection switch 162h selects the torque calculating section 162k.
① The brake switch SW2 is turned off (the switch SW2 outputs a low level signal), and the forward and reverse switching valve 8A is switched to a position other than the N position (the forward and backward switching switch SW1 outputs a low level signal). (3) The running pedal 6a is stepped over a predetermined value (the function generator 162j outputs a high level). According to the configured input torque control unit 162, the governor when the running pedal 6a is stepped down to the full throttle position during driving The control speed Nθ, which is a detection value of the lever position, becomes a maximum value, and in response to this, the speed sensing reference speed Ns also becomes a maximum value.
There is a time lag until the actual rotational speed of the engine becomes a value corresponding to the maximum governor lever value, and the rotational deviation ΔN becomes negative therebetween.
However, since the torque calculating section 162k is selected at the time of travel, the rotational deviation ΔN becomes negative and the correction torque ΔT becomes zero without being negative.
Therefore, since the target torque command value Tpo is not reduced and the pushing volume of the hydraulic pump 1 is not reduced, the running acceleration is improved as compared with the case of using the input torque control unit shown in FIG.
In addition, since the torque calculation unit 162d is selected by the selector switch 162h during the non-driving excavation work, when the engine torque cannot be afforded as in the conventional input torque limiting control, the pump pushing volume becomes small. Reduction of input torque is prevented and unnecessary engine stall is prevented.
The structure which ensures such acceleration performance is not limited to running but may rotate and work.
The hydraulic control apparatus according to the present invention described above is effective for use in various types of hydraulic construction machines equipped with a diesel engine, such as a wheel hydraulic excavator, a crawler hydraulic excavator, a hydraulic crawler crane, a wheel loader, and the like.
A variable displacement hydraulic pump driven by a prime mover, a first hydraulic actuator driven by the discharge oil from the hydraulic pump, and provided between the hydraulic pump and the first hydraulic actuator and supplied to the first hydraulic actuator A first control valve for controlling the pressurized oil and a first determination for determining a first target pushing volume for maintaining the discharge pressure of the hydraulic pump only a predetermined target value higher than the load pressure of the first hydraulic actuator Means, the second determining means for determining a second target pushing volume limiting the input torque based on the discharge pressure of the hydraulic pump, and at least one of at least the first and second target pushing volumes. In the hydraulic control apparatus of a hydraulic construction machine having a retracting oil control means for controlling the pushing out volume of the hydraulic pump, it is determined as the first determining means and outputted The hydraulic control apparatus for a hydraulic construction machine comprising the restriction means adds a restriction to the signal representative of the volume to push the target of Fig.
2. The limiting signal output means according to claim 1, wherein said limiting means outputs a limiting signal having a value greater than a minimum value of the first target pushing out volume outputted from said first determining means, said limiting signal and said first determination. A limit operation command for outputting a limit operation command signal for operating the limit signal output means by operating the maximum value selection means for selecting and outputting the larger one by comparing the magnitude of the first target pushing out volume outputted from the means and the operator; Hydraulic control of a hydraulic construction machine having a signal output means, wherein the pushing volume is controlled to be the smaller value of the target pushing volume and the second pushing volume selected by the maximum value selecting means. Device.
3. The hydraulic control apparatus of a hydraulic construction machine according to claim 2, wherein the limit operation command signal output means is a switch operated by an organizer.
3. The limit operation command signal output means according to claim 2, wherein the limit operation command signal output means outputs at least two kinds of limit operation command signals, and the limit signal output means outputs a target pushing volume which is a value in response to the input limit operation command signal. Hydraulic control equipment for hydraulic construction machinery.
5. The hydraulic control apparatus of a hydraulic construction machine according to claim 4, wherein the restriction operation command signal output means includes an operation member for outputting two or more kinds of restriction operation command signals in response to an operation amount manipulated by the operator.
The minimum value according to claim 1, wherein the limiting means selects the smaller of the first target pushing volume output from the first determining means and the second target pushing volume outputted to the second determining means. Selection means for selecting one of the target pushing volume selected from the minimum value selecting means and the second target pushing volume and the output of the selecting means or the second target pushing volume is selected; Hydraulic control device for a hydraulic construction machine comprising a selection command signal output means for outputting a selection command signal for commanding.
2. The limiting signal output means according to claim 1, wherein said limiting means outputs a limiting signal having a value greater than a minimum value of the first target pushing out volume output from said first determining means, said limiting signal and said first determining Limit operation command signal output for operating the limit signal output means by operating the maximum value selecting means for selecting and outputting the larger one by comparing the magnitude of the first target pushing volume output from the means and the operating member of the hydraulic actuator. And a pushing volume is controlled so that the pushing volume selected by the maximum value selecting means is smaller than the target pushing volume and the second target pushing volume. .
3. The hydraulic construction machine according to claim 2, wherein the hydraulic construction machine is further adapted to control the rotational speed of the prime mover, the first operating means being operated to maintain the rotational speed of the prime mover at an arbitrary rotational speed. Second operating means for returning to a position, rotational speed control means for controlling the prime mover speed in response to the first and second operating means, and a second hydraulic actuator driven by the discharge oil from the hydraulic pump And a second control valve installed between the hydraulic pump and the second hydraulic actuator to control the oil pressure supplied to the second hydraulic actuator, wherein the limit operation command signal output means is provided with the second hydraulic valve. Selection to select the second target pushing volume when the state of operating the first hydraulic actuator is determined by continuously controlling the prime mover speed by the operating means Hydraulic control apparatus for a hydraulic construction machine, characterized in that the command signal is the discrimination means and outputting.
The pressure of the conduit which connects the said hydraulic pump to the said 1st control valve, and the pressure of the conduit which connects the said 1st hydraulic actuator to the said 1st control valve. A differential pressure between the target target pressure and the detected differential pressure is calculated to calculate the first target pushing volume due to the deviation, and the second determining means is the actual rotation of the diesel engine as the prime mover. Detects the deviation between the number and the control speed displayed at the governor lever position of the diesel engine, and obtains a target torque so that the diesel engine does not stall the engine from the detected deviation and detects the discharge pressure of the variable displacement hydraulic pump. And the second target pushing out volume is calculated based on the reciprocal of the discharge pressure detected by the solution and the target torque.
10. The driving speed control apparatus according to claim 9, wherein the second determination means includes a means for determining the driving time, and during driving, only the correction is performed to increase the target torque when the actual rotation speed is greater than the control rotation speed, and the actual rotation speed is the control rotation speed when the vehicle is not running. And correcting the target torque when the target torque is greater than the target torque and decreasing the target torque when the actual rotation speed is smaller than the control rotation speed.
First operating means operated to maintain the rotational speed of the prime mover at an arbitrary rotational speed, second operating means operated to control the rotational speed of the prime mover, and returning to an initial low speed position when the operating force is relaxed; Rotation speed control means for controlling the prime mover speed in response to the first and second operating means, a variable displacement hydraulic pump driven by the prime mover, a first hydraulic actuator driven by the discharge oil from the hydraulic pump, A second hydraulic actuator driven by the discharge oil from the hydraulic pump, a first control valve installed between the hydraulic pump and the first hydraulic actuator to control the hydraulic oil supplied to the first hydraulic actuator, the A second control valve installed between the hydraulic pump and the second hydraulic actuator to control the pressurized oil supplied to the second hydraulic actuator; First determining means for determining a first target pushing volume for maintaining a discharge pressure higher than the load pressures of the first and second hydraulic actuators by a predetermined target value, and inputting on the basis of the discharge pressure of the hydraulic pump; Second determining means for determining a second target pushing volume for limiting torque and pushing for controlling the pushing volume of the hydraulic pump to be at least one of the first and second target pushing volumes. In the hydraulic control apparatus of a hydraulic construction machine provided with a volume control means, the second operating means continuously controls the motor revolution speed and outputs a discrimination signal when the state of operating the first hydraulic actuator is determined. And a discriminating means, and when the discriminating signal is output, the volume of the second target pushing out may be used regardless of the value of the first target pushing-out volume. Hydraulic control apparatus for a hydraulic construction machine characterized in that the control push the volume of the variable displacement hydraulic pump.
12. The apparatus according to claim 11, further comprising: a minimum value selecting means for selecting a small value among the first and second target pushing volumes, and a target pushing volume selected by said minimum value selecting means when the discriminating signal is not output; And a switching means for outputting the second target pushing out volume when the determination signal is output.
The limit signal output means for outputting a limit signal having a value larger than the minimum value of the first target pushing out volume, and selecting the larger one by comparing the magnitude of the limit signal with the first target pushing out volume. Operating the limit signal output means by being operated by an operator and a minimum value selecting means for selecting a small value among the maximum value pushing means outputted from the maximum value selecting means, the target pushing volume and the second target pushing volume. And a restriction operation command signal output means for outputting a restriction operation command signal.
The hydraulic cylinder according to any one of claims 11 to 13, wherein the first hydraulic actuator and the front attachment hydraulic cylinder, the second hydraulic actuator is a traveling hydraulic motor, and the first operation means is a manual operation member. The second control member is a hydraulic control device of a hydraulic construction machine, characterized in that the pedal operation member.
15. The driving apparatus according to claim 14, wherein the manual control member is a fuel lever for setting the prime mover rotational speed in response to the operated position, and the pedal type operation member also adjusts the opening area of the second control valve in response to the stepping amount thereof. Hydraulic control device of a hydraulic construction machine, characterized in that the pedal.
16. The hydraulic control apparatus of a hydraulic construction machine according to claim 15, further comprising prohibiting means for prohibiting driving of the second hydraulic actuator when the determination signal is output.
12. The apparatus according to claim 11, wherein the first target rotation speed setting means and the second operation means for setting the first target rotation speed of the prime mover in response to the operation amount of the rotation speed control means, the first operation means. Second target rotation speed setting means for setting the second target rotation speed of the prime mover in response to the manipulation amount, selection means for selecting a larger value of the first and second target rotation speeds, and the selected target rotation; A hydraulic control apparatus for a hydraulic construction machine, comprising: a speed increase-decreasing means for increasing or decreasing the number of prime mover rotations.
18. The hydraulic system of claim 17, wherein the first hydraulic actuator is a front attachment hydraulic cylinder, the second hydraulic actuator is a traveling hydraulic motor, the first operating means is a manual operation member, and the second operating member is Hydraulic control device of a hydraulic construction machine, characterized in that the pedal-type operation member.
19. The driving apparatus according to claim 18, wherein the manual control member is a fuel lever for setting the prime mover rotational speed in response to the operated position, and the pedal-type control member adjusts the opening area of the second control valve in response to the stepping amount. Hydraulic control device of a hydraulic construction machine, characterized in that the pedal.
The hydraulic control apparatus of a hydraulic construction machine according to claim 19, further comprising a prohibiting means for prohibiting the driving of the traveling hydraulic motor when the determination signal is output.
21. The method according to any one of claims 11 to 20, wherein the determining means includes the pressure in the conduit connecting the hydraulic pump to the first and second control valves, and the first and second control valves. Detecting the borrowing between the pressure of the pipeline on the high pressure side among the pipelines connecting the first and the second hydraulic actuators, calculating the deviation between the predetermined target differential pressure and the detected differential pressure, and the first target pushing volume based on the deviation. The second determining means detects a deviation between the actual rotational speed of the diesel engine as the prime mover and the control rotational speed displayed at the governor lever position of the diesel engine, and detects the diesel engine from the detected deviation. Obtaining a target torque so as not to stall the engine, and detecting the discharge pressure of the variable displacement hydraulic pump to calculate the second target pushing volume based on the inverse of the detected discharge pressure and the target torque. Hydraulic control equipment of hydraulic construction machinery.
22. The driving speed control apparatus according to claim 21, wherein the second determining means includes means for determining the driving time, and during driving, only the correction is performed to increase the target torque when the actual rotation speed is greater than the control rotation speed. And correcting the target torque when the target torque is greater than the target torque and decreasing the target torque when the actual rotation speed is smaller than the control rotation speed.
Manual operation member operated to adjust the diesel engine to an arbitrary rotation speed, the driving pedal which is operated to control the traveling speed and the operation force is released to return to the initial position, the diesel in response to the operation amount of the manual operation member and the driving pedal Driven by a rotation speed control means for controlling engine speed, a variable displacement hydraulic pump driven by the diesel engine, a hydraulic actuator for proat attachment driven by discharge oil from the hydraulic pump, and discharge oil from the hydraulic pump. A traveling hydraulic motor, a front attachment control valve installed between the hydraulic pump and the front attachment hydraulic actuator for controlling the pressurized oil supplied to the hydraulic actuator, and installed between the hydraulic pump and the traveling hydraulic motor. And supply to the traveling hydraulic motor in response to the stepping amount of the traveling pedal. A driving control valve for controlling the pressurized oil to be used, and a first target pushing volume for maintaining a discharge pressure of the hydraulic pump to be higher than a load pressure of the driving hydraulic motor for the front attachment by a predetermined target value; The deciding means, the second deciding means for determining a second target pushing volume limiting the input torque on the basis of the discharge pressure of the hydraulic pump, and the target pushing any one of the first and second target pushing volumes. A hydraulic control apparatus of a hydraulic construction machine having a pushing volume control means for controlling the pushing volume of the hydraulic pump so that the inside volume is lowered, wherein the driving pedal continuously controls the diesel engine speed and the hydraulic pressure for the front attachment. Judging means for outputting a judging signal upon judging a state where the actuator is being operated; and if the judging signal is output, the first means. Target hydraulic pressure control apparatus for a hydraulic construction machine comprising: selection means for said first select the volume to push the second target, regardless of the value of the volume to push.
The said 1st determination means is a pressure of the conduit which connects the said hydraulic pump to the said 1st and 2nd control valves, and the said 1st and 2nd control valves to the said 1st and 2nd control valves. Detects the differential pressure between the pressure of the high-pressure side of the pipelines connecting the two hydraulic actuators, calculates the deviation between the predetermined target differential pressure and the detected differential pressure, and calculates the first target pushing volume based on the deviation. And the second determining means detects a deviation between the actual rotational speed of the diesel engine as the prime mover and the control rotational speed displayed at the governor lever position of the diesel engine, and the diesel engine is not engine stalled from the detected deviation. The target torque is determined not only, but the discharge pressure of the variable displacement hydraulic pump is detected, and the second target pushing volume is detected based on the inverse of the detected discharge pressure and the target torque. Hydraulic control system for a construction machine.
25. The driving speed control apparatus according to claim 24, wherein the second determination means includes means for determining the driving time, and during driving, only the correction is performed to increase the target torque when the actual rotation speed is greater than the control rotation speed, and the actual rotation speed is the control rotation speed during non-driving. The hydraulic control device of a hydraulic construction machine according to claim 1, wherein the target torque is increased when the torque is greater than the target torque and the target torque is decreased when the actual rotation speed is larger than the control rotation speed.
KR92702343A 1991-01-28 1992-01-28 Hydraulic control system in hydraulic construction machine KR970000491B1 (en)
JP91-26912 1991-01-28
JP91-184802 1991-07-24
KR930700738A KR930700738A (en) 1993-03-16
KR970000491B1 true KR970000491B1 (en) 1997-01-13
KR92702343A KR970000491B1 (en) 1991-01-28 1992-01-28 Hydraulic control system in hydraulic construction machine
DE (2) DE69220293T2 (en)
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JP3646812B2 (en) * 1995-05-02 2005-05-11 株式会社小松製作所 Control circuit for mobile crusher
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JP3622142B2 (en) * 1999-08-04 2005-02-23 新キャタピラー三菱株式会社 Working arm control device for work machine
JP3390707B2 (en) * 1999-10-19 2003-03-31 住友建機製造株式会社 Control equipment for construction machinery
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JP5914510B2 (en) * 2011-10-20 2016-05-11 日立建機株式会社 Hydraulic drive device for electric hydraulic work machine
US9671763B2 (en) * 2012-01-05 2017-06-06 Hitachi Construction Machinery Co., Ltd. Device for controlling construction machinery
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JP2831377B2 (en) * 1988-07-04 1998-12-02 日立建機株式会社 Engine speed control device for construction machinery
KR940008638B1 (en) * 1988-07-08 1994-09-24 오까다 하지메 Hydraulic driving apparatus
JP2615207B2 (en) * 1988-07-08 1997-05-28 日立建機株式会社 Hydraulic drive
JP2721384B2 (en) * 1989-02-20 1998-03-04 日立建機株式会社 Hydraulic circuit of work machine
JP2840957B2 (en) * 1989-03-31 1998-12-24 株式会社 小松製作所 Variable circuit of pump discharge volume in closed center load sensing system
1992-01-28 KR KR92702343A patent/KR970000491B1/en not_active IP Right Cessation
1992-01-28 DE DE1992620293 patent/DE69220293T2/en not_active Expired - Fee Related
1992-01-28 DE DE1992631776 patent/DE69231776T2/en not_active Expired - Fee Related
EP0522171B1 (en) 1997-06-11
EP0791771B1 (en) 2001-09-05 Method of controlling speed change of hydraulic drive device for vehicle and speed change device
KR100486453B1 (en) 2005-04-29 Hydraulic traveling vehicle and method of controlling speed of prime mover of hydraulic traveling vehicle
1992-11-13 A201 Request for examination
1996-12-18 G160 Decision to publish patent application
1997-03-31 E701 Decision to grant or registration of patent right