WO2009093399A1 - 合流制御システム - Google Patents
合流制御システム Download PDFInfo
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- WO2009093399A1 WO2009093399A1 PCT/JP2008/073087 JP2008073087W WO2009093399A1 WO 2009093399 A1 WO2009093399 A1 WO 2009093399A1 JP 2008073087 W JP2008073087 W JP 2008073087W WO 2009093399 A1 WO2009093399 A1 WO 2009093399A1
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- flow rate
- pressure
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- command
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B11/00—Servomotor systems without provision for follow-up action; Circuits therefor
- F15B11/16—Servomotor systems without provision for follow-up action; Circuits therefor with two or more servomotors
- F15B11/17—Servomotor systems without provision for follow-up action; Circuits therefor with two or more servomotors using two or more pumps
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B2211/00—Circuits for servomotor systems
- F15B2211/20—Fluid pressure source, e.g. accumulator or variable axial piston pump
- F15B2211/205—Systems with pumps
- F15B2211/20507—Type of prime mover
- F15B2211/20515—Electric motor
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B2211/00—Circuits for servomotor systems
- F15B2211/20—Fluid pressure source, e.g. accumulator or variable axial piston pump
- F15B2211/205—Systems with pumps
- F15B2211/2053—Type of pump
- F15B2211/20538—Type of pump constant capacity
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B2211/00—Circuits for servomotor systems
- F15B2211/20—Fluid pressure source, e.g. accumulator or variable axial piston pump
- F15B2211/205—Systems with pumps
- F15B2211/2053—Type of pump
- F15B2211/20546—Type of pump variable capacity
- F15B2211/20553—Type of pump variable capacity with pilot circuit, e.g. for controlling a swash plate
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B2211/00—Circuits for servomotor systems
- F15B2211/20—Fluid pressure source, e.g. accumulator or variable axial piston pump
- F15B2211/205—Systems with pumps
- F15B2211/20576—Systems with pumps with multiple pumps
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B2211/00—Circuits for servomotor systems
- F15B2211/20—Fluid pressure source, e.g. accumulator or variable axial piston pump
- F15B2211/255—Flow control functions
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B2211/00—Circuits for servomotor systems
- F15B2211/20—Fluid pressure source, e.g. accumulator or variable axial piston pump
- F15B2211/26—Power control functions
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B2211/00—Circuits for servomotor systems
- F15B2211/20—Fluid pressure source, e.g. accumulator or variable axial piston pump
- F15B2211/265—Control of multiple pressure sources
- F15B2211/2654—Control of multiple pressure sources one or more pressure sources having priority
Definitions
- the present invention relates to a merging control system used for, for example, a hydraulic device such as an injection molding machine or a press machine.
- FIG. 5 this type of merging control system is shown in FIG. 5 (see Japanese Patent Laid-Open No. 4-78306).
- an electromagnetic proportional valve 110 is connected to the discharge line 103 of the variable displacement pump 101, and the discharge line 103a of the fixed displacement pump 104 is merged with the discharge line 103.
- a check valve 105 is provided in the discharge line 103a, and an unload valve 106 is connected thereto. The unload valve 106 is controlled by the output from the comparator 111.
- a swash plate driving cylinder 108 that drives the swash plate of the variable displacement pump 101 is controlled by a swash plate control valve 109.
- the unload valve 106 When the flow rate command value qref input to the comparator 111 is smaller than a predetermined value, the unload valve 106 is turned off, the position N1 is reached, and the oil discharged from the fixed displacement pump 104 is returned to the tank 102 and is variable. Only the oil discharged by the displacement pump 101 is sent to the actuator. At this time, the electromagnetic proportional valve 110 has an opening corresponding to the flow rate command value qref, and the swash plate control valve 109 is operated so that the differential pressure before and after the electromagnetic proportional valve 110 becomes constant, so that the swash plate is driven. The discharge amount of the variable displacement pump 101 is controlled via the cylinder 108.
- the unload valve 106 is turned on by the signal from the comparator 111 and the position N2 is reached. Become.
- the fixed displacement pump 104 and the tank 102 are disconnected, and the oil discharged from the fixed displacement pump 104 is sent to the discharge line 103 via the check valve 105, and the variable displacement pump 101 discharges. Merge with the oil to be used.
- the oil discharge flow rate q is continuously increased up to the total capacity of the capacity of the variable displacement pump 101 and the capacity of the fixed displacement pump 104 as shown in FIG. Can be controlled.
- the oil from the variable displacement pump 101 and the oil from the fixed displacement pump 104 merge after the discharge amount of the variable displacement pump 101 reaches the limit.
- the flow rate of oil increases rapidly immediately after the merge. That is, in the transition region 50 where the oil supply state by only the variable displacement pump 101 shifts to the oil supply state by both the variable displacement pump 101 and the fixed displacement pump 104, the oil flow rate and pressure increase rapidly. Shock.
- a similar problem may occur when shifting from the oil supply state by both the variable displacement pump 101 and the fixed displacement pump 104 to the oil supply state by only the variable displacement pump 101.
- an object of the present invention is to provide a merging control system capable of smoothly transitioning without a shock when switching between a single operation and a merging operation in a merging control system that merges liquids discharged from a plurality of pumps. It is in.
- the merge control system of the present invention is A first variable flow rate control device capable of discharging the liquid to the first discharge line by controlling the flow rate;
- a second variable flow rate control device capable of discharging the liquid by controlling the flow rate to the second discharge line that merges with the first discharge line;
- a check valve provided in the second discharge line so that a flow from the second variable flow control device to the first discharge line is in a forward direction;
- a pressure sensor for detecting the pressure of the first discharge line;
- Pressure flow control that receives one pressure command, one flow command, and a signal representing the detected pressure from the pressure sensor, and outputs an operation amount for obtaining a pressure and a flow corresponding to the pressure command and the flow command.
- the first variable flow control device When the operation amount is received from the pressure flow control unit and the operation amount is equal to or less than a predetermined set value, the first variable flow control device is a liquid whose flow rate changes continuously according to the operation amount.
- the first and second speed signals are generated based on the manipulated variables so that the second variable flow control device does not discharge liquid and output to the first and second variable flow control devices, respectively.
- the operation amount exceeds the set value, the first and second variable flow rate control devices discharge liquid so that the total flow rate changes continuously according to the operation amount.
- an operation amount distribution unit that generates the first and second speed signals based on the operation amount and outputs the first and second speed signals to the first and second variable flow rate control devices, respectively.
- the pressure flow control unit receives one pressure command, one flow command, and a signal representing the detected pressure from the pressure sensor, and receives a pressure corresponding to the pressure command and the flow command.
- An operation amount for obtaining a flow rate is output to the operation amount distribution unit.
- the operation amount distribution unit discharges liquid with a flow rate that the first variable flow rate control device continuously changes according to the operation amount;
- the first and second speed signals are generated based on the manipulated variable and output to the first and second variable flow control devices, respectively.
- the first and second variable flow rate control devices cause the first and second speeds to discharge liquid whose total flow rate changes continuously according to the manipulated variable.
- a signal is created based on the manipulated variable and is output to the first and second variable flow control devices.
- the discharge flow rate from the first variable flow rate control device and the discharge flow rate from the second variable flow rate control device are merged, and the operation amount is distributed by the operation amount distribution unit. Since the first and second variable flow rate control devices are controlled by the first and second speed signals, there is no shock when switching between the single operation and the merge operation, and the transition between the single operation and the merge operation is performed. Can be smooth.
- the operation amount distribution unit is provided at the subsequent stage of the pressure flow control unit, when the flow rate is reduced to a predetermined value or less by the pressure flow control unit, Since the operation of the second variable flow control device is stopped, energy saving can be achieved.
- the manipulated variable distribution unit When the manipulated variable is less than or equal to the set value, the manipulated variable distribution unit outputs the manipulated variable as a first speed signal to the first variable flow control device, and outputs a second speed signal that is zero.
- the manipulated variable exceeds the set value while being output to the second variable flow control device, the set value is output to the first variable flow control device as a first speed signal, and the manipulated variable is A value obtained by subtracting the set value is output as a second speed signal to the second variable flow control device.
- the operation amount when the operation amount is equal to or less than the set value, the operation amount is set to the first speed signal, the second speed signal is set to zero, and the operation amount exceeds the set value.
- the set value is used as the first speed signal, and the value obtained by subtracting the set value from the manipulated variable is used as the second speed signal. Therefore, the first and second speed signals can be created with a simple calculation. can do.
- the first and second variable flow rate control devices include a fixed displacement pump and a servo motor that drives the fixed displacement pump.
- the first and second variable flow rate control devices are composed of the fixed displacement pump and the servo motor that drives the fixed displacement pump, so the structure is simple and inexpensive.
- the pressure flow control unit limits the value calculated by the pressure control calculation based on the pressure command and a signal representing the detected pressure from the pressure sensor so as not to exceed a value corresponding to the flow command.
- the value calculated by the pressure control calculation is limited so as not to exceed the value according to the flow rate command, when the pressure is lower than the target value by a simple calculation, automatic The flow rate is controlled.
- One embodiment is: When a control signal indicating activation or stop of the first variable flow control device is received and a signal indicating an operation amount is received from the pressure flow control unit, and the operation amount is equal to or smaller than a threshold value smaller than the set value.
- a control signal indicating stop is output to the second variable flow rate control device, while a control signal indicating drive is output to the second variable flow rate control device when the manipulated variable exceeds the threshold value.
- a distribution unit is provided.
- the control signal distribution unit when the operation amount is equal to or smaller than a threshold value smaller than the set value, the control signal distribution unit outputs a control signal indicating control stop to the second variable flow control device. Therefore, power consumption can be reduced, energy saving can be achieved, and when the manipulated variable exceeds the threshold value, a control signal indicating the start of control is output to the second variable flow rate control device to enter a standby state. Therefore, when the second variable flow control device is started, the response is good and no shock occurs.
- the pressure flow control unit is Based on the pressure command, the flow rate command, and a signal representing the operation amount from the pressure flow control unit, a cutoff characteristic of the pressure override in the pressure flow characteristic diagram is set, and this cutoff characteristic is given.
- a cut-off characteristic setting unit that outputs a pressure command is included.
- the pressure flow control unit includes a cutoff characteristic setting unit that outputs a pressure command to which a cutoff characteristic is given, the cutoff width can be freely adjusted to improve the stability of the system. Can be increased.
- the cut-off characteristic setting unit calculates a pressure command to which the cut-off characteristic is given according to the following formulas (1) and (2).
- Pi_C is a pressure command with a cutoff characteristic
- Vq is an operation amount output from the pressure flow control unit
- Pi is the pressure command
- Qi is the flow rate command
- CF is a predetermined constant and represents the cut-off width.
- the cut-off characteristic is given by the above formulas (1) and (2), and therefore the cut-off characteristic can be given by a simple calculation.
- the discharge flow rate from the first variable flow rate control device and the discharge flow rate from the second variable flow rate control device are merged, and the operation amount is distributed by the operation amount distribution unit. Since the first and second variable flow rate control devices are continuously controlled by the two-speed signal, the transition between the single operation and the merge operation can be smoothly performed without causing a shock.
- the operation amount distribution unit is provided at the subsequent stage of the pressure flow control unit, when the flow rate is reduced to a predetermined value or less by the pressure flow control unit, Since the operation of the second variable flow control device is stopped, energy saving can be achieved.
- FIG. 1 is a block diagram of a merging control system according to one embodiment of the present invention.
- FIG. 2 is a diagram illustrating a flow rate characteristic between the flow rate command and the flow rate.
- FIG. 3 is a diagram showing a pressure flow characteristic between the pressure and the flow rate.
- FIG. 4 is an enlarged view of FIG.
- FIG. 5 is a hydraulic circuit diagram of a conventional merging control system.
- FIG. 6 is a graph showing the relationship between the flow rate command value and the discharge flow rate of the conventional merging control system.
- this merging control system includes a first variable flow control device 1, a second variable flow control device 2, a pressure flow control unit 40, and a signal distribution unit 50.
- the first variable flow rate control device 1 includes a first fixed displacement pump 11, a first motor 12 that drives the first fixed displacement pump 11, a first driver 13 that drives the first motor 12, And an encoder 14 that detects the rotation angle of the first motor 12, and controls the rotation speed of the first motor 12 to control the flow rate of the hydraulic oil as an example of the liquid from the first fixed displacement pump 11. To be discharged.
- the first motor 12, the first driver 13, and the encoder 14 constitute an example of a servo motor.
- the second variable flow rate control device 2 includes a second fixed displacement pump 21, a second motor 22 that drives the second fixed displacement pump 21, and a second driver 23 that drives the second motor 22. And an encoder 24 for detecting the rotation angle of the second motor 22 and controlling the rotation speed of the second motor 22 to discharge the hydraulic oil from the second fixed displacement pump 21 while controlling the flow rate. It is like that.
- the second motor 22, the second driver 23, and the encoder 24 constitute an example of a servo motor.
- the first and second fixed displacement pumps 11 and 21 are used in the first and second variable flow rate control devices 1 and 2 without using the variable displacement pumps.
- the structure becomes simple.
- the first fixed displacement pump 11 of the first variable flow control device 1 discharges hydraulic oil to the first discharge line 10 and supplies it to the main hydraulic circuit 5.
- the pressure of the hydraulic oil in the first discharge line 10 is detected by the pressure sensor 7.
- the second fixed displacement pump 21 of the second variable flow control device 2 discharges hydraulic oil to the second discharge line 20 that joins the first discharge line 10.
- the second discharge line 20 is provided with a check valve 6 in which the flow from the second fixed displacement pump 21 of the second variable flow rate control device 2 to the first discharge line 10 becomes a forward direction. Therefore, the hydraulic oil is prevented from flowing back to the second discharge line 20.
- the pressure flow control unit 40 receives one pressure command Pi, one flow command Qi, and a signal representing the detected pressure from the pressure sensor 7, and responds to the pressure command Pi and the flow command Qi.
- the operation amount Vq for obtaining the obtained pressure and flow rate is calculated and output to the signal distribution unit 50.
- the pressure flow control unit 40 includes a cut-off characteristic setting unit 41, a joining point 42, a pressure control calculation unit 43, and a speed limiter 45.
- the cut-off characteristic setting unit 41 receives the pressure command Pi, the flow rate command Qi, and the manipulated variable Vq, and the detected pressure (load pressure) detected by the pressure sensor 7 is the maximum command pressure (maximum target pressure). ) Exceeding 90%, for example, as shown in FIGS. 3 and 4, the pressure command Pi and the flow command Qi are controlled so that the same cut-off control as the flow command Qi is substantially cut off is performed. Based on the operation amount Vq, the pressure command Pi_C to which the cut-off characteristic is given is calculated and output to the joining point 42.
- the pressure command Pi_C to which this cutoff characteristic is given is calculated by the following formulas (1) and (2).
- Pi_C is a pressure command with a cutoff characteristic
- Vq is an operation amount output from the pressure flow control unit 40
- Pi is the pressure command
- Qi is the flow rate command
- CF is a predetermined constant and represents the cut-off width.
- the pressure command Pi_C to which the cut-off characteristic is given can be obtained by the simple calculation according to the above formulas (1) and (2).
- the cutoff width (difference between the target pressure and the pressure at which the cutoff control is started) CF is set to 10% of the maximum target pressure.
- the cut-off width CF is generally set to 5 to 10% of the maximum target pressure, but if it is smaller than that, the control tends to become unstable.
- Vq ⁇ 0 of Vq ⁇ 0 means a pressure holding state (in the main engine hydraulic circuit 5, a hydraulic cylinder (not shown) is pressed toward the load at a high pressure, but is moving.
- the pressure command Pi is lowered in order to lower the pressure of the first discharge line 10 from the state of no)
- this corresponds to a state in which the first motor 12 is reversely rotated to lower the load pressure.
- the pressure axis and the flow axis are both expressed as% of the maximum value
- the broken line indicates the flow rate of the first fixed displacement pump 11
- the alternate long and short dash line indicates the flow rate of the second fixed displacement pump 21.
- the solid line represents the total flow rate of the first and second fixed displacement pumps 11 and 21. 4 is an enlarged view of a main part of FIG.
- the method of providing the cut-off characteristic is not limited to the above formulas (1) and (2), and various known methods are possible.
- the operation amount is such that the control along the solid line in FIGS. 3 and 4 is performed based on the flow rate command, the pressure command, and the detection value from the pressure sensor.
- the obtained formula may be used, or a storage device storing a lookup table that draws a solid line in FIGS. 3 and 4 may be used.
- the cut-off characteristic setting unit itself may be omitted, and the cut-off characteristic may be given by the characteristic of a relief valve or the like.
- the joining point 42 outputs a signal obtained by subtracting the detection signal from the pressure sensor 7 from the pressure command Pi_C to which the cutoff characteristic is given to the pressure control calculation unit 43.
- the pressure control calculation unit 43 receives a signal from the adding point 42, performs, for example, PID (proportional integral differentiation) control calculation, and outputs the obtained pressure signal Vp to the speed limiter 45.
- PID proportional integral differentiation
- the pressure control calculation unit 43 may perform other known pressure control calculations such as a PI (proportional integral) control calculation.
- the speed limiter 45 limits the pressure signal Vp from the pressure control calculation unit 43 so as not to exceed a value corresponding to the flow rate command Qi, and outputs an operation amount Vq.
- the operation amount Vq is obtained by limiting the pressure signal Vp from the pressure control calculation unit 43 so as not to exceed the value according to the flow rate command Qi.
- the flow rate is automatically controlled.
- the signal distribution unit 50 includes an operation amount distribution unit 51 and a control signal distribution unit 52.
- the operation amount distribution unit 51 distributes the operation amount Vq to the first speed signal V1 and the second speed signal V2 according to the rules described later, and the first speed signal V1 and the second speed signal V2 Output to the first driver 13 of the variable flow control device 1 and the second driver 23 of the second variable flow control device 2, respectively.
- the control signal distribution unit 52 receives the control signal S1 and the operation amount Vq, generates a control signal S2 according to the rules described later, and distributes the control signal S2 to the second driver 23 of the second variable flow rate control device 2, that is, ,Output.
- the operation amount distribution unit 51 uses the operation amount Vq as a first speed signal V1 for the first variable. While outputting to the 1st driver 13 of the flow control apparatus 1 and outputting the 2nd speed signal V2 which is zero to the 2nd driver 23 of the 2nd variable flow control apparatus 2, the said operation amount Vq is the said setting value Vmax1. Is exceeded, the set value Vmax1 is output as the first speed signal V1 to the first driver 13 of the first variable flow control device 1, and the value obtained by subtracting the set value Vmax1 from the manipulated variable Vq. (Vq ⁇ Vmax1) is output as the second speed signal V2 to the second driver 23 of the second variable flow control device 2.
- the operation amount distribution unit 51 generates the first and second speed signals V1 and V2 by the following speed distribution algorithm.
- Vq is the operation amount
- Vmax1 is the maximum speed of the first motor 12 of the first variable flow control device 1
- V1 is the first speed signal
- V2 is a second speed signal.
- both the flow rate command and the flow rate are expressed as% of the maximum value
- the broken line represents the flow rate of the first fixed displacement pump 11
- the alternate long and short dash line represents the flow rate of the second fixed displacement pump 21.
- the solid line represents the total flow rate of the first and second fixed displacement pumps 11 and 21.
- the manipulated variable distributor 51 outputs the first speed signal V1.
- the operation amount distribution unit 51 drives only the first motor 12 with the first speed signal V1 via the first driver 13 when the operation amount Vq is equal to or less than the maximum speed Vmax1 of the first motor 12.
- the operation amount Vq exceeds the maximum speed Vmax1 of the first motor 12
- the first motor 12 is driven at the maximum speed Vmax1 via the first driver 13
- the second motor 22 is driven to the second driver 23.
- V2 Vq-Vmax1
- the operation amount distribution unit 51 can obtain the first and second speed signals V1 and V2 by a simple calculation.
- the control signal distribution unit 52 includes a first control signal S1 that represents turning on (ON) or turning off (OFF) to bring the first driver 13 of the first variable flow control device 1 into an activated state or a stopped state.
- the signal representing the operation amount Vq from the pressure flow control unit 40 is received.
- the first control signal S1 being OFF does not mean that the speed of the first motor 12 is controlled to zero, but it means that the control of the first motor 12 itself is stopped.
- the control signal distribution unit 52 outputs an OFF second control signal S2 indicating a stop state to the second driver 23 of the second variable flow control device 2.
- control signal distribution unit 52 has a predetermined threshold value (Vmax1) when the first control signal S1 is ON and the operation amount Vq received from the pressure flow control unit 40 is smaller than the set value (Vmax1). ) / 2 or less, when the second control signal S2 of OFF is output to the second driver 23 of the second variable flow control device 2, while the manipulated variable Vq exceeds the threshold value (Vmax1) / 2, An ON second control signal S ⁇ b> 2 representing the activated state is output to the second driver 23 of the second variable flow control device 2.
- the threshold value (Vmax1) / 2 is a value corresponding to 1/2 of the maximum speed Vmax1 of the first motor 12 corresponding to the set value.
- control signal distribution unit 52 creates the second control signal S2 by the following control signal distribution algorithm and outputs the second control signal S2 to the second driver 23 of the second variable flow control device 2.
- Vq is the operation amount
- Vmax1 is the maximum speed of the first motor 12 of the first variable flow control device 1.
- the control signal distributor 52 turns off the second control signal S2 and performs the second variable flow rate control. Energy saving can be achieved by turning off the second driver 23 of the device 2 so as not to consume power.
- the cutoff characteristic setting unit 41 includes the pressure command Pi, Based on the flow rate command Qi and the manipulated variable Vq, the pressure command Pi_C to which the cutoff characteristic is given is calculated by the following formulas (1) and (2).
- the pressure command Pi_C is input to the joining point 42 from the cut-off characteristic setting unit 41. Then, at the joining point 42, the detection signal from the pressure sensor 7 is subtracted from the pressure command Pi_C, and the obtained signal is input from the joining point 42 to the pressure control calculation unit 43.
- the pressure control calculation unit 43 receives a signal from the joining point 42, performs PID (proportional integral derivative) control, and inputs the obtained pressure signal Vp to the speed limiter 45.
- PID proportional integral derivative
- the speed limiter 45 limits the pressure signal Vp from the pressure control calculation unit 43 so as not to exceed a value corresponding to the flow rate command Qi, obtains an operation amount Vq, and obtains the operation amount Vq as a signal.
- the data is output to the distribution unit 50.
- the operation amount distribution unit 51 of the signal distribution unit 50 uses the following speed distribution algorithm based on the operation amount Vq and the maximum speed Vmax1 of the first motor 12 as a set value, and the first and second speed signals V1, Create V2.
- the operation amount distribution unit 51 outputs the first speed signal V1.
- the operation amount distribution unit 51 drives only the first motor 12 with the first speed signal V1 via the first driver 13 when the operation amount Vq is equal to or less than the maximum speed Vmax1 of the first motor 12.
- the operation amount Vq exceeds the maximum speed Vmax1 of the first motor 12
- the first motor 12 is driven at the maximum speed Vmax1 via the first driver 13
- the second motor 22 is driven to the second driver 23.
- V2 Vq-Vmax1
- an operation amount distribution unit 51 is provided at the subsequent stage of the pressure flow control unit 40, and the operation amount Vq from the pressure flow control unit 40 is distributed so that the first speed signal V1 and the second speed Since the signal V2 is generated and inputted to the first and second drivers 13 and 23, as can be seen from FIG. 4, which is an enlarged view of the main part of FIG. 3, the pressure is (Pi-CF ), The rotational speed of the second motor 22 gradually decreases, the discharge flow rate of the second fixed displacement pump 21 gradually decreases from 60%, the pressure is 96%, and the discharge flow rate is zero. become.
- the first motor 12 rotates at a constant rotational speed until the pressure reaches 96%, and the discharge flow rate of the first fixed displacement pump 11 is constant at 40%, but when the pressure exceeds 96%.
- the rotational speed of the first motor 12 gradually decreases, the discharge flow rate of the first fixed displacement pump 11 gradually decreases from 40%, and the discharge flow rate becomes zero when the pressure is 100%.
- the operation amount distribution unit 51 provided at the subsequent stage of the pressure flow control unit 40 distributes the operation amount Vq from the pressure flow control unit 40 to generate the first speed signal V1 and the second speed signal V2. Therefore, when the flow rate is reduced at a high pressure of 96% or more due to the cut-off characteristic, the operation of the second fixed displacement pump 21 stops, that is, the discharge of the second fixed displacement pump 21. Since the amount is zero when the pressure is in the range of 96 to 100%, energy saving can be achieved.
- both the first fixed displacement pump 11 and the second fixed displacement pump 21 are driven until the pressure is about 100%. It becomes impossible to achieve energy saving.
- control signal distribution unit 52 creates the second control signal S2 by the following control signal distribution algorithm and outputs the second control signal S2 to the second driver 23 of the second variable flow control device 2.
- Vq is the operation amount
- Vmax1 is the maximum speed of the first motor 12 of the first variable flow control device 1.
- the control signal distributor 52 turns off the second control signal S2 and performs the second variable flow rate control. Energy saving is achieved by turning off the second driver 23 of the device 2 so as not to consume power.
- the control signal distributor 52 turns on the second control signal S2 to turn on the second variable flow rate control device 2.
- the second motor 22 can be driven with good responsiveness by receiving and operating. Accordingly, from a single operation in which hydraulic oil is discharged only from the first fixed displacement pump 11 of the first variable flow control device 1, the first fixed displacement pump 11 and the second variable flow of the first variable flow control device 1 are discharged. As shown in FIG. 2, it is possible to make the transition to the merging operation of merging the hydraulic oil from the second fixed displacement pump 21 of the control device 2 smooth and smooth.
- variable flow rate control device 1 and the second variable flow rate control device 2 are used.
- third variable flow rate control device, the fourth variable flow rate control device, etc. Discharge hydraulic fluids such as the variable flow rate control device and the fourth variable flow rate control device may be joined to the first discharge line 10 via check valves, respectively.
- the operation amount distribution unit 51 is based on the operation amount Vq and the maximum speed Vmax1 of the first motor 12 as a predetermined set value.
- the set value may be slightly smaller than the maximum rotational speed Vmax1 of the first motor 12.
- the speed distribution algorithm of the operation amount distribution unit is not limited to the above example.
- the first variable flow control device 1 when the operation amount is equal to or less than a predetermined set value, the first variable flow control device 1 operates the operation amount.
- the first and second speed signals are generated based on the manipulated variable so that the second variable flow rate control device 2 does not discharge the liquid, while discharging the liquid whose flow rate is continuously changed according to the above.
- the first and second variable flow rate control devices 1 and 2 are configured to discharge liquid so that the total flow rate changes continuously according to the operation amount.
- the characteristics are not limited to the above example, and the characteristics can be expressed by broken lines, curves, etc. having many inflection points. Also good.
- the maximum rotational speeds Vmax1, Vmax2 of the first and second motors 12, 22 and the discharge capacities Vcc1, Vcc2 of the first and second fixed displacement pumps 11, 21 may be arbitrary values. In this case, switching between the independent operation and the merge operation is performed at the location of the flow rate command of% divided by the ratio of Vmax1 ⁇ Vcc1: Vmax2 ⁇ Vcc2.
- pressure flow control unit 40 and the signal distribution unit 50 of the above embodiment may be configured by software, may be configured by a digital circuit, or may be configured by an analog circuit.
- the first and second fixed displacement pumps 11 and 21 are used. However, it is also possible to control the discharge amount by using one of them as a variable displacement pump.
- an inverter can be used as a driver.
- a current sensor that detects the driving current of the first motor 12 and indirectly detects the pressure of the first discharge line 10 may be used.
- the liquid is hydraulic oil, but not limited to hydraulic oil, any liquid can be used, and the present invention can be applied to any hydraulic system.
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Abstract
Description
第1吐出ラインに液体を流量制御して吐出し得る第1可変流量制御装置と、
上記第1吐出ラインに合流する第2吐出ラインに液体を流量制御して吐出し得る第2可変流量制御装置と、
上記第2吐出ラインに、上記第2可変流量制御装置から第1吐出ラインへの流れが順方向になるように設けられたチェック弁と、
上記第1吐出ラインの圧力を検出する圧力センサと、
1つの圧力指令、1つの流量指令、および、上記圧力センサからの検出圧力を表す信号を受けて、上記圧力指令および流量指令に応じた圧力および流量を得るための操作量を出力する圧力流量制御部と、
上記圧力流量制御部から操作量を受けて、上記操作量が、予め定められた設定値以下であるときには、上記第1可変流量制御装置が、操作量に応じて連続的に流量が変化する液体を吐出すると共に、上記第2可変流量制御装置が液体を吐出しないように、第1および第2速度信号を上記操作量に基づいて作成して上記第1および第2可変流量制御装置に夫々出力する一方、上記操作量が、上記設定値を越えたときには、上記第1および第2可変流量制御装置が、合計流量が操作量に応じて連続的に変化するように、夫々液体を吐出するように、第1および第2速度信号を上記操作量に基づいて作成して上記第1および第2可変流量制御装置に夫々出力する操作量分配部と
を備えることを特徴としている。
上記操作量分配部は、上記操作量が、上記設定値以下であるときには、その操作量を第1速度信号として上記第1可変流量制御装置に出力すると共に、零である第2速度信号を上記第2可変流量制御装置に出力する一方、上記操作量が、上記設定値を越えたときには、その設定値を第1速度信号として上記第1可変流量制御装置に出力すると共に、上記操作量から上記設定値を減算して得られた値を第2速度信号として上記第2可変流量制御装置に出力する。
上記第1および第2可変流量制御装置は、固定容量形ポンプとその固定容量形ポンプを駆動するサーボモータから構成されている。
上記圧力流量制御部は、上記圧力指令、および、上記圧力センサからの検出圧力を表す信号に基づく圧力制御演算により算出された値が上記流量指令に応じた値を越えないように制限する。
上記第1可変流量制御装置の起動または停止を表す制御信号を受けると共に、上記圧力流量制御部から操作量を表す信号を受けて、上記操作量が、上記設定値よりも小さな閾値以下であるときに、停止を表す制御信号を上記第2可変流量制御装置に出力する一方、上記操作量が上記閾値を越えたときに、駆動を表す制御信号を上記第2可変流量制御装置に出力する制御信号分配部を備える。
上記圧力流量制御部は、
上記圧力指令、上記流量指令、および、上記圧力流量制御部からの操作量を表す信号に基づいて、圧力流量特性図における圧力オーバライドのカットオフ特性を設定して、このカットオフ特性が付与された圧力指令を出力するカットオフ特性設定部を含む。
上記カットオフ特性設定部は、下記の式(1)、(2)により、カットオフ特性が付与された圧力指令を算出する。
0 <Vq ≦ Qi → Pi_C = ( Pi×Qi - CF×Vq ) / Qi (2)
ここで、Pi_Cは、カットオフ特性が付与された圧力指令、
Vqは、上記圧力流量制御部から出力される操作量、
Piは、圧力指令、
Qiは、流量指令、
CFは、予め定められた定数で、カットオフ幅を表す。
0 <Vq ≦ Qi → Pi_C = ( Pi×Qi - CF×Vq ) / Qi (2)
ここで、Pi_Cは、カットオフ特性が付与された圧力指令、
Vqは、上記圧力流量制御部40から出力される操作量、
Piは、圧力指令、
Qiは、流量指令、
CFは、予め定められた定数で、カットオフ幅を表す。
Vmax1 < Vq → V1 = Vmax1, V2 = Vq - Vmax1
ここで、Vqは、操作量、
Vmax1は、第1可変流量制御装置1の第1モータ12の最高速度、
V1は、第1速度信号、
V2は、第2速度信号である。
S1 = ON → Vq ≦ (Vmax1)/2 → S2 = OFF
(Vmax1)/2 < Vq → S2 = ON
ここで、Vqは、操作量、
Vmax1は、第1可変流量制御装置1の第1モータ12の最高速度である。
0 <Vq ≦ Qi → Pi_C = ( Pi×Qi - CF×Vq ) / Qi (2)
Vmax1 < Vq → V1 = Vmax1, V2 = Vq - Vmax1
S1 = ON → Vq ≦ (Vmax1)/2 → S2 = OFF
(Vmax1)/2 < Vq → S2 = ON
ここで、Vqは、操作量、
Vmax1は、第1可変流量制御装置1の第1モータ12の最高速度である。
Vq ≦ Vmax1 → V1 = Vq, V2 = 0
Vmax1 < Vq → V1 = Vmax1, V2 = Vq - Vmax1
という速度分配アルゴリズムで、第1および第2速度信号V1,V2を作成したが、上記設定値は、上記第1モータ12の最高回転速度Vmax1よりも若干小さな値にしてもよい。
Claims (7)
- 第1吐出ライン(10)に液体を流量制御して吐出し得る第1可変流量制御装置(1)と、
上記第1吐出ライン(10)に合流する第2吐出ライン(20)に液体を流量制御して吐出し得る第2可変流量制御装置(2)と、
上記第2吐出ライン(20)に、上記第2可変流量制御装置(2)から第1吐出ライン(10)への流れが順方向になるように設けられたチェック弁(6)と、
上記第1吐出ライン(10)の圧力を検出する圧力センサ(7)と、
1つの圧力指令(Pi)、1つの流量指令(Qi)、および、上記圧力センサ(7)からの検出圧力を表す信号を受けて、上記圧力指令(Pi)および流量指令(Qi)に応じた圧力および流量を得るための操作量(Vq)を出力する圧力流量制御部(40)と、
上記圧力流量制御部(40)から操作量(Vq)を受けて、上記操作量(Vq)が、予め定められた設定値以下であるときには、上記第1可変流量制御装置(1)が、操作量(Vq)に応じて連続的に流量が変化する液体を吐出すると共に、上記第2可変流量制御装置(2)が液体を吐出しないように、第1および第2速度信号(V1およびV2)を上記操作量(Vq)に基づいて作成して上記第1および第2可変流量制御装置(1および2)に夫々出力する一方、上記操作量(Vq)が、上記設定値を越えたときには、上記第1および第2可変流量制御装置(1および2)が、合計流量が操作量(Vq)に応じて連続的に変化するように、夫々液体を吐出するように、第1および第2速度信号(V1およびV2)を上記操作量(Vq)に基づいて作成して上記第1および第2可変流量制御装置(1および2)に夫々出力する操作量分配部(51)と
を備えることを特徴とする合流制御システム。 - 請求項1に記載の合流制御システムにおいて、
上記操作量分配部(51)は、上記操作量(Vq)が、上記設定値以下であるときには、その操作量(Vq)を第1速度信号(V1)として上記第1可変流量制御装置(1)に出力すると共に、零である第2速度信号(V2)を上記第2可変流量制御装置(2)に出力する一方、上記操作量(Vq)が、上記設定値を越えたときには、その設定値を第1速度信号(V1)として上記第1可変流量制御装置(1)に出力すると共に、上記操作量(Vq)から上記設定値を減算して得られた値を第2速度信号(V2)として上記第2可変流量制御装置(2)に出力することを特徴とする合流制御システム。 - 請求項1または2に記載の合流制御システムにおいて、
上記第1および第2可変流量制御装置(1および2)は、固定容量形ポンプ(11および21)とその固定容量形ポンプ(11および21)を駆動するサーボモータから構成されていることを特徴とする合流制御システム。 - 請求項1に記載の合流制御システムにおいて、
上記圧力流量制御部(40)は、上記圧力指令(Pi)、および、上記圧力センサ(7)からの検出圧力を表す信号に基づく圧力制御演算により算出された値が上記流量指令(Qi)に応じた値を越えないように制限することを特徴とする合流制御システム。 - 請求項1に記載の合流制御システムにおいて、
上記第1可変流量制御装置(1)の起動または停止を表す制御信号を受けると共に、上記圧力流量制御部(40)から操作量(Vq)を表す信号を受けて、上記操作量(Vq)が、上記設定値よりも小さな閾値以下であるときに、停止を表す制御信号を上記第2可変流量制御装置(2)に出力する一方、上記操作量(Vq)が上記閾値を越えたときに、駆動を表す制御信号を上記第2可変流量制御装置(2)に出力する制御信号分配部(52)を備えることを特徴とする合流制御システム。 - 請求項1に記載の合流制御システムにおいて、
上記圧力流量制御部(40)は、
上記圧力指令(Pi)、上記流量指令(Qi)、および、上記圧力流量制御部(40)からの操作量(Vq)を表す信号に基づいて、圧力流量特性図における圧力オーバライドのカットオフ特性を設定して、このカットオフ特性が付与された圧力指令を出力するカットオフ特性設定部(41)を含むことを特徴とする合流制御システム。 - 請求項6に記載の合流制御システムにおいて、
上記カットオフ特性設定部(41)は、下記の式(1)、(2)により、カットオフ特性が付与された圧力指令を算出することを特徴とする合流制御システム。
Vq ≦ 0 → Pi_C = Pi (1)
0 <Vq ≦ Qi → Pi_C = ( Pi×Qi - CF×Vq ) / Qi (2)
ここで、Pi_Cは、カットオフ特性が付与された圧力指令、
Vqは、上記圧力流量制御部(40)から出力される操作量、
Piは、圧力指令、
Qiは、流量指令、
CFは、予め定められた定数で、カットオフ幅を表す。
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