JP3931004B2 - Hybrid hydraulic system and hydraulic construction machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is suitable for use in a hydraulic system of a construction machine using a hydraulic mechanism such as a hydraulic excavator, and suitable for use in a hybrid hydraulic system using an engine and an electric motor as a pump drive source, and a hydraulic excavator. Of hydraulic construction machinery.
[0002]
[Prior art]
In construction machines such as excavators, there are a mechanical type and a hydraulic type as a mechanism, but a hydraulic type is mainstream because of advantages such as strength of excavation force and simplicity of structure. FIG. 5 is a system configuration diagram of a hydraulic system used in a construction machine using a hydraulic mechanism such as a conventional hydraulic excavator.
[0003]
As shown in FIG. 5, the conventional hydraulic system includes a hydraulic pump 31 and an engine (diesel engine) 32, and the hydraulic pump 31 is driven by the engine 32 to generate hydraulic pressure in the hydraulic oil ( The engine 32 is started by the cell motor 36). The magnitude of the generated hydraulic energy is determined in accordance with the work amount of the hydraulic pump 31. Here, the controller (control means) 30 controls the rotational speed of the engine 32, and when a large amount of hydraulic energy is required, the engine rotation is performed. The work speed of the hydraulic pump 31 is increased by increasing the speed. Conversely, when a large amount of hydraulic energy is not required, the work speed of the hydraulic pump 31 is decreased by decreasing the engine speed.
[0004]
The hydraulic oil thus generated is adjusted to a required flow rate through the control valve 33 and sent to each actuator 34, where it is converted into a mechanical movement of each device (for example, traveling device, turning device, working device). It has become so. The actuator 34 to be supplied with hydraulic energy is selected by operating the work lever 35. That is, an operation signal is transmitted to the control valve 33 by operating the work lever 35, and the control valve 33 moves the spool of the internal hydraulic circuit to supply hydraulic oil to the target actuator 34. is there.
[0005]
When hydraulic oil is being sent to the actuator 34, the hydraulic pressure increases. Therefore, by detecting the hydraulic pressure in the control valve 33, it is possible to determine whether or not the machine is working from its size. In the conventional hydraulic system shown in FIG. 5, a predetermined pressure switch 33a is provided in the internal hydraulic circuit of the control valve 33, and when the hydraulic pressure exceeds a predetermined value, a working signal indicating that the machine is working is transmitted to the controller. 30 is input.
[0006]
A typical example of how to use a construction machine having a hydraulic system as described above, for example, a hydraulic excavator, is a dump loading operation. Dump loading work is the work of digging soil with a hydraulic excavator and loading the excavated soil into the dump truck. Since the dump truck is replaced when the soil of the loading platform is full, the hydraulic excavator is used during the replacement. Is in a standby state.
[0007]
Since there is no work to the outside during this standby state, it is not necessary to drive the hydraulic pump 31 to generate hydraulic energy, and conversely, wasteful fuel for driving the hydraulic pump 31 is consumed. However, once the engine 32 is stopped, a loss time for starting operation occurs when the work is returned next time, and the engine 32 does not start rotating immediately after starting. Furthermore, it takes some time for the hydraulic pressure to rise to the required level after the engine 32 rotates, and further loss time will occur before returning to work. Also, if the engine 32 is stopped, comfort equipment such as an air conditioner will not work.
[0008]
As described above, when the engine 32 is stopped, wasteful fuel consumption is eliminated, but various problems occur. Therefore, conventionally, the engine 32 is not stopped during standby, but the rotational speed of the engine 32 is reduced, thereby reducing fuel consumption and immediately increasing the hydraulic pressure. Of course, the operation for reducing the engine rotation speed can be performed by the driver's operation of the throttle dial. However, in the conventional hydraulic system, the control for automatically reducing the engine rotation speed is performed in the standby state.
[0009]
This control is called auto engine control (AEC). As shown in FIG. 6, when a work signal is not input from the control valve 33 for a predetermined time (that is, when the work lever 35 is not operated for a predetermined time). ), A rotational speed command signal is transmitted from the controller 30 to the engine 32 to reduce the rotational speed of the engine 32. When a work signal is input from the control valve 33 (that is, when the work lever is operated), a rotation speed command signal is transmitted from the controller 30 to the engine 32 again to return to the original rotation speed. .
[0010]
[Problems to be solved by the invention]
However, in the control method (AEC) according to the conventional hydraulic system described above, the engine speed is reduced, but the engine 32 is still operating, and there is no wasted fuel consumption. is not. In addition, as long as the engine 32 is operating, noise and vibration are unavoidable. As described above, the conventional hydraulic system is insufficient in terms of both quick return to work after standby, reduction of fuel consumption in standby state, and reduction of noise vibration.
[0011]
The present invention has been devised in view of such problems, and by using an engine and an electric motor together as a pump drive source, quick return to work after standby, fuel waste and noise vibration in the standby state can be achieved. It is an object of the present invention to provide a hybrid hydraulic system and a hydraulic construction machine that can achieve both significant reduction.
[0012]
[Means for Solving the Problems]
  For this reason, in the hybrid hydraulic system of the present invention, an actuator that converts hydraulic pressure into mechanical movement, a hydraulic pump that supplies hydraulic oil to the actuator, an engine that drives the hydraulic pump, an output shaft of the engine, and the A clutch interposed between the input shaft of the hydraulic pump, an electric motor connected to the input shaft of the hydraulic pump, load detecting means for detecting or estimating a load state of the actuator, and the load detecting means Control means for integrally controlling start and stop of the engine, start and stop of the electric motor, and connection and disconnection of the clutch based on the detected or estimated load state of the actuator.When the load state of the actuator detected or estimated by the load detection unit is no load by the control unit, the clutch is disconnected, the engine is stopped, the electric motor is operated, Control to drive the hydraulic pump by an electric motorIt is characterized by that.
[0013]
  MaPreferably, a flywheel is provided between the clutch and the hydraulic pump.2More preferably, the flywheel is configured as a power transmission member for transmitting power from the electric motor to the input shaft of the hydraulic pump.3).
[0014]
  In addition, after the clutch is disengaged and the engine is stopped by the control means, the electric motor is controlled to drive the hydraulic pump when the rotational speed of the hydraulic pump becomes a predetermined value or less. (Claims)4).
  Further, a rotation speed adjusting means for adjusting the rotation speed of the electric motor is provided, and when the hydraulic pump is driven by the electric motor, the rotation speed of the hydraulic pump is lower than the rotation speed during normal operation. It is preferable to control the rotation speed adjusting means so that the rotation speed is maintained at a predetermined speed.5).
[0015]
  In addition, an operating means for an operator to operate the actuator is provided, and when the operating lever is operated in a direction to operate the actuator by the control means, the clutch is connected to start the engine, and the electric motor It is preferable to perform control to stop the driving of the hydraulic pump by6In this case, it is more preferable that the control means controls the hydraulic pump to be driven by the electric motor for a predetermined time after starting the engine and connecting the clutch.7).
[0016]
  A plurality of the actuators, and a control valve that is interposed between the hydraulic pump and the plurality of actuators, and that feeds hydraulic oil supplied from the hydraulic pump to any of the plurality of actuators. Accordingly, the control valve may be operated by the operating means to select an actuator to which hydraulic oil is to be sent (claim).8).
[0017]
  The load detecting means may detect or estimate a load state of the actuator based on a hydraulic pressure on a hydraulic circuit connecting the actuator and the hydraulic pump.9), Or a load state of the actuator may be detected or estimated based on a change in the rotational speed of the hydraulic pump.0The load state of the actuator may be detected or estimated based on the operation position of the operation means.1).
[0018]
  Further, the electric motor is configured to function as a generator by inputting a driving force from the hydraulic pump, and a battery connected to the electric motor and capable of being charged, and switching means for switching the electric motor to the generator. When the electric motor is used as a drive source, the control means supplies electric power from the battery to the electric motor, and when the electric motor is not used as a drive source, the switching means is operated to operate the electric motor. It is preferable to perform control such that the battery is charged with the electric power generated by the input of the driving force from the input shaft of the hydraulic pump.2).
[0019]
  The battery further comprises a remaining charge detection means for detecting or estimating the remaining charge of the battery, and the control means detects the battery detected or estimated by the remaining charge detection means when the hydraulic pump is driven by the electric motor. When the remaining amount of charge of the engine drops to a state that requires charging, the clutch is connected and the engine is started, and the switching means is operated so that the electric motor is switched to the generator. Preferably (claim 1)3In this case, it is more preferable to set the rotational speed of the engine to a predetermined rotational speed lower than the rotational speed during normal operation.4).
[0020]
  In addition, a power-up switch operable by an operator is provided, and when the power-up switch is turned on by the control means, the switching means is operated even when the hydraulic pump is driven by the engine to generate the electric motor. It is preferable to perform control to switch from the machine to the drive source.5In this case, it is more preferable to operate the switching means to switch the electric motor to the generator again when a predetermined time has elapsed since the power-up switch was turned on.6).
[0021]
  And the hydraulic construction machine of the present invention (claim 1)7) Is the above-described hybrid hydraulic system (claims 1-1).6) Is one of the features.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 and 2 show a hybrid hydraulic system as an embodiment of the present invention, and here, a case where it is applied to a hydraulic excavator which is a kind of construction machine is shown. Note that the hybrid hydraulic system of the present invention can be applied not only to a hydraulic excavator but also to general construction machines using a hydraulic mechanism, and further to not only a construction machine but also a general machine using a hydraulic mechanism.
[0023]
Hereinafter, the configuration of the hybrid hydraulic system of the present embodiment will be described with reference to FIG.
As shown in FIG. 1, this hybrid hydraulic system is similar to the hydraulic system of a conventional hydraulic excavator. The hydraulic pump 12 generates hydraulic pressure to hydraulic oil, the engine 7 that drives the hydraulic pump 12, the plurality of actuators 14, the hydraulic pressure A control valve 13 for supplying hydraulic oil from the pump 12 to the actuator 14 and a work lever 16 are provided.
[0024]
First, the description will be made of each of these components. The hydraulic pump 12 is a general pump that is usually used in a hydraulic excavator, and compresses hydraulic oil by a rotary motion to generate hydraulic pressure. For example, a gear pump, a vane pump, a piston pump, or the like can be used as the hydraulic pump 12 for the hydraulic excavator, and an appropriate pump is used according to the application of the hydraulic excavator and other requirements.
[0025]
As the engine 7 for driving the hydraulic pump, a diesel engine (of course, a gasoline engine may be used) is generally used. The engine 7 is provided with a fuel injection device 7a. The fuel injection device 7a controls the engine rotational speed by adjusting the fuel injection amount by an engine control signal from a controller 6 described later, or stops the engine by fuel cut. It is supposed to be. For example, when the fuel injection device 7a is a mechanical governor, the actuator moves the governor lever according to an engine control signal from the controller 6 to adjust the fuel injection amount. When the fuel injection device 7a is an electronic governor, an engine control signal is directly input from the controller 6 to the electronic governor to adjust the fuel injection amount.
[0026]
The actuator 14 is a device that converts hydraulic energy of hydraulic oil supplied from the hydraulic pump 12 via the control valve 13 into mechanical movement. The hydraulic excavator is provided with a plurality of actuators 14 according to the purpose. For example, a hydraulic cylinder for moving the working device, a traveling motor (hydraulic motor) for moving a traveling device (wheels, etc.), a turning motor (hydraulic motor) for moving a turning device (turning gear), and the like.
[0027]
The control valve 13 is a device that feeds hydraulic pressure of hydraulic oil supplied from the hydraulic pump 12 to an arbitrary actuator 14, and is controlled by operation of a work lever (operation means) 16 by an operator. The work lever 16 is an input means for operating each device, and there are a hydraulic signal output type and an electric signal output type. In the control valve 13, the spool of the internal hydraulic circuit is moved by a signal (hydraulic signal or electric signal) from the work lever 16 to supply hydraulic oil to the target actuator 14.
[0028]
The control valve 13 is provided with a pressure switch (load detecting means) 13a. The pressure switch 13a is a switch that is turned on when the internal hydraulic pressure of the control valve 13 is greater than or equal to a predetermined value. The predetermined value is set to a hydraulic pressure when the apparatus is operating (that is, when a load is applied to the actuator 14). When the pressure switch 13a is turned on, a signal (work signal) is sent to the controller 6. ) Is output.
[0029]
In addition to the above-described components, this hybrid hydraulic system further includes the components described below.
First, a clutch 8 is connected between the engine 7 and the hydraulic pump 12 to connect and disconnect the output between the output shaft 7b of the engine 7 and the input shaft 12a of the hydraulic pump 12. The clutch 8 is controlled by the controller 6 and is connected / disconnected by a clutch signal from the controller 6. In addition, although a general hydraulic clutch or an electromagnetic clutch can be used as the clutch 8, it is preferable to employ an electromagnetic clutch in terms of the simplicity of the configuration.
[0030]
An output gear 11 is coaxially fixed to the input shaft 12 a of the hydraulic pump 12. The output gear 11 is a member for outputting the driving force output from the engine 7 and an electric motor 9 described later to the outside, and the driving force of the compressor of the air conditioner is taken out from the output gear 11. The output gear 11 has a large diameter so as to have sufficient inertia, and a flywheel for driving the hydraulic pump 12 by inertial force when the clutch 8 is disconnected and the driving force from the engine 7 is disconnected. It is supposed to function as well.
[0031]
In this hybrid hydraulic system, an electric motor 9 is further provided as a drive source for driving the hydraulic pump 12 in addition to the engine 7 described above. The electric motor 9 has an output shaft connected to the gear 10, and the gear 10 is engaged with the output gear 11. For this reason, the output of the electric motor 9 is transmitted to the output gear 11 via the gear 10. In this case, the output gear 11 functions as a power transmission member for transmitting the output of the electric motor 9 to the hydraulic pump 12.
[0032]
The electric motor 9 is a general direct current motor, and its type is not limited. However, as will be described later, it is configured such that it also functions as a generator by the input of rotation from the output gear 11 side. Electric power is supplied to the electric motor 9 by the battery 3. This battery 3 is for supplying power not only to the electric motor 9 but also to other electric / electronic systems (for example, a hydraulic pump 12, a control system for the engine 7, an air conditioner, a light, a radio, etc.) 1. A general rechargeable vehicle-mounted secondary battery can be used. The terminal voltage is input from the battery 3 to the controller 6.
[0033]
In addition, when the motor output of the electric motor 9 is large, it is preferable to operate at a high voltage. Therefore, the battery 3 can be a high voltage battery dedicated to the electric motor 9. In this case, to supply power to the other electric / electronic system 1, a low voltage battery of 24V or the like is provided separately or supplied after the voltage from the high voltage battery for the electric motor 9 is stepped down by a step-down converter. To do.
[0034]
Switching of the electric motor 9 to the generator is performed by a mode switching switch (switching means) 2. The mode change switch 2 is a device for switching the electric circuit between the battery 3 and the electric motor 9 to the power side or the charging side, and can be constituted by a general relay. The mode changeover switch 2 is controlled by the controller 6, and the mode is changed by a changeover signal from the controller 6.
[0035]
When the circuit is switched to the power side by the mode change switch 2, electricity flows from the battery 3 toward the electric motor 9, and the electric motor 9 functions as a drive source. On the contrary, when the circuit is switched to the charging side, electricity flows from the electric motor 9 toward the battery 3, and the electric motor 9 functions as a generator.
[0036]
A motor speed control device (rotational speed adjusting means) 4 is provided on the circuit when switched to the power side by the mode switch 2. The motor speed control device 4 is a device that controls the direct-current power supply from the battery 3 to transmit power to the electric motor 9, and is preferably composed of a semiconductor switching circuit such as a known chopper circuit.
[0037]
The motor speed control device 4 receives the motor control signal (voltage signal, PWM signal, FM signal, etc.) from the controller 6 and performs power control in the range of 0 to 100%. When the power is 0%, the supplied power is 0 and the electric motor 9 is stopped. When the power is 100%, the maximum power is supplied from the battery 3 to the electric motor 9, and the motor speed is maximized. That is, the motor speed control device 4 can continuously and variably control the motor speed by the motor control signal from the controller 6.
[0038]
On the other hand, a constant voltage power supply device 5 is provided on the circuit when switched to the charging side by the mode switch 2. The constant voltage power supply 5 is a device that, when the electric motor 9 functions as a generator, converts the unstable power input from the generator to a constant voltage and transmits it to the battery 3 side. Both step-down type and step-up type are possible). By providing the constant voltage power supply device 5, it is possible to supply the electric power generated by the generator (electric motor) 9 to the electric / electronic system 1 at the same time while charging the battery 3, and the electric motor 9 can be supplied to a normal alternator. It can be used as.
[0039]
The hybrid hydraulic system further includes a pickup 17, a power-up switch 18, an eco switch 19 and a throttle dial 15 as functional elements. The pickup 17 is provided so as to face the circumferential surface of the output gear 11, and detects the presence or absence of teeth carved on the circumferential surface of the output gear 11. A pulse signal (rotational speed signal) is output to the controller 6 in accordance with the presence or absence of teeth detected as the output gear 11 rotates.
[0040]
The power-up switch 18, the eco switch 19 and the throttle dial 15 are provided in a cockpit (not shown) together with the above-described work lever 16. When the power-up switch 18 demands a higher hydraulic pressure, the eco switch 19 is a switch provided for performing energy-saving operation. By pressing the switches 18 and 19, a signal is input to the controller 6 respectively. It has become so. The throttle dial 15 is a means for setting the rotational speed of the engine 7 stepwise or continuously. For example, a potential meter or a rotary switch can be used.
[0041]
In addition to the above-described components, a key switch 20 is provided in the cockpit. This key switch 20 is for starting or stopping the engine. When the operator turns on the key switch 20, a start signal is input from the key switch 20 to the controller 6, and conversely, the key switch 20 is turned off. Sometimes a stop signal is input.
[0042]
As described above, the components newly provided in the hybrid hydraulic system in addition to the same functional elements as those of the conventional hydraulic system have been described. However, the conventional hydraulic system is also used for the function of the controller (control means) 6 for integrated control of these components. There is a big difference compared to. Hereinafter, the function of the controller 6 according to the hybrid hydraulic system will be described with reference to the functional block diagram shown in FIG.
[0043]
As shown in FIG. 2, the controller 6 includes engine control means 21, clutch control means 22, motor control means 23, operation switching control means 24, timer 25, charge determination means 26, and start / stop control means 27 as functional elements. I have it. The controller 6 is a general electronic control device constituted by a microcomputer (of course, it may be a logic circuit or the like without depending on the microcomputer), and each of the functional elements 21 to 27 is a program for operating the microcomputer. Can be configured by appropriately designing (or by appropriately designing a logic circuit).
[0044]
Each functional element will be described. First, the engine control means 21 is a control means for controlling the operating state of the engine 7. In the engine control means 21, an engine switching control means 24, a start / stop signal from the start / stop control means 27, a restart signal from the charge determination means 26, and an engine speed setting signal from the throttle dial 15 are described based on an engine speed setting signal. 7 is appropriately output to the fuel injection device 7a to adjust the fuel injection amount to control the engine rotation speed, or to stop the engine by fuel cut.
[0045]
Specifically, when a stop signal is input from the operation switching control means 24 or the start / stop control means 27, the fuel injection device 7a is made to cut the fuel injection in order to stop the engine 7. Conversely, when a start signal is input, fuel is injected into the fuel injection device 7a to start the engine 7. The fuel injected here is an amount of fuel adjusted for starting, and after starting, the fuel injection amount is controlled by the fuel injection device 7a so that the engine rotational speed during normal operation (working engine rotational speed) is obtained. It is supposed to let you.
[0046]
When a restart signal is input from the charge determination means 26 when the engine 7 is stopped, the fuel injection device 7a is injected with a startable fuel injection amount to restart the engine 7, and the engine 7 is restarted. Thereafter, the fuel injection amount from the fuel injection device 7a is controlled so as to be a predetermined engine rotation speed (energy saving engine rotation speed) lower than the working engine rotation speed. When an engine speed setting signal is input from the throttle dial 15, the fuel injection amount from the fuel injection device 7a is appropriately increased or decreased so as to achieve the set engine speed.
[0047]
The clutch control means 22 is a control means for controlling the connection / disconnection of the clutch 8 and controls the connection / disconnection of the clutch 8 based on clutch connection / disconnection signals from an operation switching control means 24, a start / stop control means 27, and a charge determination means 26 described later. Is supposed to do. Specifically, when a clutch disconnection signal is input from the operation switching control means 24 or the start / stop control means 27, the clutch 8 is disconnected to disconnect the engine 7 from the hydraulic pump 12, and conversely, the operation switching control means 24, When a clutch connection signal is input from the stop control means 27 or the charge determination means 26, the clutch 8 is connected to connect the engine 7 to the hydraulic pump 12.
[0048]
Next, the motor control means 23 will be described. The motor control means 23 is a control means for controlling the operating state of the electric motor 9 by controlling the mode changeover switch 2 and the motor speed control device 4. In the motor control means 23, an operation switching control means 24, a power-side / charge-side switching signal from the charge determination means 26, a cranking signal from the start / stop control means 27, a power-up signal from the power-up switch 18 and an eco-type are described. Based on the eco signal from the switch 19, a mode switching signal is output to the mode switching switch 2 to switch between the power side and the charging side of the circuit, and a motor control signal is output to the motor speed control device 4 to generate an electric motor. 9 on / off and the motor rotation speed are controlled.
[0049]
Specifically, when a switching signal from the operation switching control means 24 is input to the power side, the circuit is switched from the charging side to the power side by the mode switch 2 so that the electric motor 9 is used as the drive source of the hydraulic pump 12. In addition, the motor speed control device 4 is configured to adjust the amount of power supplied to the electric motor 9 so as to be a predetermined motor rotation speed (motor rotation speed during energy saving operation). Conversely, when a switching signal from the operation switching control means 24 or the charge determination means 26 is input, the circuit is switched from the power side to the charging side by the mode switch 2 so that the electric motor 9 functions as a generator. It is like that.
[0050]
When a cranking signal is input from the start / stop control means 27, the circuit is switched from the charging side to the power side by the mode changeover switch 2 to crank the engine 7, and the amount of power supplied to the electric motor 9 is changed. The motor speed control device 4 is controlled so as to obtain a predetermined motor rotation speed (motor rotation speed during cranking) at the maximum.
[0051]
In addition, when a power-up signal is input from the power-up switch 18 during normal operation, the mode switch 2 switches the circuit from the charging side to the power side in order to add the output of the electric motor 9 to the output of the engine 7. The motor speed control device 4 is configured to adjust the amount of power supplied to the electric motor 9 so as to obtain a predetermined motor rotation speed (motor rotation speed at power-up). Further, when an eco signal is input from the eco switch 19 during the energy saving operation, the motor speed control device 4 is set so that the motor rotation speed becomes a motor rotation speed during the second energy saving operation that is lower than the motor rotation speed during the energy saving operation. The amount of electric power supplied to the electric motor 9 is adjusted.
[0052]
Next, the operation switching control means 24 will be described. The operation switching control means 24 is a control means for switching the operation mode between the normal operation and the energy saving operation according to the operation state of the apparatus, and from the pressure switch 13a. Based on the work signal and a pulse signal (rotational speed signal) from the pickup 17, the operation state of the apparatus is judged, and a control signal is appropriately output to the engine control means 21, clutch control means 22, and motor control means 23 to switch the operation mode. It is like that.
[0053]
Specifically, the operation switching control means 24 considers that the apparatus is in an operating state (that is, a state in which a load is applied to the actuator 14) while a work signal is input from the pressure switch 13a. It has become. When the work signal from the pressure switch 13a is turned off, the timer 25 is activated. When the operation signal is turned off for a predetermined time, it is determined that the device is in a standby state (that is, the actuator 14 is in a no-load or substantially no-load state). It is like that.
[0054]
When it is determined that the apparatus is in the standby state, the operation switching control means 24 first performs the first energy saving operation. In the first energy saving operation, a clutch disengagement signal is output to the clutch control means 22 to disengage the clutch 8, and then a stop signal is output to the engine control means 21 to stop the engine 7. The engine 7 is stopped by this first energy saving operation, and the hydraulic pump 12 is driven to rotate by the inertia of the output gear 11 as a flywheel. Further, during the first energy saving operation, the operation switching control means 24 calculates the rotation speed of the output gear 11 (the rotation speed of the input shaft 12a of the hydraulic pump 12) based on the rotation speed signal from the pickup 17, and the calculated rotation speed. Is reduced to a predetermined value (a value corresponding to the motor rotation speed during energy saving operation) or less.
[0055]
When it is determined that the rotation speed of the output gear 11 has decreased to a predetermined value or less, the second energy saving operation is performed. In the second energy saving operation, a switching signal to the drive side is outputted to the motor control means 23 in order to drive the hydraulic pump 12 by switching the function of the electric motor 9 from the generator to the drive source. By this second energy saving operation, the hydraulic pump 12 is rotated by the electric motor 9 at a predetermined motor rotation speed during the energy saving operation.
[0056]
On the other hand, when the work signal from the pressure switch 13a is turned on during the energy saving operation (during the first energy saving operation or the second energy saving operation), the operation switching control means 24 first starts the engine control means to start the engine 7. A start signal is output to 21 and subsequently a clutch connection signal is output to the clutch control means 22 in order to connect the clutch 8. The timer 25 is activated simultaneously with the output of the clutch connection signal, and when the predetermined time has elapsed, a switching signal to the charging side is output to the motor control means 23 for switching the function of the electric motor 9 to the generator. Yes.
[0057]
The charge determination means 26 is a means for determining the state of charge of the battery 3 to prevent overdischarge of the battery 3 in the second energy saving operation, and has a voltmeter (remaining charge detection means) inside. Yes. Then, the terminal voltage input from the battery 3 is measured, and when the measured terminal voltage becomes a predetermined value or less, the battery 3 determines that the remaining charge level has decreased to a state that requires charging. Yes.
[0058]
When it is determined that the remaining charge amount of the battery 3 has decreased to a state where charging is required, the charging determination unit 26 instructs the motor control unit 23 to switch to the charging side in order to switch the function of the electric motor 9 to the generator. , A restart signal is output to the engine control means 21 to drive the hydraulic pump 12 by the engine 7, and a clutch connection signal is output to the clutch control means 22.
[0059]
Finally, the start / stop control means 27 will be described. The start / stop control means 27 is a control means for starting and stopping the engine 7, and the engine 7 is not automatically started and stopped like the operation switching control means 24 described above. Instead, the engine 7 is started and stopped by appropriately outputting control signals to the engine control means 21 and the motor control means 23 in response to the operation of the key switch 20 by the operator.
[0060]
Specifically, when a start signal is input by turning on the key switch 20 by the operator, the start / stop control means 27 outputs a clutch connection signal to the clutch control means 22 to connect the engine 8 to the hydraulic pump 12. In order to crank the engine 7 by the electric motor 9, the motor control means 23 outputs a switching signal to the power side, and the engine control means 21 outputs a start signal to inject start fuel to the engine 7. It has become. Conversely, when a stop signal is input by the operator's key switch 20 being turned off, a stop signal is output to the engine control means 21 in order to cut off fuel injection to the engine 7, and a clutch control means in order to disconnect the clutch 8. A clutch disengagement signal is output to 22.
[0061]
Since the hybrid hydraulic system as one embodiment of the present invention is configured as described above, the following operations and effects can be obtained when the hydraulic excavator provided with the hybrid hydraulic system is operated. The operation and effect of the hybrid hydraulic system will be described below with reference to the time chart shown in FIG.
First, when the operator turns a key switch (not shown) when the hydraulic excavator is stopped (that is, when the engine 7 and the electric motor 9 are stopped), a start signal is input from the key switch to the controller 6.
[0062]
In response to this start signal, the controller 6 outputs a clutch signal to the clutch 8 to connect the clutch 8 and outputs a mode change signal to the mode change switch 2 to switch the circuit to the power side, so that the motor speed control device 4 Is set to the maximum value, and the engine control signal is output to the fuel injection device 7a of the engine 7 to set the fuel injection amount at the start (the governor position is set to the fuel injection position at the start). . Thus, the maximum electric power is supplied from the battery 3 to the electric motor 9, and the electric motor 9 functions as a cell motor, and cranks the engine 7 through the gear 10, the output gear (flywheel) 11, and the clutch 8. The fuel injected from the fuel injection device 7a is ignited by cranking by the electric motor 9, and the engine 7 is started.
[0063]
After the engine 7 is started, the controller 6 outputs a mode switching signal to the mode switch 2 to switch the circuit to the charging side. Since the electric current from the battery 3 to the electric motor 9 is cut off by switching the circuit, the electric motor 9 is no longer a power generation source. However, since the engine 7 is rotating, this time the clutch 8 and the output gear (flywheel) 11. The electric motor 9 is rotationally driven by the engine 7 via the gear 10, and the electric motor 9 functions as a generator (alternator). Then, it is stabilized by the constant voltage power supply device 5 provided in the circuit, charged to the battery 3 and supplied to the other electric / electronic system 1.
[0064]
While the hydraulic pump 12 is being driven by the engine 7, it can be set to an arbitrary engine speed by turning the throttle dial 15 in the same manner as a general hydraulic excavator, and has a magnitude corresponding to the engine speed. Hydraulic pressure can be supplied to the control valve 13. Then, by operating the work lever 16, hydraulic pressure can be sent from the control valve 13 to the target actuator 14 to cause the work device to perform a desired operation.
[0065]
While the work device is operated in this way, a work signal is input from the pressure switch 13a. However, when the work is interrupted and the actuator 14 is not moved as shown in FIG. 3 (time point t0), the pressure switch The work signal from 13a is turned off, and the controller 6 switches the operation mode from the normal operation to the energy saving operation (first energy saving operation) when the predetermined time tt1 has elapsed (time point t1).
[0066]
In the first energy saving operation, as described above, after the clutch 8 is disengaged, the fuel injection from the fuel injection device 7a is immediately cut and the engine 7 is stopped. As a result, the power to the hydraulic pump 12 is cut off, but the actuator 14 is not operated, so there is no load or almost no load, and the inertia of the output gear (flywheel) 11 is sufficiently large. The gear 11 continues to rotate for a while while gradually reducing the rotation speed. During this time, since the hydraulic pump 12 is driven by the rotation of the output gear 11, a hydraulic pressure having a magnitude corresponding to the rotational speed is generated. Further, since the engine 7 is stopped, there is little noise vibration and the fuel consumption is zero.
[0067]
When the operator operates the work lever 16, the work signal from the pressure switch 13a is turned on, and the controller 6 recognizes the work state (time t2). Then, an engine control signal is output to the fuel injection device 7 a to inject fuel for starting, and a clutch signal is output to the clutch 8 to connect the clutch 8. Although the engine 7 is cranked by the connection of the clutch 8, the engine 7 is cranked at a rotational speed much faster than when the electric motor 9 functions as a cell motor. Increases rapidly to a predetermined working engine rotational speed, and the rotational speed N of the output gear 11 also rapidly increases to the working rotational speed N1.
[0068]
At this time, the controller 6 starts the engine 7 by the above control and outputs a mode switching signal to the mode switch 2 to switch the electric motor 9 from the charging side to the power side. As a result, the rotation speed N of the output gear 11 is prevented from decreasing due to a load caused by the engagement of the clutch 8, and the rotation speed N quickly increases to the work rotation speed N1. The starting assistance by the electric motor 9 is temporarily performed at the start-up of the engine 7, and after a predetermined time tt2 has elapsed from the time t2, the electric motor 9 is output by outputting a mode switching signal to the mode switching switch 2. Let it function as a generator again.
[0069]
When the operation is interrupted again and the actuator 14 does not move (time point t3), the controller 6 switches the operation mode from the normal operation to the energy saving operation (first energy saving operation) when the predetermined time tt1 has elapsed (time point t4). When the rotation speed N of the output gear 11 decreases to a predetermined rotation speed (energy saving rotation speed) N0, the controller 6 switches the operation mode from the normal operation to the first energy saving operation (second time point t5).
[0070]
In the second energy saving operation, as described above, a mode switching signal is output to the mode switching switch 2 to switch the circuit from the charging side to the power side. As a result, the electric motor 9 functioning as a generator from the battery 3 via the motor speed control device 4 functions as an original motor and is driven to the hydraulic pump 12 via the gear 10 and the output gear 11. Power is transmitted.
[0071]
At this time, since the hydraulic pump 12 is unloaded, the electric motor 9 can maintain the rotational speed N of the output gear 11 with a small output. The controller 6 controls the electric power to the electric motor 9 by the motor speed control device 4 while feeding back the rotational speed N of the input shaft 12a calculated based on the rotational speed signal from the pickup 17, and the rotational speed of the output gear 11 is controlled. Control is performed so that N is maintained at a predetermined energy-saving rotational speed N0. As a result, even when a long work waiting state continues, a constant hydraulic pressure is maintained by driving by the electric motor 9. Further, since the engine 7 is stopped, there is little noise vibration and the fuel consumption is zero.
[0072]
When the operator operates the work lever 16, the work signal from the pressure switch 13a is turned on, and the controller 6 recognizes the work state (time t6). Then, an engine control signal is output to the fuel injection device 7a to inject fuel for starting, and a clutch signal is output to the clutch 8 to connect the clutch 8. When the clutch 8 is connected, the engine 7 is in a cranking state, but the engine 7 starts almost without delay due to the drive by the electric motor 9 and the inertia of the output gear 11, and the rotational speed N of the output gear 11 is the working rotational speed. It rises quickly to N1. However, the starting assistance by the electric motor 9 is temporarily performed at the start-up of the engine 7, and after a predetermined time tt2 has elapsed from the time point t6, a mode switching signal is output to the mode switching switch 2 to generate the electric motor 9. To function as a machine.
[0073]
The energy saving rotational speed N0 is sufficiently lower than the working rotational speed N1, but higher than the idle rotational speed when the engine 7 is started (for example, 1000 rpm to 1500 rpm). By selecting such a rotational speed N0, a large amount of energy is maintained in combination with the inertia of the output gear 11, and when the load is applied downstream of the hydraulic pump 12 by operating the work lever 16 or when the engine is started. The influence of the load due to the connection of the clutch 8 is small, and the rotational speed N of the output gear 11 rises without delay in response to the operation of the work lever 16.
[0074]
The controller 6 always senses the state of charge of the battery 3 based on the terminal voltage. When the remaining charge of the battery 3 is reduced to a state that requires charging during the second energy-saving operation, the mode changeover switch 2 is immediately used. A mode switching signal is output to switch the circuit to the charging side. Then, an engine injection control signal is output to inject start fuel, and a clutch signal is output to connect the clutch 8, and the engine 7 is cranked and started. After starting, the engine speed is controlled so that the rotation speed N of the output gear 11 is maintained at the energy saving rotation speed N0. As a result, the electric motor 9 is driven by the engine 7 via the clutch 8, the output gear 11, and the gear 10 to function as a generator, and the overdischarge of the battery 3 is prevented.
[0075]
In addition, when the standby state continues for a long time, such as waiting for a long dump, the eco switch 19 can be pushed by the operator's judgment. When the eco switch 19 is pressed, the controller 6 outputs a motor control signal to the motor speed control means 4, and the second energy saving rotation speed N2 (for example, 800 rpm) where the rotation speed N of the output gear 11 is lower than the energy saving rotation speed N0. ) Reduce the motor speed so that As a result, noise vibration in the standby state is further reduced, and the time until the battery 3 is in a state that needs to be charged after the discharge speed of the battery 3 is reduced is extended.
[0076]
When the eco switch 19 is pressed again, the controller 6 outputs a motor control signal to the motor speed control means 4 so that the rotation speed N of the output gear 11 returns to the normal energy saving rotation speed N0. To raise. When the operation lever 16 is operated, the controller 6 recognizes that it has returned to the operation state and connects the clutch 8 as described above to start the engine 7 and drives the function of the electric motor 9 after the start. Switch from source to generator.
[0077]
Furthermore, when a larger work capacity is required in the work state, the power-up switch 18 can be pushed by the operator's judgment. When the power up switch 18 is pressed, the controller 6 starts power up control. That is, a mode switching signal is output to the mode switch 2 to switch the circuit from the charging side to the power side, and a motor control signal is output to the motor speed control means 4 to set the motor rotation speed to a predetermined value. Thereby, the driving force of the electric motor 9 is added to the driving force of the engine 7, and the working capacity of the hydraulic excavator is greatly improved. However, when the power-up control continues for a certain time, the controller 6 automatically outputs a mode switching signal to the mode switch 2 to switch the circuit from the power side to the charging side. As a result, burning of the electric motor 9 and overdischarge of the battery 3 are prevented.
[0078]
Thus, according to the present hybrid hydraulic system, when the work signal from the pressure switch 13a is not input for a predetermined time, the clutch 8 is disengaged and the engine 7 is stopped, so that there is little noise vibration and wasteful fuel is not consumed. There is an advantage. Moreover, since the input shaft 12a of the hydraulic pump 12 is rotated by the inertia of the output gear (flywheel) 11 even after the engine 7 is stopped, the engine 7 can be started immediately by simply connecting the clutch 8. There is an advantage that work can be returned quickly.
[0079]
When the standby state continues and the rotation speed N of the output gear 11 decreases, the input shaft 12a is driven by the electric motor 9 to maintain the predetermined energy-saving rotation speed N0. There is an advantage that the engine 7 can be started and the work can be returned quickly. Further, when returning to the working state, the electric motor 9 is driven until the engine 7 is started up, so that the rotational speed N is prevented from being lowered due to a load associated with the connection of the clutch 8, and the working state is promptly restored. There is an advantage that you can.
[0080]
Further, the remaining charge amount of the battery 3 is always watched based on the terminal voltage, and when the remaining charge amount is lowered, the electric motor 9 is switched to the generator, so that the battery 3 can be prevented from being overdischarged. There is also an advantage. Further, since the electric motor 9 functions as a generator (alternator) and also functions as a cell motor when the engine 7 is started, there is an advantage that it is not necessary to separately provide an alternator and a cell motor and the number of parts can be reduced. .
[0081]
Further, since the electric motor 9 is intended to maintain the rotational speed in a no-load state when the work is interrupted, there is an advantage that the electric motor 9 can be reduced in size. Further, there is an advantage that the number of parts can be reduced by using the output gear 11 as a flywheel and also as a power transmission member for transmitting the output of the electric motor 9 to the input shaft 12a.
[0082]
The output gear (flywheel) 11 continues to rotate even after the engine 7 is stopped due to its inertial force, and is driven by the electric motor 9 when the rotational speed is reduced. The compressor of the air conditioner can be driven even when it is done, and the operator can continue to use the air conditioner.
[0083]
Further, when the standby state continues for a long time, the rotation speed N of the output gear 11 can be set to the second energy saving rotation speed N2 lower than the energy saving rotation speed N0 by pressing the eco switch 18. Furthermore, there is an advantage that noise vibration can be reduced and the time until the battery 3 is discharged can be extended. Even in this case, the engine 7 can be smoothly started in combination with the inertia of the output gear 11 when returning to the working state.
[0084]
Further, when the power up switch 18 is pushed in the working state, there is an advantage that the working ability of the hydraulic excavator can be greatly improved by adding the driving force of the electric motor 9 to the driving force of the engine 7. In addition, since a certain time limit is provided in this power-up control, there is an advantage that burning of the electric motor 9 and overdischarge of the battery 3 can be prevented.
[0085]
Although one embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention. For example, in the above-described embodiment, the remaining charge amount of the battery 3 is estimated from the terminal voltage of the battery 3. However, the battery liquid detected by providing a specific gravity sensor (remaining charge detection means) in the battery 3. The remaining charge may be estimated from the specific gravity. It is also possible to estimate the voltage and current from the integration time.
[0086]
Further, in the above-described embodiment, the pressure switch 13a is provided as the load detection means, and it is determined whether or not the apparatus is in a standby state based on the hydraulic pressure in the hydraulic circuit of the control valve 13. However, the present invention is not limited to this. The operation position of the lever 16 may be detected, and if the operation position is a neutral position, it may be determined that it is in a standby state. Further, it may be determined whether the apparatus is in a working state or a standby state based on a change in the rotational speed N of the output gear 11 detected by the pickup 17 (how the rotational speed N falls). For example, when the decrease in the rotational speed N is large, it can be determined that a load is applied to the apparatus.
[0087]
In the above-described embodiment, the power transmission between the electric motor 2 and the hydraulic pump 12 is performed by meshing the output gear 11 with the gear 10, but a belt and a pulley (one pulley is also used as a flywheel). ) May transmit power. Furthermore, as shown in FIG. 4, the electric motor 9 may be disposed coaxially with the input shaft 12a of the hydraulic pump 12, and the rotor of the electric motor 9 may be configured integrally with the input shaft 12a.
[0088]
In the above-described embodiment, a DC motor is provided as the electric motor 9. However, it is also possible to provide an AC motor by using a known technique such as vector control or an inverter. However, in this case, it is assumed that the electric motor (AC motor) has a regenerative capability, and naturally, the motor speed control device 4 and the constant voltage power supply device 5 need to be compatible with AC.
[0089]
Furthermore, the control method by the controller 6 is not limited to the above-described embodiment, and various control methods are possible. For example, in the above-described embodiment, the operator performs power-up control by pressing the power-up switch 18. However, the load of the actuator 14 is detected, and the electric motor 9 assists according to the detected load. You can also do it.
[0090]
When the detected load on the actuator 14 is small, the clutch 8 is disengaged to stop the engine 7 and the hydraulic pump 12 can be driven only by the electric motor 9. Further, by receiving power supply from the outside, if the engine 7 is stopped, the clutch 8 is disengaged, and the hydraulic pump 12 is driven only by the electric motor 9, it can function as an electric excavator that does not emit exhaust gas at all. .
[0091]
That is, according to the hybrid hydraulic system of the present invention, the integrated control of the engine 7, the electric motor 9 and the clutch 8 according to the load state of the actuator 14 is possible, and the working status of the hydraulic construction machine including the hydraulic excavator is possible. It is possible to perform optimal hydraulic control according to the conditions.
[0092]
【The invention's effect】
  As described above in detail, the hybrid hydraulic system of the present invention (Claims 1 to 1).6), Based on the detected or estimated actuator load state, integrated control of engine start / stop, electric motor start / stop, and clutch engagement / disengagement enables optimum hydraulic pressure corresponding to the usage of the actuator. There is an advantage that control can be performed.
[0093]
  In particular, the detected or estimated actuator load state is negative.LoadSometimes the clutch is disengaged and the engine is stopped, and the hydraulic pump is driven by the electric motor.BecauseIn addition, noise and vibration in the standby state can be greatly reduced, wasteful fuel consumption can be eliminated, and work can be returned quickly.The
[0094]
  In addition, if a flywheel is provided between the clutch and the hydraulic pump, the hydraulic pump is rotated by the inertia of the flywheel even after the engine is stopped, so the engine can be started immediately by simply connecting the clutch. Has the advantage of being able to return to work quickly (claims)2In this case, if the flywheel is configured as a power transmission member for transmitting power from the electric motor to the input shaft of the hydraulic pump, the number of parts is not increased.3).
[0095]
  In addition, if the hydraulic motor is driven by the electric motor when the rotational speed of the hydraulic pump falls below a predetermined value after the clutch is disconnected and the engine is stopped, the consumption of electricity by the electric motor can be suppressed. Has the advantage of being able to4). Further, if the rotation speed of the electric motor is adjusted so that the rotation speed of the hydraulic pump is maintained at a predetermined rotation speed lower than the rotation speed during normal operation, noise vibration can be further reduced. There are advantages (claims)5).
[0096]
  If the operating lever is operated in the direction of operating the actuator, the clutch is connected to start the engine and the drive of the hydraulic pump by the electric motor is stopped. Has the advantage of being possible (claims6In particular, if the hydraulic pump is driven by the electric motor for a predetermined time after the engine is started and the clutch is connected, it is possible to prevent the engine rotation speed from being lowered due to the load accompanying the clutch connection and to quickly There is an advantage that work return is possible (claims)7).
[0097]
  When the electric motor is used as a drive source, power is supplied from the battery to the electric motor. When the electric motor is not used as the drive source, the battery is charged with the generated power by switching to the generator. There is an advantage that the electric motor can be operated without supplying the electric power, and there is also an advantage that the number of parts can be reduced because it is not necessary to provide an alternator separately.2).
[0098]
  In addition, when the remaining charge of the battery drops to a state that requires charging when the hydraulic pump is driven by the electric motor, the engine is started by switching the clutch and the electric motor is switched to the generator. There is an advantage that overdischarge can be prevented.3In this case, noise vibration can be reduced by setting the engine speed to a predetermined speed lower than the speed during normal operation.4).
[0099]
  Furthermore, if the electric motor is switched from the generator to the driving source even when the hydraulic pump is driven by the engine when the power-up switch is turned on, the driving force of the electric motor is added to the driving force of the engine and the work of the actuator is performed. There is an advantage that the ability can be greatly improved.5In this case, if the electric motor is switched to the generator again after a predetermined time has elapsed since the power-up switch is turned on, there is an advantage that battery overdischarge and electric motor burnout can be prevented. (Claim 1)6).
[0100]
  And the hydraulic construction machine of the present invention (claim 1)7) According to the above-described hybrid hydraulic system (claims 1 to 1)6), There is an advantage that it is possible to achieve both a quick return to work after standby and a significant reduction in fuel waste and noise vibration in the standby state.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of a hybrid hydraulic system as an embodiment of the present invention.
FIG. 2 is a functional block diagram showing functions of a controller according to a hybrid hydraulic system as one embodiment of the present invention.
FIG. 3 is a time chart for explaining the operation of the hybrid hydraulic system as one embodiment of the present invention.
FIG. 4 is a diagram showing a modified example of the configuration of the hybrid hydraulic system as one embodiment of the present invention.
FIG. 5 is a diagram showing a configuration of a conventional hydraulic system.
FIG. 6 is a time chart for explaining the operation of a conventional hydraulic system.
[Explanation of symbols]
1 Electric / electronic system
2 Mode selector switch (switching means)
3 battery
4 Motor speed control device (rotational speed adjusting means)
5 Constant voltage power supply
6 Controller (control means)
7 engine
7a Fuel injection device
8 Clutch
9 Electric motor
10 Gear
11 Output gear (flywheel)
12 Hydraulic pump
13 Control valve
13a Pressure switch (load detection means)
14 Actuator
15 Throttle dial
16 Work lever (operating means)
17 Pickup
18 Power-up switch
19 Eco Switch
20 Key switch

Claims (17)

An actuator that converts hydraulic pressure into mechanical movement;
A hydraulic pump for supplying hydraulic oil to the actuator;
An engine for driving the hydraulic pump;
A clutch interposed between the output shaft of the engine and the input shaft of the hydraulic pump;
An electric motor coupled to the input shaft of the hydraulic pump;
Load detecting means for detecting or estimating the load state of the actuator;
Control means for integrally controlling start and stop of the engine, start and stop of the electric motor, and connection and disconnection of the clutch based on the load state of the actuator detected or estimated by the load detection means ;
When the load state of the actuator detected or estimated by the load detection unit is no load, the control unit disengages the clutch to stop the engine and the electric motor to operate, A hybrid hydraulic system, wherein the hydraulic pump is driven by a motor . Characterized in that includes a flywheel between said clutch and said hydraulic pump, a hybrid hydraulic system of claim 1, wherein. 3. The hybrid hydraulic system according to claim 2 , wherein the flywheel is configured as a power transmission member for transmitting power from the electric motor to an input shaft of the hydraulic pump. The control means, after disengaging the clutch and stopping the engine, causes the electric motor to drive the hydraulic pump when the rotational speed of the hydraulic pump becomes a predetermined value or less. Item 4. The hybrid hydraulic system according to Item 2 or 3 . A rotation speed adjusting means for adjusting the rotation speed of the electric motor;
The control means controls the rotation speed adjusting means so that the rotation speed of the hydraulic pump is maintained at a predetermined rotation speed lower than the rotation speed during normal operation when the hydraulic pump is driven by the electric motor. wherein the hybrid hydraulic system according to any one of claims 1 to 4. An operating means for an operator to operate the actuator;
The control means connects the clutch to start the engine and stops driving of the hydraulic pump by the electric motor when the operating lever is operated in a direction to operate the actuator. Item 6. The hybrid hydraulic system according to any one of Items 1 to 5 . The hybrid hydraulic system according to claim 6 , wherein the control means drives the hydraulic pump by the electric motor for a predetermined time after starting the engine and connecting the clutch. A plurality of the actuators are provided,
A control valve that is interposed between the hydraulic pump and the plurality of actuators and that feeds hydraulic oil supplied from the hydraulic pump to any of the plurality of actuators;
The control valve, characterized in that the actuator should feed the working oil is operated is selected, according to claim 6 or 7 hybrid hydraulic system described by the manipulation means. The load detecting means, and detecting or estimating the load condition of the actuator based on the oil pressure on the hydraulic circuit connecting the said actuator and the hydraulic pump, according to any one of claims 1 to 8 Hybrid hydraulic system. The hybrid hydraulic system according to any one of claims 1 to 8 , wherein the load detection means detects or estimates a load state of the actuator based on a change in rotational speed of the hydraulic pump. The hybrid hydraulic system according to any one of claims 6 to 8 , wherein the load detection unit detects or estimates a load state of the actuator based on an operation position of the operation unit. The electric motor is configured to function as a generator by inputting a driving force from the hydraulic pump, and
A rechargeable battery connected to the electric motor;
Switching means for switching the electric motor to a generator;
The control means supplies electric power from the battery to the electric motor when the electric motor is used as a driving source, and operates the switching means when the electric motor is not used as a driving source to turn the electric motor into a generator. The hybrid hydraulic system according to any one of claims 1 to 11 , wherein the battery is charged with electric power generated by switching and input of a driving force from an input shaft of the hydraulic pump. A remaining charge detection means for detecting or estimating the remaining charge of the battery;
The control means connects the clutch when the remaining charge of the battery detected or estimated by the remaining charge detection means when the hydraulic pump is driven by the electric motor is reduced to a state that requires charging. 13. The hybrid hydraulic system according to claim 12 , wherein the engine is started and the electric motor is switched to a generator by operating the switching means. The hybrid hydraulic system according to claim 13 , wherein the control means sets the rotational speed of the engine to a predetermined rotational speed lower than the rotational speed during normal operation. Power up switch that can be operated by the operator
The control means operates the switching means to switch the electric motor from a generator to a drive source even when the hydraulic pump is driven by the engine when the power-up switch is turned on. Item 15. The hybrid hydraulic system according to any one of Items 12 to 14 . 16. The hybrid hydraulic pressure according to claim 15 , wherein the control means operates the switching means to switch the electric motor to the generator again when a predetermined time has elapsed since the power-up switch was turned on. system. A hydraulic construction machine comprising the hybrid hydraulic system according to any one of claims 1 to 16 .

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