JP2009019748A - Energy regeneration device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an energy regeneration device capable of increasing energy regeneration efficiency when energy of pressurized oil is accumulated in an accumulator. <P>SOLUTION: The energy regeneration device provided with an oil pump 52 driven by a power source 1 and delivering pressurized oil, a lubrication object part 72 to which pressurized oil delivered from the oil pump 52 is supplied and which is lubricated and cooled by the pressurized oil, and the accumulators 78, 79, 80 to which pressurized oil delivered from the oil pump 52 is supplied and which accumulates energy of the pressurized oil, includes pressure intensifiers 67, 88 intensifying pressure of the pressurized oil supplied to the lubrication object part 72 from the oil pump 52, and control devices 86, 74, 75, 76, 88 accumulating energy of intensified pressure pressurized oil to the accumulators 78, 79, 80. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an energy regeneration device capable of converting kinetic energy of a power source into fluid energy of pressure oil and storing the fluid energy in a pressure accumulator.

  Conventionally, there has been known an energy regeneration device that drives an oil pump to the power of a power source, supplies a part of the pressure oil discharged from the oil pump to an accumulator, and accumulates the hydraulic pressure of the pressure oil. An example of the regenerative device is described in Patent Document 1. The energy regeneration device described in Patent Document 1 is for a vehicle, and the vehicle is provided with an oil pump that is driven by the rotational force of the engine. An oil passage through which the pressure oil discharged from the oil pump is supplied is provided. The oil passage is connected to a pressure regulating valve, and is configured such that the pressure oil regulated by the pressure regulating valve is supplied to the transmission and the clutch device. Further, a part of the pressure oil discharged from the oil pump to the oil passage is supplied to the accumulator via the electromagnetic valve, and the hydraulic pressure of the pressure oil is accumulated in the accumulator. Further, an oil passage is provided for transmitting the hydraulic pressure accumulated in the accumulator to the suction port of the oil pump. In the energy regeneration device described in Patent Document 1, when the oil pump is stopped when the engine is temporarily stopped, the hydraulic pressure of the transmission and the clutch device can be secured by the hydraulic pressure of the accumulator. Therefore, it is said that the energy that has been discarded can be reused, and efficient and efficient use of energy can be achieved.

JP 2006-37820 A

  In the energy regeneration device described in Patent Document 1, the hydraulic pressure accumulated in the accumulator can be used effectively, but the pressure oil that can be supplied from the accumulator to the hydraulic pressure required by the transmission and the clutch device. There is a possibility of shortage, and there remains room for improvement in this respect.

  The present invention has been made paying attention to the above technical problem, and an object of the present invention is to provide an energy regeneration device capable of increasing the energy regeneration efficiency of pressure oil.

  In order to achieve the above object, the invention of claim 1 is directed to an oil pump that is driven by a power source and discharges pressure oil, to which pressure oil discharged from the oil pump is supplied, and by the pressure oil In an energy regeneration device comprising a lubrication target portion to be lubricated and cooled, and a pressure accumulator for supplying pressure oil discharged from the oil pump and storing energy of the pressure oil, the energy regenerator is discharged from the oil pump. A pressure increasing device that increases the hydraulic pressure of the pressure oil before the pressure oil reaches the lubrication target portion, and a control device that stores the energy of the pressure oil increased by the pressure increasing device in the pressure accumulator. It is characterized by having.

  According to a second aspect of the present invention, in addition to the configuration of the first aspect, a plurality of the pressure accumulators are provided, and the control device transfers the energy of the pressure oil stored in the pressure accumulator to the suction port of the oil pump. And a control for storing the pressure oil energy boosted by the pressure boosting device in the pressure accumulator, and the pressure oil energy stored in the pressure accumulator is transmitted to the suction port of the oil pump. It is characterized by including first switching means for performing control separately for each pressure accumulator.

  According to a third aspect of the present invention, in addition to the configuration of the second aspect, a heating device for separately heating the pressure oil supplied to the plurality of pressure accumulators is provided for each pressure accumulator. A control for heating the stored pressure oil with a heating device and a control for discharging the heated pressure oil from the pressure accumulator and supplying it to the suction port of the oil pump separately for each pressure accumulator. Switching means is provided.

  According to the first aspect of the present invention, the oil pump is driven by the power source to discharge the pressure oil. Pressure oil discharged from the oil pump is supplied to the lubrication target portion. Further, before the pressure oil discharged from the oil pump reaches the lubrication target portion, the hydraulic pressure of the pressure oil is increased by the pressure increasing device. Furthermore, the energy of the pressurized pressure oil can be stored in the accumulator. That is, the pressure oil whose pressure has been increased is stored in the accumulator, and the pressure oil whose energy has been reduced is supplied to the lubrication target portion. Therefore, the efficiency of collecting the pressure oil energy with the accumulator is improved.

  According to the invention of claim 2, in addition to obtaining the same effect as that of the invention of claim 1, “accumulation control” for storing the energy of the pressure oil increased by the pressure intensifier in the accumulator and the accumulator It is possible to perform “discharge control” in which the energy of the stored pressure oil is transmitted to the suction port of the oil pump. Moreover, the pressure accumulation control and the discharge control can be performed separately for each pressure accumulator.

  According to the invention of claim 3, in addition to obtaining the same effect as that of the invention of claim 2, the control of heating the pressure oil stored in the pressure accumulator with the heating device, and the heated pressure oil from the pressure accumulator The control of discharging and supplying to the suction port of the oil pump can be performed separately for each accumulator.

  In the present invention, the oil pump is a fluid machine that is driven by power and sucks and discharges the pressure oil. The oil pump includes a rotary oil pump and a reciprocating oil pump. The rotary oil pump includes a gear pump, a balanced vane pump, and a screw pump. The reciprocating oil pump includes an axial piston pump and a radial piston pump. The power source is a power device that generates power for driving the oil pump, and the power source includes an engine that converts thermal energy into kinetic energy and outputs it, an electric motor that converts electric energy into kinetic energy and outputs it, Examples include flywheel systems that output inertial energy power. The lubrication target part in this invention is a part that is supplied with the pressure oil discharged from the oil pump and is lubricated and cooled by the lubricant. This lubrication target part is a part where heat generation, wear, seizure, etc. occur due to sliding, rolling, and contact between elements.For example, a bearing that supports a rotating element, a meshing part of gears in a gear transmission, A contact portion between the belt and the pulley in the winding transmission device, a contact portion between the disk and the power roller in the traction transmission device, and the like are included.

  The pressure accumulator in this invention may be any of piston type, diaphragm type, and bladder type. The pressure booster in the present invention includes a pressure booster (converter) that can increase (increase) the output hydraulic pressure with respect to the input hydraulic pressure. This pressure booster may be either a converter with a constant pressure increase rate or a converter capable of changing the pressure increase rate. When a pressure booster capable of changing the pressure increase rate is used, the pressure increase rate is controlled by an electronic control unit. That is, the pressure booster is constituted by a pressure booster and an electronic control device. Further, the control device of the present invention is a device for supplying the pressure oil increased by the pressure increasing device to the pressure accumulator, and the control device includes an oil passage connected to the pressure increasing device and a switching valve for switching the oil passage. An electronic control device (controller) for controlling the switching valve is included. The heating device in the present invention includes a device for transferring the heat of gas or hot water to pressure oil, an electric heater, and the like. In the “accumulation pressure control” in the present invention, in addition to the control for increasing the energy (hydraulic pressure) of the pressure oil stored in the accumulator, the control for increasing the energy of the pressure oil stored in the accumulator is terminated, and the pressure accumulation A control for holding the energy of the pressure oil stored in the vessel is included. In the present invention, “performing each pressure accumulator individually (separately)” includes distinguishing between a pressure accumulator performing each control and a pressure accumulator not performing each control. Further, “performing each pressure accumulator individually (separately)” includes changing the timing of performing each control by each accumulator.

  Next, specific examples of the present invention will be specifically described with reference to the drawings. FIG. 2 is a gear train diagram of a vehicle Ve to which the present invention is applied. In FIG. 2, reference numeral 1 denotes an internal combustion engine 1 as a power source of the vehicle Ve. The internal combustion engine 1 is a power device that burns fuel and converts its thermal energy into kinetic energy. As the internal combustion engine 1, specifically, a gasoline engine, a diesel engine, an LPG engine, or the like can be used. In the following description, the power source 1 is referred to as “engine 1” for convenience. The fuel is supplied to the combustion chamber of the engine 1 and burns, and the exhaust gas discharged from the combustion chamber is released into the atmosphere via an exhaust pipe (not shown), an exhaust purification catalyst (not shown), and the like. Is done. Further, a cooling device (not shown) for cooling the engine 1 with cooling water is provided.

  The crankshaft 2 of the engine 1, that is, the output shaft 2 is arranged in the width direction of the vehicle Ve. And the torque converter 3 is connected with the output shaft 2 of the engine 1 so that power transmission is possible. A forward / reverse switching mechanism 4 is connected to the torque converter 3 so that power can be transmitted, and a continuously variable transmission 5 is connected to the forward / backward switching mechanism 4 so that power can be transmitted. The torque converter 3, the forward / reverse switching mechanism 4, and the continuously variable transmission 5 are provided inside the casing 12. The torque converter 3 connected to the output side of the engine 1 is a transmission device that transmits power by kinetic energy of fluid. The torque converter 3 has a hollow casing 6, a pump impeller 7, and a turbine runner 8. An output shaft 2 of the engine 1 is connected to the casing 6 so that power can be transmitted. Moreover, the casing 6 and the pump impeller 7 are connected so as to rotate integrally. The turbine runner 8 is disposed inside the casing 6. The turbine runner 8 is provided so as to be rotatable relative to the pump impeller 7, and an input shaft 40 is connected to the turbine runner 8 so as to be able to transmit power, specifically, to rotate integrally. Hydraulic oil is supplied into the casing 6. The pump impeller 7 and the turbine runner 8 are provided with a large number of blades (not shown). When the pump impeller 7 rotates, a spiral flow of hydraulic oil is generated. By transmitting the kinetic energy of the spiral flow to the turbine runner 8, power transmission is performed between the pump impeller 7 and the turbine runner 8.

  A stator 9 is arranged on the inner peripheral side of the pump impeller 7 and the turbine runner 8. The stator 9 is a mechanism that selectively changes the flow direction of the hydraulic oil sent out from the turbine runner 8 to flow into the pump impeller 7. The stator 9 is fixed to the casing 12 via a one-way clutch 10 and a hollow shaft 11. A lockup clutch 13 is provided inside the casing 6. The lock-up clutch 13 is a transmission device that transmits power between the casing 6 and the input shaft 40 by frictional force. The lock-up clutch 13 constitutes a power transmission path parallel to the power transmission path formed by the pump impeller 7 and the turbine runner 8. The lock-up clutch 13 has a friction material 41 that rotates the input shaft 40 integrally. By pressing the friction material 41 against the casing 6, power is transmitted between the casing 6 and the input shaft 40 by a frictional force. It becomes possible to do.

  The forward / reverse switching mechanism 4 is a mechanism that is employed when the rotational direction of the engine 1 is limited to one direction. The forward / backward switching mechanism 4 is a drive pulley (described later) with respect to the rotational direction of the input shaft 40. It is a mechanism that switches the rotation direction between forward and reverse. In this specific example, a planetary gear mechanism, particularly a double pinion type planetary gear mechanism is used as the forward / reverse switching mechanism 4. The forward / reverse switching mechanism 4 has a sun gear 18 and a ring gear 19 arranged on the same axis. The forward / reverse switching mechanism 4 has a pinion gear 20 meshed with the sun gear 18 and another pinion gear 21 meshed with the pinion gear 20 and the ring gear 19. Further, a carrier 22 that supports these pinion gears 20 and 21 so as to rotate and revolve is provided. The sun gear 18 is configured to rotate integrally with the input shaft 40. Further, an actuator for selectively connecting / disconnecting the sun gear 18 and the carrier 22 and controlling rotation / stop of the ring gear 19 is provided. Examples of the actuator include a hydraulic actuator that converts hydraulic pressure to operating force, and an electromagnetic actuator that converts electromagnetic force to operating force.

  In this specific example, a case where a hydraulic actuator is used as an actuator will be described. Specifically, a forward clutch 23 and a reverse brake 24 are provided. The forward clutch 23 is a friction engagement device in which the operating member is operated by the hydraulic pressure in the clutch hydraulic chamber, and the sun gear 18 and the carrier 22 are selectively connected and released. The reverse brake 24 is a friction engagement device in which the operation member is operated by the hydraulic pressure in the brake hydraulic chamber and the rotation / stop of the reverse ring gear 19 is controlled. When the shift position for moving the vehicle Ve forward is selected, the hydraulic pressure in the clutch hydraulic chamber is increased, and the hydraulic pressure in the brake hydraulic chamber is decreased. As a result, the forward clutch 23 is engaged and the reverse brake 24 is released. On the other hand, when the shift position for moving the vehicle Ve backward is selected, the hydraulic pressure in the clutch hydraulic chamber is reduced and the hydraulic pressure in the brake hydraulic chamber is increased. As a result, the forward clutch 23 is released and the reverse brake 24 is engaged. When a shift position (parking position) for stopping the vehicle Ve is selected, both the hydraulic pressure in the clutch hydraulic chamber and the brake hydraulic chamber are reduced, and both the forward clutch 23 and the reverse brake 24 are operated. Completely freed.

  The continuously variable transmission 5 has a drive (primary) pulley 25 and a driven (secondary) pulley 26. A rotation axis (not shown) of the driving pulley 25 and a rotation axis (not shown) of the driven pulley 26 are arranged in parallel. An endless belt 29 is wound around the drive pulley 25 and the driven pulley 27. Thus, the continuously variable transmission 5 is a so-called belt type continuously variable transmission. The drive pulley 25 has a fixed piece and a movable piece, and is provided with a hydraulically controlled actuator 27 that controls the clamping force applied from the drive pulley 25 to the belt 29. The actuator 27 has a primary hydraulic chamber and a piston. The driven pulley 26 has a fixed piece and a movable piece, and is provided with a hydraulically controlled actuator 28 that controls the clamping force applied from the driven pulley 26 to the belt 29. The actuator 28 has a secondary hydraulic chamber and a piston. The transmission ratio of the continuously variable transmission 5 is controlled by controlling the clamping pressure applied to the belt 29 from the drive pulley 25, and the continuously variable transmission is controlled by controlling the clamping pressure applied to the belt 29 from the driven pulley 26. The transmission torque of the transmission 5 is controlled.

  For example, when performing a shift that increases the transmission ratio of the continuously variable transmission 5, control is performed to reduce the hydraulic pressure in the primary hydraulic chamber. On the other hand, when performing a shift to reduce the gear ratio of the continuously variable transmission 5, control is performed to increase the hydraulic pressure in the primary hydraulic chamber. Furthermore, when making the gear ratio of the continuously variable transmission 5 constant, the hydraulic pressure in the primary hydraulic chamber is controlled to be constant. Moreover, when raising the transmission torque of the continuously variable transmission 5, control which raises the hydraulic pressure of a secondary hydraulic chamber is performed. On the other hand, when the transmission torque of the continuously variable transmission 5 is reduced, control for reducing the hydraulic pressure in the secondary hydraulic chamber is performed. Further, when the transmission torque of the continuously variable transmission 5 is made constant, control for making the hydraulic pressure in the secondary hydraulic chamber constant is performed. Further, a driven pulley 26 that is an output member of the continuously variable transmission 5 is coupled to the transmission device 30 so as to be able to transmit power. Examples of the transmission device 30 include a gear transmission device and a winding transmission device. A drive wheel 32 is connected to the transmission device 30 through a final reduction gear 31 so that power can be transmitted.

  Next, the configuration of the hydraulic control device 50 that supplies pressure oil to the pressure oil required portion that controls the power transmission state in the power transmission path from the engine 1 to the drive wheels 32 will be described with reference to FIG. In this specific example, examples of the pressure oil required portion 51 include a clutch hydraulic chamber, a brake hydraulic chamber, a primary hydraulic chamber, and a secondary hydraulic chamber. And the oil pump 52 which discharges the pressure oil supplied to the pressure oil required part 51 is provided. The oil pump 52 is configured to be driven by a power source, in this specific example 1, by the power of the engine 1. Specifically, the oil pump 52 includes the rotor 15 and the body 17, and the rotor 15 is connected to the pump impeller 7 so that power can be transmitted. The body 15 is fixed to the casing 12, and the body 15 cannot rotate. The oil pump 52 has a suction port 53 and a discharge port 54, and a check valve (check valve) 57 is provided in an oil passage 56 from the oil pan 55 to the suction port 53. The check valve 57 is configured to be opened when oil is sucked into the oil pump 52 from the oil pan 55 and closed when the oil returns from the oil pump 52 to the oil pan 55.

  A primary oil passage 58 is connected to the discharge port 54 of the oil pump 52, and the primary oil passage 58 is connected to the pressure oil required portion 51. A primary regulator valve 59 is provided as a pressure control valve for controlling the hydraulic pressure in the primary oil passage 58. The primary regulator valve 59 has an input port 60 and a drain port 61, and the input port 60 is connected to the primary oil passage 58. A secondary oil passage 62 is connected to the drain port 61. The oil pressure in the primary oil passage 58 is controlled by adjusting the amount of oil discharged from the primary oil passage 58 to the secondary oil passage 62. Further, the oil in the secondary oil passage 62 is supplied to the torque converter 3, and the oil discharged from the torque converter 3 is supplied to the oil passage 63. A secondary regulator valve 64 is provided as a pressure control valve that controls the hydraulic pressure of the secondary oil passage 62.

  The secondary regulator valve 64 has an input port 65 and a drain port 66, and the input port 65 is connected to the secondary oil passage 62. An oil passage 63 is connected to the drain port 66. The oil pressure in the secondary oil passage 62 is controlled by adjusting the amount of oil discharged from the secondary oil passage 62 to the oil passage 63. That is, the secondary regulator valve 64 and the torque converter 3 are arranged in parallel as a pressure oil distribution system. Further, a pressure increasing circuit 67 is connected to the oil passage 63. The pressure increasing circuit 67 has an input port 68, an output port 69, a drain port 70, and the like. The input port 68 is connected to the oil passage 63, the output port 69 is connected to the oil passage 71, and the drain port 70. Is connected to the oil passage 71. The pressure increasing circuit 67 is a mechanism that increases the hydraulic pressure of the input port 68 and outputs it from the output port 69, and part of the oil is discharged to the oil passage 71 when the pressure is increased. In addition, the pressure oil of the oil discharged to the oil passage 71 is not increased. As this pressure increasing circuit 67, for example, a known hydraulic continuous discharge converter can be used. This hydraulic continuous discharge type converter includes a check valve, a high pressure check valve, a hydraulic cylinder, a pressure increasing piston, and the like. Then, the hydraulic cylinder is low-pressure fast-forwarded by the input hydraulic pressure, and when a load is generated in the hydraulic cylinder, the pressure-increasing spool is operated, the pressure-increasing piston is operated, and the pressure-increasing piston is continuously reciprocated. The pressure of the hydraulic cylinder is automatically increased by the continuous operation of the pressure increasing piston. In addition to the above configuration, the pressure boosting circuit 67 may employ a structure described in Japanese Utility Model Laid-Open No. 5-64507. The oil passage 71 is connected to the lubrication target portion 72. As described above, the pressure increasing circuit 67 is arranged upstream of the lubrication target portion 72 in the supply direction of the pressure oil discharged from the oil pump 52. In other words, the pressure increasing circuit 67 is disposed in the oil passage connecting the oil pump 52 and the lubrication target portion 72. The lubrication target portion 72 is a portion that is lubricated and cooled by lubricating oil, for example, a meshing portion between gears, a contact portion between a friction material and a plate constituting a friction engagement device, and a contact between a pulley and a belt. A part etc. are mentioned.

  Next, a mechanism for storing fluid energy of the pressure oil discharged from the oil pump 52, specifically, a hydraulic pressure will be described. First, switching valves 74, 75, and 76 are connected to the primary oil passage 58 with an oil passage 73 interposed therebetween. The oil passage 73 is provided with a throttle portion 77. The throttle portion 77 may be either a choke or an orifice. Further, an accumulator 78 is connected to the switching valve 74, an accumulator 79 is connected to the switching valve 75, and an accumulator 80 is connected to the switching valve 76. These accumulators 78, 79, and 80 are accumulators that accumulate the hydraulic pressure of the pressure oil, and for example, piston-type accumulators can be used. This piston-type accumulator is a known device having a hollow container, a piston movably disposed in a direction along an axis in the container, and a compression coil spring that applies a pressing force to the piston.

  The switching valve 74 has four ports, the port 81 is connected to the oil passage 73, and the port 82 is connected to the accumulator 78. The port 83 is connected to the suction port 53 of the oil pump 52 via the oil passage 84. Further, an output port 69 of a pressure increasing circuit 67 is connected to the port 85 with an oil passage 86 interposed therebetween. A check valve 87 is provided in the oil passage 86. The switching valve 74 is constituted by a solenoid valve. By controlling the switching valve 74, the port 82 connected to the accumulator 78 can be controlled to be shut off. In addition, the switching valve 74 can be used to control the port 82 to be connected to at least one of the oil passage 86 or the primary oil passage 73 and to shut off the port 81. Further, the switching valve 74 is used to control the port 82 connected to the accumulator 78 to the oil passage 84 and shut off the two ports 81 and 85 together.

  The switching valve 75 has four ports, a port 89 is connected to the oil passage 73, and a port 90 is connected to the accumulator 78. The port 92 is connected to the oil passage 84. Further, an oil passage 86 is connected to the port 93. The switching valve 75 is constituted by a solenoid valve. The switching valve 75 is used to control the port 90 connected to the accumulator 79. Further, it is possible to perform control to connect the port 90 to at least one of the oil passage 86 or the primary oil passage 73 and shut off the port 89 using the switching valve 75. Further, the switching valve 75 is used to control the port 90 connected to the accumulator 79 to the oil passage 84 and shut off the two ports 92 and 93 together.

  The switching valve 76 has four ports, the port 94 is connected to the oil passage 73, and the port 95 is connected to the accumulator 80. The port 96 is connected to the oil passage 84. Further, an oil passage 86 is connected to the port 97. The switching valve 76 is constituted by a solenoid valve. Using this switching valve 76, it is possible to control to shut off the port 95 connected to the accumulator 80. Further, the switching valve 76 can be used to control the port 95 to be connected to at least one of the oil passage 86 or the primary oil passage 73 and to shut off the port 96. Further, the switching valve 76 can be used to control the port 95 connected to the accumulator 80 to the oil passage 84 and shut off the two ports 94 and 97 together.

  Furthermore, a heating device 98 is provided that can heat the pressure oil stored in the accumulators 78, 79, 80 in a batch or separately. The heating device 98 includes a heat source 99 and heat exchangers 101, 102, and 103. Here, examples of the heat source 99 include a mechanism for holding or circulating heat to be discarded, such as the exhaust pipe described above or the cooling device described above. The heat exchanger 101 is a heat transfer device that transfers the heat of the heat source 99 to the oil in the accumulator 78. The heat exchanger 101 has a function of performing heat exchange between the heat source 99 and the pressure oil, and a function of interrupting heat exchange. The heat exchanger 102 is a heat transfer device that transfers the heat of the heat source 99 to the oil in the accumulator 79, and the heat exchanger 102 has a function of performing heat exchange between the heat source 99 and the oil. And has a function of blocking heat exchange. Furthermore, the heat exchanger 103 is a heat transfer device that transfers heat of the heat source 99 to the oil in the accumulator 80, and the heat exchanger 103 has a function of performing heat exchange between the heat source 99 and the oil. And has a function of blocking heat exchange. As the heat exchangers 101, 102, and 103, for example, any of a plate heat exchanger, a glass heat exchanger, a tube heat exchanger, and the like may be used. The check valve 87 is opened when the pressure oil increased by the pressure increase circuit 67 is supplied to the switching valves 74, 75, 76, and the pressure oil discharged from the ports of the switching valves 74, 75, 76 is released. When it tries to flow into the pressure increasing circuit 67, it has the structure closed.

  An electronic control device 88 is provided as a controller for controlling the vehicle 1, and various signals are input to the electronic control device 88. For example, the number of engine revolutions, the number of revolutions of the driving pulley 25, the number of revolutions of the driven pulley 26, the acceleration request for the vehicle 1, the signal indicating the braking request for the vehicle 1, the amount of pressure oil in the accumulators 78, 79, 80 and the pressure oil The signal indicating the energy (hydraulic pressure) of the engine, the signal indicating the temperature of the pressure oil in the accumulators 78, 79, 80, the signal indicating the temperature of the exhaust gas, the signal indicating the temperature of the cooling water, the signal indicating the shift position, and the engine 2 The signal of the switch to start / stop is input. Here, the signal indicating the shift position includes a drive position where torque of the engine 2 is transmitted to the drive wheels 32 and a non-drive position where torque of the engine 2 is not transmitted to the drive wheels 32. Further, the switch for starting / stopping the engine 2 includes a switch for controlling start / stop of the engine 1 by operating a button, in addition to a switch for turning on / off by operating an ignition key. Based on these signals and data stored in the electronic control unit 88, a signal for controlling the engine output, a signal for controlling the forward clutch 23 and the reverse brake 24, and engagement / release of the lockup clutch 13 are controlled. A signal for controlling the transmission ratio and the transmission torque of the continuously variable transmission 5, a signal for individually controlling the heat exchange / stop of heat exchange in the heat exchangers 101, 102, 103, in the switching valves 74, 75, 76 A signal for individually controlling connection / cutoff between ports, a signal for controlling the pressure increase rate of the pressure increase circuit 67, and the like are output.

  Next, the operation of the hydraulic control device 50 shown in FIG. 1 will be described. When the engine 1 is operated and the oil pump 52 is driven by the engine torque, the oil in the oil pan 55 is sucked into the oil pump 52 and discharged to the primary oil passage 58. The pressure oil discharged to the primary oil passage 58 is supplied to the pressure oil required portion 51. Further, the oil pressure in the primary oil passage 58 is controlled by the primary regulator valve 59, and a part of the oil in the primary oil passage 58 is discharged to the secondary oil passage 62. Here, the hydraulic pressure of the secondary oil passage 62 is lower than the hydraulic pressure of the primary oil passage 58. The hydraulic pressure in the secondary oil passage 62 is controlled by the secondary regulator valve 64 and supplied to the torque converter 3. The oil discharged from the secondary oil passage 62 to the oil passage 63 is increased in pressure by the pressure increasing circuit 67 and supplied to the oil passage 86. A part of the oil in the oil passage 63 is sent to the lubrication target portion 72 via the oil passage 71. The oil pressure in the oil passage 63 is lower than the oil pressure in the secondary oil passage 62.

  Further, a control example of the switching valves 74, 75, 76 will be described based on the flowchart of FIG. First, it is determined whether or not a condition for performing regenerative control is satisfied (step S1). The regenerative control is a control for accumulating the fluid energy of the pressure oil discharged from the oil pump 54, that is, the hydraulic pressure, in at least one of the accumulators 78, 79, and 80. The conditions for performing this regenerative control are the operating state of the engine 1, the vehicle speed of the vehicle Ve, the acceleration request (depressed state of the accelerator pedal), the braking request (depressed state of the brake pedal), and the accumulated pressure of the accumulators 78, 79, 80 It is determined based on the state.

  First, as a precondition for performing the regenerative control, it is possible to reduce the hydraulic pressure of the pressure oil supplied to the pressure oil required portion 51. For example, when braking the vehicle Ve, specifically, when the accelerator switch is turned off and the brake switch is turned on while the vehicle Ve is traveling at a predetermined vehicle speed or higher, the precondition is satisfied. That is, when the vehicle Ve is braked, the required driving force required from the vehicle speed and the accelerator opening is reduced, so that the torque transmitted from the engine 2 to the continuously variable transmission 5 is reduced and the speed of the continuously variable transmission 5 is changed. The ratio is small. Further, the torque input to the forward / reverse switching mechanism 4 decreases. For this reason, it is possible to reduce the hydraulic pressure of the pressure oil required part 51. In addition to the fact that this precondition is satisfied, the “condition for performing regenerative control” is satisfied when pressure accumulation in at least one of the accumulators 78, 79, and 80 is possible.

  If the determination in step S1 is affirmative, regenerative control is executed in an accumulator capable of accumulating pressure (step S2), and this control routine is terminated. For example, when the accumulator 78 can store pressure, the switching valve 74 is controlled so that the port 82 is connected to at least one of the oil passage 73 or the oil passage 86 and the port 83 is shut off. When the accumulator 79 can accumulate pressure, the switching valve 75 is controlled so that the port 90 is connected to at least one of the oil passage 73 or the oil passage 86 and the port 92 is shut off. Further, when the accumulator 78 can store pressure, the switching valve 74 is controlled so that the port 95 is connected to at least one of the oil passage 73 or the oil passage 86 and the port 96 is shut off. By such control, the energy of at least one of the pressure oil in the oil passage 73 or the pressure oil in the oil passage 86 is accumulated in at least one of the accumulators 74, 75, and 76. In particular, before the pressure oil in the oil passage 63 reaches the lubrication target portion 72, the oil pressure of the pressure oil can be increased by the pressure increase circuit 67, and the energy of the pressure oil can be stored in the accumulator. A part of the pressure oil supplied to the pressure increasing circuit 67 is supplied to the lubrication target portion 72 without being increased in pressure. Therefore, the efficiency of recovering the pressure oil energy is further improved.

  If a negative determination is made in step S1, it is determined whether a condition for performing power running control is satisfied (step S3). The power running control is a control for supplying energy stored in the accumulator to the suction port 53 of the oil pump 52. Whether or not the condition for performing the power running control is satisfied is determined based on the operation state of the engine 1, the vehicle speed of the vehicle Ve, the depression state of the accelerator pedal, the depression state of the brake pedal, and the like, as well as the accumulated pressure state of the accumulator. .

  First, as a precondition for performing power running control, it is necessary to increase the hydraulic pressure of the pressure oil supplied to the pressure oil required portion 51. For example, when the vehicle Ve starts and accelerates, specifically, when the accelerator switch is turned off and the brake switch is turned on, the accelerator switch is turned on and the brake switch is turned off. To establish. That is, when the vehicle Ve starts, the torque transmitted from the engine 1 to the continuously variable transmission 5 is high, the gear ratio of the continuously variable transmission 5 is large, and the torque transmitted by the forward / reverse switching mechanism 4 is also high. It is necessary to increase the hydraulic pressure in the pressure oil required portion 51. In addition to the fact that this precondition is satisfied, when the pressure of at least one of the accumulators 78, 79, 80 is equal to or higher than a predetermined pressure stored in advance in the electronic control unit 88, “power running control is performed. "Condition" is met. Here, the predetermined pressure stored in the electronic control unit 88 is used to determine whether or not the hydraulic pressure of at least one of the accumulators contributes to increasing the hydraulic pressure of the pressure oil required portion 51, and is previously tested. The predetermined pressure thus obtained is stored in the electronic control device 88.

  When a positive determination is made in step S3, power running control is executed (step S4), and this control routine is terminated. For example, when the pressure of the accumulator 78 is equal to or higher than a predetermined pressure stored in the electronic control unit 88, the switching valve 74 is connected so that the port 82 and the port 83 are connected and both the ports 81 and 85 are shut off. Is controlled. When the pressure of the accumulator 79 is equal to or higher than a predetermined pressure stored in the electronic control device 88, the switching valve 75 is connected so that the port 90 and the port 92 are connected and the ports 93 and 89 are both shut off. Is controlled. Further, when the pressure of the accumulator 80 is equal to or higher than a predetermined pressure stored in the electronic control unit 88, the switching valve 76 is connected so that the port 95 and the port 96 are connected and the ports 94 and 97 are both shut off. Is controlled. In this way, the hydraulic energy of at least one of the accumulators 78, 79, 80 is supplied to the suction port 53 of the oil pump 52. Therefore, the suction efficiency of the oil pump 52 is improved.

  On the other hand, if a negative determination is made in step S3, it is determined whether or not a condition for performing “shut-off control for maintaining a state where energy is accumulated in the accumulator” is established (step S6). This “condition for performing the shut-off control” is determined based on, for example, the operating state of the engine 1, the vehicle speed of the vehicle Ve, the depressed state of the accelerator pedal, the depressed state of the brake pedal, and the like, and the accumulated pressure state in the accumulator. First, as a precondition for performing the shut-off control, it may be mentioned that the hydraulic pressure of the pressure oil required portion 51 may be maintained substantially constant. For example, the precondition is satisfied when the vehicle Ve travels at a constant vehicle speed. Specifically, the torque input to the forward / reverse switching mechanism 4 is constant, the gear ratio of the continuously variable transmission 5 is constant, and the torque transmitted by the continuously variable transmission 5 is also constant. The hydraulic pressure of the pressure oil required portion 51 may be maintained almost constant.

  In addition to satisfying this precondition, when the pressure of the accumulator is equal to or higher than a predetermined value stored in advance in the electronic control device 88, it is determined that the “condition for performing shut-off control” is satisfied. When an affirmative determination is made in step S5, the cutoff control is executed (step S6), and this control routine is terminated. For example, the switching valve 74 is controlled so that the port 82 is shut off when the pressure of the accumulator 78 is equal to or higher than a predetermined value stored in the electronic control device 88 in advance. Further, the switching valve 75 is controlled so that the port 90 is shut off when the pressure of the accumulator 79 is equal to or higher than a predetermined value stored in the electronic control device 88 in advance. Further, the switching valve 76 is controlled so that the port 95 is shut off when the pressure of the accumulator 80 is equal to or higher than a predetermined value stored in the electronic control device 88 in advance.

  On the other hand, if a negative determination is made in step S5, it is determined whether or not the “automatic stop condition for engine 1” is satisfied (step S7). For example, there is no change in the operation of the switch for starting / stopping the engine 2, the accelerator pedal is not depressed, the brake pedal is depressed, and the engine 2 is operated, and When the vehicle speed is equal to or lower than the low vehicle speed stored in advance in the electronic control unit 88, the “engine 1 automatic stop condition” is satisfied, and the engine 2 is stopped. If the determination in step S7 is affirmative, it is necessary to supply pressure oil to the primary hydraulic chamber and the secondary hydraulic chamber in preparation for restarting the stopped engine 1 and starting the vehicle Ve. There is. Further, it is necessary to secure a torque capacity to such an extent that the forward clutch 23 of the forward / reverse switching mechanism 4 is not completely released.

  Therefore, if the determination in step S7 is affirmative, control is performed to ensure the hydraulic pressure in the primary hydraulic chamber and the secondary hydraulic chamber by supplying the primary hydraulic passage 58 with the hydraulic pressure accumulated in any of the accumulators. (Step S8), the control routine ends. That is, in step S8, when the hydraulic pressure of the accumulator 78 is transmitted to the oil passage 58, the switching valve 74 is controlled so that the port 81 and the port 82 are connected and the ports 83 and 85 are both shut off. . In step S8, when the hydraulic pressure of the accumulator 79 is transmitted to the oil passage 58, the switching valve 75 is controlled so that the port 89 and the port 90 are connected and the ports 92 and 93 are both shut off. . Further, in step S8, when the hydraulic pressure of the accumulator 80 is transmitted to the oil passage 58, the switching valve 76 is controlled so that the port 94 and the port 95 are connected and the ports 96 and 97 are both shut off. .

  Next, an example of a subroutine that can be executed in parallel with the process of step S2 or step S6 will be described with reference to FIG. First, the temperature of the pressure oil in the accumulator is detected, and it is determined whether the temperature is equal to or lower than a first predetermined value (step S11). The technical meaning of the first predetermined value used in step S1 is a reference temperature for determining whether or not to perform control for heating the pressure oil. For example, the viscosity of the pressure oil depends on the temperature, and when the temperature is lowered, the viscosity is increased and the fluidity is lowered. Therefore, the relationship between the temperature and the viscosity is experimentally obtained in advance, and the temperature at which the desired fluidity can be ensured is stored in the electronic control unit 88 as a predetermined value.

  If the determination in step S11 is affirmative, "control to heat the pressure oil in the accumulator" is performed (step S12). The “control for heating the pressure oil in the accumulator” is “a control for heating the pressure oil by transferring the heat of the heat source 99 to the pressure oil in the accumulator by the heat exchanger”. Following this step S12, it is determined whether or not the temperature of the pressure oil in the accumulator has reached a second predetermined value or more (step S13). The second predetermined value used in step S13 is a temperature for ending the heating before the pressure oil is heated to a temperature at which the function of pressure oil may be reduced. The reduction in the function of pressure oil means that, for example, the pressure oil deteriorates and the lubrication performance decreases. The second predetermined value used in step S13 is also obtained experimentally and stored in advance in the electronic control unit 88. Note that the second predetermined value is higher than the first predetermined value.

  If the determination in step S13 is affirmative, the “control for heating the pressure oil in the accumulator” is terminated (step S14), and the control routine is terminated. On the other hand, if a negative determination is made in step S13, the “control for heating the pressure oil in the accumulator” is continued, and this control routine is terminated. Further, if the determination in step S11 is affirmative, the control routine is terminated without performing the “control for heating the pressure oil in the accumulator”. When the control of FIG. 4 is performed in combination with the control of FIG. 1, the pressure oil heated in the accumulator can be discharged to the oil passage 84 or the primary oil passage 73. Therefore, the fluidity of the pressure oil can be ensured in the pressure oil required portion 51, and the operation responsiveness of the operation member, for example, the piston is improved. Further, when pressure oil is supplied to the torque converter 3, warm-up of the torque converter 3 is promoted. Therefore, the heat of the heat source 99 can be efficiently regenerated. In this specific example, the regenerative control, power running control, and shut-off control can be performed individually for each accumulator 78, 79, 80. Therefore, the energy regeneration efficiency in each accumulator is further improved.

  Here, the correspondence between the configuration shown in FIGS. 1 and 2 and the configuration of the present invention will be described. The engine 1 corresponds to the power source of the present invention, and the oil pump 52 corresponds to the oil pump in the present invention. The lubrication target portion 72 corresponds to the lubrication target portion of the present invention, the accumulators 78, 79, and 80 correspond to the pressure accumulator of the present invention, and the pressure increase circuit 67 corresponds to the pressure increase device of the present invention. The oil passage 86, the switching valves 74, 75, and 76 and the electronic control device 88 correspond to the control device of the present invention.

  The correspondence between the functional means shown in FIG. 3 and the configuration of the present invention will be described. Steps S1, S2, S3, S4, S5 and S6 correspond to the first switching means in the present invention. The correspondence between the functional means shown in FIGS. 3 and 4 and the configuration of the present invention will be described. Steps S1, S2, S3, S4, S5 and S6 in FIG. 3 and S11 and S12 in FIG. This corresponds to the second switching means of the present invention. Further, the control performed in steps S1, S2, S5 and S6 in FIG. 3 corresponds to the “pressure accumulation control” of the present invention. That is, in the “pressure accumulation control” in the present invention, in addition to the control for increasing the energy of the pressure oil stored in the accumulator, the control for increasing the energy of the pressure oil stored in the accumulator is terminated, and the pressure oil stored in the accumulator The control which maintains the energy of is included.

  The present invention is not limited to the above specific example. In the above specific example, the engine is cited as the power source for driving the oil pump. However, the oil pump is driven by the power of the electric motor or flywheel. The vehicle of the structure which carries out may be sufficient. Moreover, although the vehicle which mounted the belt-type continuously variable transmission was demonstrated as a transmission mounted in a vehicle, another continuously variable transmission, specifically, a toroidal type continuously variable transmission may be sufficient. This toroidal continuously variable transmission includes a hydraulic chamber that controls the tilt angle of the power roller, and a hydraulic chamber that applies a clamping force in the direction along the axis to the input disk and the output disk. In this case, the pressure oil required portion includes a hydraulic chamber that controls the tilt angle of the power roller, and a hydraulic chamber that applies a clamping pressure in the direction along the axis to the input disk and the output disk. Moreover, although the hydraulic control apparatus mounted in the vehicle is taken as an example, the present invention can also be applied to a hydraulic control apparatus that supplies pressure oil to a hydraulic actuator of a construction machine or an industrial machine. In this specific example, the number of accumulators may be two, or four or more. In this specific example, a plurality of accumulators are provided, but a single accumulator may be provided.

It is a schematic diagram which shows the structure of the energy regeneration apparatus of this invention. It is a schematic diagram which shows the structure of the vehicle which has an energy regeneration apparatus of this invention. It is a flowchart which shows the example of control of the energy regeneration apparatus of this invention. It is a figure which shows the subroutine which can be performed in parallel with the flowchart of FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Engine, 52 ... Oil pump, 72 ... Lubrication object part, 78, 79, 80 ... Accumulator, 67 ... Booster circuit, 86 ... Oil path, 74, 75, 76 ... Switching valve, 88 ... Electronic control apparatus.

Claims (3)

An oil pump that is driven by a power source to discharge pressure oil, a lubrication target portion to which pressure oil discharged from the oil pump is supplied and lubricated and cooled by the pressure oil, and a discharge from the oil pump In the energy regenerative device provided with a pressure accumulator that is supplied with the pressure oil and stores the energy of the pressure oil,
A pressure increasing device that increases the hydraulic pressure of the pressure oil before the pressure oil discharged from the oil pump reaches the lubrication target part;
An energy regenerative device comprising: a control device that stores energy of the pressure oil increased by the pressure increase device in the pressure accumulator. A plurality of the pressure accumulators are provided, and the control device includes a device that transmits energy of the pressure oil stored in the pressure accumulator to the suction port of the oil pump,
Control for storing the energy of the pressure oil boosted by the pressure booster in the pressure accumulator, and control for transmitting the energy of the pressure oil stored in the pressure accumulator to the suction port of the oil pump. The energy regeneration device according to claim 1, further comprising a first switching unit that performs each operation separately. A heating device for heating the pressure oil supplied to the plurality of pressure accumulators separately for each pressure accumulator is provided,
Control for heating the pressure oil stored in the pressure accumulator with a heating device and control for discharging the heated pressure oil from the pressure accumulator and supplying it to the suction port of the oil pump are separately performed for each pressure accumulator. The energy regeneration device according to claim 2, further comprising second switching means to be performed.

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