JP3962165B2 - HST control method for hydraulic-mechanical transmission - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an HST control method for a hydraulic-mechanical transmission.
[0002]
[Prior art]
  Conventionally, a traveling mode by a hydraulic continuously variable transmission (HST) and a traveling mode by a hydraulic-mechanical transmission (HMT) are controlled to be automatically switched at a shift mode switching point.
[0003]
[Problems to be solved by the invention]
  However, since the transmission mode is switched unconditionally at the transmission mode switching point, when the speed ratio changes due to load fluctuation or the like during traveling near the transmission mode switching point, the transmission mode switching frequently occurs. There was a problem.
[0004]
[Means for Solving the Problems]
  The above is the problem to be solved by the present invention. Next, means for solving the problem will be described.
[0005]
  In claim 1,Hydraulic transmission unit using an HST continuously variable transmission constituted by a hydraulic pump and a hydraulic motor, and a hydraulic pressure-shifted by the HST continuously variable transmission and a planetary gear unit-a hydraulic pressure provided with a mechanical transmission (HMT)- In the HST control method of the mechanical transmission, control is performed so that the HST mode by the HST continuously variable transmission and the HMT mode by the hydraulic-mechanical transmission (HMT) are automatically switched at the transmission mode switching point (X). Then, with respect to the target speed ratio instructed by the speed ratio indicating lever which is the travel operation lever, the HST mode in which the shift to the target speed ratio is a traveling state by the HST continuously variable transmission, and the hydraulic-mechanical type When the vehicle travels across the shift mode switching point (X) of the HMT mode, which is a traveling state by the speed change mechanism, the speed ratio at the shift mode switching point (X) is changed as the provisional target speed ratio to change the speed. After over de switching operation, hydraulic, characterized in that the transmission speed ratio instructed by the speed ratio instruction lever as the target speed ratio - HST control method for a mechanical transmissionIt is.
[0006]
  In claim 2,2. The HST control method for a hydraulic-mechanical transmission according to claim 1, wherein when performing a shift over the shift mode switching point (X) in addition to the instruction by the speed ratio indicating lever, the current shift at the instructed time point. Shift while maintaining modeIs.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
  Next, an embodiment of the present invention will be described.
[0008]
  1 is a front view of a hydraulic-mechanical transmission, FIG. 2 is a cross-sectional view taken along line AA, FIG. 3 is a block diagram of the hydraulic-mechanical transmission, and FIG. 4 is an output of the hydraulic-mechanical transmission and a hydraulic pump. FIG. 5 is a diagram showing a clutch operating state corresponding to a shift state, FIG. 6 is a clutch switching instruction control flowchart, FIG. 7 is a diagram showing a relationship between time and speed ratio, and FIG. 8 is a control output diagram of the clutch with time as an axis, FIG. 9 is a flowchart of the command speed ratio control, FIG. 10 is a flowchart of the volume correction sharing control, and FIG. 11 is a correspondence diagram of the operation amount of the speed ratio command lever and the target speed. 12 is a control diagram of the controller 100, FIG. 13 is a brake control flowchart diagram, and FIG. 14 is a neutral control flowchart diagram.
[0009]
  1 and 2,Hydraulic-mechanical transmission (HMT)The configuration of will be described.
  Hydraulic-mechanical transmission (HMT),HST continuously variable transmission (21) (hereinafter referred to as HST21)And a mission 30 including the planetary gear unit 7.
  The HST 21 includes a hydraulic pump 22 and a hydraulic motor 23 contained in an HST case 31 and a center section 32, and the center section 32 is fixed to a case 33 of the mission 30.
[0010]
  An input shaft 25 is inserted through the HST 21, and a movable swash plate 22 a and a cylinder block 22 b of the hydraulic pump 22 are inserted into the input shaft 25. The cylinder block 22b is inserted into the input shaft 25 so as not to rotate relative to the input shaft 25, and the cylinder block 22b is driven together with the input shaft 25.
  Plural plunger pumps 22c are slidably disposed on the cylinder block 22b. The movable swash plate 22a is in contact with the tip of the plunger pump 22c, and the hydraulic oil discharge amount of the hydraulic pump 22 can be adjusted by adjusting the inclination angle of the movable swash plate 22a. Yes. The hydraulic oil discharged by the hydraulic pump 22 is sent to the hydraulic motor 23 through an oil passage provided in the center section 32.
[0011]
  A hydraulic motor output shaft 26 is inserted into the hydraulic motor 23 of the HST 21, and one end of the hydraulic motor output shaft 26 is pivotally supported by the HST case 31. A movable swash plate 23a and a cylinder block 23b of the hydraulic motor 23 are inserted into the hydraulic motor output shaft 26, and the cylinder block 23b is configured so as not to rotate relative to the hydraulic motor output shaft 26. Plural plunger pumps 23c are slidably disposed on the cylinder block 23b, and the movable swash plate 23a is in contact with the distal end of the plunger pump 23c. By adjusting, the capacity of the hydraulic motor 23 can be adjusted. With this configuration, the rotational speed with respect to the amount of hydraulic oil fed from the hydraulic pump 22 is adjusted.
[0012]
  Next, the configuration of the mission 30 will be described.
  The mission 30 is covered by a mission case 33. The transmission case 33 is provided with an input shaft 25, a hydraulic motor output shaft 26, a drive shaft 27, and a drive shaft 18, and is rotatably supported. .
  The mission case 33 is provided with a planetary gear portion 7 composed of planetary gears. In the mission case 33, the planetary gear portion 7 is divided by a clutch portion 35 and a case 34. The planetary gear unit 7 is composed of a sun gear 1, planetary gears 2 and 3, an input gear 4, and a carrier 6, which will be described later. The gear 5 fixed to the carrier 6 is connected to the clutch unit 35 by a case 34 together with the planetary gear unit 7. It is configured to be more isolated.
[0013]
  The clutch portion 35 is provided with a clutch 11 inserted on the hydraulic motor output shaft 26 and a clutch 12 inserted on the drive shaft 27. The clutch housing of the clutch 11 is fixed on the hydraulic motor output shaft 26, and the clutch box of the clutch 11 is inserted into a rolling bearing inserted into the hydraulic motor output shaft 26. A gear 14 is fixed to the clutch box of the clutch 11, and the gear 14 is driven together with the hydraulic motor output shaft 26 by connecting the clutch 11.
  The clutch housing of the clutch 12 is fixed on the drive shaft 27, and the clutch box of the clutch 12 is inserted into a rolling bearing that is inserted into the drive shaft 27. A gear 16 is fixed to the clutch box of the clutch 12, and the gear 16 is driven together with the drive shaft 27 by connecting the latch 12.
[0014]
  Since the planetary gear unit 7 is isolated from the clutch unit 35 by the case 34 in the transmission case 33, the planetary gear unit 7 can be protected from sludge generated from the clutches 11 and 12, and the planetary gear unit. 7 durability is improved.
[0015]
  The sun gear 1 is inserted and fixed to the input shaft 25, and a power transmission pipe 28 in which the gear 4 is integrally formed is inserted so as to be relatively rotatable. The planetary gear unit 7 is inserted into the input shaft 25 and the power transmission pipe 28. The gear 5 fixed to the carrier 6 of the planetary gear unit 7 meshes with a gear 9 that is inserted and fixed to the drive shaft 27, and the gear 9 meshes with a gear 19 that is inserted and fixed to the drive shaft 18. ing. With this configuration, the driving force of the gear 5 is transmitted to the drive shaft 18 through the gears 9 and 19.
[0016]
  In FIG. 3, the output of the engine 24 is transmitted to the drive shaft 27 via either the HST 21 or the planetary gear unit 7 or the HST 21 and the planetary gear unit 7.
  One end of an input shaft 25 is connected to the engine 24, and the output of the engine 24 is introduced to the HST 21 via the input shaft 25. The HST 21 includes a hydraulic pump 22 and a hydraulic motor 23, and the hydraulic pump 22 and the hydraulic motor 23 are configured to have a variable capacity. For this reason, the drive ratio of the hydraulic motor 23 to the hydraulic pump 22 can be adjusted by adjusting the capacity of the hydraulic pump 22 or the hydraulic motor 23.
  The input shaft 25 is connected to the hydraulic pump 22, and the hydraulic pump 22 is driven by the input shaft 25. With the above configuration, the output of the engine 24 drives the hydraulic pump 22 of the HST 21 via the input shaft 25, and the hydraulic motor 23 is driven by the hydraulic pump 22. A hydraulic motor output shaft 26 is connected to the hydraulic motor 23 and is driven by the hydraulic motor 23.
[0017]
  The other end of the input shaft 25 is connected to the planetary gear unit 7.
  The planetary gear unit 7 includes a sun gear 1, a planetary gear 2, a planetary gear 3, a carrier 6 and an input gear 4. The sun gear 1 is inserted and fixed to the other end of the input shaft 25, and the planetary gear 2 is engaged with the sun gear 1. The planetary gear 2 meshes with the planetary gear 3, and the planetary gear 3 meshes with the input gear 4. The planetary gears 2 and 3 are pivotally supported by pivots fixed to the carrier 6 and revolve with respect to the sun gear 1.
[0018]
  Further, in the planetary gear unit 7, the planetary gear 2 and the planetary gear 3 are arranged in three pairs, and the planetary gear 2 and the planetary gear 3 are on the circumference with the rotation center of the carrier 6 being concentric. Is configured to rotate.
  A planetary gear 2 is meshed with the outer periphery of the sun gear 1, and a planetary gear 3 is disposed outside the planetary gear 2 with respect to the center of rotation of the carrier 6. A gear 5 is fixed to the carrier 6, and the sun gear 1, the input gear 4, the carrier 6, and the gear 5 are configured so that the rotation centers are located on the same straight line.
  The gear 5 fixed to the carrier 6 meshes with a gear 9 that is fixedly inserted into one end of a drive shaft 27, and is configured to be able to transmit a driving force to the gear 9. The gear 9 meshes with a gear 19 that is inserted and fixed to the drive shaft 18. With this configuration, the driving force of the gear 5 is transmitted to the drive shaft 18 through the gears 9 and 19.
[0019]
  The input gear 4 is integrally formed on the outer periphery of the power transmission pipe 28 at one end of the power transmission pipe 28, and the gear 10 is inserted and fixed on the outer periphery of the other end of the power transmission pipe 28. Yes. The gear 10 is engaged with a gear 14 inserted into a hydraulic motor output shaft 26. The gear 14 is fixed to a clutch box of a clutch 11 that is fitted and fixed to a hydraulic motor output shaft 26, and the gear 14 is driven together with the hydraulic motor output shaft 26 by operating the clutch 11. It has become.
  A gear 15 is inserted and fixed on the outer periphery of one end of the hydraulic motor output shaft 26, and the gear 15 meshes with a gear 16 that is inserted into the drive shaft 27. The gear 16 is fixed to a clutch box of the clutch 12 inserted and fixed to the drive shaft 27, and the driving force is applied to the drive shaft 27 by the gear 16 by operating the clutch 12, together with the gear 16. 27 is configured to rotate. A gear 9 is fixed to the drive shaft 27, and a gear 19 inserted and fixed to the drive shaft 18 is engaged with the gear 9. The output of the drive shaft 27 is transmitted to the drive shaft 18 through the gears 9 and 19.
[0020]
  In the above configuration, when the clutch 11 is disengaged, the clutch 12 is operated, and the gear 16 and the drive shaft 27 are connected, the drive shaft 27 is driven by the drive force of the hydraulic motor output shaft 26 of the HST 21. Is done. Further, the output of the drive shaft 27 is transmitted to the drive shaft 18 through the gears 9 and 19.
  The output of the engine 24 is shifted in the HST 21 and output from the hydraulic motor output shaft 26. When the hydraulic motor output shaft 26 is driven, the gear 15 is driven, and the gear 16 meshed with the gear 15 is driven. A clutch box of the clutch 12 is fixed to the gear 16, and the gear 12 and the drive shaft 27 are connected because the clutch 12 is operating. As a result, the drive shaft 27 is driven by the output of the hydraulic motor output shaft 26.
  That is, by disconnecting the clutch 11 and operating the clutch 12, the drive shaft 27 is driven only by the driving force shifted by the HST 21. Further, the output of the drive shaft 27 is transmitted to the drive shaft 18 through the gears 9 and 19.
[0021]
  Further, when the clutch 11 is operated, the gear 14 and the hydraulic motor output shaft 26 are connected, and the clutch 12 is disconnected, the driving force of the input shaft 25 and the driving force of the hydraulic motor output shaft 26 are planetary. The drive shaft 27 is driven by the output synthesized in the gear unit 7 and synthesized in the planetary gear unit 7.
  The output of the engine 24 is transmitted to the sun gear 1 through the input shaft 25, and the driving force of the input shaft 25 is introduced into the planetary gear unit 7 by the sun gear 1. Further, the driving force of the hydraulic motor output shaft 26 is transmitted to the gear 10 through the gear 14 when the clutch 11 is connected. The power transmission pipe 28 is driven by the gear 10 and the input gear 4 formed integrally with the other end of the power transmission pipe 28 is driven. The driving force of the hydraulic motor output shaft 26 is transmitted to the planetary gear unit 7 by the input gear 4.
  In the planetary gear unit 7, the driving forces of the input shaft 25 and the hydraulic motor output shaft 26 are combined to drive the carrier 6. The driving force of the carrier 6 is transmitted to the gear 9 by the gear 5 fixed to the carrier 6, and is transmitted to the driving shaft 27 by the gear 9.
  As a result, the drive shaft 27 is driven by the drive force transmitted to the planetary gear unit 7 by the input shaft 25 and the drive force shifted by the HST 21. Further, the output of the drive shaft 27 is transmitted to the drive shaft 18 through the gears 9 and 19.
[0022]
  A power source rotational speed detector 104 is disposed in the vicinity of the input shaft 25 so that the rotational speed of the input shaft 25 can be detected. A rotation detector 103 is also provided in the vicinity of the gear 9 inserted and fixed to one end of the drive shaft 27 to detect the number of rotations of the gear 9.
  The power source rotation speed detector 104 and the rotation detector 103 are connected to the controller 100, and the detection values of the power source rotation speed detector 104 and the rotation detector 103 are input to the controller 100. .
[0023]
  A speed indicator and solenoid valves 105 and 106 are connected to the controller 100 and are controlled by the controller 100. The speed display is configured such that the speed is calculated from the detection values of the power source rotation speed detector 104 and the rotation detector 103 and displayed. Further, the operation of the clutch 11 and the clutch 12 is controlled by electromagnetic valves 105 and 106 connected to the controller 100.
  In the controller 100, an operation is performed based on the detection values of the power source rotational speed detector 104 and the rotational detector 103, and the controller 100 controls the electromagnetic valves 105 and 106 so that the clutches 11 and 12 are disconnected or connected. Switching takes place.
  That is, by the controller 100Hydraulic-mechanical transmission (HMT)The driving state can be automatically switched according to the driving speed, and a smooth speed change is realized.
[0024]
  In the driving method, when the drive shaft 27 is driven by the drive force of the hydraulic motor output shaft 26 of the HST 21, the drive shaft is driven by the combined drive force of the drive force of the input shaft 25 and the drive force of the hydraulic motor output shaft 26. The case where the motor 27 is driven is set to the HMT mode. In the HST mode, the clutch 11 is disengaged and the clutch 12 is connected as described above. In the HMT mode, the clutch 11 is connected and the clutch 12 is disconnected as described above.
  In FIG. 4, a graph 41 indicates the hydraulic oil discharge amount of the hydraulic pump 22, a graph 42 indicates the hydraulic oil discharge amount of the hydraulic motor 23, and a graph 43Hydraulic-mechanical transmission (HMT)Is shown.
  In the graph 43, the left side from the neutral point N is the backward drive, and the right is the forward drive. Further, at the neutral point N, the output rotation is 0 and no drive is performed. In this configuration, the drive is driven in the HST mode in the entire area on the reverse side and in the range of low speed rotation on the forward side, and is driven in the HMT mode in the range of medium speed rotation and high speed rotation.
[0025]
  Next, a control configuration of the discharge amount of the hydraulic pump 22 will be described with reference to a graph 41 showing the hydraulic oil discharge amount of the hydraulic pump 22 corresponding to the graph 43. The discharge amount of the hydraulic pump 22 is 0 at a point corresponding to the neutral point N of the graph 43, the discharge amount is negative below the discharge amount 0, and the upward is positive. Points P1 and P2 are the minimum discharge amount in the hydraulic pump 22. That is, the discharge amount of the hydraulic pump 22 at the points P1 and P2 is the maximum negative discharge amount.
  In the graph 42, the hydraulic oil discharge amount of the hydraulic motor 23 decreases on the backward side from the point P2, and decreases on the forward side from the point P1, and the discharge amount is constant between the points P1 and P2. It is kept in.
[0026]
  That is, when the output rotation is increased to the reverse side from the neutral point N, the output rotation for driving the hydraulic motor 23 to the reverse side is increased by increasing the discharge amount of the hydraulic pump 22 to the negative side. That is, by tilting the movable swash plate 22a of the hydraulic pump 22 to the minus side, the hydraulic oil discharge of the hydraulic pump 22 is increased to the minus side. Since the discharge amount of the hydraulic motor 23 is kept constant, when the discharge amount of the hydraulic pump 22 increases to the minus side, the hydraulic motor 23 is further driven to the minus side.
[0027]
  When the output rotation is further increased to the reverse side and the output rotation is performed to the reverse side rather than the point P2, the discharge amount of the hydraulic pump 22 is maintained at the discharge amount at the point P2, and the discharge amount of the hydraulic motor 23 is decreased. Thereby, the relative discharge amount of the hydraulic pump 22 and the hydraulic motor 23 changes, and the discharge amount of the hydraulic pump 22 increases with respect to the discharge amount of the hydraulic motor 23. That is, the output of the hydraulic motor 23 further increases to the minus side. As described above, by adjusting the discharge amounts of the hydraulic pump 22 and the hydraulic motor 23 when performing output control on the reverse side, it is possible to increase the output rotation range to the reverse side.
[0028]
  Next, a case where the output rotation is increased toward the forward side will be described.
  Increasing the output rotation forward from the neutral point N is performed by increasing the discharge amount of the hydraulic pump 22. Since the discharge amount of the hydraulic motor 23 of the HST 21 is constant, the discharge amount of the hydraulic pump 22 increases with respect to the discharge amount of the hydraulic motor 23 by increasing the discharge amount of the hydraulic pump 22, and the rotation of the hydraulic motor 23. Increase. In the HST mode, the drive is performed only by the HST 21, so that the output rotation increases as the output rotation of the hydraulic motor 23 increases. Further, no clutch operation is required when shifting from the reverse range to the forward range and when shifting from the forward range to the reverse range. Since shifting is performed by the HST 21 in the entire reverse speed range and the forward low speed range, the clutch operation is not required in the entire reverse speed range and the forward low speed range. For this reason, smooth shifting operation can be performed in the entire reverse speed range and in the forward low speed range, and since the shifting is performed by the HST 21 which is easy to perform delicate speed arbitration, operability is good.
[0029]
  When the discharge amount of the hydraulic pump 22 is further increased in the forward-side output range, the output rotation in the HST mode coincides with the output rotation in the HMT mode corresponding to the discharge amount of the hydraulic pump 22 at the point X. That is, when the output rotation on the forward side is increased, switching from the HST mode to the HMT mode is performed at this point X. Further, when the output rotation is decreased from the state of outputting in the HMT mode and the output rotation is decreased from the point X, switching from the HMT mode to the HST mode is performed.
[0030]
  As described above, switching from the HST mode to the HMT mode is performed by controlling connection and disconnection of the clutch 11 and the clutch 12.
That is, as shown in FIG. 5, when switching from the HST mode to the HMT mode, the clutch 11 is operated from the disconnected state to the connected state, and the clutch 12 is operated from the connected state to the disconnected state. Conversely, when switching from the HMT mode to the HST mode, the clutch 12 is operated from the disconnected state to the connected state, and the clutch 11 is operated from the connected state to the disconnected state.
  By controlling the clutches 11 and 12 as described above, the drive mode at the point X can be switched.
[0031]
  When the output rotation exceeds the point X and driving is performed in the HMT mode, the input shaft 25 to which the rotation supplied from the hydraulic motor 23 to the planetary gear unit 7 and the rotation of the engine 24 are mechanically transmitted is the planetary gear. The output rotation is determined by the rotation supplied to the unit 7. That is, in the HMT mode, the output rotation increases as the difference between the rotational speeds of the input shaft 25 and the hydraulic motor 23 increases.
  If the discharge amount of the hydraulic pump 22 is decreased and the output rotation of the hydraulic motor 23 is decreased in the output rotation forward from the point X, the input shaft 25 is maintained constant. The difference in output rotation of the shaft 25 increases. This increases the output rotation.
[0032]
  Further, when the discharge amount of the hydraulic pump 22 is decreased and the discharge amount of the hydraulic pump 22 reaches P1, the discharge amount of the hydraulic pump 22 is maintained at P1, and the discharge amount of the hydraulic motor 23 decreases. . Since the discharge amount of the hydraulic pump 22 is constant and the discharge amount of the hydraulic motor 23 decreases, the discharge amount of the hydraulic pump 22 with respect to the hydraulic motor 23 increases relatively. Thereby, the hydraulic motor 23 is accelerated. As shown in the graphs 41 and 42, the output rotation of the hydraulic motor 23 increases to the minus side. Therefore, the input rotation of the input shaft 25 to the planetary gear unit 7 and the input of the hydraulic motor 23 to the planetary gear unit 7 are performed. The difference in rotation increases and the output rotation increases.
[0033]
  As described above, the discharge amount of the hydraulic pump 22 is adjusted to control the output of the hydraulic motor 23. When the output is further increased, the discharge amount of the hydraulic pump 22 is kept constant, and the discharge amount of the hydraulic motor 23 is controlled. By adjusting the output and adjusting the output by changing the relative discharge amount of the hydraulic pump 22 and the hydraulic motor 23, the range of adjustable output rotation can be increased even in a hydraulic pump and a hydraulic motor having a small discharge amount. For this reason, HST21 can be comprised compactly.
  In addition, since the HST mode and the HMT mode are switched at the point X where the output rotations of the HST mode and the HMT mode coincide with each other, the output mode can be smoothly switched.
[0034]
  Further, in the above configuration, the output is made by the HST 21 in the entire reverse region and the forward low speed region, and from the intermediate forward speed region to the high speed regionHydraulic-mechanical transmission (HMT)Because it is driven byHydraulic-mechanical transmission (HMT)By mounting the gear, it is possible to perform a shift according to the usage situation of the small vehicle. In addition, since the shift range corresponds to a small vehicle, the handleability of the small vehicle is improved.
[0035]
  Further, since the vehicle is driven by the HST 21 in the forward and reverse zones, a delicate speed setting can be performed in the double speed range, and the quality of work can be improved. Also, from the middle forward speed range to the high speed rangeHydraulic-mechanical transmission (HMT)As a result, the engine can be smoothly shifted, and at the same time, the loss of engine output can be reduced, the output can be improved, and the fuel consumption can be improved. Furthermore, the speed change mechanism can be configured simply.
[0036]
  In the following, shifting with the controller 100 or the like as the center,Shift modeA control structure such as switching and braking will be described with reference to FIGS. 3 and 6 to 13.
  As shown in FIG. 3, a brake pack 110 is disposed on the drive shaft 18, and the brake pack 110 is controlled via the mechanical link 141 by depressing the brake pedal 140 to generate a brake action on the drive shaft 18. It is composed. The blur brake switch 111 is configured to output an operation signal to the controller 100 when the brake pedal 140 is depressed.
[0037]
  The controller 100 is linked with a speed ratio indicating lever 120, a pump swash plate controller 121, and a motor swash plate controller 122, which are travel operation levers, and between the speed ratio indicating lever 120 and the controller 100. A position sensor 120a for detecting the operation amount of the speed ratio indicating lever 120 is provided. Then, the controller 100 that has input the detection result of the position sensor 120a outputs the inclination angle to the pump / motor swash plate controllers 121 and 122, respectively, thereby interlocking with the pump / motor swash plate controllers 121 and 122. The rotary swash plates 22a and 22b of the hydraulic pumps and motors 22 and 23 are adjusted to control the rotation output of the HST 21.
[0038]
  Further, electromagnetic valves 105 and 106 are interlocked with the controller 100, and the electromagnetic valves 105 and 106 are controlled to control the connection and disconnection of the clutches 11 and 12. Further, the gear 9 fixed to the drive shaft 27 is provided with a rotation detector 103 so that the rotational speed and direction of the drive shaft 27 can be detected. The controller 100 can input the rotation speed and the rotation direction.
[0039]
  With the above configuration, the above-described HST mode and HMT mode areShift mode switchingA control method will be described with reference to FIGS.
  As described above, at the point X where the output rotation in the HST mode coincides with the output rotation in the HMT mode.Shift mode switchingIt is possible to reduce the shock caused by the switching operation,Shift modeSince the switching is performed by operating the clutches 11 and 12 via the electromagnetic valves 105 and 106 according to an instruction from the controller 100, an electrical delay time and a mechanical delay time are generated. For this reason, after detecting the switching speed ratio Vx at the point X,Shift modeWhen a switching instruction is issued, a timing shift occurs and a shock due to the switching operation occurs.
[0040]
  Therefore, we added delay timeShift mode offThe replacement control method will be described with reference to the flowchart of FIG.
  First, in process 232, the controller 100 detects and inputs the rotational speed of the engine 24 from the power source rotational speed detector 104 and the hydraulic oil temperature of the hydraulic oil tank 130 for the hydraulic machine from the hydraulic oil sensor 131. Then, the delay time h is calculated from the delay time calculation map using the input engine speed and hydraulic oil temperature as input values. The delay time calculation map is a mapping in which the engine speed and hydraulic oil temperature are associated with the electrical and mechanical operation required times of the clutches 11 and 12.
[0041]
  Then, in the process 233, simulation calculation is performed with the delay time h as the time interval, and the speed ratio V (t + h) after h seconds at the time t is predicted. Here, prediction calculation by the Miln method is performed as an example. However, since the delay time h is a time step, various other simulation calculations are possible. Next, in the conditional branch 234, the speed ratio V (t + h) after h seconds calculated for prediction is compared with the switching speed ratio Vx at the point X, and the speed ratio V (t + h) is larger than the speed ratio Vx. If there is (that is, it is predicted that the switching arrival point X is reached after h seconds), the clutch 11 is operated in the process 235. Thereby, the gear 14 described above is driven by the hydraulic motor output shaft 26, and the power in the HMT mode starts to be driven.
[0042]
  In the conditional branch 236, the current speed ratio V (t) is compared with the switching speed ratio Vx. If the speed ratio V (t) is smaller than the speed ratio Vx, the control loop end 238 is passed back to the start 231 and the next control loop is entered. Then, when the speed ratio V (t) becomes larger than the speed ratio Vx again in process 236, the process proceeds to process 237 and the clutch 12 is disengaged. Thereby, the drive transmission from the hydraulic motor output shaft 26 to the drive shaft 27 via the gears 15 and 16 is cut off, and the power in the HST mode is cut off.
  If the speed ratio V (t + h) is smaller than the switching speed ratio Vx in the process 234, the process proceeds to the conditional branch 236, where the speed ratio V (t) is determined, and then the loop control is performed.
[0043]
  That is, the delay time h is set as a simulation calculation time step, and the speed ratio V (t + h) after h seconds at a certain time t is predicted from the time step, and the speed ratio V (t + h) isShift modeIt is determined whether or not the speed ratio Vx, which is the optimum speed ratio for switching, is reached. If the speed ratio V (t + h) is expected to reach the speed ratio Vx, the clutch 11 is immediately connected and driving in the HMT mode is started. Then, the control loop is continued, and when the current speed ratio V (t) reaches the speed ratio Vx, the clutch 12 is immediately disconnected and the drive in the HST mode is shut off. FIG. 7 is a graph showing the relationship between time and speed ratio, and FIG.Shift modeIt is a figure showing the connection state of the clutch 11 and the clutch 12 by switching control. Time Tx is a predicted time for the speed ratio to reach Vx, and FIG. 8 shows that the clutch 11 is operated h hours before time Tx and the clutch 12 is disengaged when time Tx is reached. Yes.
[0044]
  Next, a method for controlling the HST 21 of the present invention will be described with reference to FIGS. In the HST mode and the HMT mode, acceleration / deceleration is possible by controlling the discharge amount of the hydraulic pumps / motors 22/23 of the HST 21, and as described above, on both sides of P1 / P2 shown in FIG. The target for changing the discharge amount is switched between the hydraulic pumps / motors 22/23.
[0045]
  In such a configuration, even when the operator desires rapid deceleration or acceleration, the control of the discharge amount of the hydraulic pump 22 and the control of the discharge amount of the hydraulic motor 23 are performed sequentially. The time will be longer. Therefore, these problems are solved by performing the indicated speed ratio control as shown in FIG.
[0046]
  First, the case of sudden deceleration from Pa to Pb in FIG. 4 will be described.
  At Pa, the operator operates the speed ratio instruction lever 120 to give a speed ratio instruction targeting Pb. At this time, the discharge amounts of the hydraulic pumps and motors 22 and 23 that realize the speed ratio at Pb are determined. Therefore, the controller 100 issues a control command to the pump / motor swash plate controllers 121 and 122 at the same time. Thus, the movable swash plates 22a and 23a of the hydraulic pumps and motors 22 and 23 are simultaneously inclined to realize the speed ratio at Pb.
[0047]
  Thereby, rapid deceleration from Pa to Pb is possible, the operator can obtain the expected speed quickly, and operability is improved. Further, even in the case of rapid acceleration from Pb to Pa, it is possible by performing the same operation as described above.
[0048]
  A case will be described in which a shift is made across the shift mode switching point X in FIG.
  In the case of rapid acceleration from Pc to Pa in FIG. 4, the operator operates the speed ratio instruction lever 120 at Pc to give a speed ratio instruction targeting Pa. At this time, the discharge amounts of the hydraulic pumps / motors 22, 23 that realize the speed ratio at Pa are determined. However, when the discharge amount in Pa is instructed to the hydraulic pumps 22 and 23 in Pc, since the point X is crossed as described above, the switching from the HST mode to the HMT mode is performed, and a shock due to the mode switching is caused. May occur, and in some cases, the parts such as the clutches 11 and 12 may be damaged.
[0049]
  Therefore, when the speed ratio instruction of Pa is performed at Pc, the controller 100 instructs the pump / motor swash plate controllers 121 and 122 about the switching speed ratio Vx at the point X. As a result, the hydraulic pumps / motors 22, 23 are adjusted to the speed ratio at the point X, and at this time, the switching from the HST mode to the HMT mode is performed. Subsequently, the controller 100 instructs the speed ratio at Pa to the pump / motor swash plate controllers 121 and 122, and simultaneously adjusts the movable swash plates 22a and 23a of the hydraulic pumps and motors 22 and 23 so as to adjust the speed at Pd. Get the ratio.
[0050]
  In this way, even in the rapid acceleration across the X point, the rapid acceleration can be performed without applying a load to the clutch etc. once through the speed ratio Vx at the X point. Acceleration is also possible. Similarly, even in the case of sudden deceleration from Pa to Pc, after passing through the speed ratio Vx at the point X, a shock of switching from the HMT mode to the HST mode is generated by instructing the speed ratio of Pc. Without slowing down.
[0051]
  The control flow shown in the above example of sudden acceleration and sudden deceleration from Pa to Pb and Pc to Pa will be described with reference to the flowchart of FIG.
  First, it is determined whether or not the speed ratio instructed in the conditional branch 242 extends over the point X. And if you do not cross the X point,Shift modeSince switching (switching between the HST mode and the HMT mode) is not required, the hydraulic pumps / motors 22 and 23 are simultaneously controlled using the speed ratio instructed in the process 244 as a target speed ratio to perform a shift. In the case where the speed is changed over the point X, in step 243, the switching speed ratio Vx is set to the provisional target speed ratio. And in conditional branch 245Shift modeDetermining whether switching is possible, that is, as described aboveShift modeDetermine the switching timing. If the switching is impossible (the output rotations of the HST mode and the HMT mode are different), the waiting time loop 246 is repeated, and when switching is possible, the process 247Shift modeIn step 248, the operator's instruction speed ratio is set to the target speed ratio, and the hydraulic pumps and motors 22 and 23 are simultaneously controlled to perform rapid acceleration and rapid deceleration.
[0052]
  next,Shift modeThe HST mode and HMT mode switching restriction control near the switching point X will be described.
  As described above, switching from the HST mode to the HMT mode and switching from the HMT mode to the HST mode are as follows.Shift modeAlthough it is performed at the switching point X, the speed ratio changes automatically due to external factors such as when a load change occurs during traveling at the speed ratio near the point X.Shift modeMay switch. As a result, frequently around point XShift modeThere is a problem that switching occurs, the load on the clutches 11 and 12 and the like becomes large, and vibrations continue to occur frequently.
[0053]
  In order to solve these problems, the following configuration is adopted. That is, at point XShift modeThe switching control of the speed ratio is performed only when instructed by the operator from the speed ratio indicating lever 120, or the speed ratio shift according to the instruction of the speed ratio indicating lever 120, orShift modeAfter switchingShift modeControl to maintain. By performing such control, for example, even when traveling with large load fluctuations in tractor towing work, etc.Shift modeFrequent switching does not occur and stable running is possible.
[0054]
  Next, the volumetric efficiency sharing control will be described.
  Since the volumetric efficiency of the HST 21 in the speed change portion changes due to load fluctuations, even if the operator operates the speed ratio indicating lever 120 to control the hydraulic pumps / motors 22/23, the expected speed cannot be obtained. There is a need for correction. Therefore, a control flow for correction sharing will be described with reference to the flowchart of FIG. First, in the conditional branch 252, it is determined whether or not the swash plate angle of the movable swash plate 22a of the hydraulic pump 22 is maximum. If the swash plate angle of the movable swash plate 22a is not maximized, an instruction is sent to the pump swash plate controller 121 to correct the tilt by moving the movable swash plate 22a. If it is detected that the swash plate angle of the movable swash plate 22a is the maximum, the target swash plate angle value of the movable swash plate 23a of the hydraulic motor 23 of the HST 21 is calculated in the process 253, and the motor swash plate controller 122 is obtained. Is sent to control the swash plate angle of the hydraulic motor 23. .
[0055]
  Thereby, correction at the time of load fluctuation is performed by controlling the movable swash plate 22a of the hydraulic pump 22 within a range that can be corrected by the hydraulic pump 22. After the swash plate angle of the movable swash plate 22a reaches the maximum, the movable swash plate 23a of the hydraulic motor 23 inherits the correction, so that the correction can be continuously performed in the vicinity of P1 and P2 in FIG. It can reduce the shock and discomfort.
[0056]
  Next, a method for improving the operation feeling by the speed ratio indicating lever 120 will be described.
  As described above, when the speed ratio indicating lever 120 is operated by the operator, the position sensor 120a detects the operation amount (position or rotation angle, etc.) of the speed ratio indicating lever 120, and the controller 100 inputs the detection result. . Here, the controller 100 calculates the target speed 222 of the traveling vehicle from the input value 221, but there are several relationships 223 between the input value 221 and the target speed 222 depending on the input value 221 from the position sensor 120a as shown in FIG. It is divided and divided into areas. In the present embodiment, when the input value 221 is in the low speed range, the slope of the relationship 223 is small, and as the input value 221 becomes the medium speed range and the high speed range, the slope of the relationship 223 increases. Yes.
[0057]
  Then, the controller 100 outputs the target speed 222 calculated from the relationship 223 to the pump / motor swash plate controllers 121 and 122, and the pump / motor swash plate controllers 121 and 122 move the movable pumps of the hydraulic pumps and motors 22 and 23. The plates 22a and 22b are controlled to output the target speed 222.
[0058]
  Since the controller 100 calculates the target speed 222 based on the relationship 223 as described above, the relationship between the operation amount of the speed ratio indicating lever 120 and the target speed 222 is not a simple linear function as in the prior art. If the indicated position of the ratio indicating lever 120 is a low speed position, a moderate speed increase is performed. As a result, when the worker wants to move delicately at a low speed, such as when the aircraft is housed in a warehouse, an operation that matches the operator's sense can be performed. Further, if the indicated position of the speed ratio indicating lever 120 is a high speed position, the acceleration increases. As a result, effective acceleration / deceleration can be performed during high-speed traveling that does not require a subtle speed change, and even when it is desired to increase the speed from a low speed range, a speed that fits the operator's sense can be obtained.
[0059]
  Next, a method for controlling the target speed 222 according to the operation speed of the speed ratio indicating lever 120 will be described.
  As described above, the operation amount of the speed ratio indicating lever 120 is detected by the position sensor 120a, and the controller 100 inputs the input value 221. Here, the speed correction means 224 uses the input value 221 as shown in FIG. An operation speed (ΔV / Δt) of the speed ratio indicating lever 120 is calculated, and a correction value (k × ΔV / Δt) obtained by multiplying the operation speed by a coefficient k is output. Then, the target speed 222 is calculated using the value obtained by adding the correction value to the input value 221 as a new input value 221.
[0060]
  By performing such control, conventionally, even if the speed ratio indicating lever 120 is moved quickly, if the movement does not move to a position where the operation becomes large, the traveling speed does not increase to the expected speed, and the operation feeling is deteriorated. When the speed ratio indicating lever 120 is operated at a high speed in the hope that the operator wants to increase the speed quickly, the target speed 222 is set in consideration of the operation speed. The traveling speed expected by the operator is set, and an operation feeling that matches the operator's sense is obtained.
[0061]
  Next, the operation state of the brake mechanism will be described with reference to the flowchart of FIG.
  First, in the conditional branch 202, the controller 100 detects the state of the brake switch 111. If the brake switch 111 is turned on by an operator's operation during traveling in the HST mode or the HMT mode, the clutch 11 or the clutch 12 is disconnected in a process 203. As a result, the brake pack 110 causes a brake action on the drive shaft 18, but the clutch 12 is disengaged when traveling in the HST mode and the clutch 11 is disengaged when traveling in the HMT mode. Since the transmission is cut off, the braking action and the driving force do not compete with each other, the braking action is efficiently generated, the wear of the clutches 11 and 12 can be prevented, and the durability of the clutches 11 and 12 can be improved. is there.
[0062]
  Next, when the ON signal is not detected from the brake switch 111 in the conditional branch 202, the detection result of the previous conditional branch 202 is further determined in the conditional branch 204, and the previous brake switch 111 does not detect the ON signal. Proceed to the end 210 of the control loop, then proceed from start 201 to the next control loop. That is, when the brake switch 111 is maintained in the ON state, the process is not performed and the control loop is repeated.
[0063]
  On the other hand, if the previous conditional branch 202 has detected an ON signal in the conditional branch 204, that is, the ON signal is detected from the brake switch 111 in the previous control loop, and the ON signal from the brake switch 111 in the current control loop. If not detected, the actual speed ratio value is set to the target speed ratio in step 205. Here, the actual speed ratio is the speed ratio of the drive shaft 27 detected by the rotation detector 103. Then, in process 206, the inclination angle of the hydraulic pump / motor 22/23 is calculated from the target gear ratio, and the controller 100 swash plate of the hydraulic pump / motor 22/23 via the pump / motor swash plate controller 121/122. Control the corners. Then, the target speed ratio is compared with the speed ratio at the point X in the conditional branch 207, and if the target speed ratio is larger than the speed ratio at the point X, the clutch 11 is connected in step 208 to transmit power to the HMT. If the vehicle travels and the target gear ratio is smaller than the gear ratio at point X, the clutch 12 is connected in step 209 to transmit power and perform HST travel.
[0064]
  In this way, when releasing the brake from the power cut state by the clutches 11 and 12 and returning the driving force, the speed ratio on the power transmission side and the actual speed ratio of the drive shaft 27 are combined, and then the HST is further increased. After determining the mode and HMT mode, the clutches 11 and 12 are configured to be re-fitted, so that the power can be restored smoothly and the impact on the components such as the clutches 11 and 12 can be reduced. In addition, durability can be improved.
[0065]
  Finally, a control method by the controller 100 or the like during the neutral position operation of the speed ratio indicating lever 120 will be described with reference to the flowchart of FIG.
  The rotational driving force from the engine 24 is shifted and output by adjusting the swash plate angle of the hydraulic pumps / motors 22/23 of the HST according to the operation amount of the speed ratio indicating lever 120, and the machine is stopped. In this case, the speed ratio indicating lever 120 is operated to the neutral position. Therefore, when the controller 100 detects that the speed ratio indicating lever 120 has been operated to the neutral position, it is first determined whether or not the swash plate angle of the HST hydraulic pump 22 is near the neutral position in the conditional branch 212 in the figure. .
[0066]
  Here, when the swash plate angle of the hydraulic pump 22 is not in the neutral position, in the process 217, control is performed so that the swash plate angle of the hydraulic pump 217 becomes the neutral stationary swash plate angle on the flat ground. Return to start 211 to perform the next control loop. On the other hand, when it is detected that the position is near the neutral position in the conditional branch 212, it is further determined whether or not the speed ratio is low in the conditional branch 213. If it is low, the rotational direction is determined in the conditional branch 214. Do.
[0067]
  If the rotational direction is forward, in step 216, the swash plate angle of the hydraulic pump 22 is decreased by the minimum operating swash plate angle (the minimum unit by which the angle of the inclined plate of the hydraulic pump 22 can be adjusted). If the rotational direction is reverse, in step 215, the swash plate angle of the hydraulic pump 22 is increased by the minimum operating swash plate angle. That is, when the vehicle is moving forward at a low speed, the vehicle accelerates slightly in the backward direction. When the vehicle is moved backward at a low speed, the vehicle accelerates slightly in the forward direction.
[0068]
  When the above process 215 or 216 is finished, the process returns from the end 218 of the neutral control flow to the start 211 to repeat the next control loop. By repeating the above-described processing, the aircraft that is moving forward at low speed gradually decelerates and eventually travels backward at low speed. Then, the aircraft that has entered the low speed reverse travel state gradually increases in speed, and eventually shifts to the forward travel at a low speed. Similarly, the low-speed forward and reverse movements are repeated in the low-speed reverse aircraft.
[0069]
  By performing such neutral control, if the operation to the neutral position of the speed ratio indicating lever 120 is performed, the aircraft repeats a slight forward and backward movement at a low speed, but the acceleration or deceleration in the processing 215 and 216 is performed. Since this is performed in the smallest unit capable of adjusting the angle of the swash plate, the machine in a very low speed state can be slightly moved back and forth slightly and can maintain a substantially stopped state. And since the motive power is transmitted to the drive shaft 27 in the stop state by this neutral control, even when stopping on an inclined surface or a hill, a reliable stop state can be maintained. Further, when the speed ratio indicating lever 120 is operated again to the forward or reverse speed ratio, the operation such as the clutch connection is unnecessary, so the delay time at the start is eliminated and the operator's operation feeling is improved. And neutral control with excellent operability is realized.
[0070]
【The invention's effect】
  Since the present invention is configured as described above, the following effects can be obtained.
  As in claim 1Hydraulic transmission unit using an HST continuously variable transmission constituted by a hydraulic pump and a hydraulic motor, and a hydraulic pressure-shifted by the HST continuously variable transmission and a planetary gear unit-a hydraulic pressure provided with a mechanical transmission (HMT)- In the HST control method of the mechanical transmission, control is performed so that the HST mode by the HST continuously variable transmission and the HMT mode by the hydraulic-mechanical transmission (HMT) are automatically switched at the transmission mode switching point (X). Then, with respect to the target speed ratio instructed by the speed ratio indicating lever which is the travel operation lever, the HST mode in which the shift to the target speed ratio is a traveling state by the HST continuously variable transmission, and the hydraulic-mechanical type When the vehicle travels across the shift mode switching point (X) of the HMT mode, which is a traveling state by the speed change mechanism, the speed ratio at the shift mode switching point (X) is changed as the provisional target speed ratio to change the speed. After over de switching operation, shifting the speed ratio which is instructed by the speed ratio instruction lever as the target speed ratioSoShift modeEven when the gear ratio across the switching point is instructed, the speed expected by the operator can be obtained quickly without generating a shock.
[0071]
  As in claim 22. The HST control method for a hydraulic-mechanical transmission according to claim 1, wherein when performing a shift over the shift mode switching point (X) in addition to the instruction by the speed ratio indicating lever, the current shift at the instructed time point. Since the speed is changed while maintaining the mode,Even if you run a large load fluctuation in tractor towing work, etc.Shift modeAs a result, frequent switching was not generated, and stable driving became possible.
[Brief description of the drawings]
FIG. 1 is a front view of a hydraulic-mechanical transmission.
FIG. 2 is a cross-sectional view taken along line AA in FIG.
FIG. 3 is a block diagram of a hydraulic-mechanical transmission.
FIG. 4 is a diagram showing a relationship between an output of a hydraulic-mechanical transmission and a discharge amount of a hydraulic pump and a hydraulic motor.
FIG. 5 is a diagram illustrating an operation state of a clutch corresponding to a shift state.
FIG. 6 is a flowchart of clutch switching instruction control.
FIG. 7 is a relationship diagram of time and speed ratio.
FIG. 8 is a control output diagram of a clutch with time as an axis.
FIG. 9 is an instruction speed ratio control flowchart.
FIG. 10 is a flow chart of volume correction sharing control.
FIG. 11 is a correspondence diagram between an operation amount of a speed ratio indicating lever and a target speed.
FIG. 12 is a control diagram of a controller.
FIG. 13 is a brake control flowchart.
FIG. 14 is a flowchart of neutral control.
[Explanation of symbols]
  22 Hydraulic pump
  22a (Hydraulic pump) Movable swash plate
  23 Hydraulic motor
  23a (Hydraulic motor) Movable swash plate
  100 controller
  103 Rotation detector
  104 Engine speed detector
  105 Solenoid valve
  106 Solenoid valve
  110 Brake pack
  111 Brake switch
  120 Speed ratio indicator lever
  120a Position sensor
  121 Pump swash plate controller
  122 Motor swash plate controller

Claims (2)

Hydraulic transmission unit using an HST continuously variable transmission constituted by a hydraulic pump and a hydraulic motor, and a hydraulic pressure-shifted by the HST continuously variable transmission and a planetary gear unit-a hydraulic pressure provided with a mechanical transmission (HMT)- In the HST control method of the mechanical transmission, control is performed so that the HST mode by the HST continuously variable transmission and the HMT mode by the hydraulic-mechanical transmission (HMT) are automatically switched at the transmission mode switching point (X). Then, with respect to the target speed ratio instructed by the speed ratio indicating lever which is the travel operation lever, the HST mode in which the shift to the target speed ratio is a traveling state by the HST continuously variable transmission, and the hydraulic-mechanical type When the vehicle travels across the shift mode switching point (X) of the HMT mode, which is a traveling state by the speed change mechanism, the speed ratio at the shift mode switching point (X) is changed as the provisional target speed ratio to change the speed. After over de switching operation, hydraulic, characterized in that the transmission speed ratio instructed by the speed ratio instruction lever as the target speed ratio - HST control method for a mechanical transmission. 2. The HST control method for a hydraulic-mechanical transmission according to claim 1, wherein when performing a shift over the shift mode switching point (X) in addition to the instruction by the speed ratio indicating lever, the current shift at the instructed time point. A HST control method for a hydraulic-mechanical transmission, characterized in that shifting is performed while maintaining a mode .

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