JP5063431B2 - Tractor - Google Patents

Description

  The present invention relates to a tractor that performs a multi-stage traveling shift by connecting a main transmission and a sub-transmission that are configured using a hydraulic clutch in series.

2. Description of the Related Art A tractor that performs a multi-stage traveling shift by connecting a main transmission and a sub-transmission configured using a hydraulic clutch in series is known. For example, the tractor shown in Patent Document 1 is a main transmission (first main transmission mechanism) that performs three-speed shifts with three hydraulic clutches, and a sub-transmission (first transmission) that performs two-speed shifts with two hydraulic clutches. A two-speed transmission), and these hydraulic clutches are operated and controlled based on the pressure increase control of the electromagnetic proportional valves, respectively, so that a six-stage traveling shift is possible. In addition, the tractor disclosed in Patent Document 2 includes a main transmission that performs four shifts with four hydraulic clutches, and a sub-transmission that performs two shifts with two hydraulic clutches, and constitutes a main transmission. The four hydraulic clutches to be operated are controlled based on the switching control of the electromagnetic direction switching valve, and the two hydraulic clutches constituting the auxiliary transmission are controlled to operate based on the boost control of the electromagnetic proportional valve. It is possible to change the gear speed.
JP 2000-205391 A JP 2000-62500 A

  According to the hydraulic clutch operation control based on the pressure increase control of the electromagnetic proportional valve, a smooth running shift with less shift shock is possible. However, as in Patent Document 1, the hydraulic clutches of the main transmission and the sub-transmission are used. If all are controlled by an electromagnetic proportional valve, there is a problem that the required number of electromagnetic proportional valves increases, resulting in an expensive travel transmission. On the other hand, in the one disclosed in Patent Document 1, although each hydraulic clutch of the sub-transmission is controlled by an electromagnetic proportional valve, each hydraulic clutch of the main transmission is controlled by an electromagnetic direction switching valve. However, in order to perform a smooth travel shift based on the pressure increase control of the electromagnetic proportional valve, the hydraulic clutch of the sub-transmission device must be engaged / disengaged at every shift, and thus provided in the sub-transmission device. It is necessary to improve the durability of the hydraulic clutch, and there is a possibility that the shift time becomes longer due to the simultaneous shift of the main transmission and the auxiliary transmission, or that a shift shock occurs due to the shift timing of both transmissions.

SUMMARY OF THE INVENTION The present invention has been created in view of the above-described circumstances in order to solve these problems. The invention of claim 1 is directed to a main transmission and a sub-transmission that are configured using a hydraulic clutch. And a plurality of hydraulic clutches constituting the main transmission are each subjected to alternative operation control based on boost control of an electromagnetic proportional valve. The hydraulic clutch constituting the auxiliary transmission is controlled based on the switching control of the electromagnetic direction switching valve. Further, the auxiliary transmission has a neutral position and requires a change of the auxiliary transmission. in, along with cutting the main transmission, the auxiliary transmission device temporarily neutral, after reducing the rotational difference between the transmission upstream side and a transmission downstream side of the auxiliary transmission device, connect the hydraulic clutch of the auxiliary transmission device It was a tractor, characterized by further connecting the hydraulic clutch of the main transmission system based on the step-up control of the proportional solenoid valve. In this case, the travel transmission can be configured at a lower cost than that in which all the hydraulic clutches of the main transmission and the sub-transmission are controlled by electromagnetic proportional valves. Further, since it is not necessary to connect / disconnect the hydraulic clutch of the auxiliary transmission device at every shift, an increase in cost for improving the durability of the hydraulic clutch provided in the auxiliary transmission device is avoided. In addition, the auxiliary transmission has a neutral position, and at the time of traveling shift that requires switching of the auxiliary transmission, the auxiliary transmission is temporarily set to neutral, and the rotational difference between the upper transmission side and the lower transmission side of the auxiliary transmission is determined. Since the hydraulic clutch of the auxiliary transmission is connected after the reduction, the occurrence of shock at the time of switching of the auxiliary transmission can be suppressed.
According to a second aspect of the present invention, when a traveling shift requiring switching of the auxiliary transmission is performed, the transmission of the auxiliary transmission is improved by connecting the hydraulic clutch of the main transmission with the auxiliary transmission set to neutral. The tractor according to claim 1, wherein a difference in rotation between the side and the lower transmission side is reduced. In this way, since the main transmission is used to reduce the rotational difference between the transmission upper side and the transmission lower side of the auxiliary transmission, it is possible to avoid complication of structure and cost increase.
According to a third aspect of the present invention, the transmission of the sub-transmission can be performed by instantaneously connecting the hydraulic clutch of the main transmission in a state where the sub-transmission is in a neutral state at the time of traveling shift requiring switching of the sub-transmission. The rotational difference between the upper side and the lower side of the transmission is reduced, and then the hydraulic clutch of the auxiliary transmission is connected, and the hydraulic clutch of the main transmission is connected based on the boost control of the electromagnetic proportional valve. A tractor according to claim 1 or 2. If it does in this way, a series of gear shift operation can be performed smoothly, shortening the neutral stay time of an auxiliary gearbox.
In the invention of claim 4, the hydraulic clutch of the main transmission is held for a predetermined time in the vicinity of the clutch meet without being returned to the stroke end on the cutting side after being instantaneously connected in a state where the auxiliary transmission is in a neutral state. 4. The tractor according to claim 3, wherein the tractor is connected based on boost control of the electromagnetic proportional valve after the hydraulic clutch of the auxiliary transmission is connected. In this way, after connecting the hydraulic clutch of the sub-transmission device, it is possible to omit the processing and time to move the hydraulic clutch of the main transmission device to the clutch meet position, so that it can be immediately connected. Can be further shortened.

  Next, embodiments of the present invention will be described with reference to the drawings. In FIG. 1, T is an agricultural tractor, and a transmission case 1 is mounted on the tractor T. As shown in FIG. 2, the transmission case 1 inputs the power of the engine E via the main clutch mechanism 2 and branches the input power into the travel power transmission path 3 and the PTO power transmission path 4. The travel power transmission path 3 is provided with a plurality of transmissions for shifting the travel power in multiple stages. The transmission provided in the travel power transmission path 3 is configured using a frictional multi-plate hydraulic clutch, and is always meshed with a hydraulic clutch transmission that does not require the main clutch mechanism 2 on the transmission upper side to be cut off during a shift operation. And a mesh type transmission that requires the main clutch mechanism 2 to be disengaged during a shift operation. The combination of the hydraulic clutch type transmission and the mesh type transmission allows the driving power to be reduced. Multi-speed shifting is performed.

  More specifically, the travel power transmission path 3 is configured by using friction multi-plate hydraulic clutches C1 to C4, and the main transmission 5 that performs four-speed shifting, and the friction multi-plate hydraulic clutch CF, CR. , A forward / reverse transmission 6 that performs forward / reverse shift of the driving power, a high / medium / low transmission 7 that performs a three-stage shift, and a friction multi-plate type. And a sub-transmission device 8 that performs a two-step shift in high and low levels. In normal operation, as shown in FIG. 3, the main transmission 5 and the sub-transmission are provided. A combination of shifts by the device 8 enables eight-stage travel shifts and forward / reverse switching by the forward / reverse transmission 6. In the present embodiment, a 24-speed traveling shift is possible by further combining the shifts of the high, medium, and low transmission 7, but the high, medium, and low transmission 7 is not the main part of the present invention. The detailed explanation is omitted.

  The traveling power changed by the main transmission 5, the high / medium / low transmission 7 and the auxiliary transmission 8 is transmitted to the front axle and the rear axle. The power transmission path to the front axle is provided with a double speed transmission device 9 that shifts or cuts the power transmitted to the front axle at a high or low level, and the front wheel at the time of turning is changed by shifting or cutting the power by the double speed transmission device 9. Switching between double speed drive, 4WD and 2WD is performed. The double speed transmission device 9 is configured using a frictional multi-plate hydraulic clutch, thereby enabling smooth shifting and disconnection.

  The PTO power transmission path 4 is provided with a PTO clutch 10 configured using a frictional multi-plate hydraulic clutch and a PTO transmission 11 configured using a constantly meshing gear transmission. An independent PTO power transmission system that is not influenced by the state, that is, a PTO power transmission path 4 of an independent PTO specification is configured.

  The tractor T of this embodiment is configured with a hydraulic circuit as shown in FIG. This hydraulic circuit includes two hydraulic pumps P1 and P2, operates the double speed transmission device 9, the lift cylinder 12 and the lift rod cylinder 13 with the hydraulic pressure supplied from one hydraulic pump P1, and from the other hydraulic pump P2. The steering unit 14, the main transmission 5, the forward / reverse transmission 6, the auxiliary transmission 8, the PTO clutch 10, and the automatic brake turning device 15 are configured to operate with the supplied hydraulic pressure.

  At least the hydraulic clutches C1 to C4, CL, and CH of the main transmission 5 and the auxiliary transmission 8 are operated based on the control of the electromagnetic valve. According to the hydraulic clutch operation control based on the pressure increase control of the electromagnetic proportional valve, a smooth traveling shift with less shift shock is possible. However, the hydraulic clutches C1 to C4, CL, If all the CHs are controlled by an electromagnetic proportional valve, there is a problem that the required number of electromagnetic proportional valves increases, resulting in an expensive traveling transmission. Further, when the hydraulic clutches CL and CH of the auxiliary transmission 8 are controlled by electromagnetic proportional valves and the hydraulic clutches C1 to C4 of the main transmission 5 are controlled by electromagnetic switching valves, an inexpensive travel transmission is provided. However, in order to perform a smooth running shift based on the pressure increase control of the electromagnetic proportional valve, the hydraulic clutches CL and CH of the subtransmission device 8 must be engaged / disengaged at every shift. The durability of the hydraulic clutches CL and CH provided in the transmission 8 must be improved.

  Therefore, in the tractor T of the present embodiment, as shown in FIG. 4, the hydraulic clutches C1 to C4 of the main transmission 5 are selectively controlled based on the boost control of the electromagnetic proportional valves 16a to 16d, respectively. The hydraulic clutches CL and CH of the auxiliary transmission 8 are controlled based on switching control of the electromagnetic direction switching valve 17. In this way, the traveling transmission can be configured at a lower cost than that in which the hydraulic clutches C1 to C4, CL, and CH of the main transmission 5 and the auxiliary transmission 8 are all controlled by the electromagnetic proportional valves. Further, since it is not necessary to connect and disconnect the hydraulic clutches CL and CH of the auxiliary transmission 8 at every shift, an increase in cost for improving the durability of the hydraulic clutches CL and CH provided in the auxiliary transmission 8 is avoided. .

  The auxiliary transmission 8 has a neutral position, and at the time of a traveling shift that requires switching of the auxiliary transmission 8, the auxiliary transmission 8 is temporarily set to the neutral position between the upper transmission side and the lower transmission side of the auxiliary transmission 8. After the rotation difference is reduced, the hydraulic clutches CL and CH of the auxiliary transmission 8 are connected. For example, the electromagnetic direction switching valve 17 is provided with three switching positions. At the first switching position, only the hydraulic clutch CL of the auxiliary transmission 8 is engaged, and at the second switching position (neutral position: neutral position) Both hydraulic clutches CL and CH of the transmission 8 are disconnected, and only the hydraulic clutch CH of the auxiliary transmission 8 is engaged at the third switching position. Then, during a traveling shift that requires switching of the auxiliary transmission 8, the rotation of the upper transmission side and the lower transmission side of the auxiliary transmission 8 is performed in a neutral state where both hydraulic clutches CL and CH of the auxiliary transmission 8 are disconnected. By reducing the difference, it is possible to suppress the occurrence of shock due to the rotation difference.

  In order to reduce the rotational difference between the transmission upper side and the transmission lower side of the sub-transmission device 8 at the time of traveling shift that requires switching of the sub-transmission device 8, the main transmission device is kept in the state where the sub-transmission device 8 is in the neutral state. 5 hydraulic clutches C1 to C4 may be connected.

  For example, as shown in FIG. 5B, when shifting from the 4th speed to the 5th speed, after the 4th speed hydraulic clutch C4 of the main transmission 5 is turned off, the electromagnetic direction switching valve 17 is set to the neutral position, With the both hydraulic clutches CL and CH of the auxiliary transmission 8 turned off, the first speed hydraulic clutch C1 of the main transmission 5 is boosted based on the boost control of the electromagnetic proportional valve 16a. As a result, the rotational speed on the high speed hydraulic clutch CH side in the auxiliary transmission 8 decreases. Then, the electromagnetic direction switching valve 17 is switched at the timing when the rotational difference between the transmission upper side and the transmission lower side of the high speed hydraulic clutch CH becomes small, and the high speed hydraulic clutch CH of the auxiliary transmission 8 is turned on.

  On the other hand, in the case of shifting from the fifth speed to the fourth speed, the first-direction hydraulic clutch C1 of the main transmission 5 is turned off, and then the electromagnetic direction switching valve 17 is set to the neutral position, and both hydraulic clutches CL, CH of the auxiliary transmission 8 are set. In the state of being cut off, the fourth speed hydraulic clutch C4 of the main transmission 5 is boosted based on the boost control of the electromagnetic proportional valve 16d. As a result, the rotational speed on the low speed hydraulic clutch CL side in the auxiliary transmission 8 increases. Then, the electromagnetic direction switching valve 17 is switched at the timing when the rotational difference between the transmission upper side and the transmission lower side of the low speed hydraulic clutch CL becomes small, and the low speed hydraulic clutch CL of the auxiliary transmission 8 is turned on.

  Further, during a travel shift that requires switching of the subtransmission 8, the hydraulic clutches C1 to C4 of the main transmission 5 are instantaneously connected in a state where the subtransmission 8 is in the neutral state. The rotational difference between the transmission upper side and the transmission lower side is reduced, and then the hydraulic clutches CL and CH of the auxiliary transmission 8 are connected, and the hydraulic pressure of the main transmission 5 is controlled based on the boost control of the electromagnetic proportional valves 16a to 16d. The clutches C1 to C4 may be connected. In this way, it is possible to smoothly perform a series of shift operations while shortening the neutral stay time of the auxiliary transmission 8.

  For example, as shown in FIG. 6B, when shifting from the 4th speed to the 5th speed, after the 4th speed hydraulic clutch C4 of the main transmission 5 is disconnected, the electromagnetic direction switching valve 17 is set to the neutral position, With both hydraulic clutches CL and CH of the auxiliary transmission 8 being disconnected, the first-speed hydraulic clutch C1 of the main transmission 5 is instantaneously connected based on a sudden pressure increase of the electromagnetic proportional valve 16a. As a result, the rotational speed on the high speed hydraulic clutch CH side in the auxiliary transmission 8 decreases. Thereafter, the electromagnetic direction switching valve 17 is switched to turn on the high speed hydraulic clutch CH of the auxiliary transmission 8 and the first speed hydraulic clutch C1 of the main transmission 5 is turned on based on the boost control of the electromagnetic proportional valve 16a. To do. In this embodiment, an abrupt pressure increase state is instantly displayed prior to the gradual pressure increase control of the electromagnetic proportional valves 16a to 16d. This is because the hydraulic clutches C1 to C4 are quickly moved to the clutch meet position. This is a process for moving, and is intended to prevent a delay in the operation of the hydraulic clutches C1 to C4 due to simple boost control.

  Further, in the case of traveling speed change that requires switching of the auxiliary transmission 8, the hydraulic clutches C1 to C4 of the main transmission 5 are instantaneously connected in a state where the auxiliary transmission 8 is in the neutral state, and then until the stroke end on the cutting side. Without returning, the clutch clutch may be held for a predetermined time and connected based on the boost control of the electromagnetic proportional valves 16a to 16d after the hydraulic clutches CL and CH of the auxiliary transmission 8 are connected. In this way, after connecting the hydraulic clutches CL and CH of the auxiliary transmission 8, the processing and time for moving the hydraulic clutches C1 to C4 of the main transmission 5 to the clutch meet position can be omitted and immediately connected. The time required for a series of shifting operations can be further shortened.

  For example, as shown in FIG. 6C, when shifting from the 4th speed to the 5th speed, after the 4th speed hydraulic clutch C4 of the main transmission 5 is disconnected, the electromagnetic direction switching valve 17 is set to the neutral position, With both hydraulic clutches CL and CH of the auxiliary transmission 8 being disconnected, the first-speed hydraulic clutch C1 of the main transmission 5 is instantaneously connected based on a sudden pressure increase of the electromagnetic proportional valve 16a. At this time, the first-speed hydraulic clutch C1 is held for a predetermined time in the vicinity of the clutch meet without returning to the stroke end on the cutting side. Specifically, after the first-speed hydraulic clutch C1 is instantaneously connected, the pressure is increased at the timing when the first-speed hydraulic clutch C1 returns to the clutch meet position, and the pressure balanced with the return spring of the first-speed hydraulic clutch C1 is maintained. . Thereafter, the electromagnetic direction switching valve 17 is switched to turn on the high speed hydraulic clutch CH of the auxiliary transmission 8 and the first speed hydraulic clutch C1 of the main transmission 5 is turned on based on the boost control of the electromagnetic proportional valve 16a. To do.

  Next, a specific control example of the electromagnetic proportional valves 16a to 16d and the electromagnetic direction switching valve 17 will be described with reference to FIG. As shown in this figure, the tractor T is provided with a control device 22 configured using a microcomputer or the like. On the input side of the control device 22, a shift-up switch 23 that increases the traveling gear stage by one step, a shift-down switch 24 that decreases the traveling gear step by one step, and an engine rotation sensor 25 that detects engine rotation, Axle rotation sensor 26 that detects the rotation of the axle, an oil temperature sensor 27 that detects the oil temperature of the hydraulic circuit, a forward / reverse sensor 28 that detects the operating position of the forward / reverse shift lever 20, and whether the main clutch mechanism 2 is turned on or off. Is connected to the main clutch sensor 29, and the electromagnetic proportional valves 16 a to 16 d and the electromagnetic direction switching valve 17 are connected to the output side of the control device 22. That is, the control device 22 is configured to control the electromagnetic proportional valves 16a to 16d and the electromagnetic direction switching valve 17 based on the input signals from the switches 23 and 24 and the sensors 25 to 29. A control procedure of the electromagnetic proportional valves 16a to 16d and the electromagnetic direction switching valve 17 according to the operation of the shift up switch 23 and the shift down switch 24 will be described. In addition, the following description is based on Example 1 among Examples 1-3 mentioned above.

  In the first speed state, the first-speed hydraulic clutch C1 of the main transmission 5 and the low-speed hydraulic clutch CL of the auxiliary transmission 8 are engaged. When shifting from the first speed to the second speed in accordance with the operation of the upshift switch 23, the first speed hydraulic clutch C1 of the main transmission 5 is disengaged while the low speed hydraulic clutch CL of the auxiliary transmission 8 is kept engaged. The second-speed hydraulic clutch C2 is engaged based on the boost control of the electromagnetic proportional valve 16b.

  Further, when shifting from the second speed to the third speed in accordance with the operation of the upshift switch 23, the second speed hydraulic clutch C2 of the main transmission 5 is kept engaged with the low speed hydraulic clutch CL of the auxiliary transmission 8 kept engaged. The third-speed hydraulic clutch C3 is engaged based on the boost control of the electromagnetic proportional valve 16c.

  When shifting from the 3rd speed to the 4th speed in response to the operation of the upshift switch 23, the 3rd speed hydraulic clutch C3 of the main transmission 5 is kept engaged with the low speed hydraulic clutch CL of the auxiliary transmission 8 kept engaged. The 4th-speed hydraulic clutch C4 is engaged based on the boost control of the electromagnetic proportional valve 16d.

  When shifting from the 4th speed to the 5th speed in accordance with the operation of the upshift switch 23, the 4th speed hydraulic clutch C4 of the main transmission 5 is disengaged, and then the electromagnetic directional control valve 17 is set to the neutral position so With the both hydraulic clutches CL and CH of the device 8 turned off, the first speed hydraulic clutch C1 of the main transmission 5 is boosted based on the boost control of the electromagnetic proportional valve 16a. As a result, the rotational speed on the high speed hydraulic clutch CH side in the auxiliary transmission 8 decreases. Then, the electromagnetic direction switching valve 17 is switched at the timing when the rotational difference between the transmission upper side and the transmission lower side of the high speed hydraulic clutch CH becomes small, and the high speed hydraulic clutch CH of the auxiliary transmission 8 is turned on.

  Further, when shifting from the fifth speed to the sixth speed in accordance with the operation of the upshift switch 23, the first speed hydraulic clutch C1 of the main transmission 5 is kept engaged with the high speed hydraulic clutch CH of the auxiliary transmission 8 kept engaged. The second-speed hydraulic clutch C2 is engaged based on the boost control of the electromagnetic proportional valve 16b.

  When shifting from the sixth speed to the seventh speed in accordance with the operation of the upshift switch 23, the second speed hydraulic clutch C2 of the main transmission 5 is kept engaged with the high speed hydraulic clutch CH of the subtransmission 8 kept engaged. The third-speed hydraulic clutch C3 is engaged based on the boost control of the electromagnetic proportional valve 16c.

  Further, when shifting from the seventh speed to the eighth speed in accordance with the operation of the upshift switch 23, the third speed hydraulic clutch C3 of the main transmission 5 is kept engaged with the high speed hydraulic clutch CH of the subtransmission 8 kept engaged. The 4th-speed hydraulic clutch C4 is engaged based on the boost control of the electromagnetic proportional valve 16d.

  Conversely, when shifting from the 8th speed to the 7th speed according to the operation of the shift down switch 24, the 4th speed hydraulic clutch C4 of the main transmission 5 is kept with the high speed hydraulic clutch CH of the auxiliary transmission 8 kept engaged. And the third-speed hydraulic clutch C3 is engaged based on the pressure increase control of the electromagnetic proportional valve 16c.

  When shifting from the 7th speed to the 6th speed in accordance with the operation of the downshift switch 24, the 3rd speed hydraulic clutch C3 of the main transmission 5 is kept engaged with the high speed hydraulic clutch CH of the auxiliary transmission 8 kept engaged. The second-speed hydraulic clutch C2 is engaged based on the boost control of the electromagnetic proportional valve 16b.

  When shifting from the sixth speed to the fifth speed in accordance with the operation of the downshift switch 24, the second speed hydraulic clutch C2 of the main transmission 5 is turned on while the high speed hydraulic clutch CH of the subtransmission 8 is kept engaged. The first-speed hydraulic clutch C1 is engaged based on the boost control of the electromagnetic proportional valve 16a.

  When shifting from the 5th speed to the 4th speed according to the operation of the downshift switch 24, the 1st speed hydraulic clutch C1 of the main transmission 5 is disengaged, and then the electromagnetic directional control valve 17 is set to the neutral position so that the sub-shift is performed. With both hydraulic clutches CL and CH of the device 8 disconnected, the pressure of the fourth speed hydraulic clutch C4 of the main transmission 5 is increased based on the pressure increase control of the electromagnetic proportional valve 16d. As a result, the rotational speed on the low speed hydraulic clutch CL side in the auxiliary transmission 8 increases. Then, the electromagnetic direction switching valve 17 is switched at the timing when the rotational difference between the transmission upper side and the transmission lower side of the low speed hydraulic clutch CL becomes small, and the low speed hydraulic clutch CL of the auxiliary transmission 8 is turned on.

  When shifting from the 4th speed to the 3rd speed in accordance with the operation of the downshift switch 24, the 4th speed hydraulic clutch C4 of the main transmission 5 is kept engaged with the low speed hydraulic clutch CL of the auxiliary transmission 8 kept engaged. The third-speed hydraulic clutch C3 is engaged based on the boost control of the electromagnetic proportional valve 16c.

  When shifting from the 3rd speed to the 2nd speed according to the operation of the downshift switch 24, the 3rd speed hydraulic clutch C3 of the main transmission 5 is kept engaged with the low speed hydraulic clutch CL of the auxiliary transmission 8 being kept engaged. The second-speed hydraulic clutch C2 is engaged based on the boost control of the electromagnetic proportional valve 16b.

  When shifting from the second speed to the first speed in accordance with the operation of the downshift switch 24, the second speed hydraulic clutch C2 of the main transmission 5 is kept engaged with the low speed hydraulic clutch CL of the auxiliary transmission 8 kept engaged. The first-speed hydraulic clutch C1 is engaged based on the boost control of the electromagnetic proportional valve 16a.

  According to the present embodiment configured as described, the main transmission device 5 and the sub-transmission device 8 that are configured by using the hydraulic clutches C1 to C4, CL, and CH are connected in series to perform a multi-stage traveling shift. The plurality of hydraulic clutches C1 to C4 that are the tractor T and constitute the main transmission 5 are subjected to alternative operation control based on the boost control of the electromagnetic proportional valves 16a to 16d, respectively. Since the hydraulic clutches CL and CH constituting the operation are controlled based on the switching control of the electromagnetic direction switching valve 17, all the hydraulic clutches C1 to C4, CL and CH of the main transmission device 5 and the auxiliary transmission device 8 are all electromagnetic. Compared with the one controlled by the proportional valve, the traveling transmission can be configured at a low cost. Further, since it is not necessary to connect and disconnect the hydraulic clutches CL and CH of the auxiliary transmission 8 at every shift, an increase in cost for improving the durability of the hydraulic clutches CL and CH provided in the auxiliary transmission 8 is avoided. .

  In addition, the auxiliary transmission 8 has a neutral position, and at the time of traveling shift that requires switching of the auxiliary transmission 8, the auxiliary transmission 8 is temporarily set to the neutral, and the transmission upper side and the transmission lower side of the auxiliary transmission 8 are Since the hydraulic clutches CL and CH of the auxiliary transmission 8 are connected after the rotation difference is reduced, the occurrence of shock when the auxiliary transmission 8 is switched can be suppressed.

  Further, when a traveling shift requiring switching of the auxiliary transmission 8 is performed, the transmission of the auxiliary transmission 8 is transmitted by connecting the hydraulic clutches C1 to C4 of the main transmission 5 with the auxiliary transmission 8 in the neutral state. Since the rotation difference between the upper side and the lower side of transmission is reduced, it is not necessary to add a separate device, and the complexity of the structure and the increase in cost can be avoided.

  Further, according to the second and third embodiments, the hydraulic clutches C1 to C4 of the main transmission 5 are set in the state where the subtransmission 8 is in a neutral state at the time of traveling shift that requires switching of the subtransmission 8. Is connected instantaneously to reduce the rotational difference between the transmission upper side and the transmission lower side of the auxiliary transmission 8 and then the hydraulic clutches CL and CH of the auxiliary transmission 8 are connected and the electromagnetic proportional valves 16a to 16d are connected. Since the hydraulic clutches C1 to C4 of the main transmission 5 are connected based on the step-up control, a series of shifting operations can be smoothly performed while the neutral staying time of the auxiliary transmission 8 is shortened.

  In addition, according to the third embodiment, the hydraulic clutches C1 to C4 of the main transmission 5 are connected instantaneously with the auxiliary transmission 8 in the neutral state, and then are not returned to the stroke end on the cutting side. Since the hydraulic clutch CL, CH of the auxiliary transmission 8 is connected after the hydraulic clutch CL, CH of the auxiliary transmission 8 is connected in the vicinity of the meet, it is connected based on the boost control of the electromagnetic proportional valves 16a-16d. After connecting the CH, the processing and time for moving the hydraulic clutches C1 to C4 of the main transmission 5 to the clutch meet position can be omitted, and the connection can be made immediately. As a result, the time required for a series of shifting operations is further shortened. be able to.

It is a perspective view of a tractor. It is a whole sectional view of a transmission case. It is explanatory drawing of a travel shift pattern. It is a hydraulic circuit diagram which shows the hydraulic structure of a tractor. (A) is a timing chart for explaining a problem to be solved by the present invention, and (B) is a timing chart showing a first embodiment of the present invention. (A) is a timing chart for explaining a problem to be solved by the present invention, (B) is a timing chart showing a second embodiment of the present invention, and (C) is a third embodiment of the present invention. It is a timing chart which shows. It is a block diagram which shows the input / output of a control apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Transmission case 5 Main transmission 8 Sub transmission 16a-16d Electromagnetic proportional valve 17 Electromagnetic direction switching valve 22 Control apparatuses C1-C4 Main transmission hydraulic clutch CL, CH Sub transmission hydraulic clutch T Tractor

Claims (4)

A tractor that performs a multi-stage traveling shift by connecting a main transmission and a sub-transmission configured in series using a hydraulic clutch in series,
The plurality of hydraulic clutches constituting the main transmission are each subjected to alternative operation control based on boost control of an electromagnetic proportional valve,
The hydraulic clutch that constitutes the auxiliary transmission is subjected to operation control based on switching control of the electromagnetic direction switching valve,
Further, the auxiliary transmission has a neutral position,
In traveling shifting that requires switching of the sub-transmission, the main transmission is turned off, the sub-transmission is once neutral, and the rotational difference between the upper transmission side and the lower transmission side of the auxiliary transmission is reduced. A tractor characterized in that a hydraulic clutch of an auxiliary transmission is connected and further a hydraulic clutch of a main transmission is connected based on boost control of an electromagnetic proportional valve .   For travel shifting that requires switching of the sub-transmission, the hydraulic clutch of the main transmission is connected with the sub-transmission in the neutral state, so that the upper transmission side and the lower transmission side of the sub-transmission device are connected. The tractor according to claim 1, wherein the rotation difference is reduced.   For travel shifts that require switching of the auxiliary transmission, the hydraulic clutch of the main transmission is instantaneously connected in a state where the auxiliary transmission is neutral, so that the transmission upper side and transmission lower side of the auxiliary transmission are 3. The hydraulic clutch of the subtransmission device is then connected, and then the hydraulic clutch of the main transmission device is connected based on the boost control of the electromagnetic proportional valve. Tractor.   The hydraulic clutch of the main transmission is held for a predetermined time in the vicinity of the clutch meet without being returned to the stroke end on the cutting side after being instantaneously connected in a state where the auxiliary transmission is neutral, and the hydraulic clutch of the auxiliary transmission is 4. The tractor according to claim 3, wherein the tractor is connected based on boost control of the electromagnetic proportional valve after being connected.

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