JP5331570B2 - Transmission device for work vehicle - Google Patents

Description

  The present invention relates to a technology of a transmission device provided in a work vehicle, and particularly to a technology of an arrangement configuration of the transmission device.

  Conventionally, power is branched from the engine, one is transmitted to the planetary gear mechanism, and the other is transmitted to the planetary gear mechanism after a continuously variable transmission via a hydraulic continuously variable transmission mechanism (hereinafter simply referred to as “HST”). A transmission device for a work vehicle configured to synthesize and output both powers by the planetary gear mechanism is known (see, for example, Patent Document 1).

  In order to adapt the transmission to a high horsepower engine, (A) a large-capacity HST is installed, or (B) a complex power transmission mechanism is configured by using two or more planetary gear mechanisms. There was a need to do.

  However, when the measures (A) and (B) described above are taken, it is disadvantageous in that the transmission becomes large and it becomes difficult to mount the transmission on a work vehicle.

JP 2001-108060 A

  In view of the above situation, the present invention provides a transmission for a work vehicle that can be adapted to a high horsepower engine without increasing the size of the transmission.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

In Claim 1, The input shaft which transmits the motive power from a drive source, The continuously variable transmission which is arrange | positioned on the said input shaft, and outputs the power transmitted from the said input shaft in a stepless manner, A work vehicle comprising a reverser clutch device that extracts and outputs power output from a continuously variable transmission in a forward rotation direction or a reverse rotation direction on a power transmission upstream side of a differential mechanism that distributes power to left and right wheels. In this transmission, a planetary gear mechanism is disposed between the input shaft and the differential mechanism, and a first transmission portion of the planetary gear mechanism is interlocked with the input shaft, and a second of the planetary gear mechanism. The transmission unit is linked to the continuously variable transmission via a synthetic clutch device, the third transmission unit of the planetary gear mechanism is linked to the input unit of the differential mechanism, and the axial direction of the input shaft In the planetary gear mechanism and the continuously variable transmission, In a position between, and the reverser clutch unit, said is obtained by arranging the synthetic clutch apparatus takes power from the continuously variable transmission.

According to a second aspect of the present invention, in the transmission for a work vehicle according to the first aspect, the continuously variable transmission is disposed in the vicinity of the rear side surface of the transmission case.

Since the present invention is configured as in claims 1 and 2, there is an effect that it can be applied to a high horsepower engine without increasing the size of the transmission.

The side view which showed the whole structure of the working vehicle which comprises the transmission which concerns on 1st embodiment of this invention. The schematic diagram which similarly showed the transmission. Similarly side sectional drawing. The figure which showed the relationship between the inclination angle of an input side swash plate, and the rotation speed of an output shaft. The figure which showed the relationship between the rotation speed of an output shaft, and the vehicle speed of a working vehicle. The figure which showed the relationship between the tractive force of the working vehicle in 1st embodiment, and a vehicle speed. The schematic diagram which showed the transmission which concerns on 2nd embodiment of this invention. The figure which showed the relationship between the tractive force of the working vehicle in 2nd embodiment, and a vehicle speed. The schematic diagram which showed the transmission which concerns on 3rd embodiment of this invention. The figure which showed the relationship between the tractive force of the working vehicle in 3rd embodiment, and a vehicle speed.

  Next, a work vehicle 1 including a transmission 4 which is an embodiment of a transmission for a work vehicle according to the present invention will be described. In addition, the following description is given by defining the direction indicated by the arrow F in the drawing as the front.

  As shown in FIG. 1, the work vehicle 1 performs various agricultural work and civil engineering work using a tilling device such as a rotary and a work machine such as a loader. The work vehicle 1 mainly includes a body frame 2, an engine 3, a transmission 4, front wheels 5 and 5, rear wheels 6 and 6, a cabin 7, and the like.

  The body frame 2 is a main structure of the work vehicle 1. The machine body frame 2 is composed of a plurality of plate materials or the like with the longitudinal direction as the front-rear direction.

  The engine 3 serves as a drive source that generates power for driving the work vehicle 1. The engine 3 is provided in the front part of the body frame 2.

  The transmission 4 shifts the power generated by the engine 3. The transmission 4 is provided at the rear part of the body frame 2.

  The front wheels 5 and 5 are respectively provided on the left and right of the front part of the body frame 2. The rear wheels 6 and 6 are respectively provided on the left and right of the rear portion (transmission device 4) of the body frame 2. The front wheels 5 and 5 and the rear wheels 6 and 6 are rotationally driven by the power changed by the transmission 4.

  The cabin 7 covers a space where the operator gets on. The cabin 7 is provided from the front and rear substantially central part to the rear part of the body frame 2. In the cabin 7, a handle 7a, a seat 7b, a transmission lever 7c, and the like are provided.

  The handle 7a is used to steer the work vehicle 1. The handle 7 a is provided at the front part in the cabin 7. The seat 7b is for an operator to sit on. The seat 7b is provided behind the handle 7a. The transmission lever 7 c is for setting the traveling speed of the work vehicle 1 by setting the transmission ratio of the transmission 4. The transmission lever 7c is provided on the right side of the seat 7b. The transmission lever 7c is an embodiment of the transmission ratio setting means according to the present invention.

  Below, the structure of the transmission 4 which is 1st embodiment of the transmission which concerns on this invention is demonstrated using FIG.2 and FIG.3. The transmission 4 mainly includes a transmission case 10, an input shaft 20, a continuously variable transmission 40, a reverser clutch device 50, a composite clutch device 60, a planetary gear mechanism 70, an auxiliary transmission mechanism 80, a differential mechanism 90, and the like.

  As shown in FIG. 3, the transmission case 10 is a box-shaped member that houses various shafts, gears, and the like that constitute the power transmission path of the transmission 4. Specifically, the transmission case 10 houses an input shaft 20, a continuously variable transmission 40, a reverser clutch device 50, and the like, which will be described later.

  The transmission case 10 mainly includes a front case 10a, a front support wall 10b, a rear case 10c, and the like. A front support wall 10b is fixed to the rear portion of the front case 10a. An opening 10d that penetrates the front support wall 10b in the front-rear direction is formed at a substantially central portion of the front support wall 10b. A rear case 10c is fixed to the rear portion of the front support wall 10b. A rear support wall 10e is formed in the left-right direction on the vertical plane inside the middle part of the rear case 10c.

  An opening 11 is formed in the rear part of the transmission case 10 and is opened rearward. The opening 11 is closed by a PTO cover 12 fixed to a rear portion of the transmission case 10 by a predetermined fastening member. That is, the PTO cover 12 is a member that forms the rear side surface of the transmission case 10. On the PTO cover 12, a PTO output shaft 13 for transmitting power to a work machine mounted on the work vehicle 1 is projected rearward.

  As shown in FIGS. 2 and 3, the input shaft 20 is a member that is rotationally driven by the power generated by the engine 3. The input shaft 20 mainly includes a first input shaft 21, a second input shaft 22, and the like.

  The front end portion of the first input shaft 21 is interlocked with the output shaft 3a of the engine 3 via the drive shaft 3b. A rear end portion of the first input shaft 21 extends rearward. An engine power output gear 21 a is fixed in the middle of the first input shaft 21.

  The second input shaft 22 is disposed on the same axis line as the first input shaft 21 and behind the first input shaft 21. The front end portion of the second input shaft 22 is interlocked and connected to the rear end portion of the first input shaft 21 via a shaft coupling 22a. The rear end portion of the second input shaft 22 is rotatably supported by the PTO cover 12.

  The continuously variable transmission 40 shifts and outputs input power continuously. The continuously variable transmission 40 mainly includes a cylinder block 41, a hydraulic pump 42, a hydraulic motor 43, an output shaft 44, a first output gear 45, a second output gear 46, and the like.

  The cylinder block 41 is a substantially columnar member, and will be described later with input side plungers 42a, 42a..., Input side spool valves 42c, 42c..., Output side plungers 43a, 43a. A plurality of holes through which the valves 43c, 43c... Are inserted are formed. The second input shaft 22 is inserted through the axial center of the cylinder block 41 and is splined to the second input shaft 22. As a result, the cylinder block 41 rotates integrally with the second input shaft 22.

  The hydraulic pump 42 is a variable displacement hydraulic pump configured to change its capacity. The hydraulic pump 42 mainly includes input side plungers 42a, 42a, etc., an input side swash plate 42b, input side spool valves 42c, 42c,.

  The input side plungers 42a, 42a,... Are inserted into a plurality of holes formed in the cylinder block 41 to suck and discharge hydraulic oil.

  The input-side swash plate 42b is a plate-like member configured to be fixed to the PTO cover 12 by bolts 42e and 42e through the rear housing 42d and to change the inclination angle with respect to the second input shaft 22. In the present embodiment, the inclination angle of the input side swash plate 42 b is configured to be changeable from −α to α with respect to the axial direction of the rotation axis (second input shaft 22) of the cylinder block 41. The projecting ends of the input side plungers 42a, 42a, ... are in contact with the input side swash plate 42b.

  The input-side spool valves 42c, 42c,... Are inserted into a plurality of holes formed in the cylinder block 41, and switch the oil path of the hydraulic oil that is sucked or discharged by the input-side plungers 42a, 42a,. is there.

  In the hydraulic pump 42 configured as described above, when the cylinder block 41 rotates while the input side swash plate 42b is inclined, the input side plungers 42a, 42a,... And the input side spool valves 42c, 42c,. While revolving around the second input shaft 22 together with the cylinder block 41, it reciprocates in the axial direction in the hole of the cylinder block 41. By the reciprocating motion of the input side plungers 42a, 42a,..., Hydraulic oil is sucked and discharged through the oil passages switched by the input side spool valves 42c, 42c,.

  The hydraulic motor 43 is a constant capacity hydraulic motor configured so that its capacity cannot be changed. The hydraulic motor 43 mainly includes output side plungers 43a, 43a,..., An output side swash plate 43b, output side spool valves 43c, 43c,.

  The output side plungers 43a, 43a,... Are inserted into a plurality of holes formed in the cylinder block 41, and suck and discharge the hydraulic oil.

  The output-side swash plate 43b is a plate-like member configured such that the inclination angle with respect to the second input shaft 22 cannot be changed. The output-side swash plate 43 b is disposed on the second input shaft 22 and in front of the cylinder block 41 so as to be rotatable relative to the second input shaft 22. The protruding end of output side plunger 43a * 43a ... is contact | abutted by the output side swash plate 43b.

  The output side spool valves 43c, 43c,... Are inserted into a plurality of holes formed in the cylinder block 41, and switch the oil path of the hydraulic oil sucked or discharged by the output side plungers 43a, 43a,. is there.

  In the hydraulic motor 43 configured as described above, when hydraulic oil is supplied by the hydraulic pump 42, the output side plungers 43a, 43a,... Reciprocate in the axial direction in the hole of the cylinder block 41. The output side swash plate 43b rotates relative to the cylinder block 41 by the reciprocating motion of the output side plungers 43a, 43a.

  The output shaft 44 is a member that rotates integrally with the output-side swash plate 43b. The output shaft 44 is a hollow shaft having a hollow shaft center portion. The output shaft 44 is fixedly attached to the output-side swash plate 43b with the input shaft 20 inserted through the output shaft 44.

  The first output gear 45 is a gear fixed to the front end of the output shaft 44.

  The second output gear 46 is a gear fixed to the output shaft 44 behind the first output gear 45.

  Below, the operation | movement aspect of the continuously variable transmission 40 comprised as mentioned above is demonstrated using FIG.3 and FIG.4. The cylinder block 41 is rotated by the power transmitted from the engine 3 via the input shaft 20. At this time, the rotational speed of the input shaft 20 (the rotational speed of the cylinder block 41) is Nin. When the input side swash plate 42b is orthogonal to the axis of the rotation axis (second input shaft 22) of the cylinder block 41, that is, when the inclination angle of the input side swash plate 42b is 0, the input side plungers 42a, 42a,・ ・ Does not reciprocate. Accordingly, since the supply of hydraulic oil from the hydraulic pump 42 to the hydraulic motor 43 is cut off, the output side plungers 43a, 43a,... Do not reciprocate, and the output side swash plate 43b is integrated with the cylinder block 41. Thus, it rotates at the rotational speed Nin. That is, the output shaft 44 rotates at the rotational speed Nin integrally with the input shaft 20 via the output-side swash plate 43b and the cylinder block 41.

  When the input-side swash plate 42b is tilted toward the deceleration side (-α side in FIG. 4), the output-side swash plate 43b rotates relative to the cylinder block 41 in the direction opposite to the rotation direction of the input shaft 20. When the inclination angle of the input side swash plate 42b is inclined to −α, the output side swash plate 43b rotates relative to the cylinder block 41 at the same rotational speed as the rotational speed Nin of the input shaft 20. Accordingly, the rotation speed of the output shaft 44 is zero.

  When the input side swash plate 42b is tilted to the speed increasing side (α side in FIG. 4), the output side swash plate 43b rotates relative to the cylinder block 41 in the same direction as the rotation direction of the input shaft 20. When the inclination angle of the input side swash plate 42b is inclined to α, the output side swash plate 43b rotates relative to the cylinder block 41 at the same rotational speed as the rotational speed Nin of the input shaft 20. Therefore, the rotation speed of the output shaft 44 is twice Nin.

  Further, by arranging the continuously variable transmission 40 on the input shaft as in the present embodiment, the transmission 4 can be made to correspond to the high horsepower engine 3 without enlarging the transmission 4.

  As shown in FIGS. 2 and 3, the reverser clutch device 50 extracts power from the output shaft 44. The reverser clutch device 50 mainly includes a lid 51, a clutch shaft 52, a first forward gear 53, a reverse gear 54, a first forward clutch 55, a reverse clutch 56, and the like.

  The lid 51 is a member that closes the opening 10d of the front support wall 10b. The lid 51 is fixed to the front support wall 10b by a bolt 51a.

  The clutch shaft 52 is a member arranged in parallel with the input shaft 20 and the output shaft 44. The front end of the clutch shaft 52 is rotatably supported by the lid body 51. The rear end of the clutch shaft 52 is rotatably supported by the rear support wall portion 10e.

  The first forward gear 53 is a gear that is rotatably supported in the middle portion of the clutch shaft 52. The first forward gear 53 is interlocked with the second output gear 46 via an intermediate gear 53a (see FIG. 2).

  The reverse gear 54 is a gear that is rotatably supported by the clutch shaft 52 in front of the first forward gear 53. The reverse gear 54 is meshed with the first output gear 45.

  The first forward clutch 55 enables connection / disconnection of power between the first forward gear 53 and the clutch shaft 52. The first forward clutch 55 is fixed to the clutch shaft 52 in front of the first forward gear 53.

  The reverse clutch 56 enables power connection / disconnection between the reverse gear 54 and the clutch shaft 52. The reverse clutch 56 is fixed to the clutch shaft 52 behind the reverse gear 54. The first forward clutch 55, the reverse clutch 56, and the second forward clutch 64 and the third forward clutch 65, which will be described later, are constituted by hydraulic clutches, and can be turned “on” or “off” by switching electromagnetic valves. A detection unit is provided in the vicinity of the transmission lever 7c, and the detection unit is connected to the electromagnetic valve to detect a rotation operation of the transmission lever 7c, and the first forward clutch 55 and the like are switched by the rotation operation. It is assumed that it is configured.

  Below, the operation | movement aspect of the reverser clutch apparatus 50 comprised as mentioned above is demonstrated. The first forward gear 53 is rotationally driven by the power transmitted from the second output gear 46 via the intermediate gear 53a. The reverse gear 54 is rotationally driven by the power transmitted from the first output gear 45. By interposing the intermediate gear 53 a between the first forward gear 53 and the second output gear 46, the first forward gear 53 is rotationally driven in the direction opposite to the rotational direction of the reverse gear 54. When the first forward gear 53 and the clutch shaft 52 are connected by the first forward clutch 55, the power of the first forward gear 53 is transmitted to the clutch shaft 52. In this case, the rotation direction of the power transmitted to the clutch shaft 52 is a direction for moving the work vehicle 1 forward (hereinafter simply referred to as “forward rotation direction”). When the reverse gear 54 and the clutch shaft 52 are connected by the reverse clutch 56, the power of the reverse gear 54 is transmitted to the clutch shaft 52. In this case, the rotation direction of the power transmitted to the clutch shaft 52 is a direction for moving the work vehicle 1 backward (hereinafter simply referred to as “reverse rotation direction”).

  In this way, by switching between the first forward clutch 55 and the reverse clutch 56, the rotational direction of the power transmitted to the clutch shaft 52 can be switched, so that the forward and reverse of the work vehicle 1 can be switched. .

  The reverser clutch device 50 is configured to be detachable as one unit. Specifically, by removing the bolt 51a from the front, the reverser clutch device 50 can be pulled out integrally as a unit. Thereby, the maintenance of the reverser clutch device 50 can be easily performed, and the assembly can be easily performed.

  In the present embodiment, the reverser clutch device 50 includes the first forward clutch 55 that extracts the power from the continuously variable transmission 40 in the forward rotation direction and the reverse clutch 56 that extracts the power in the reverse rotation direction. However, the present invention is not limited to this. That is, the first forward clutch 55 and the reverse clutch 56 can be provided in the composite clutch device 60.

  As shown in FIG. 2, the composite clutch device 60 takes out the power of the hydraulic motor 43 transmitted through the output shaft 44. The composite clutch device 60 mainly includes a counter shaft 61, a second forward gear 62, a third forward gear 63, a second forward clutch 64, a third forward clutch 65, and the like.

  The counter shaft 61 is a member disposed in parallel with the input shaft 20 and the output shaft 44.

  The second forward gear 62 is a gear that is rotatably supported in the middle portion of the counter shaft 61. The second forward gear 62 is meshed with the first output gear 45.

  The third forward gear 63 is a gear that is rotatably supported by the counter shaft 61 behind the second forward gear 62. The third forward gear 63 is meshed with the second output gear 46 via the intermediate gear 53a.

  The second forward clutch 64 enables connection / disconnection of power between the second forward gear 62 and the counter shaft 61. The second forward clutch 64 is a low-speed clutch that extracts low-speed power from the continuously variable transmission 40. The second forward clutch 64 is attached to the counter shaft 61 behind the second forward gear 62.

  The third forward clutch 65 is capable of connecting and disconnecting power between the third forward gear 63 and the counter shaft 61. The third forward clutch 65 is a high-speed clutch that extracts high-speed power from the continuously variable transmission 40. The third forward clutch 65 is attached to the counter shaft 61 in front of the third forward gear 63.

  Below, the operation | movement aspect of the synthetic | combination clutch apparatus 60 comprised as mentioned above is demonstrated. The second forward gear 62 is rotationally driven by the power transmitted from the first output gear 45. The third forward gear 63 is rotationally driven by the power transmitted from the second output gear 46 via the intermediate gear 53a. By passing the intermediate gear 53 a between the third forward gear 63 and the second output gear 46, the third forward gear 63 is rotationally driven in the direction opposite to the rotational direction of the second forward gear 62.

  When the second forward gear 62 and the counter shaft 61 are connected by the second forward clutch 64, the power of the second forward gear 62 is transmitted to the counter shaft 61. When the third forward gear 63 and the counter shaft 61 are connected by the third forward clutch 65, the power of the third forward gear 63 is transmitted to the counter shaft 61.

  In this way, by switching between the second forward clutch 64 and the third forward clutch 65, the rotational direction of the power transmitted from the output shaft 44 to the counter shaft 61 can be switched.

  The planetary gear mechanism 70 is disposed in front of the synthetic clutch device 60, and synthesizes and outputs the power from the engine 3 and the power from the hydraulic motor 43. The planetary gear mechanism 70 mainly includes a carrier 71, planetary gears 72, 72..., A sun gear 73, an outer gear 74, and the like.

  The carrier 71 is supported at the front end portion of the counter shaft 61 so as to be rotatable relative to the counter shaft 61. The carrier 71 serves as a first transmission portion of the planetary gear mechanism 70. The front end portion of the carrier 71 is provided with a gear portion 71a having teeth formed on the outer periphery thereof. The gear portion 71a of the carrier 71 is meshed with the engine power output gear 21a.

  The planetary gears 72, 72,... Are rotatably supported at the rear end portion of the carrier 71 via planetary shafts 72a, 72a,. A plurality of planetary gears 72, 72... Are provided on a concentric circle with the counter shaft 61 as the center.

  The sun gear 73 is supported on the counter shaft 61 and behind the carrier 71 so as not to rotate relative to the counter shaft 61. The sun gear 73 is a second transmission part of the planetary gear mechanism 70. The sun gear 73 meshes with the planetary gears 72, 72.

  The outer gear 74 is supported on the counter shaft 61 and behind the sun gear 73 so as to be rotatable relative to the counter shaft 61. The outer gear 74 is a third transmission part of the planetary gear mechanism 70. The front end portion of the outer gear 74 is provided with a gear portion 74a having teeth formed on the inner periphery thereof. A rear end portion of the outer gear 74 is provided with a gear portion 74b having teeth formed on the outer periphery thereof. The gear portion 74a of the outer gear 74 is meshed with the planetary gears 72, 72.

  Below, the operation | movement aspect of the planetary gear mechanism 70 comprised as mentioned above is demonstrated. The carrier 71 is rotationally driven by the power transmitted from the input shaft 20 via the engine power output gear 21a. As a result, the planetary shafts 72a, 72a,... Are rotated around the counter shaft 61, and as a result, the planetary gears 72, 72,.

  Further, the planetary gears 72, 72,... Are rotated (rotated) around the planetary shafts 72a, 72a, etc. by the power transmitted from the counter shaft 61 via the sun gear 73.

  The outer gear 74 is rotationally driven by planetary gears 72, 72. The power of the outer gear 74 is output from the gear portion 74b.

  As described above, the power transmitted from the input shaft 20 and the power transmitted from the counter shaft 61 are combined by the planetary gears 72, 72, and output by the outer gear 74.

  As described above, the reverser clutch device 50 and the composite clutch device 60 are arranged between the planetary gear mechanism 70 and the continuously variable transmission 40 in the axial direction of the input shaft 20, whereby the transmission 4 is configured in a compact manner. be able to. Further, the reverser clutch device 50 and the composite clutch device 60 can be arranged at positions close to each other, and the configuration of the hydraulic circuit for controlling the operations of the reverser clutch device 50 and the composite clutch device 60 can be simplified. it can.

  As shown in FIGS. 2 and 3, the subtransmission mechanism 80 shifts and outputs the transmitted power. The auxiliary transmission mechanism 80 mainly includes a high-speed driving gear 81, a low-speed driving gear 82, an auxiliary transmission output shaft 83, a high-speed driven gear 84, a low-speed driven gear 85, an auxiliary transmission clutch 86, and the like.

  The high speed drive gear 81 is a gear fixed to the front end portion of the clutch shaft 52.

  The low speed drive gear 82 is a gear fixed to the clutch shaft 52 behind the high speed drive gear 81. The low speed drive gear 82 is meshed with the gear portion 74 b of the outer gear 74.

  The auxiliary transmission output shaft 83 is a member disposed in parallel with the clutch shaft 52. The auxiliary transmission output shaft 83 is an input part of a differential mechanism 90 described later. The front end of the auxiliary transmission output shaft 83 is rotatably supported by the front support wall 10b. The rear end of the auxiliary transmission output shaft 83 is rotatably supported by the rear support wall portion 10e.

  The high-speed driven gear 84 is a gear that is rotatably supported by the front end portion of the auxiliary transmission output shaft 83. The high speed driven gear 84 is meshed with the high speed drive gear 81.

  The low-speed driven gear 85 is a gear that is rotatably supported by the auxiliary transmission output shaft 83 behind the high-speed driven gear 84. The low speed driven gear 85 is meshed with the low speed drive gear 82. In the present embodiment, the gear ratio by the low-speed drive gear 82 and the low-speed driven gear 85 is larger than the gear ratio by the high-speed drive gear 81 and the high-speed driven gear 84 (that is, when the rotation speed of the clutch shaft 52 is constant, The rotational speed of the low-speed driven gear 85 is smaller than the rotational speed of the high-speed driven gear 84).

  The auxiliary transmission clutch 86 is disposed behind the high-speed driven gear 84 and in front of the low-speed driven gear 85 so that either the high-speed driven gear 84 or the low-speed driven gear 85 and the auxiliary transmission output shaft 83 cannot be rotated relative to each other. And a state in which the connection is released so that the high-speed driven gear 84 and the low-speed driven gear 85 and the sub-transmission output shaft 83 can be rotated relative to each other.

  Below, the operation | movement aspect of the subtransmission mechanism 80 comprised as mentioned above is demonstrated. When the first forward clutch 55 or the reverse clutch 56 is in operation, the clutch shaft 52 is rotationally driven by the power transmitted from the output shaft 44 of the continuously variable transmission 40, so that the low speed drive gear 82 and the high speed drive gear 81 are driven. Driven by rotation.

  Further, when the second forward clutch 64 or the third forward clutch 65 is operating, the low speed drive gear 82 is rotationally driven by the power transmitted from the outer gear 74 of the planetary gear mechanism 70, and as a result, the clutch shaft 52 and the high speed drive are driven. The gear 81 is rotationally driven.

  The low speed driven gear 85 is rotationally driven by the power transmitted from the low speed drive gear 82. The high-speed driven gear 84 is rotationally driven by the power transmitted from the high-speed drive gear 81.

  When the low speed driven gear 85 and the sub transmission output shaft 83 are connected by the sub transmission clutch 86, the power of the low speed driven gear 85 is transmitted to the sub transmission output shaft 83. When the high speed driven gear 84 and the sub transmission output shaft 83 are connected by the sub transmission clutch 86, the power of the high speed driven gear 84 is transmitted to the sub transmission output shaft 83.

  Thus, by switching the auxiliary transmission clutch 86, it is possible to change the rotational speed of the power transmitted from the clutch shaft 52 to the auxiliary transmission output shaft 83, and thus, the vehicle speed of the work vehicle can be changed.

  Further, by selectively switching between the reverser clutch device 50 and the composite clutch device 60, the power from the continuously variable transmission 40 or the power from the planetary gear mechanism 70 can be selectively taken out to the clutch shaft 52. Thereby, desired power can be taken out as necessary.

  The differential mechanism 90 distributes and outputs the power transmitted from the auxiliary transmission mechanism 80 to the left and right. The differential mechanism 90 is interlocked with the rear end portion of the auxiliary transmission output shaft 83. That is, the differential mechanism 90 is disposed on the power transmission downstream side of the input shaft 20, the continuously variable transmission 40, the reverser clutch device 50, and the like. The power distributed to the left and right by the differential mechanism 90 is transmitted to the left and right rear wheels 6 and 6 after being decelerated by the final reduction mechanism 91.

  In the present embodiment, the description of the path through which the power from the engine 3 is transmitted to the front wheels 5 and 5 and the PTO output shaft 13 is omitted.

  Hereinafter, with reference to FIGS. 2 and 5, the relationship between the rotation speed of the output shaft 44 of the continuously variable transmission 40 and the vehicle speed of the work vehicle 1 in the work vehicle 1 including the transmission 4 configured as described above. Will be explained. In F1 of FIG. 5, when the first forward gear 53 and the clutch shaft 52 are connected by the first forward clutch 55, the second forward gear 62 and the counter shaft 61 are connected by the second forward clutch 64 in F2. F3 is when the third forward gear 63 and the counter shaft 61 are connected by the third forward clutch 65, and R is when the reverse gear 54 and the clutch shaft 52 are connected by the reverse clutch 56. Each is shown. For convenience of explanation, it is assumed that the low speed driven gear 85 and the sub transmission output shaft 83 are connected by the sub transmission clutch 86 in any case.

  When the first forward gear 53 and the clutch shaft 52 are connected by the first forward clutch 55, or when the reverse gear 54 and the clutch shaft 52 are connected by the reverse clutch 56 (see F1 and R in FIG. 5). When the rotational speed of the output shaft 44 is zero, the vehicle speed of the work vehicle 1 is zero.

  As indicated by F1, when the first forward gear 53 and the clutch shaft 52 are connected by the first forward clutch 55, the vehicle speed of the work vehicle 1 increases when the rotational speed of the output shaft 44 is increased.

  In the vicinity of the point where F1 and F2 intersect, the first forward clutch 55 is released, and the second forward gear 62 and the counter shaft 61 are connected by the second forward clutch 64. In this case, as indicated by F2, when the rotational speed of the output shaft 44 is decreased, the vehicle speed of the work vehicle 1 increases.

  In the vicinity of the point where F2 and F3 intersect, the second forward clutch 64 is released, and the third forward gear 63 and the counter shaft 61 are connected by the third forward clutch 65. In this case, as indicated by F3, when the rotation speed of the output shaft 44 is increased, the vehicle speed of the work vehicle 1 increases.

  Further, as indicated by R, when the reverse gear 54 and the clutch shaft 52 are connected by the reverse clutch 56, when the rotational speed of the output shaft 44 is increased, the vehicle speed of the work vehicle 1 decreases from 0, that is, The work vehicle 1 moves backward.

  In FIG. 5, the low speed driven gear 85 and the auxiliary transmission output shaft 83 are connected by the auxiliary transmission clutch 86, but the high speed driven gear 84 and the auxiliary transmission output shaft 83 are connected by the auxiliary transmission clutch 86. When connected, the mode of shifting is substantially the same.

  That is, when the first forward gear 53 and the clutch shaft 52 are connected by the first forward clutch 55, the vehicle speed of the work vehicle 1 increases when the rotation speed of the output shaft 44 is increased.

  When the first forward clutch 55 is released and the second forward clutch 64 connects the second forward gear 62 and the counter shaft 61, the vehicle speed of the work vehicle 1 increases when the rotational speed of the output shaft 44 is decreased. .

  When the second forward clutch 64 is released, and the third forward gear 63 and the counter shaft 61 are connected by the third forward clutch 65, when the rotation speed of the output shaft 44 is increased, the vehicle speed of the work vehicle 1 increases. .

  Further, when the reverse gear 54 and the clutch shaft 52 are connected by the reverse clutch 56, when the rotational speed of the output shaft 44 is increased, the vehicle speed of the work vehicle 1 decreases from 0, that is, the work vehicle 1 moves backward. .

  When the high-speed driven gear 84 and the auxiliary transmission output shaft 83 are connected, the vehicle speed changes with respect to the change in the rotation speed of the output shaft 44, compared to when the low-speed driven gear 85 and the auxiliary transmission output shaft 83 are connected. Becomes larger.

  FIG. 6 shows the relationship between the vehicle speed of the work vehicle 1 and the traction force in the work vehicle 1 including the transmission 4 configured as described above.

  A curve E <b> 1 in FIG. 6 indicates the output of the engine 3. L1, L2, L3, H1, H2, and H3 indicate the relationship between the vehicle speed and the traction force under each condition described below.

  When L1 and H1 are connected to the first forward gear 53 and the clutch shaft 52 by the first forward clutch 55, L2 and H2 are connected to the second forward gear 62 and the counter shaft 61 by the second forward clutch 64. In this case, L3 and H3 indicate the case where the third forward gear 63 and the counter shaft 61 are connected by the third forward clutch 65, respectively.

  L1, L2, and L3 are connected to the high-speed driven gear 84 by the auxiliary transmission clutch 86 when the low-speed driven gear 85 and the auxiliary transmission output shaft 83 are connected by the auxiliary transmission clutch 86. The case where the auxiliary transmission output shaft 83 is connected is shown.

  As shown in FIG. 6, the transmission 4 can cover the output range of the engine 3 by the combination of the reverser clutch device 50, the composite clutch device 60, and the auxiliary transmission clutch 86, and corresponds to the output of the engine 3. Shifting is possible. Further, by combining the continuously variable transmission 40 and the planetary gear mechanism 70, it is possible to change the number of clutches only by switching a small number of clutches (in this embodiment, the reverser clutch device 50, the composite clutch device 60, and the auxiliary transmission clutch 86). The vehicle speed can be changed within a range. As a result, fine shifting is only required by adjusting the main shifting (the amount of hydraulic oil discharged by the hydraulic pump 42), and the shifting operation of the work vehicle 1 can be easily performed.

  In the present embodiment, the continuously variable transmission 40 is arranged behind the planetary gear mechanism 70 in the axial direction of the input shaft 20, but the present invention is not limited to this. That is, the planetary gear mechanism 70 is disposed behind the continuously variable transmission 40 in the axial direction of the input shaft 20, and the reverser clutch device 50 and the composite clutch device 60 are interposed between the continuously variable transmission 40 and the planetary gear mechanism 70. It is also possible to adopt a configuration in which

  Below, the transmission 204 which is 2nd embodiment of a transmission is demonstrated. In addition, the same code | symbol is attached | subjected to the member of the structure substantially the same as the transmission 4 (refer FIG. 2) in 1st embodiment, and description is abbreviate | omitted.

  As shown in FIG. 7, the transmission 204 is different from the transmission 4 in that a synthetic clutch device 260 is provided instead of the synthetic clutch device 60. The synthetic clutch device 260 is different from the synthetic clutch device 60 in that the third forward gear 63 and the third forward clutch 65 are not provided.

  FIG. 8 shows the relationship between the vehicle speed of the work vehicle and the traction force in the work vehicle including the transmission 204 configured as described above.

  A curve E2 in FIG. 8 shows the output of the engine 203. L1, L2, H1, and H2 indicate the relationship between the vehicle speed and the traction force under each condition described below. Note that the output horsepower of the engine 203 is lower than the output horsepower of the engine 3.

  When L1 and H1 are connected to the first forward gear 53 and the clutch shaft 52 by the first forward clutch 55, L2 and H2 are connected to the second forward gear 62 and the counter shaft 61 by the second forward clutch 64. If so, each is shown.

  L1 and L2 are connected to the low-speed driven gear 85 and the auxiliary transmission output shaft 83 by the auxiliary transmission clutch 86, and H1 and H2 are connected to the high-speed driven gear 84 and the auxiliary transmission output shaft 83 by the auxiliary transmission clutch 86. Are respectively shown.

  As shown in FIG. 8, the transmission 204 can cover the output range of the engine 203 by the combination of the reverser clutch device 50, the composite clutch device 260, and the auxiliary transmission clutch 86, and corresponds to the output of the engine 203. Shifting is possible. Further, by combining the continuously variable transmission 40 and the planetary gear mechanism 70, a wide variety of clutches (reverser clutch device 50, composite clutch device 260, and auxiliary transmission clutch 86 in this embodiment) can be switched. The vehicle speed can be changed within a range. As a result, fine shifting is only required by adjusting the main shifting (the amount of hydraulic oil discharged by the hydraulic pump 42), and the shifting operation of the work vehicle 1 can be easily performed.

  Further, as can be seen by comparing the transmission 4 and the transmission 204, the continuously variable transmission 40, the reverser clutch device 50, and the planetary gear mechanism 70 are commonly used even when the engine horsepower is different. it can. In this way, by providing versatility to the continuously variable transmission 40, the reverser clutch device 50, and the planetary gear mechanism 70, it is possible to share components and reduce component costs.

  Below, the transmission 304 which is 3rd embodiment of a transmission is demonstrated. In addition, the same code | symbol is attached | subjected to the member of the structure substantially the same as the transmission 4 (refer FIG. 2) in 1st embodiment, and description is abbreviate | omitted.

  As shown in FIG. 9, the transmission 304 is different from the transmission 4 in that the synthetic clutch device 60 and the planetary gear mechanism 70 are not provided.

  FIG. 10 shows the relationship between the vehicle speed of the work vehicle and the traction force in the work vehicle equipped with the transmission 304 configured as described above.

  A curve E3 in FIG. 10 shows the output of the engine 303. L1 and H1 indicate the relationship between the vehicle speed and the traction force under each condition described below. The output horsepower of the engine 303 is assumed to be lower than the output horsepower of the engine 203.

  L1 and H1 show the case where the first forward gear 53 and the clutch shaft 52 are connected by the first forward clutch 55.

  L1 indicates that the low-speed driven gear 85 and the auxiliary transmission output shaft 83 are connected by the auxiliary transmission clutch 86, and H1 indicates that the high-speed driven gear 84 and the auxiliary transmission output shaft 83 are connected by the auxiliary transmission clutch 86. Show the case respectively.

  As shown in FIG. 10, the transmission 304 can cover the output range of the engine 303 by the combination of the reverser clutch device 50 and the sub-transmission clutch 86, and a shift corresponding to the output of the engine 303 is possible.

  As can be seen by comparing the transmission 4 and the transmission 304, the continuously variable transmission 40 and the reverser clutch device 50 can be used in common even when the horsepower of the engine is different. In this way, by providing the continuously variable transmission 40 and the reverser clutch device 50 with versatility, it is possible to share parts and reduce the part cost.

  As described above, the transmission device 4 is arranged on the input shaft 20 for transmitting power from the engine 3 and continuously variable transmission for continuously shifting and outputting the power transmitted from the input shaft 20. Differential mechanism that distributes the power to the left and right rear wheels 6 and 6 and the reverser clutch device 50 that extracts and outputs the power output from the continuously variable transmission 40 in the forward rotation direction or the reverse rotation direction. 90 power transmission upstream side. With this configuration, the transmission 4 can be made to correspond to the high horsepower engine 3 without enlarging the transmission 4. Further, the continuously variable transmission 40 and the reverser clutch device 50 can be used for various transmissions, and the cost can be reduced by sharing parts.

  In the transmission device 4, the planetary gear mechanism 70 is disposed between the input shaft 20 and the differential mechanism 90, the carrier 71 of the planetary gear mechanism 70 is linked to the input shaft 20, and the sun gear 73 of the planetary gear mechanism 70 is connected. Is linked to the continuously variable transmission 40 and the outer gear 74 of the planetary gear mechanism 70 is linked to the auxiliary transmission output shaft 83. By comprising in this way, the continuously variable transmission 40 and the planetary gear mechanism 70 are combined, and the vehicle speed of the work vehicle 1 can be changed in a wide vehicle speed range. Further, by combining the continuously variable transmission 40 and the planetary gear mechanism 70, it is possible to suppress a reduction in power transmission efficiency in the power transmission path.

Further, the transmission 4 is in the axial direction of the input shaft 20, between the planetary gear mechanism 70 and the continuously variable transmission 40, the reverser clutch unit 50, takes power from the continuously variable transmission 40 Synthesis clutch device 60 And are arranged. By comprising in this way, the transmission 4 can be comprised compactly and the mounting property to the work vehicle 1 can be improved. Moreover, each clutch can be arrange | positioned in the mutually close position, and the structure of the hydraulic circuit for controlling operation | movement of each clutch can be simplified.

  The continuously variable transmission 40 is disposed in the vicinity of the rear side surface of the transmission case 10. By configuring in this way, the continuously variable transmission 40 having a relatively large number of maintenance can be arranged at a position where maintenance is easy from the rear of the work vehicle 1, and workability during maintenance can be improved.

1 Working vehicle 3 Engine (drive source)
4 Transmission 6 Rear wheel (wheel)
DESCRIPTION OF SYMBOLS 10 Transmission case 20 Input shaft 40 Continuously variable transmission 42 Hydraulic pump 43 Hydraulic motor 50 Reverser clutch apparatus 60 Synthetic clutch apparatus 70 Planetary gear mechanism 71 Carrier (1st transmission part)
73 Sungear (second transmission part)
74 Outer gear (third transmission part)
80 Sub-transmission mechanism 83 Sub-transmission output shaft (differential mechanism input section)
90 Differential mechanism

Claims (2)

An input shaft that transmits power from the drive source;
A continuously variable transmission that is arranged on the input shaft and continuously outputs and transmits power transmitted from the input shaft;
A reverser clutch device that extracts and outputs the power output from the continuously variable transmission in the forward rotation direction or the reverse rotation direction;
In a transmission for a work vehicle provided on a power transmission upstream side of a differential mechanism that distributes power to left and right wheels,
A planetary gear mechanism is disposed between the input shaft and the differential mechanism;
The first transmission part of the planetary gear mechanism is interlocked with the input shaft,
The second transmission part of the planetary gear mechanism is interlocked with the continuously variable transmission via a synthetic clutch device,
The third transmission part of the planetary gear mechanism is interlocked with the input part of the differential mechanism,
In the axial direction of the input shaft, at a position between the planetary gear mechanism and the continuously variable transmission,
The reverser clutch device;
A transmission for a work vehicle, comprising: a synthetic clutch device that extracts power from the continuously variable transmission. 2. The work vehicle transmission according to claim 1, wherein the continuously variable transmission is disposed in the vicinity of a rear side surface of the transmission case.

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