JPH0781624B2 - Transmission structure for traveling of work vehicle - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial application] The present invention is provided with a shift gear type transmission capable of four-stage switching, a hydraulic cylinder for switching the shift gears, and a shift valve switching operation. The present invention relates to a traveling power transmission structure of a work vehicle configured to perform.

[Conventional technology]

As the above-mentioned work vehicle, there has been a work vehicle disclosed in, for example, Japanese Patent Laid-Open No. 52251/1987. That is, a pair of hydraulic cylinders that are provided with two shift parts that are shifted in two stages by switching one shift gear in a parallel state, and that individually switch the two shift gears, and one shift valve that controls these hydraulic cylinders. , And a hydraulic piston for operating the shift clutch is provided, and the control valve of the hydraulic piston and the hydraulic cylinder are linked so that the shift clutch automatically engages and disengages in association with switching of any of the two shift parts. By providing a clutch control mechanism for switching the shift valves, the shift cylinders are switched by the hydraulic cylinders so that the speed of each shift unit is in a predetermined stage speed state. The disengagement operation and the operation to engage the shifting clutch after the shifting is completed are performed by the hydraulic piston. What it has become to be automatically.

[Problems to be solved by the invention]

In the case of the conventional structure, since the two speed change parts are arranged in parallel, any one of the predetermined speed reduction ratios that needs to be expressed in each of the four speed stages can be obtained at one single speed change part only. It was necessary to make it appear, and it was necessary to make each of the speed change parts relatively large so as to expose a large reduction ratio.

It is an object of the present invention to provide a gear shifter that can be easily operated while allowing the gear shift portion to be downsized and smoothly shifting the shift gears, while further simplifying the structure. It is in.

[Means for solving problems]

In the transmission structure for traveling of the work vehicle according to the present invention, two of the synchromesh type two-stage switchable transmission parts are arranged in a state of being interlocked in series, and any of the transmission parts is on the transmission better side. Alternatively, a transmission clutch is arranged on the lower transmission side, and a pair of hydraulic cylinders for switching and operating the shift gear of the one transmission portion and the shift gear of the other transmission portion separately; a hydraulic piston for operating the transmission clutch; One shift valve for controlling any of the hydraulic cylinders is provided, and the shift unit closer to the shift clutch is automatically linked to the disengagement operation of the shift unit farther from the shift clutch in the shift unit. Is turned off automatically, and one hydraulic cylinder and the other front A linkage mechanism linked with a hydraulic silane, the shift clutch is automatically disengaged in association with the disengagement operation of the shift portion closer to the shift clutch, and the shift portion closer is engaged. A clutch control mechanism is provided which links the hydraulic cylinder for the speed change portion closer to the state where the speed change clutch is automatically turned on in cooperation with the operation, and the control valve of the hydraulic piston. This is a characteristic configuration. The action and effect are as follows.

[Work]

Along with the switching of the shift valve, each hydraulic cylinder switches the shift gear to switch the transmission unit to a predetermined speed state. Then, when only the gear shifting portion closer to the gear shifting clutch is switched, the clutch control mechanism is used, and when only the gear shifting portion farther from the gear shifting clutch and both the gear shifting portion and the far gear shifting portion are switched. For the mechanism and the clutch control mechanism, the shift clutch is automatically disengaged or turned back on. That is, the shift clutch disengagement operation required for shift gear switching and the shift clutch engagement operation upon completion of shift gear switching are automatically performed.

When switching the transmission part farther from the shift clutch, the transmission part closer to the shift clutch is temporarily turned off by the linkage mechanism so that the transmission structure is located between the remote transmission part and the shift clutch. The rotation inertia of the member is suppressed from being transmitted to the transmission unit, and the shift gear and the gear to be engaged easily rotate in synchronization.

Automatic disengagement of shift clutch associated with shift gear switching,
Also, since it is possible to automatically engage the shift clutch upon completion of switching of the shift gear, the control mechanism for the shift clutch does not have to be linked to any of the shift hydraulic cylinders because the linkage mechanism exists. , The hydraulic cylinder for switching the speed change portion closer to the speed change clutch can be simply linked.

Rotational power is introduced into one of the two-speed transmission units to be speed-regulated, and is transmitted to the other two-speed transmission unit to be speed-adjusted and output, whereby four-speed speed is revealed. . That is, the speed is adjusted at two points, that is, one transmission section and the other transmission section.

Therefore, even if the speed reduction ratio of each transmission unit is set to be smaller than the conventional one, the speed reduction ratio as a whole can be set to a desired value.

〔The invention's effect〕

Shifting can be easily done by simply switching the shift valve, but by connecting both shifting parts in series, it is possible to create both shifting parts in a small size with a relatively small reduction ratio, making the overall mission compact. Became possible.

Moreover, the shifting of the shifting portion farther from the shifting clutch can be performed while facilitating the synchronization of the shift gear by the action of the linking mechanism, so that the shifting can be performed smoothly and quietly with less gear squeaking. Became.

Furthermore, automatic control of the shifting clutch associated with switching of the shifting portion can be obtained with a simple structure in which the clutch control valve is linked only to the hydraulic cylinder for the shifting portion closer to the clutch, which is economical. I was able to make an advantage.

〔Example〕

 Next, examples will be shown.

As shown in FIGS. 1 and 2, the rotational output of the engine (E) is introduced into the transmission case (2) through the main clutch (C ₁ ) and the input cylinder shaft (1), and the main body of the synchromesh type is used. The rotation output of the main transmission device (3) is transmitted to the transmission device (3), and the synchromesh sub-transmission is performed through the synchromesh type forward / reverse switching device (4) and the shift clutch (C ₂ ). The transmission shaft (6) of the auxiliary transmission device (5) is directly connected to the rear wheel differential mechanism (7) and is also transmitted via the gear transmission mechanism (8). A transmission structure for traveling of an agricultural tractor is configured in conjunction with the front wheel transmission shaft (9).

The main transmission device (3) includes a first main transmission unit (3a) and a second shift gear (12) capable of switching between two stages by a first shift gear (11).
And a second main transmission portion (3b) capable of switching between two stages by means of serial connection so that the rotation output of the first main transmission portion (3a) is transmitted to the second main transmission portion (3b). By combining the speed stages that the first main transmission unit (3a) appears and the second main transmission unit (3b) that appears, four speeds can be achieved. The sub transmission (5) is provided with a first sub transmission (5) capable of switching between two stages by the third shift gear (13).
The rotation output of the first sub-transmission unit (5a) is transmitted to the second sub-transmission unit (5b) between a) and the second sub-transmission unit (5b) that can be switched between two stages by the fourth shift gear (14). Is connected in series, and a four-stage speed change can be achieved by combining the speed stages of the first sub-transmission unit (5a) and the speed stages of the second sub-transmission unit (5b). I can do it. That is,
As a whole, on the forward side and the reverse side, four speeds by the main transmission (3) and four speeds by the auxiliary transmission (5)
The speed can be switched in 16 steps by combining with the step speed. The operation structure for this speed change is constructed as follows.

That is, as shown in FIG. 4, the first shift gear (11) is connected to the first sliding shifter (11a) and the first link type interlocking mechanism (1
5) via the first hydraulic cylinder (16) to the second shift gear (12) via the second sliding shifter (12a) and the second link type interlocking mechanism (17) via the second hydraulic cylinder (18). , The third shift gear (13) to the third sliding shifter (13
a), the third hydraulic cylinder (20) through the third link type interlocking mechanism (19) causes the fourth shift gear (14) to move to the fourth sliding shifter (14a) and the fourth link type interlocking mechanism (21). The fourth hydraulic cylinder (22) is used to perform switching operations respectively, and the first to fourth hydraulic cylinders (1
As shown in FIG. 3, one rotary type speed change valve (24) is connected to 6), (18), (20) and (22). The speed change valve (24) has one neutral operating position (N) and 16 transmission operating positions (I) to (XVI) and is operated to these operating positions (N), (I) to (XVI). The operating position (N) or (I) or ... (XV
First to fourth hydraulic cylinders (16), (18), (20) so that the main transmission device (3) and the auxiliary transmission device (5) are placed in the transmission disengaged state or the speed-expressed transmission state corresponding to I). ，
It is configured to control (22).

As shown in FIG. 3, the second hydraulic cylinder (18) and the third hydraulic cylinder (18)
For each of the hydraulic cylinders (20), a pair of hydraulic pistons (25a), (25b) or (26a), (26b) for operating the hydraulic cylinders (18) or (20) in a neutral state.
And the hydraulic pistons (25a), (25
b) or (26a), (26b) control valve (2
7) or (28) sliding spool (27a) or (28a)
The interlocking mechanism (29) or (30) is equipped with interlocking flexibility to make the working stroke of the hydraulic cylinder (16) or (22) smaller than the piston (16a) or (22a) working stroke. Main control side linkage mechanism in which the first hydraulic cylinder (16) and the second cylinder (18) are linked by interlocking the control valve (27) or (28) with the hydraulic cylinder (16) or (22). (31) or a sub-transmission side link mechanism (32) that links the third hydraulic cylinder (20) and the fourth hydraulic cylinder (22). The linkage mechanism (31) or (32) is provided in the main transmission device (3) or the auxiliary transmission device (5) at the first main transmission portion (3a) or the second auxiliary transmission that is farther from the speed change clutch (C ₂ ). upon switching of part (5b), operative to be switched second main speed change unit closer to the speed-changing clutch (C ₂₎ (3b) or the first auxiliary transmission section (5a) temporarily neutral position It is a thing. That is,
As the hydraulic cylinder (16) or (22) is turned off from the transmission position before shifting toward the new transmission position, one of the transmission parts (29a), (29) of the interlocking mechanism (29) or (30)
b), or (30a) or (30b) is separated from the passive part (29c) or (30c), and the control valve (27) or (28) refuels from one drainage position (a) due to self-restoring force. It is switched to the position (b) and a pair of hydraulic pistons (25
a), (25b) or (26a), (26b) are driven to the approach side by the pressure oil from the control valve (27) or (28), and these hydraulic pistons (25a), (25b) or (26
a), (26b) and the piston (18a) or (20a) due to the difference in pressure receiving area, one hydraulic piston (25a) or (2)
5b), (26a) or (26b) pushes back the hydraulic cylinder (18) or (20) to the neutral state in preference to the pressure oil from the transmission valve (24). Then, as the hydraulic cylinder (16) or (22) reaches a new transmission position,
The other transmission part (29b) or (29a) or (30b) or (30a) of the interlocking mechanism (29) or (30) is a passive part (2
9c) or (30c) to contact the control valve (2
7) or (28) is switched from the oil supply position (b) to the other oil discharge position (a), and the pressure oil from the speed change valve (24) is pushed to the neutral state of the hydraulic cylinder (18) or (20). The hydraulic piston (25a) or (25b), (26
A) or (26b) is pushed back to the standby position and the hydraulic cylinder (18) or (20) is returned to its original transmission state.

The swing gear (33a) for slidingly operating the switching gear (33) of the forward / reverse switching device (4) is mounted on the swing arm (34) and the rotary support shaft (35) of the swing arm (34). The forward / reverse lever (36) for manual operation is linked.

As shown in FIG. 1, the speed change clutch (C ₂ ) is operated by a hydraulic piston (37) installed in the clutch body. Then, a sequence valve (41) connected by forming a pilot oil passage (40) to a pilot operation part of a control valve (39) that controls a hydraulic piston (37) for opening and closing the shift clutch (C ₂ ), This sequence valve (41) is interlocked with the piston (20a) of the third hydraulic cylinder (20), the interlocking mechanism (42), the operating oil chambers of the hydraulic pistons (25a), (25b), and the automatic oil passage switching valve. A sequence valve (44) connected so as to be switched and connected to the control valve (27) by (43), a link-type interlocking mechanism (45) in which the sequence valve (44) is interlocked with a forward / reverse lever (36), A sequence valve (47) interposed in an oil passage (46) connecting the control valve (39) and the hydraulic pump (P), and this sequence valve (4)
The second hydraulic cylinder (18) and the third hydraulic pressure are controlled by the flexible interlocking mechanism (48) similar to the interlocking mechanism (29) that interlocks 7) with the piston (18a) of the second hydraulic cylinder (18). A clutch control mechanism (49) is formed by linking each of the cylinder (20) and the forward / reverse switching device (4) with the control valve (39). The clutch control mechanism (49) includes first to fourth shift gears (11), (12),
The gear shift clutch (C ₂ ) is automatically engaged and disengaged in cooperation with the switching of (13), (14) and the switching gear (33). That is, when switching the second main transmission unit (3b), the piston (18) of the second hydraulic cylinder (18) is
As a) is turned from the transmission position before shifting to the new transmission position, the sequence valve (4) is separated from one transmission part (48a) or (48b) of the interlocking mechanism (48).
7) is switched from one oil supply position (b) to the oil discharge position (a) due to the self-restoring force, and oil is discharged from the operation chamber of the hydraulic piston (37) and the hydraulic piston (37) is disengaged. It is decompressed. Then, as the piston (18a) enters a new transmission position and operates, the other transmission portion (48b) or (48a) of the interlocking mechanism (48) contacts the passive portion (48c) and the sequence valve (47). ) Is returned to the oil supply position (b) and oil is supplied to the operation chamber of the hydraulic piston (37) to pressurize the hydraulic piston (37) into the clutched state. Then, at the time of switching the first main transmission unit (3a),
By operating the second hydraulic cylinder (18) for the main transmission side linkage mechanism (31) as described above, the sequence valve (47) is switched in the same manner as when switching the second main transmission unit (3b). , The piston (16a) of the first hydraulic cylinder (16)
The hydraulic piston (37) is decompressed as the gear shifts from the transmission position before shifting toward the new transmission position, and the hydraulic piston (37) is added as the piston (16a) enters the new transmission position and operates. It returns to the pressure state. At the time of switching the first subtransmission unit (5a), as the piston (20a) of the third hydraulic cylinder (20) is turned off from the transmission position before the shift toward the new transmission position, the interlocking mechanism (42) operates. One of the transmission parts (42a) or (42b) separates from the passive part (42c), and the sequence valve (41) switches from one refueling position (b) to the oil discharge position (a) due to self-restoring force, The control valve (39) is in the clutch disengaged position due to the self-restoring force. Then, as the piston (20a) enters a new transmission position and operates, the other transmission portion (42b) or (42a) of the interlocking mechanism (42) contacts the passive portion (42c) and the sequence valve (41 ) Is switched to the other refueling position (b), and the control valve (39) is returned to the clutch engaged position by the pilot pressure oil. Then, when the second auxiliary transmission section (5b) is switched, the third hydraulic cylinder (2) is provided due to the auxiliary transmission side linking mechanism (32).
0) is operated as described above and the sequence valve (41) is switched in the same manner as when switching the first subtransmission unit (5a), so that the piston (22a) of the fourth hydraulic cylinder (22) is in the pre-shift position. The control valve (39) shifts to the clutch disengaged position when the transmission valve moves from the transmission position to the new transmission position, and the control valve (39) enters the clutch as the piston (22a) enters the new transmission position and operates. It returns to the position. And forward / reverse switching device (4)
When the forward / reverse lever (36) is swung during the switching of the gears, one of the transmission parts (45a) or (45) of the interlocking mechanism (45) is
b) Separated from the passive part (45c) Sequence valve (44)
Switches from one oil discharge position (a) to the oil supply position (b) due to the self-restoring force, and the hydraulic piston (25a) or (25
b) pushes the piston (18a) to the neutral position and operates the sequence valve (47) from one oil supply position (b) to the oil discharge position (a) via the interlocking mechanism (48),
The hydraulic piston (37) is decompressed. Then, as the forward / reverse lever (36) moves to the forward position or the reverse position, the other transmission portion (45b) or (45) of the interlocking mechanism (45).
a) contacts the passive part (45c), the sequence valve (44) is switched to the other oil drain position (a), and the piston (18a)
Is returned to the original transmission position by the pressure oil from the speed change valve (24), and the sequence valve (47) is returned to the original oil supply position (b), whereby the hydraulic piston (37)
Returns to the pressurized state.

In short, the main transmission device (3) and the sub transmission device (5) are switched by the switching operation of the transmission valve (24).
That is, hydraulic power is used. When the first main transmission unit (3a) and the second auxiliary transmission unit (5b) are switched, the third main conversion unit (3b) or the first main conversion unit (3b) located between this and the transmission clutch (C ₂ ). The sub-transmission unit (5a) is switched to the neutral position, and the dynamic inertia of the mission component located between the first main transmission unit (3a) or the second sub-transmission unit (5b) and the transmission clutch (C ₂ ) is reduced. Transmission to the first main transmission unit (3a) or the second auxiliary transmission unit (5b) is suppressed. That is, the synchronization of the first main transmission portion (3a) and the second auxiliary transmission portion (5b) is facilitated.

The forward / reverse switching device (4) is switched by an artificial operation force by swinging the forward / backward lever (36). However, simply by operating the forward / reverse lever (36), the switching gear (33)
The transmission disengagement operation required for switching and the transmission input operation after completion of switching are automatically performed. Note that (38) shown in FIG. 3 is the operation pressure of the shift clutch (C ₂ ). Is a modulation valve for gradually increasing.

[Another embodiment]

The present invention can be applied to various work vehicles such as a truck and a lawn mower in addition to an agricultural tractor.

It should be noted that reference numerals are added to the claims for convenience of comparison with the drawings, but the present invention is not limited to the structures of the accompanying drawings by the entry.

[Brief description of drawings]

The drawings show an embodiment of a transmission structure for traveling of a work vehicle according to the present invention. Fig. 1 is a sectional view of a mission, Fig. 2 is a transmission system diagram, Fig. 3 is a hydraulic circuit diagram, and Fig. 4 is an interlocking mechanism. Perspective view of
FIG. 5 is a sectional view of a hydraulic cylinder and a valve. (3a), (3b), (5a), (5b) ... Transmission, (11),
(12), (13), (14) …… Shift gear, (16), (1
8), (20), (22) …… hydraulic cylinder, (24) …… shift valve, (31) (32) …… coupling mechanism, (37) …… hydraulic piston, (39) …… control valve, (49) ……
Clutch control mechanism, (C ₂ ) ... Shift clutch.

Claims (2)

[Claims] 1. Two of the synchromesh type two-stage switchable transmission parts (3a, 5a or 3b, 5b) are arranged so as to be interlocked in series, and the transmission parts (3a, 3b or 5a, 5b) are arranged. ), The transmission clutch (C ₂ ) is arranged on the transmission upper side or the transmission lower side, and one of the transmission portions (3a or 5a)
Pair of hydraulic cylinders (16, 18 or 20, 22) for individually switching between the shift gear (11 or 13) and the shift gear (12 or 14) of the other transmission portion (3b or 5b), and the shift clutch (C ₂₎ hydraulic piston operating the (3
7), one shift valve (24) for controlling any of the hydraulic cylinders (16, 18 or 20, 22) is provided, and the shift clutch (3a, 3b or 5a, 5b) of the shift clutch (3a, 3b or 5a, 5b) is provided. C ₂ the shifting portion farther from) (transmission portion closer to 3a or 5b) the shift clutch in conjunction to cut the operation of (C ₂₎ (3b or 5a) is automatically turned off, and , One of the hydraulic cylinders (16 or 20) and the other one in a state in which the nearer gear shifting portion (3a or 5b) is automatically turned on in association with the entry operation of the farer gear shifting portion (3b or 5a). The linkage mechanism (31 or 32) linked to the hydraulic silane (18 or 22), and the linkage mechanism (31 or 32) linked to the engagement operation of the shift portion (3b or 5a) closer to the shift clutch (C ₂ ). shifting clutch (C ₂₎ is automatically turned off, and enters the shift portion closer (3b or 5a) work The shift clutch in conjunction with the shift portion of the (C ₂₎ closer to the state is automatically enter said hydraulic cylinder for (3b or 5a) (18 or 20), hydraulic piston (37) Clutch control mechanism (4
9) A work transmission structure for work vehicles equipped with. 2. The transmission structure for traveling of a work vehicle according to claim 1, wherein the clutch control mechanism (49) is a hydraulic type.