JP2004225773A - Transmission device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transmission device with a shift lever placeable at a first shift position, a second shift position and a third shift position as a shift pattern in order from a neutral position and having improved operability by making the shift pattern of the shift lever intuitively understandable and avoiding the neutral position from being laid between the shift positions. <P>SOLUTION: The transmission device comprises a working shift transmission mechanism 122 as a consistently meshing shift transmission mechanism provided on a working shaft 67, a key-sliding shift transmission mechanism 138A provided on a travel shaft 78, and a working shift member 145 and a travel shift member 157 axially movable when engaging with the shift lever 36 and attached to the working shift transmission mechanism 122 and the key-sliding shift transmission mechanism 138A, respectively. The working shift member 145 and the travel shift member 157 are used for shifting operation. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a transmission such as an agricultural work machine.
[0002]
[Prior art]
A transmission using a selective sliding transmission mechanism is known as a transmission (for example, see Patent Document 1).
[0003]
[Patent Document 1]
Japanese Utility Model Publication No. 6-43561 (page 2-3, FIG. 1, FIG. 4)
[0004]
FIG. 1 of Patent Document 1 is described with reference to FIG. 18 below, and FIG. 4 is described with reference to FIG. 19 below. The reference numerals have been re-assigned.
FIG. 18 is a cross-sectional view of a conventional transmission. The transmission has an input shaft 202, a second shaft 203, a third shaft 204, and an output shaft 205 supported in a case 201. Gears 206 and 207 are mounted, and gears 208 and 209 which are always meshed with the gears 206 and 207 are rotatably mounted on the second shaft 203, and the second shaft 203 and the gears 208 and 209 are mounted on the second shaft 203 between the gears 208 and 209. A mechanical clutch 210 for selectively connecting one of the shafts 209 to 209 is provided. A slide gear 213 is slidably connected to the second shaft 203 by a spline. A transmission gear 215 having a gear portion 215a that is disengaged by the slide of the slide gear 13 and a gear portion 215b that always meshes with the loose fitting gear 214 is rotatable on the shaft 202. It is those attached. Reference numeral 216 denotes an operation fork for moving the slide gear 213.
The slide gear 213, the loose fitting gear 214, and the transmission gear 215 constitute a first sub-transmission mechanism 217 of a gear slide type in which the transmission gear 215 can obtain two kinds of rotation speeds by the sliding operation of the slide gear 213.
[0005]
FIG. 19 is an explanatory view for explaining a conventional shift pattern, in which a guide hole 224 serving as a guide for moving the main shift lever 222 has a horizontal H-shape. , Neutral, and second forward speed.
[0006]
[Problems to be solved by the invention]
In FIG. 18, in the slide-type first auxiliary transmission mechanism 217, that is, in the selective sliding transmission mechanism, the slide gear 213 that rotates together with the second shaft 203 moves rightward in the figure from the state in which the slide gear 213 meshes with the loose fitting gear 214. When the transmission gear 215 meshes with the transmission gear 215, the rotation shafts of the slide gear 213 and the transmission gear 215 (that is, the second shaft 203 and the input shaft 202) are different from each other. Gear teeth are easily worn.
[0007]
In the speed change pattern shown in FIG. 19, the first forward speed and the second forward speed are arranged on both sides of the neutral position. Therefore, when the speed is increased from the first forward speed to the second forward speed, the neutral position is set. The main shift lever 222 is operated via the main shift lever 222.
[0008]
If the main shift lever 222 can be operated without going through the neutral position, the cooperation between the first forward speed and the second forward speed becomes smooth, and the operability is improved. Further, if the meshing between the gears is improved, the gear can be shifted without being caught at each shift position, and the main shift lever 222 can be operated more smoothly.
[0009]
Therefore, an object of the present invention is to improve the operability of the transmission lever by improving the transmission.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, a first aspect of the present invention is directed to a transmission for shifting the power from a prime mover on a work shift shaft and a travel shift shaft and transmitting the power to the work device and the traveling wheels. An input gear that receives power from the prime mover, a constant-mesh transmission mechanism that transmits the power of the input gear to the working device, or interrupts the power, and a plurality of gears that are integrally attached to the working transmission shaft. A first gear train composed of gears, and a second gear train composed of a plurality of gears that is rotatably mounted on the traveling transmission shaft and is meshed with the first gear train. A key-slide type transmission mechanism for transmitting the power to the traveling wheel side by integrally rotating the selected gear and the traveling transmission shaft by selectively engaging with each gear of the second gear train; Type transmission mechanism and The key sliding transmission mechanism, and a shift member movable in an axial direction when engaged to shift lever annexed respectively, characterized in that to perform the shift operation in the shift member.
[0011]
In the conventional selective sliding type transmission mechanism, since the gear is moved on the shaft and meshes with the other two gears, the shift pattern of the shift lever includes, for example, a first speed position and a second speed position on both sides of the neutral position. Although the position has to be arranged, in the present invention, by providing the traveling transmission shaft with a key-slide type transmission mechanism, for example, the first transmission gear, the second transmission gear, By arranging the third-speed gears in order, the keys can be slid to select these gears in order and couple them to the traveling speed change shaft. As a shift pattern of the speed change lever, the first speed is sequentially shifted from the neutral position. Position, second speed position, third speed position, and so on. Therefore, it is easy to intuitively understand the shift pattern of the shift lever, and since the neutral position does not exist between the shift positions, the operability of the shift lever can be improved.
[0012]
In addition, the use of a constant-mesh transmission mechanism reduces gear noise and gear wear during shifting compared to conventional selective-sliding transmission mechanisms, and allows gears to mesh more smoothly. Further, the use of the key-slide type speed change mechanism reduces the possibility of catching at the time of speed change, so that the speed change lever can be operated more smoothly.
[0013]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described below with reference to the accompanying drawings. The drawings should be viewed in the direction of reference numerals.
FIG. 1 is a perspective view of a walking-type agricultural working machine provided with a transmission according to the present invention. A walking-type agricultural working machine 10 (hereinafter simply referred to as “agricultural working machine 10”) is driven from an engine 11 as a prime mover. Power is transmitted to left and right traveling wheels 13 and 14 (only the reference numeral 13 on the near side is shown) and left and right tilling devices 15 and 16 disposed in front of these traveling wheels 13 and 14 through the drive unit 12. This is an agricultural machine having a structure in which a working device such as a ridger is connected to the rear part of the transmission case 12a constituting the above. The cultivator 15 or 16 plows a field while raising a ridge with a ridger, for example.
[0014]
FIG. 2 is a side view of an agricultural working machine provided with the transmission according to the present invention. The agricultural working machine 10 includes an engine 11 disposed on an upper portion of a body, a driving device 12 mounted on a lower portion of the engine 11, and Tilling devices 15 and 16 as working devices rotatably attached to the front of the device 12 via left and right tilling shafts 15a and 16a (only the reference numeral 15a on the near side is shown). Running wheels 13 and 14 rotatably mounted via an axle 13a and a right axle 14a (not shown), a handle 18 extending obliquely upward from the rear of the transmission case 12a, and a rear end of the transmission case 12a. And a coupling mechanism 21.
[0015]
Here, reference numeral 17 denotes a clutch case for accommodating a clutch (which will be described in detail later) constituting the drive device 12, reference numeral 31 denotes a traveling auxiliary wheel mounted on the front end of the transmission case 12a so as to be vertically adjustable, and reference numeral 32 denotes a transmission. A fender covering the front part of the case 12a and the upper part of the tillage devices 15, 16; 33, an engine cover covering the upper part of the engine 11; 34, an air cleaner; 35, a cap for a fuel tank filler port; 36, a shift lever; Lever, 38 is a clutch lever, 41 is a flip-up lever for flipping up the working device connected to the connecting mechanism 21, and 42 is a sinking position adjusting lever for adjusting the sinking position of the working device connected to the connecting mechanism 21. .
[0016]
FIG. 3 is a plan view of the agricultural working machine provided with the transmission according to the present invention. The agricultural working machine 10 has a recoil starter knob 51 for starting the engine 11 on the right front portion of the handle 18 and an output of the engine 11. The throttle lever 52 to be adjusted and the above-described differential lock lever 37 are arranged, an engine switch 53 for stopping the engine 11 is attached to the left rear portion of the handle 18, the clutch lever 38 is attached to the rear portion of the handle 18, and the drive device 12 ( FIG. 1 shows that the shift lever 36 is extended rearward from the rear center and the flip-up lever 41 is extended rearward from the rear left portion of the coupling mechanism 21.
[0017]
FIG. 4 is a cross-sectional view of a driving device provided with the transmission according to the present invention. The driving device 12 uses the driving force of the engine 11 (see FIG. 2) to drive the wheels 13 and 14 (see FIG. 2) and the tilling device 15. , 16 (see FIG. 2), and includes a clutch 61 connected to the crankshaft 11a of the engine 11, a power transmission mechanism 62 connected to the clutch 61, the above-described clutch case 17, and a power transmission mechanism 62. The above-mentioned transmission case 12a is housed.
[0018]
The clutch 61 has an input side connected to the crankshaft 11a, and an output side clutch output shaft 61a connected to an input shaft 64 constituting the power transmission mechanism 62.
[0019]
The power transmission mechanism 62 includes an input shaft 64, a bevel gear 66 as an input gear that meshes with a bevel gear 64 a provided integrally with the input shaft 64, a working shaft 67 as a working speed change shaft that supports the bevel gear 66, A first drive sprocket 68 and a second drive sprocket 71 attached to the working shaft 67, a first driven sprocket 73 connected to the first drive sprocket 68 via a first chain 72, and the first driven sprocket 73 are supported. A tilling assist shaft 74, the above-described tilling shafts 15a and 16a receiving driving force from the tilling assist shaft 74 by a plurality of gears, and a second driven sprocket 77 connected to the second drive sprocket 71 via a second chain 76. , As a traveling speed change shaft for supporting the second driven sprocket 77. A shaft 78, a third drive sprocket 81 integrally formed with the traveling shaft 78, a third driven sprocket 83 connected to the third drive sprocket 81 via a third chain 82, and a third drive sprocket 83. It includes the above-described left axle 13a and right axle 14a that receive driving force. The working shaft 67 and the traveling shaft 78 are members that constitute a part of a transmission that will be described in detail later.
[0020]
The clutch case 17 includes an upper case 86 provided with a shaft insertion hole 17a through which the crankshaft 11a passes, and a lower case 87 attached to a lower portion of the upper case 86.
[0021]
The lower case 87 includes a substantially cylindrical bearing portion 91 that rotatably supports the clutch output shaft 61a and the input shaft 64, and a clutch-side mounting surface 92 as a first coupling surface for mounting to the transmission case 12a.
[0022]
The bearing portion 91 is a portion formed at a lower portion with a cylindrical portion 93 fitted to the transmission case 12a.
Reference numeral 90 in the drawing denotes the axis of the cylindrical portion 93, and the above-described clutch-side mounting surface 92 is a surface perpendicular to the axis 90.
[0023]
The transmission case 12a is a member that is divided into two right and left parts. A fitting hole 94 that fits into the cylindrical portion 93 of the clutch case 17 and a transmission-side mounting surface that is mounted on the clutch-side mounting surface 92 of the clutch case 17 are provided at the top. 95. In addition, 96 ... (... shows a plurality, the same shall apply hereinafter) are bolts which couple the clutch case 17 and the transmission case 12a.
100 in the drawing is the axis of the fitting hole 94, which coincides with the axis 90. The transmission-side mounting surface 95 is a surface perpendicular to the axis 100.
[0024]
FIG. 5 is a plan view of the transmission case and the clutch case according to the present invention. The transmission case 12a is shown by a solid line, and the clutch case 17 is shown by an imaginary line.
[0025]
The transmission case 12a is a combination of a left case 101 and a right case 102 at respective mating surfaces 101a and 102a. A substantially U-shaped left mounting surface is provided on each of the left case 101 and the right case 102. 101b and a right mounting surface 102b. Reference numerals 103 ..., 104 ... denote bolts and nuts for connecting the left case 101 and the right case 102.
[0026]
The left mounting surface 101b and the right mounting surface 102b are parts constituting the above-described transmission-side mounting surface 95, and include bolt insertion holes 101c, 101c, and bolt insertion holes 102c, 102c through which bolts 96... Prepare.
[0027]
The clutch-side mounting surface 92 (see FIG. 4) of the clutch case 17 mounted on the transmission-side mounting surface 95 is provided with bolts 96 at positions corresponding to the bolt insertion holes 101c, 101c, 102c, 102c of the transmission-side mounting surface 95. Is provided with a bolt hole (not shown) for screwing.
[0028]
The fitting hole 94 of the transmission case 12a includes a left semicircular recess 105 formed in the left case 101 in a semicircular shape, and a right semicircular recess 106 formed in the right case 102 in a semicircular shape.
[0029]
As described above, since the transmission-side mounting surface 95 is perpendicular to the axis 100 (see FIG. 4), the left mounting surface 101b and the right mounting surface 102b are perpendicular to the axis 100.
[0030]
FIG. 6 is a cross-sectional view of the driving device according to the present invention. The power transmission mechanism 62 of the driving device 12 includes a transmission 111 having the above-described working shaft 67 and the traveling shaft 78, and a chain transmission connected to the transmission 111. It includes a speed reducer 112 of a type, a differential 113 connected to the speed reducer 112, and a left axle 13a and a right axle 14a connected to the left and right of the differential 113. In addition, 15b ... and 16b ... are tilling nails attached to the tilling shafts 15a and 16a.
[0031]
The speed reducer 112 includes the third drive sprocket 81 described above, a third driven sprocket 83, and a third chain 82 bridged over the third drive sprocket 81 and the third driven sprocket 83.
[0032]
FIG. 7 is a sectional view of a main part of the transmission according to the present invention. The transmission 111 includes a work shaft 67 and a traveling shaft 78 rotatably mounted on the left case 101 and the right case 102 via bearings 116 to 119, respectively. , A work speed change mechanism 122 provided on the work shaft 67 as a constantly meshing speed change mechanism, and a travel speed change mechanism 123 provided on the travel shaft 78.
[0033]
The working shaft 67 is integrally formed to mesh with a first male spline 67a spline-coupled to a female spline 66a provided on the bevel gear 66, a second male spline 67b provided at an intermediate portion, and the traveling transmission mechanism 123 side. It includes a first drive gear 67c and a third male spline 67d spline-coupled to a female spline 71a provided on the second drive sprocket 71.
[0034]
The work speed change mechanism 122 is a constant mesh speed change mechanism, that is, a constant mesh type speed change mechanism, and includes a work shaft 67, an input gear 126 spline-coupled to a second male spline 67 b of the work shaft 67, and an input gear 126. A coupling sleeve 127 meshes with the first drive sprocket 126 and the first drive sprocket 68 integrally formed with the coupling teeth 68a meshing when the coupling sleeve 127 moves. The gear is always connected to the first driven sprocket 73 (see FIG. 4) via the gear 72, that is, the gear is always meshed when it is used as a gear.
[0035]
The traveling transmission mechanism 123 includes a traveling shaft 78, a first drive gear 67 c of the work shaft 67, a second drive gear 131 and a third drive gear 132 spline-coupled to a second male spline 67 b of the work shaft 67, The two-drive sprocket 71, the second chain 76, the second driven sprocket 77, and the first drive gear 67c, the second drive gear 131, and the third drive that are rotatably fitted to the traveling shaft 78 and that are on the working shaft 68 side. A first driven gear 133, a second driven gear 134 and a third driven gear 136 respectively meshed with the gear 132, a neutral positioning return 137 rotatably fitted to the traveling shaft 78 for defining a neutral position for shifting; A slide movably disposed in a longitudinal groove 78a formed in the outer surface of the shaft 78 in the axial direction. Consisting of over 138 Metropolitan.
[0036]
The running shaft 78, the slide key 138, the neutral positioning return 137, the first driven gear 133, the second driven gear 134, the third driven gear 136, and the second driven sprocket 77 are members that constitute a key slide type transmission mechanism 138A.
[0037]
The first driven gear 133, the second driven gear 134, the third driven gear 136, and the second driven sprocket 77 have engagement grooves 133a, 134a, 136a, and 77a with which the slide key 138 is engaged, respectively, formed on the inner surface.
[0038]
The first drive gear 67c, the second drive gear 131, and the third drive gear 132 constitute a first gear train 139A, and the first driven gear 133, the second driven gear 134, and the third driven gear 136 constitute a second gear train 139A. These members constitute the gear train 139B.
[0039]
The neutral positioning return 137 has an engaged concave portion 137a with which the slide key 138 is engaged on the inner surface.
The slide key 138 includes an engagement claw 138a provided to engage with the engagement grooves 133a, 134a, 136a, 77a and the engagement recess 137a, a linear portion 138b extending from the engagement claw 138a, A locking end 138c is provided at an end of the linear portion 138b. A slide key 138 is provided on the back surface of the engaging claw 138a and the linear portion 138b. Is provided with a spring 141 that presses against the side of. Reference numeral 142 denotes a stopper for the slide key 138, which is attached to the traveling shaft 78.
[0040]
The first drive gear 67c and the first driven gear 133 are in the first forward speed during traveling, and the second drive gear 131 and the second driven gear 134 are in the second forward speed during traveling, the third drive gear 132 and the third driven gear 136. The third forward speed during traveling, the second drive sprocket 71, the second chain 76, and the second driven sprocket 77 are for retreating during traveling.
[0041]
FIG. 8 is a cross-sectional view (exploded view) showing a working speed change mechanism according to the present invention. A female spline 126a formed on the input side gear 126 is connected, a tooth portion 127b formed on the input side gear 126 is engaged with a tooth portion 127a formed on the connecting sleeve 127, and the connecting sleeve 127 is slid in the axial direction to be connected. The teeth 127a of the sleeve 127 are engaged with the coupling teeth 68a of the first drive sprocket 68. Since the coupling sleeve 127 and the first drive sprocket 68 to be coupled are on the same working shaft 67, When connecting the coupling sleeve 127 to the first drive sprocket 68, the teeth 127a of the coupling sleeve 127 Smoothly mesh with the coupling teeth 68a of the rocket 68, difficult to cause gear noise, wear and loss of teeth is unlikely to occur. In addition, 127b is an annular groove formed on the outer surface of the coupling sleeve 127.
[0042]
For example, two shafts are arranged in parallel, and a gear C slidably mounted on the other shaft is selectively coupled to one of the two gears A and B mounted on one shaft (such a case). In the case where the transmission mechanism is referred to as a "selective sliding transmission mechanism."), The gears A and C (or the gears B and C) are less likely to mesh with each other, and gear noise and missing teeth are likely to occur.
[0043]
9A and 9B are cross-sectional views showing a shift member attached to the transmission according to the present invention, wherein FIG. 9A shows a work transmission mechanism side and FIG. 9B shows a traveling transmission mechanism side.
(A) shows that a work shift member 145 as a shift member is attached to the work transmission mechanism 122.
[0044]
The working shift member 145 is attached to an intermediate portion of the working shift rod 146 slidably mounted in the transmission case 12a in the axial direction, and an intermediate portion of the working shift rod 146 for insertion into the annular groove 127b of the coupling sleeve 127. A working side fork member 147 and a working side arm member 148 attached to an end of a working side shift member 146 protruding outside the transmission case 12a for engaging with the shift lever 36 (see FIG. 3). .
The working-side arm member 148 is attached to the working-side shift rod 146 with a bolt 149, and includes an engaged recess 148a that engages with the shift lever 36 side.
[0045]
In order to support the working-side shift rod 146, the left case 101 includes a ball 151 into a hole 101d into which the tip of the working-side shift rod 146 is inserted, and a spherical recess 146a provided at the tip of the working-side shift rod 146. The right case 102 includes a through hole 102d through which the work side shift rod 146 penetrates, and a through hole 102d through which the work side shift rod 146 penetrates. And a dust seal 154 provided adjacent to.
[0046]
(B) shows that the traveling speed change mechanism 123 is provided with a traveling shift member 157 as a shift member.
The traveling shift member 157 is composed of a traveling side shift rod 158 slidably mounted in the transmission case 12a in the axial direction, and an annular member 161 having an H-shaped cross section engaged with the locking end 138c of the slide key 138. And a traveling-side fork member 162 attached to an intermediate portion of the traveling-side shift rod 158 to be inserted into an annular groove 161a formed on the outer surface of the annular member 161, and a transmission lever 36 (see FIG. 3). And a traveling-side arm member 163 attached to an end of a traveling-side shift rod 158 protruding outside the transmission case 12a.
The traveling-side arm member 163 is attached to the traveling-side shift rod 158 with a bolt 149, and includes an engaged concave portion 163a that engages with the shift lever 36 side.
[0047]
In order to support the traveling-side shift rod 158, the left case 101 has a ball 151f inserted into a hole 101f into which the distal end of the traveling-side shift rod 158 is inserted, and a spherical recess 158a provided at the distal end of the traveling-side shift rod 158. The right case 102 includes a through hole 102e through which the traveling side shift rod 158 penetrates, and a through hole 102e through which the traveling side shift rod 158 penetrates. And a dust seal 166 provided adjacent to.
[0048]
FIG. 10 is a cross-sectional view illustrating a differential according to the present invention. The differential 113 detects a rotation difference between the traveling wheels 13 and 14 (see FIG. 3) when the agricultural machine 10 (see FIG. 3) turns. The third driven sprocket 83 and a plurality of support shafts 171... (Only one is shown in the drawing) attached to the third driven sprocket 83 so as to extend in the radial direction. (Only one is shown in the figure) rotatably mounted on these support shafts 171 and a left differential meshed with these differential small bevel gears 172 and spline-coupled to the left axle 13a. It is composed of a large dynamic bevel gear 173 and a right differential large bevel gear 174 meshed with the small differential bevel gear 172 and spline-coupled to the right axle 14a. Reference numerals 176 and 176 denote bearings mounted on the left case 101 and the right case 102 for rotatably supporting the left axle 13a and the right axle 14a, and 177 and 177 denote dust seals.
[0049]
The left axle 13a and the right axle 14a are provided with a fitting recess 13b at an end of the left axle 13a, a fitting protrusion 14b at an end of the right axle 14a, and a fitting protrusion 14b at the fitting recess 13b. The third driven sprocket 83 is rotatably fitted via the third driven sprocket 83. In addition, 13c and 14c are bushes provided between the third driven sprocket 83 and the respective axles 13a and 14a.
[0050]
Reference numeral 181 denotes a differential lock mechanism for stopping the function of the differential device 113 and integrally rotating the left axle 13a and the right axle 14a, and a lock member 182 spline-coupled to the left axle 13a, A slider 183 for sliding the member 182 in the axial direction, the above-described differential lock lever 37 (see FIG. 3), and a cable (not shown) for connecting each of the slider 183 and the differential lock lever 37 are provided. By operating the lever 37, the lock member 182 is slid to couple the claw portions 182a, 182a of the lock member 182 to the side protruding portions 83a provided on the third driven sprocket 83, and the left axle 13a and the third driven The sprocket 83 is integrally rotated, that is, the left axle 13a and the right axle 14a are integrally rotated. Make.
[0051]
FIG. 11 is a side view for explaining a mounted state of the transmission lever according to the present invention, and shows a right side view of the transmission case 12a.
The shift lever 36 includes a base member 187 swingably attached to a support shaft 186 provided on the right case 102, a lever body 188 having a tip end swingably attached to a cylindrical portion 187 a provided on the base member 187. This is a substantially L-shaped member including a first projection 191 and a second projection 192 projecting upward from an intermediate portion of the lever main body 188, and a grip 193 attached to an upper end of the lever main body 188.
The lever main body 188 is a part penetrating the transmission guide panel 195 attached to the transmission case 12a.
[0052]
FIG. 12 is an enlarged side view of an essential part for explaining an attached state of the transmission lever according to the present invention. The first projection 191 of the transmission lever 36 faces the traveling arm member 163 of the traveling shift member 157, This shows that the protrusion 192 faces the work side arm member 148 of the work shift member 145.
[0053]
The figure shows the position of the transmission lever 36 in the neutral state during traveling of the transmission 111 (see FIG. 7). More specifically, the first projection 191 is engaged with the engaged recess 163 a of the traveling side arm member 163. In this state, the second protrusion 192 is not engaged with the engaged concave portion 148a of the working-side arm member 148.
In the drawing, the working-side fork member 147 and the traveling-side fork member 162 are indicated by broken lines.
[0054]
13A and 13B are front views of a shift guide panel showing a shift pattern of a shift lever. FIG. 13A illustrates an example (the present embodiment), and FIG.
(A) In the embodiment, the transmission guide panel 195 has a guide hole 197 for guiding the transmission lever 36 (see FIG. 12).
[0055]
The guide hole 197 connects the traveling side hole 197a, the working side hole 197b provided in parallel with the traveling side hole 197a, and the respective ends of the traveling side hole 197a and the working side hole 197b. It comprises a vertical hole 197c and a side hole 197d protruding laterally from the vertical hole 197c.
[0056]
In the traveling hole 197a, the shift lever is sequentially moved from the left end to the traveling neutral position 36A (the position of N on the traveling side) and the first forward speed position 36B for moving the agricultural machine forward (1 on the traveling side). ), The second forward speed position 36C (position (2) on the traveling side) and the third forward speed position 36D (position (3) on the traveling side).
[0057]
In the working side hole 197b, the shift lever is sequentially moved from the left end to the working side neutral position 36E (the position N on the working side), the first working speed position 36F (the position {circle around (1)} on the working side) and the working side first position 36F. It is possible to move to the second speed position 36G (position (2) on the working side). The working side first speed position 36F is a position when the vehicle is traveling at the first forward speed while operating the above-described tillage devices 15 and 16 (see FIG. 1). This is the position when the vehicle travels at the second forward speed while operating the devices 15 and 16.
In the side hole 197d, the shift lever can be moved to a retreat position 36H for retreating the agricultural work machine.
[0058]
As described above, according to the shift pattern of the embodiment, the shift can be performed so as to increase the speed sequentially from the neutral positions 36A and 36E on the traveling side and the working side, and the shift pattern can be easily understood intuitively. Can be easily performed.
[0059]
(B) In the comparative example, the transmission guide panel 220 has a guide hole 222 for guiding the transmission lever.
The guide hole 222 has a running side hole 222a, a working side hole 222b provided in parallel with the running side hole 222a, and a vertical connecting the centers of the running side hole 222a and the working side hole 222b. It comprises a hole 222c and a side hole 222d which is offset from the end of the running side hole 222a toward the work side hole 222b and extends laterally.
[0060]
223A is the traveling neutral position, 223B is the first forward speed position, 223C is the second forward speed position, 223D is the working neutral position, 223E is the first working speed position, and 223F is the first working position. The second speed position and 223G are the reverse positions.
[0061]
In the shift pattern of this comparative example, the neutral positions 223A and 223D are located between the first speed and the second speed on both the traveling side and the working side, so that the first to second speeds or the second to second speeds are set. When shifting to the first speed, the gear must be operated via the neutral positions 223A and 223D, and the operability is inferior to the shift pattern of the embodiment shown in FIG.
[0062]
FIG. 14 is a plan view showing a state of the speed change lever according to the present invention. The speed change lever 36 is disposed at the running neutral position 36A (see FIG. 13A), and the first projection 191 of the speed change lever 36 is used for running. This shows that the second protrusion 192 is engaged with the working-side arm member 148 of the working shift member 145 by engaging the running-side arm member 163 of the shift member 157.
[0063]
The operation of the above-described transmission 111 will be described next.
FIG. 15 is a first operation diagram showing the operation of the transmission according to the present invention, and the operation of the traveling transmission mechanism 123 will be described.
In (a), the shift lever is moved from the traveling neutral position 36A to the forward first speed position 36B.
[0064]
In (b), at this time, the first protrusion 191 is engaged with the traveling side arm member 163, and the second protrusion 192 is not engaged with the working side arm member 148. Accordingly, the lever main body 188 is swung toward the front side of the drawing about the cylindrical portion 187a, and the shift lever is moved as shown in FIG. As the 191 moves, the traveling shift rod 158 slides outward, that is, in the direction of the arrow.
[0065]
As a result, the traveling-side fork member 162 moves the engagement claw 138a of the slide key 138 from within the engaged recess 137a of the neutral positioning return 137 to the engaged groove 133a of the first driven gear 133 via the annular member 161. . Therefore, the first driven gear 133 and the traveling shaft 78 can rotate integrally, and power is transmitted from the first drive gear 67c (see FIG. 7) to the traveling shaft 78.
[0066]
Similarly, in (a) and (c), when the shift lever is moved from the first forward speed position 36B to the second forward speed position C, the slide key 138 connects the second driven gear 134 and the traveling shaft 78, When power is transmitted from the second drive gear 131 (see FIG. 7) to the traveling shaft 78 and the shift lever is moved from the forward second speed position C to the forward third speed position D, the slide key 138 travels with the third driven gear 136. Power is transmitted from the third drive gear 132 (see FIG. 7) to the traveling shaft 78 by connecting the shaft 78.
[0067]
FIG. 16 is a second operation diagram showing the operation of the transmission according to the present invention, and further explains the operation of the traveling transmission mechanism 123.
In (a), the shift lever is moved from the traveling neutral position 36A to the reverse position 36H.
[0068]
In (b), at this time, the lever main body 188 is slightly swung in the direction of the arrow around the support shaft 186. The first protrusion 191 is engaged with the traveling side arm member 163, and the second protrusion 192 is not engaged with the working side arm member 148. Therefore, by swinging the lever body 188 about the cylindrical portion 187a toward the back of the paper surface and moving the shift lever as shown in (a), the first projection is made as shown in (c). As the 191 moves, the traveling shift rod 158 slides inward, that is, in the direction of the arrow.
[0069]
As a result, the traveling-side fork member 162 moves the engaging claw portion 138a of the slide key 138 from within the engaged recess 137a of the neutral positioning return 137 to the engaged groove 77a of the second driven sprocket 77 via the annular member 161. Let it. Therefore, the second driven sprocket 77 and the traveling shaft 78 can rotate integrally, and power is transmitted from the second drive sprocket 71 (see FIG. 4) to the traveling shaft 78. The rotation of the traveling shaft 78 at this time is opposite to that described with reference to FIG.
[0070]
FIG. 17 is a third operation view showing the operation of the transmission according to the present invention, and the operation of the working transmission mechanism 122 will be described.
In (a), the shift lever is moved from the traveling neutral position 36A to the working first speed position 36F via the working neutral position 36E.
[0071]
In (b), at this time, the lever body 188 is swung in the direction of the arrow around the support shaft 186. As a result, the first projection 191 is engaged with the traveling arm member 163, and the second projection 192 is also engaged with the working arm member 148.
[0072]
Therefore, by swinging the lever body 188 toward the front side of the drawing about the cylindrical portion 187a and moving the shift lever as shown in (a), the first protrusion 191 as shown in (c) is obtained. Moves, the working side shift rod 146 slides outward, that is, in the direction of the arrow. (At this time, the traveling side shift rod 158 also slides as shown in FIG. 15.)
[0073]
As a result, the working-side fork member 147 moves the coupling sleeve 127 to mesh with the coupling teeth 68a of the first drive sprocket 68. Accordingly, the work shaft 67 and the first drive sprocket 68 rotate integrally, and power is transmitted from the work shaft 67 to the tillage assist shaft 74 (see FIG. 4) via the first chain 72 (see FIG. 4). Similarly, in (a) and (c), when the shift lever is moved from the first working speed position 36F to the second working speed position 36G, the working fork member 147 moves to the position indicated by the imaginary line. The coupling sleeve 127 slides further to maintain engagement with the coupling teeth 68a.
[0074]
As described above with reference to FIGS. 3, 7 and 9, the present invention changes the power from the engine 11 on the working shaft 67 and the traveling shaft 78 to change the tilling devices 15 and 16 (see FIG. 1) and In the transmission 111 transmitting to the traveling wheels 13 and 14, the work shaft 67 transmits a bevel gear 66 receiving power from the engine 11 side, and transmits the power of the bevel gear 66 to the tillage devices 15 and 16 or shuts off the power. And a first gear train 139A composed of a plurality of gears integrally attached to the work shaft 67. The first gear train 139A is attached to the traveling shaft 78 so as to be rotatable on the shaft 78. A second gear train 139B composed of a plurality of gears meshing with the gears, a gear and a traveling shaft selected by being axially movably mounted and selectively engaging with each gear of the second gear train 139B. And a key-slide transmission mechanism 138A for transmitting power to the traveling wheels 13 and 14 by integrally rotating the transmission gear 8 and engaging the transmission lever 36 with the work transmission mechanism 122 and the key-slide transmission mechanism 138A. A work shift member 145 and a travel shift member 157 which are sometimes movable in the axial direction are additionally provided, and a shift operation is performed by the work shift member 145 and the travel shift member 157. .
[0075]
In the conventional selective sliding type transmission mechanism, since the gear is moved on the shaft and meshes with the other two gears, the shift pattern of the shift lever includes, for example, a first speed position and a second speed position on both sides of the neutral position. Although the position has to be arranged, in the present invention, by providing the traveling shaft 78 with the key slide type transmission mechanism 138A, the traveling shaft 78 is provided with, for example, the first driven gear 133, the second driven gear 134, and the third driven gear 136. Are arranged in order, by sliding the slide key 138, these gears 133, 134, and 136 can be sequentially selected and coupled to the traveling shaft 78. As a shift pattern of the transmission lever 36, the shift lever 36 is shifted from the traveling neutral position 36A. The first forward speed position 36B, the second forward speed position 36C, and the third forward speed position 36D can be arranged in this order. That. Therefore, it is easy to intuitively understand the shift pattern of the shift lever 36, and since the neutral position does not exist between the shift positions, the operability of the shift lever 36 can be improved.
[0076]
Further, by using the work speed change mechanism 122, it is possible to suppress gear noise and wear of gears during speed change as compared with the conventional selective sliding type speed change mechanism, and to achieve smoother gear engagement. Further, the use of the key-slide type transmission mechanism 138A reduces the possibility of catching at the time of shifting and allows the shift lever 36 to be operated more smoothly.
[0077]
【The invention's effect】
The present invention has the following effects by the above configuration.
According to a first aspect of the present invention, there is provided a transmission having an input gear receiving a power from a prime mover on a work transmission shaft, and a constantly meshing transmission mechanism for transmitting the power of the input gear to the work device or cutting off the power. A first gear train composed of a plurality of gears integrally attached to the work transmission shaft, and a first gear train rotatably mounted on the traveling transmission shaft and meshing with the first gear train. The two gear trains are mounted so as to be movable in the axial direction, and selectively engage with each gear of the second gear train, thereby integrally rotating the selected gear and the traveling transmission shaft to transmit power to the traveling wheel side. A key-sliding type transmission mechanism for transmitting power, and a shift member movable in the axial direction when engaged with the transmission lever is attached to the constantly meshing type transmission mechanism and the key-sliding type transmission mechanism, respectively. Shift For example, if a first speed gear, a second speed gear, and a third speed gear are arranged in this order on the traveling speed change shaft, the keys are slid to select these gears in order. The shift lever can be coupled to the traveling shift shaft, and the shift lever can be arranged in a shift pattern of a first speed position, a second speed position, and a third speed position in order from the neutral position. Therefore, it is easy to intuitively understand the shift pattern of the shift lever, and since the neutral position does not exist between the shift positions, the operability of the shift lever can be improved.
[0078]
In addition, the use of a constant-mesh transmission mechanism reduces gear noise and gear wear during gear shifting compared to a conventional selective sliding transmission mechanism, and allows gears to mesh more smoothly. Further, the use of the key-slide type speed change mechanism reduces the possibility of catching at the time of speed change, so that the speed change lever can be operated more smoothly.
[Brief description of the drawings]
FIG. 1 is a perspective view of a walking type agricultural working machine provided with a transmission according to the present invention. FIG. 2 is a side view of an agricultural working machine provided with a transmission according to the present invention. FIG. 3 is provided with a transmission according to the present invention. FIG. 4 is a cross-sectional view of a driving device including a transmission according to the present invention. FIG. 5 is a plan view of a transmission case and a clutch case according to the present invention. FIG. 6 is a driving device according to the present invention. FIG. 7 is a cross-sectional view of a main part of the transmission according to the present invention. FIG. 8 is a cross-sectional view showing a working transmission mechanism according to the present invention. FIG. 9 shows a shift member attached to the transmission according to the present invention. FIG. 10 is a cross-sectional view showing a differential according to the present invention. FIG. 11 is a side view illustrating an attached state of a shift lever according to the present invention. FIG. 12 is a sectional view showing an attached state of a shift lever according to the present invention. FIG. 13 is an enlarged side view of a main part to be described. FIG. 14 is a plan view showing the state of the transmission lever according to the present invention; FIG. 15 is a first operation view showing the operation of the transmission according to the present invention; FIG. FIG. 17 is a second operation diagram showing the operation of the transmission. FIG. 17 is a third operation diagram showing the operation of the transmission according to the present invention. FIG. 18 is a cross-sectional view of the conventional transmission. [Description of reference numerals]
11: prime mover (engine), 13, 14: running wheels, 15, 16: working device (tilling device), 36: shift lever, 66: input gear (bevel gear), 67: working shift shaft (work shaft), 78: traveling transmission shaft (traveling shaft), 111: transmission, 122: constant mesh transmission mechanism (working transmission mechanism), 123: traveling transmission mechanism, 138A: key slide type transmission mechanism, 139A: first gear Rows, 139B: second gear row, 145, 157: shift members (work shift members, traveling shift members).

Claims (1)

In a transmission for shifting power from a prime mover on a work shift shaft and a travel shift shaft to transmit the power to a work device and a traveling wheel,
The work transmission shaft includes an input gear that receives power from the prime mover, a constant mesh transmission mechanism that transmits power of the input gear to the work device, or shuts off the power, and a work transmission shaft. A first gear train consisting of a plurality of gears integrally attached to the
The traveling transmission shaft is rotatably mounted on the shaft, and a second gear train composed of a plurality of gears meshing with the first gear train, and is mounted movably in the axial direction and mounted on each gear of the second gear train. A key-slide type transmission mechanism that transmits the power to the traveling wheel side by integrally rotating the selected gear and traveling transmission shaft by selectively engaging, and
The constant mesh transmission mechanism and the key slide transmission mechanism each include a shift member that is movable in the axial direction when engaged with a shift lever, and performs a shift operation with the shift member. Transmission.

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