JP2004324812A - Transmission - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transmission capable of easily securing required rigidity and supporting force of a shift fork without increasing thickness and weight thereof and capable of reducing the manufacturing cost. <P>SOLUTION: This transmission 1 for setting a variable speed stage by connecting speed change gears M3 and M4 rotatably supported by a shaft 2 to the shaft 2 is provided with a shift rod 22 to be driven in the axial direction with speed changing operation, the shift fork 18 fixed to the shift rod 22 and having a fork-like engaging arm parts 34 and 34, and a synchro-sleeve 15 to be engaged with the engaging arm parts 34 and 34 in the condition that the engaging arm parts 34 and 34 ride over there and to be engaged with the speed change gear to connect the speed change gear to the shaft 2. Each of the engaging arm parts 34 of the shift fork 18 is formed with a slit 36, and the peripheral surface of the synchro-sleeve 15 is provided with engaging projecting parts 15a to be engaged with each of the slits 35. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a transmission that is used in a vehicle or the like and that performs a shift operation in accordance with a shift operation.
[0002]
[Prior art]
As a conventional transmission of this type, for example, a transmission disclosed in Patent Document 1 is known. This transmission has a transmission gear train composed of a main shaft and a counter shaft parallel to each other, a transmission gear fixed to one of these shafts, and a transmission gear rotatably supported on the other of the shafts. A shift rod arranged in parallel, a shift fork having one end fixed to the shift rod and extending in a direction orthogonal to the shift rod, and a shaft that rotatably supports the transmission gears are non-rotatably and axially moved. A synchro sleeve which is freely supported and faces the transmission gear is provided. This shift fork is a plate-like member formed by press working, and integrally has a fork main portion and a forked engaging arm portion. The fork main part is welded to the shift rod in a state where the shift rod is penetrated, and the engaging arm part extends to both sides thereof while straddling the outer peripheral surface of the synchro sleeve. An outer circumferential groove is formed on the outer circumferential surface of the synchro sleeve over the entire circumferential direction, and the engaging arm portion is engaged with the outer circumferential groove.
[0003]
With this configuration, in this transmission, the shift rod is driven in accordance with the shift operation, and the shift fork presses the synchro sleeve via the engagement arm portion and the outer peripheral groove, and meshes with the rotatable transmission gear, thereby changing the speed. When the gear is connected to the shaft via the synchro sleeve, a shift operation is performed. Further, a wear-resistant member is attached to the tip of each engagement arm so as to cover the tip, and the wear-resistant member comes into contact with the outer peripheral groove of the synchro sleeve, whereby the engagement arm is formed. Is prevented from being worn.
[0004]
[Patent Document 1]
JP-A-5-340471 (pages 3 and 4, FIG. 2)
[0005]
[Problems to be solved by the invention]
In the transmission having such a configuration, when the shift fork presses the synchro sleeve via the engagement arm portion with the shift operation, a large reaction force acts on the shift fork from the synchro sleeve in the axial direction. That is, a large bending moment is applied to the shift fork by a reaction force from the synchro sleeve acting on the engagement arm at the other end in a cantilever state in which one end is fixed to the shift rod. Therefore, in order to prevent deformation of the shift fork, it is necessary to have sufficient rigidity against such a bending moment. In this case, since the conventional shift fork is formed of a plate orthogonal to the shift rod, the rigidity must be increased, for example, in thickness. However, in the conventional shift fork, the engaging arm portion is engaged with the outer circumferential groove of the synchro sleeve. Therefore, when the shift fork is thickened, the width of the outer circumferential groove increases, and accordingly, the width of the synchro sleeve also increases. I will. As a result, the length of the transmission in the axial direction is increased, resulting in an increase in the size of the transmission and an increase in the weight, thereby slowing down the operation. Further, when the shift fork becomes thick, it is necessary to perform fine blanking (precision punching) or the like because a cut surface cannot be obtained with high accuracy by ordinary press working. Further, a wear-resistant member is attached to the tip of the engaging arm in order to prevent wear of the engaging arm due to friction of the synchro sleeve, so that the number of parts and the number of assembly steps increase accordingly.
[0006]
Further, in the above-described transmission, since the shift rod is welded to the main part of the fork in a state where the shift rod penetrates, this welding has to be performed on the circumferential portions on both sides where the shift rod projects from the main part of the fork. I can't get it. For this reason, normal fillet welding cannot be performed, and special equipment for that purpose is required, and the material of the plate is also limited. In addition, since the welded portion is limited only to the above-mentioned circumferential portion, the supporting force of the welded portion tends to be insufficient. The insufficient supporting force of the welded portion can be solved by, for example, increasing the diameter of the shift rod and increasing the welding area, but in this case, the shift rod becomes heavy, so that the operation also becomes dull. Alternatively, in order to cope with this problem, for example, a sleeve stopper having a reduced thickness is provided at a fork main portion that engages with the outer peripheral groove of the synchro sleeve so that the sleeve stopper does not normally contact the synchro sleeve. It is conceivable that the contact is made only when a large load is applied and the stress is dispersed. However, in order to provide such a sleeve stopper, it is necessary to perform a process such as coining (recompression) for reducing the thickness by pressing the plate several times, which increases the manufacturing cost. Also, due to the space in the transmission, it may be necessary to make the lengths of both engagement arms of the shift fork different from each other in order to avoid interference with other members. However, in such a shift fork, it is difficult to uniformly press the synchro sleeve, and a gear squeal or the like occurs during a shift operation. In this case, the shape of the engagement arm is adjusted so that the load balance and the amount of displacement of both engagement arms are uniform. However, in many cases, uniformity is difficult due to space and other restrictions.
[0007]
The present invention has been made to solve such a problem, and can easily secure required rigidity and supporting force of a shift fork without increasing thickness and weight, and reduce manufacturing cost. It is an object of the present invention to provide a transmission that can perform the transmission.
[0008]
[Means for Solving the Problems]
In order to achieve this object, the invention according to claim 1 includes a transmission gear (main third speed gear M3, main third speed gear M3) rotatably supported on a shaft (main shaft 2 in the embodiment (hereinafter the same in this section)). A transmission 1 for setting a shift speed by connecting a fourth gear M4) to a shaft, the shift rod 22 being arranged in parallel with the shaft, and driven in the axial direction with a shift operation, And a shift fork 18 extending from the shift rod 22 and having bifurcated engagement arms 34 on the distal end side, and supported by the shaft so as to be non-rotatable and movable in the axial direction. The arm portions 34, 34 are engaged while straddling each other, and are pushed in the axial direction by the shift fork 18 as the shift rod 22 moves in the axial direction. A synchro sleeve 15 for engaging the transmission gear with the shaft by meshing with the transmission gear; slits 35, 35 are formed in the engagement arms 34, 34 of the shift fork 18; , Characterized in that an engaging projection 15a engaging with the slits 35, 35 is provided.
[0009]
According to this transmission, the shift rod is driven in the axial direction with the shift operation, so that the shift fork presses the synchro sleeve engaged with the shift rod in the axial direction of the shaft to mesh with the transmission gear. Thus, the transmission gear is connected to the shaft, and the gear position is set. According to the present invention, the engagement protrusion provided on the outer peripheral surface of the synchro sleeve engages with the slit of the engagement arm of the shift fork. For this reason, the width of the shift fork including the engagement arm can be changed without changing the width of the synchro sleeve including the engagement protrusion in the axial direction of the shaft. As a result, by increasing the width of the shift fork, the rigidity thereof can be easily increased, and by setting the width appropriately, the required rigidity can be obtained without excess or shortage. Rigidity can be easily secured. Further, even when the lengths of the two engagement arms of the shift fork are different from each other, by appropriately setting the width, a good rigidity balance can be easily achieved, and the required rigidity can be obtained without excess or shortage. . Also, by increasing the size of the slit of the engagement arm, the area of the portion in contact with the engagement protrusion can be increased, so that the engagement arm is worn due to friction generated when the shift fork presses the synchro sleeve. Can be alleviated. Thereby, the wear-resistant member required in the conventional shift fork can be omitted.
[0010]
According to a second aspect of the present invention, in the transmission 1 according to the first aspect, the shift fork 18 is fixed in a state of circumscribing the outer peripheral surface of the shift rod 22 and is formed of a plate material extending at least in the axial direction of the shift rod 22. It is characterized by having been done.
[0011]
According to this transmission, the shift fork is made of a plate material, and since the plate material extends at least in the axial direction of the shift rod, rigidity can be easily secured by the width of the plate material in this axial direction, and the width of the plate material can be reduced. By changing, the rigidity can be easily changed. Further, since the rigidity can be ensured by the width of the plate, the thickness of the plate can be reduced correspondingly, and the options of the plate can be increased, so that the cost can be reduced.
[0012]
Also, since the shift fork is fixed in a state of circumscribing the outer peripheral surface of the shift rod, normal fillet welding can be performed, which eliminates the need for special equipment for welding and the material of the plate material. Options are expanded. As a result, a significant cost reduction becomes possible. Further, by increasing the length of the welded portion in the axial direction, the welding area can be increased, so that the supporting force of the welded portion can be sufficiently ensured. As a result, since a sleeve stopper is not required, processing such as coining is not required. Furthermore, the diameter of the shift rod can be reduced by increasing the welding area. As described above, the weight and size of the entire transmission can be reduced, and the cost can be reduced.
[0013]
The invention according to claim 3 is characterized in that, in the transmission 1 according to claim 2, the shift fork 18 is formed by press working.
[0014]
As described above, according to the transmission of claim 2, since the shift fork can be made of a thin plate material, according to the present invention, fine blanking or the like is not performed in forming the shift fork. It can be performed without any trouble by ordinary inexpensive press working. Further, by press working, a shift fork having a different width between portions such as a welded portion and an engagement arm portion can be easily formed, and thus a shift fork having a desired rigidity distribution can be easily obtained.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 shows a schematic configuration of a transmission according to a first embodiment of the present invention. The transmission 1 is used for a vehicle. The transmission 1 is provided with a main shaft 2 to which power is input from an engine (not shown), and a power transmitted from the main shaft 2 provided in parallel with the main shaft 2. A counter shaft 3 for outputting to a drive shaft or a propeller shaft (both not shown) is provided. The main shaft 2 is provided with main first to fifth speed gears M1 to M5 along the axial direction thereof, and the counter shaft 3 has counters 1 to 5 which mesh with the main first to fifth speed gears M1 to M5, respectively. Fifth speed gears C1 to C5 are provided. The first to fifth speed gear trains G1 to G5 on the forward side are constituted by the main first to fifth speed gears M1 to M5 and the counters 1 to 5th gears C1 to C5, respectively.
[0016]
Among the above gears, the main first speed gear M1 and the main second speed gear M2 are integrally fixed to the main shaft 2, and the counter first speed gear C1 and the counter second speed gear C2 meshing with these are rotated by the counter shaft 3. It is freely supported. The third to fifth speed gears M3 to M5 are rotatably supported by the main shaft 2, and the third to fifth speed gears C3 to C5 meshing with them are integrally fixed to the counter shaft 3.
[0017]
A reverse drive gear R1 is integrally fixed to the main shaft 2, a reverse driven gear R2 is rotatably supported on the counter shaft 3, and a reverse idle gear (not shown) is attached to these two gears R1 and R2. ) Are engaged at the same time, and these gears constitute a reverse gear train GR.
[0018]
Further, the transmission 1 includes a 1-2 speed synchronization mechanism 11, a 3-4 speed synchronization mechanism 12, and a fifth speed synchronization mechanism 13 for setting a shift speed. The first- or second-speed synchronization mechanism 11 sets a shift speed to a first speed or a second speed by selectively connecting a rotatable counter first speed gear C1 and a counter second speed gear C2 to a counter shaft 3. And a synchro sleeve (not shown), a shift fork 17 and a shift rod 21. Similarly, the third-fourth-speed synchronizing mechanism 12 sets the shift speed to the third speed or the fourth speed by selectively connecting the main third speed gear M3 and the main fourth speed gear M4 to the main shaft 2. And includes a synchro sleeve 15, a shift fork 18, and a shift rod 22. The fifth speed synchronizing mechanism 13 sets the fifth speed by connecting the main fifth speed gear M5 to the main shaft 2, and includes a synchro sleeve (not shown), a shift fork 19 and a shift fork. A rod 23 is provided. Since these synchronization mechanisms 11 to 13 have basically the same configuration, the configuration of the 3-4 speed synchronization mechanism 12 will be described below as a representative.
[0019]
The synchro sleeve 15 is arranged between the main third speed gear M3 and the main fourth speed gear M4, is provided on the main shaft 2 so as not to rotate, rotates integrally with the main shaft 2, and moves in the axial direction with respect to the main shaft 2. It is freely supported. On the outer peripheral surface of the synchro sleeve 15, an engaging projection 15a having a rectangular cross section is provided over the entire circumferential direction (see FIG. 2C). The shift rod 22 is arranged in parallel with the main shaft 2 and the counter shaft 3, and is provided movably in the axial direction. A shift piece (not shown) for driving the shift rod 22 in the axial direction is engaged with the shift rod 22, and a shift arm (both of which is provided with the shift arm) in accordance with the operation of the shift lever. (Not shown) are selectively engaged and connected.
[0020]
As shown in FIG. 2, the shift fork 18 is made of, for example, a plate formed by pressing an iron plate, is fixed to the shift rod 22, and extends toward the synchro sleeve 15. The shift fork 18 includes a central fixed portion 31 and a pair of arm portions 32, 32 symmetrically extending bifurcated from the fixed portion 31. The fixing portion 31 has a concave surface that matches the outer peripheral surface of the shift rod 22. The shift fork 18 is in contact with the outer peripheral surface of the shift rod 22 via this concave surface, and At the boundary between the arm portions 32, 32, the shift rod 22 is welded to the shift rod 22 over the entire axial direction by, for example, fillet welding. These welded portions are welded portions 24, 24. The arms 32, 32 are respectively composed of bases 33, 33 extending obliquely so as to spread each other, and engaging arms 34, 34 extending substantially parallel to each other from their ends. The engagement arms 34, 34 are slightly bent inward near the bases 33, 33, extend through the engagement portions 34 a, 34 a extending parallel to each other from the ends thereof, and then extend outward from the ends thereof, and further extend in parallel. Slightly extended. Each engaging portion 34a is formed with a slit 35 having a predetermined constant width over the entire length thereof, and each slit 35 is engaged with the engaging convex portion 15a of the synchro sleeve 15. FIG. (C).
[0021]
As described above, in the state where the engagement arms 34, 34 straddle the synchro sleeve 15, the shift fork 18 passes through the slit 35 of each engagement arm 34 and the engagement protrusion 15 a of the synchro sleeve 15. It is engaged with the synchro sleeve 15. Also, as shown in FIG. 3B, the width of the shift fork 18 is constant from the fixed portion 31 to the vicinity of the tip of the base 33, and from the tip to the vicinity of the center of the slit 35 of the engagement arm 34. It has a tapered shape, and at the tip thereof, the width is almost the same as that of the synchro sleeve 15 (see FIG. 3C).
[0022]
Next, the operation of the transmission 1 having the above-described configuration will be described with reference to FIG. 1 taking a case where the third speed or the fourth speed is selected as an example.
[0023]
When the third speed is selected by the driver's shift operation by operating the shift lever, the shift arm is engaged with the shift piece, and the shift rod 22 and the shift fork 18 integral therewith are connected via the shift piece. It is driven axially toward the third speed gear M3 (to the right in FIG. 1). As a result, the shift fork 18 presses the synchro sleeve 15 via the slits 35, 35 of both the engagement arms 34, 34 and the engagement projections 15a engaging with the shift forks 18, and the shift fork 18 is moved to the main third speed gear M3. Bite. As a result, the main third speed gear M3 is connected to the main shaft 2 via the synchro sleeve 15, so that the shift speed is set to the third speed by the third speed gear train G3. The power of the main shaft 2 is transmitted to the counter shaft 3 while being shifted by the third speed gear train G3, and further output to the drive shaft and the propeller shaft. When the fourth speed is selected, the shift rod 22 and the shift fork 18 are driven toward the main fourth speed gear M4 (to the left in FIG. 1), so that the synchro sleeve 15 is moved to the main fourth speed gear M4. The main fourth speed gear M4 is connected to the main shaft 2 and the speed is set to the fourth speed by the fourth speed gear train G4.
[0024]
As described above, according to the present embodiment, the engagement protrusions 15a of the synchro sleeve 15 are engaged with the slits 35, 35 of the engagement arms 34, 34 of the shift fork 18, so that the main shaft 2 The width of the shift fork 18 can be changed without changing the width of the synchro sleeve 15 including the engagement convex portion 15a in the axial direction of FIG. As a result, the rigidity of the shift fork 18 can be easily increased by increasing the width of the shift fork 18, and the required rigidity can be obtained without excess or deficiency by appropriately setting the width. The required rigidity can be easily secured. Further, by increasing the size of the slit 35 of the engagement arm portion 34, the area of the portion in contact with the engagement projection 15a can be increased, so that the engagement caused by the friction generated when the shift fork 18 presses the synchro sleeve 15 can be increased. Wear of the arm 34 can be reduced. Thereby, the wear-resistant member required in the conventional shift fork can be omitted.
[0025]
Further, since the shift fork 18 is made of a plate material and extends in the axial direction of the shift rod 22, rigidity can be easily secured by the width of the plate material, and the rigidity can be easily changed by changing the width. it can. Further, since the rigidity can be ensured by the width of the plate, the thickness of the plate constituting the shift fork 18 can be reduced, and the choice of the plate can be widened. Further, since the shift fork 18 is fillet-welded to the shift rod 22, special equipment for welding is not required, and the choice of plate materials is widened. Further, by increasing the length of the welds 24, 24, the welding area can be increased, so that the reaction force from the synchro sleeve 15 applied to the welds 24, 24 when the shift fork 18 moves is welded. The support force of the parts 24, 24 can be easily secured. Accordingly, since a sleeve stopper is not required, processing such as coining is not required, and the diameter of the shift rod 22 can be reduced by enlarging the area of the welded portions 24, 24.
[0026]
Further, since the plate material of the shift fork 18 becomes thinner, the shift fork 18 can be easily formed by ordinary inexpensive press working without depending on fine blanking or the like, and the welded portions 24, 24, The shift fork 18 having a different width for each portion such as the engagement arm portions 34, 34 can be easily formed. In order to avoid interference with other members in the transmission 1, when it is necessary to make the lengths of the two engaging arms 34, 34 different from each other, the widths in the axial direction are made different from each other. By maintaining the balance of the rigidity of the engaging arms 34, 34, deformation of the engaging arm 34, gear squealing, and synchronous wear due to imbalance in rigidity can be prevented. Thus, the shift fork 18 having a desired rigidity distribution can be easily formed.
[0027]
As described above, according to the present embodiment, since the shift fork 18 is formed of the plate having the slits 35 as described above, the shift fork 18 is formed by the width of the plate without increasing the thickness or weight. Required rigidity can be easily secured. In addition, the required supporting force of the shift fork 18 can be easily secured by increasing the welding area. Furthermore, simplification of welding, an increase in the thickness and material choice of the plate material, abolition of coining processing and the like, and normal press working become possible. Since the diameter of the shift rod 22 can be reduced, the weight and size of the entire transmission can be reduced.
[0028]
FIG. 3 shows a second embodiment of the present invention. In the figure, the same components as those of the first embodiment are denoted by the same reference numerals. In this embodiment, the shift piece 42 is formed integrally with the shift fork 41, and these are formed by press working. The shift fork 41 has the same configuration as the shift fork 18 of the first embodiment. The shift piece 42 extends from one side surface of the base 33 of the shift fork 41 in parallel with the shift rod 22, and is bent at a front end thereof at a substantially right angle along a line parallel to the shift rod 22. . An engagement recess 43 is formed at the tip of the shift piece 42 so that a shift arm (neither is shown) is selectively engaged with the engagement recess 43 in accordance with the operation of the shift lever. Has become.
[0029]
According to the above configuration, the shift arm is engaged with the shift piece 42 by the shift operation of the shift lever by the driver, whereby the shift fork 41 integrated with the shift piece 42 is driven in the axial direction together with the shift rod 22. Thus, a shift operation is performed. Therefore, in the present embodiment, the above-described effects of the first embodiment can be obtained similarly. In addition, since the shift piece 42 is integrated with the shift fork 41, the number of components can be reduced, and the shift fork 41 can be easily formed by press working, thereby reducing the manufacturing cost.
[0030]
【The invention's effect】
As described above, according to the transmission of the present invention, the required rigidity and support force of the shift fork can be easily secured without increasing the thickness and weight, and the manufacturing cost can be reduced. It has effects such as.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of a transmission according to a first embodiment of the present invention.
FIG. 2A is a front view, FIG. 2B is a side view, and FIG. 2C is a cross-sectional view taken along line AA in FIG. is there.
3A is a front view and FIG. 3B is a side view showing a shift fork and the like according to a second embodiment.
[Explanation of symbols]
1 Transmission 2 Main shaft (shaft)
15 Synchro sleeve 15a Engagement projection 18 Shift fork 22 Shift rod 24 Weld 34 Engagement arm 35 Slit M3 Main third speed gear (transmission gear)
M4 Main 4th gear (transmission gear)

Claims (3)

A transmission for setting a shift speed by connecting a transmission gear rotatably supported on a shaft to the shaft,
A shift rod that is arranged in parallel with the shaft and is driven in the axial direction with a shift operation;
A shift fork fixed to the shift rod, extending from the shift rod, and having a bifurcated engagement arm on the distal end side;
The shift fork is non-rotatably supported on the shaft so as to be movable in the axial direction. The shift fork is engaged with the shift arm in a state of straddling the shift fork. A synchro sleeve that connects the transmission gear to the shaft by being engaged with the transmission gear by being pressed in the axial direction at,
A transmission, wherein a slit is formed in the engagement arm portion of the shift fork, and an engagement protrusion engaging with the slit is provided on an outer peripheral surface of the synchro sleeve. 2. The transmission according to claim 1, wherein the shift fork is fixed in a state of being circumscribed on an outer peripheral surface of the shift rod, and is formed of a plate material extending at least in an axial direction of the shift rod. 3. The transmission according to claim 2, wherein the shift fork is formed by press working.

Images