JP3058671B2 - Vehicle speed detector - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a traveling speed detection device for electrically detecting the traveling speed of a vehicle such as a motorcycle from the rotation speed of an output shaft of a transmission case. Related to the device.

[Prior Art] Japanese Patent Application Laid-Open No. 64-29771 discloses that the rotation of the output shaft of a transmission case is taken out through a pair of gears meshing with each other, and the rotation of this gear is transmitted to a speedometer via a cable. Discloses a mechanical rotary power take-out device.

This conventional rotary power take-out device includes a gear case for housing the gear. The gear case is attached to an outer surface of a sprocket cover that covers the output shaft and a driving sprocket that rotates integrally with the output shaft, and a rotating shaft of a gear on the input side passes through the sprocket cover. And, the penetrating end of the rotating shaft is coaxially connected to the end of the output shaft via a joint. By this connection, the rotation of the output shaft is transmitted from the input side gear to the output side gear to the cable. It is supposed to be.

By the way, in the conventional rotary power take-out device using a gear, since a resistance is generated at a meshing portion of the gear, there is a problem that the driving torque of the output shaft is lost by the resistance. Therefore, the present applicant has attempted to change the mechanical rotary power take-out device to an electrical sensor and electrically detect the rotation speed of the output shaft.

In this sensor, a disc-shaped magnet and a pickup IC are housed in a case. By attaching this case to a sprocket cover, the shaft of the magnet and the output shaft are connected coaxially. I have. And when the magnet is rotated by the output shaft, it is picked up by the line of magnetic force.
The IC is operated to output an electric pulse indicating the number of rotations of the output shaft.

On the other hand, when the magnet of the sensor is coaxially connected to the output shaft, the connecting portion between the shaft portion of the magnet and the output shaft may have an uneven fitting in consideration of the compactness of the connecting portion and the assemblability of the sensor. It is desirable to have a simple configuration. Further, since the sensor is also a precision part, if an excessive bending load is applied to the shaft of the magnet, the sensor may be damaged.

Therefore, the coaxiality between the sensor shaft and the output shaft needs to be determined with higher precision than ever before.

[Problems to be Solved by the Invention] However, if the sprocket cover is made of a thin synthetic resin material in order to reduce the weight and cost of the sprocket cover, the cover itself will be distorted when the sprocket cover is formed. Often occurs. For this reason, even if the sensor case is attached to a predetermined position on the sprocket cover, the shaft of the magnet and the output shaft may not be coaxially aligned, and the positioning accuracy between the shaft and the output shaft may be deteriorated. There is.

In addition, since the sensor itself is exposed outside the sprocket cover, there remains a problem in appearance, and the case must be firmly formed in order to protect the sensor from stoning and stepping stones. For this reason, a dedicated hard case is required, and there is a problem that the cost is increased accordingly.

The present invention has been made based on such circumstances, and while accurately determining the coaxiality between the output shaft and the sensor shaft,
The shaft length of the sensor shaft can be kept short to prevent shaft runout, and the sensor can be protected from stoning etc. without being exposed to the outside of the transmission case. It is an object of the present invention to provide a traveling speed detecting device for a vehicle, which can suppress the overhang of the vehicle, and can prevent interference between a signal transmitting lead wire connected to a sensor and a driving member.

Means for Solving the Problems To achieve the above object, a traveling speed detecting device for a vehicle according to the present invention comprises: a transmission case connected to a crankcase of an engine; An output shaft protruding to the side of the output shaft; a drive member attached to one end of the output shaft and driven to rotate integrally with the output shaft; and covering the crankcase from the side, and having the drive member at the end thereof. And a synthetic resin crankcase cover integrally formed with a cover part that covers and covers the cover case.

In the present invention, a metal support stay interposed between the cover portion and the drive member is mounted on the transmission case, and a sensor mounting hole coaxial with the output shaft is provided on the support stay. A sensor for electrically detecting the number of rotations of the output shaft is attached to a surface of the support stay facing the cover portion, and the sensor includes a case having a built-in magnet and a detection portion facing the magnet. A sensor shaft rotatably supported by the case and transmitting the rotation of the output shaft to the magnet;
A lead for transmitting a rotation speed signal detected by the detection unit, and these magnets and the lead are arranged side by side in a direction orthogonal to the sensor axis, and the lead is connected to the support stay and the support stay. The sensor case is coaxially surrounding the sensor shaft, and the sensor case is coaxially positioned by fitting the sensor shaft into the sensor mounting hole. A cylindrical portion and a flange portion superposed on the support stay are integrally formed, and a plurality of portions of the flange portion are screwed to the support stay in a state where the cylindrical portion is fitted in the sensor mounting hole. Thereby, the sensor is fixed to the support stay, and the output shaft has a protruding portion at one end thereof, which protrudes inside the cylindrical portion. This protrusion is characterized by being connected coaxially to the sensor shaft inside of the tubular portion.

[Operation] According to this configuration, the support stay that supports the sensor includes:
Since it is made of a metal having higher rigidity than a synthetic resin material, it is hardly deformed and the occurrence of molding distortion is reduced. in addition,
The sensor shaft of the sensor is coaxially aligned with the output shaft on the transmission case side by fitting a cylindrical part integral with the case into the sensor mounting hole of the support stay. Since the cylindrical portion is screwed to the support stay while being fitted into the sensor mounting hole, the coaxiality between the output shaft and the sensor shaft can be accurately determined.

In connecting the sensor shaft and the output shaft, a protruding portion is formed at one end of the output shaft so as to protrude inside the cylindrical portion, so that the sensor shaft is directed outward from the opening end of the cylindrical portion. There is no need to greatly extend. For this reason, the shaft length of the sensor shaft can be kept short, and shaft runout can be prevented.

Since the sensor is covered by a cover portion extending from the crankcase cover, the sensor is not directly exposed to the outside of the transmission case. Therefore, there is no problem in terms of appearance, and the sensor can be protected from stoning, stepping stones, and the like accompanying the traveling of the vehicle.

In addition, since the support stay is interposed between the lead wire connected to the sensor and the rotating drive member, the lead wire and the drive member can be separated from each other by this support stay. Therefore, even though the sensor is adjacent to the driving member, the lead wire of the sensor does not get caught or entangled in the driving member, and the lead wire can be prevented from being damaged.

At the same time, since the magnet and the lead wire do not need to overlap in the axial direction of the sensor shaft, the protrusion of the sensor to the side of the support stay can be minimized.

[Embodiment] Hereinafter, the present invention will be described with reference to the drawings applied to a motorcycle.

The frame denoted by reference numeral 1 in FIG. 6 has a steering head pipe 2 at its front end. A front wheel 4 is supported on the steering head pipe 2 via a front fork 3. A main pipe 5 extending obliquely downward and rearward is connected to the steering head pipe 2, and a rear arm bracket 6 extending downward is provided at the rear end of the main pipe 5. The front end of a rear arm 7 is pivotally supported by the rear arm bracket 6. The rear arm 7 extends rearward of the rear arm bracket 6, and a rear wheel 8 as a driving wheel is supported at a rear end of the rear arm 7.

An engine 9 is supported below the main pipe 5. The engine 9 includes a main case 11 that houses a crankshaft 10. At the rear of the crankcase 11, a transmission case for housing a gear transmission (not shown)
12 are integrally formed. The transmission case 12 protrudes rearward of the crankcase 11 and has a rear end supported by the rear arm bracket 6.

A meter stay 13 extending forward is attached to the front surface of the steering head pipe 2. An electric speedometer 14 is attached to the front end of the meter stay 13. The speedometer 14 is located ahead of the upper part of the front fork 3.

As shown in FIG. 1, the transmission case of the engine 9
An output shaft 17 that outputs engine power via a bearing 18 is supported at a rear portion of the 12. One end of the output shaft 17 penetrates the side surface of the transmission case 12 and is led out.
A drive sprocket 19 as a drive member is spline-engaged with a lead-out portion of the output shaft 17, and is fixed by a nut 20 so as not to come off. A chain 22 is wound between the driving sprocket 19 and the driven sprocket 21 of the rear wheel 8, and the rotation of the output shaft 17 is transmitted to the rear wheel 8 via the sprockets 19 and 21 and the chain 22.

A crankcase cover 23 made of a synthetic resin as shown in FIG. 2 is attached to one side surface of the crankcase 11. The crankcase cover 23 is
A sprocket cover 25 functioning as a cover shaft is integrally formed at the rear end of the crankcase cover 23. The sprocket cover 25 is used for the transmission case 12 and the drive sprocket.
19 is covered from the side.

A support stay 30 made of, for example, aluminum die-cast is attached to one side surface of the transmission case 12 covered with the sprocket cover 25. As shown in FIGS. 1 and 2, the support stay 30 includes a vertically elongated flat substrate portion 31 interposed between the driving sprocket 19 and the sprocket cover 25, and upper and lower ends of the substrate portion 31. And a boss portion 32 located at Boss 32 of support stay 30
The support stay 30 is fixed to the transmission case 12 by screwing a bolt 34 inserted through the boss 32 into the mounting seat 33.

A sensor mounting hole 35 is formed in the substrate 31 of the support stay 30. The sensor mounting hole 35 is located on the axis X1 of the output shaft 17, and a cylindrical support wall 36 extending toward the drive sprocket 19 is formed around the opening of the sensor mounting hole 35.

The output shaft is provided on the substrate 31 of the support stay 30.
A sensor 38 for detecting the number of rotations of 17 is attached. The sensor 38, as shown in FIGS. 3 to 5,
A case 39 is provided which is fixed to a surface of the substrate 31 facing the sprocket cover 25. The case 39 includes a cylindrical portion 40 having one end opened, and a box-shaped portion 41 connected to the cylindrical portion 40. The cylindrical portion 40 has a pair of flange portions 4a projecting vertically. These flanges 40a
Are superposed on the substrate 31 of the support stay 30, and are fixed to the substrate 31 via bolts 44.

A bearing member 43 is provided at the open end of the cylindrical portion 40. The bearing member 43 closes the opening of the cylindrical portion 40, and the sensor shaft is located between the bearing member 43 and the end of the cylindrical portion 40.
45 are rotatably supported. The sensor shaft 45 is coaxially located with respect to the output shaft 17, and the sensor shaft 45
An engaging portion 46 having a flat prismatic shape is formed at one end of the rim.

The bearing member 43 has an oil seal 48 for sealing a penetrating portion of the sensor shaft 45.

At the open end of the cylindrical portion 40 of the case 39, a cylindrical fitting wall portion 42 functioning as a cylindrical portion is integrally formed. The fitting wall 42 covers the periphery of the engaging portion 46 of the sensor shaft 45 coaxially. The fitting wall portion 42 is fitted inside the sensor mounting hole 35 of the support stay 30 or the support wall 36 connected thereto,
By this fitting, coaxiality between the sensor shaft 45 and the output shaft 17 is ensured.

The output shaft 17 has a protruding portion 17a protruding along the axial direction at one end to which the driving sprocket 19 is fixed. The projecting portion 17a enters the inside of the fitting wall portion 42 of the case 39, and the engaging portion 46 of the sensor shaft 45 is engaged with the engaging groove 47 at the tip of the projecting portion 17a. With this engagement, the output shaft 17 and the sensor shaft 45 are connected so as to rotate integrally in the direction around the axis, and the rotation of the output shaft 17 is transmitted to the sensor shaft 45. An engagement portion between the sensor shaft 45 and the output shaft 17 is surrounded by a fitting wall portion 42, and the fitting wall portion 42 prevents foreign matter such as dust and rainwater from entering the engagement portion. Is preventing.

At the other end of the sensor shaft 45, a disk-shaped magnet 49 that rotates integrally with the sensor shaft 45 is provided coaxially. magnet
Above 49, a pickup IC 50 as a detection unit is arranged. The pickup IC 50 is close to the outer peripheral surface of the magnet 49, and when the magnet 49 is rotated, is operated by the magnetic force lines to emit an electric pulse. Then, the pickup IC 50 of the present embodiment outputs two pulses while the magnet 49 makes one rotation.

The pickup IC 50 is supported on the printed circuit board 51. The printed board 51 is fixed to the box-shaped portion 41 of the case 39 via screws 52. As shown in FIG. 4, the printed board 51 is extended rearward of the magnet 49, and a lead wire 53 is connected to an extended portion of the printed board 51.

The lead wire 53 is for sending a pulse signal output from the pickup IC 50 to the speedometer 14, and a connection portion of the lead wire 53 to the printed board 51 is adjacent to the magnet 49. The magnet 49 and the lead wire 53 are in a direction orthogonal to the axis of the sensor shaft 45, that is, the transmission case.
They are arranged side by side in 12 front and rear directions.

As shown in FIG. 1 and FIG.
After being drawn out of the case 39 of 32, it is guided downward through the space between the substrate 31 of the support stay 30 and the sprocket cover 25, and is positioned on the opposite side of the drive sprocket 19 with the substrate 31 interposed therebetween. I have. And this lead wire
As shown in FIG. 6, 53 is guided from below the sprocket cover 25 to the rear of the main pipe 5 through the periphery of the crankcase cover 23 and from there to the front speedometer 14 along the main pipe 5. I have.

The opening of the box-shaped portion 41 of the case 39 is
After accommodating the printed circuit board 51 in the inside 41, it is liquid-tightly closed by a filler 54 made of a synthetic resin.

In addition, the sprocket cover 25 is provided with a bulging portion 25a that protrudes outward to avoid interference with the sensor 38.

According to such a configuration, the support stay 30 made of aluminum die-cast for supporting the sensor 38 is much higher in rigidity than the sprocket cover 25 made of synthetic resin. Is also reduced.

In addition, the sensor shaft 45 of the sensor 38 is fitted on the sensor mounting hole 35 of the support stay 30 by fitting a fitting wall portion 42 formed in the case 39 so as to surround the sensor shaft 45, so that the When the coaxial alignment with the output shaft 17 is performed, and the fitting wall portion 42 is fitted into the sensor mounting hole 35 even in the case 39, the board portion of the support stay 30 is
Since the output shaft 17 is fixed to the sensor shaft 45 via the bolts 44, the coaxiality between the output shaft 17 and the sensor shaft 45 can be accurately determined.
Therefore, it is possible to reliably prevent a bending load that causes a failure of the sensor 38 from being applied to the sensor shaft 45.

In addition, in connecting the sensor shaft 45 and the output shaft 17, a protruding portion 17a is formed at one end of the output shaft 17 so as to protrude inside the fitting wall portion 42. It is not necessary to greatly extend outward from the open end of the horn. For this reason, the axial length of the sensor shaft 45 can be suppressed as short as possible,
Shaking of the sensor shaft 45 can be prevented.

Further, according to the above configuration, the sensor 38 is covered and concealed from the side by the sprocket cover 25.
Is not exposed to the outside of the mission case 12 as it is, which is advantageous in appearance. At the same time, the sensor 38 can be protected from stoning and stepping stones,
Not only can the sensor 38 be prevented from being damaged, but it is not necessary to provide a dedicated hard case, and the cost can be reduced accordingly.

Further, since the support stay 30 for supporting the sensor 38 is interposed between the driving sprocket 19 and the sensor 38, the sensor 38 is driven in spite of the fact that the sensor 38 is housed inside the sprocket cover 25. Can be protected from 19.

Furthermore, according to the above configuration, since the support stay 30 is interposed between the drive wire sprocket 19 and the lead wire 53 for sending out the rotation speed signal detected by the sensor 38, the support stay 30 allows the lead wire 53 And the drive sprocket 19 can be separated from each other. Thus, despite the sensor 38 being adjacent to the drive sprocket 19, the lead wire
The lead wire 53 does not get caught or entangled in the drive sprocket 19, and the lead wire 53 can be prevented from being damaged.

At the same time, since the magnet 49 of the sensor 38 and the lead wire 53 do not overlap in the axial direction of the sensor shaft 45, the sensor 38
The lead-out portion of the lead wire 53 can be formed compactly, and the protrusion of the sensor 38 to the side of the support stay 30 can be reduced.

In the above embodiment, the support stay of the sensor is made of aluminum die-cast.However, the present invention is not limited to this, and it may be made of sheet metal or a forged product. When driven by a belt, a pulley may be used.

Further, the vehicle according to the present invention is not limited to a motorcycle, and may be another vehicle such as a four-wheeled vehicle or a snowmobile.

[Effects of the Invention] According to the present invention described in detail above, the sensor shaft is coaxially aligned with the output shaft of the transmission case by fitting the cylindrical portion of the case into the sensor mounting hole of the support stay. And, even in the case, since the cylindrical portion is screwed to the support stay with the cylindrical portion fitted in the sensor mounting hole, the coaxiality of the sensor shaft with respect to the output shaft can be accurately determined, and the sensor Thus, it is possible to reliably prevent a bending load from being applied to cause a failure.

Also, by forming a protruding portion at the one end of the output shaft, which protrudes inside the cylindrical portion, it is not necessary to greatly extend the sensor shaft outward from the opening end of the cylindrical portion. The shaft length can be kept short, and the shaft runout of the sensor shaft can be prevented.

In addition, since the sensor is covered by the cover portion of the crankcase cover, it is advantageous in terms of external appearance, and the sensor can be protected from stoning and stepping stones while traveling. Therefore, it is possible to prevent the sensor from being damaged, and it is not necessary to prepare a dedicated hard case, and the cost can be reduced accordingly.

Further, since the support stay supporting the sensor is interposed between the drive member and the lead wire of the sensor, the lead wire and the drive member can be separated from each other by using the support stay. Therefore, even though the sensor is adjacent to the drive member, the lead wire does not get caught or entangled in the drive member, and damage to the lead wire can be prevented.

In addition, since the magnet and the lead wire of the sensor do not need to overlap in the axial direction of the sensor axis, the lead-out portion of the lead wire from the sensor can be formed compact, and the sensor stays on the side of the support stay. There is an advantage that overhang is reduced.

[Brief description of the drawings]

 FIG. 1 shows an embodiment of the present invention. FIG. 1 is a sectional view of a mounting portion of a sensor, FIG. 2 is a view taken in the direction of the line II in FIG. 1, and FIG. FIG. 4 is a sectional view taken along the line III-III in FIG. 4, FIG. 4 is a sectional view taken along the line IV-IV in FIG. 5, FIG. 5 is a plan view of the sensor, and FIG. is there. 9 ... Engine, 11 ... Crankcase, 12 ... Transmission case, 17 ... Output shaft, 17a ... Protrusion, 19 ... Drive member (drive sprocket), 23 ... Crankcase cover, 25 ... Cover Part (sprocket cover), 30 ... support stay, 35 ... sensor mounting part, 38 ... sensor 39 ... case 40a ... flange part, 42 ... cylindrical part (fitting wall part), 45 ... sensor Shaft, 49: Magnet, 50: Detector (Pickup IC) 53: Lead wire.

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Akitaka Suzuki 2500 Shinkai, Iwata City, Shizuoka Prefecture Inside Yamaha Motor Co., Ltd. (72) Inventor Kunihiko Miwa 2500 Shinkai, Iwata City, Shizuoka Prefecture Inside Yamaha Motor Co., Ltd. (56 References: JP-A-64-29771 (JP, A) JP-A-3-287707 (JP, A) JP-A 57-93861 (JP, U) JP-A 1-139024 (JP, U) JP-A 50-109679 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) B62J 39/00 B62J 23/00

Claims (1)

(57) [Claims] A transmission case connected to a crankcase of the engine; an output shaft supported by the transmission case and having one end protruding to the side of the transmission case; and attached to one end of the output shaft to be integral with the output shaft. And a synthetic resin crankcase cover that covers the crankcase from the side. A cover part that covers the drive member from the side is integrated with an end of the crankcase cover. In the vehicle formed, a metal support stay interposed between the cover portion and the drive member is mounted on the transmission case, and a sensor mounting hole coaxial with the output shaft is formed on the support stay. And a sensor for electrically detecting the rotation speed of the output shaft is provided on a surface of the support stay facing the cover. Only, the sensor includes a case having a built-in detector facing the magnet and the magnet is rotatably supported in this case, a sensor shaft for transmitting rotation of the output shaft to the magnet,
A lead for transmitting a rotation speed signal detected by the detection unit, and these magnets and the lead are arranged side by side in a direction orthogonal to the sensor axis, and the lead is connected to the support stay and the support stay. The sensor case is coaxially surrounding the sensor shaft, and the sensor case is coaxially positioned by fitting the sensor shaft into the sensor mounting hole. A cylindrical portion and a flange portion superposed on the support stay are integrally formed, and a plurality of portions of the flange portion are screwed to the support stay in a state where the cylindrical portion is fitted in the sensor mounting hole. Thereby, the sensor is fixed to the support stay, and the output shaft has a protruding portion at one end thereof, which protrudes inside the cylindrical portion. The protrusion running speed detecting device for a vehicle, characterized in that it is connected coaxially to the sensor shaft inside of the tubular portion.