JP5687378B1 - Vehicle with swing lock device - Google Patents

Abstract

In a vehicle in which the rear of the vehicle body swings, the swing of the rear portion of the vehicle body is stopped during parking while maintaining the running performance. A vehicle includes a rear suspension 20 for suspending a rear wheel, and a swing lock device 60 for stopping swinging of the rear wheel. The rear suspension supports each rear wheel and a pair of left and right suspension arms 21L, R that are rotatably attached to the vehicle body and a balancer lever that is rotatably attached to the vehicle body. 40 and a pair of left and right dampers 35L, R connected between the suspension arm and the left and right ends sandwiching the rotation axis of the balancer lever. The swing lock device is fixed to the balancer lever and has a stopper 70 formed with one or a plurality of fitting portions, and is fixed to the vehicle body so that the lock pin 81 is fitted into the fitting portion according to a predetermined operation. And a lock pin actuating mechanism 80 that is actuated. [Selection] Figure 3

Description

  The present invention relates to a vehicle provided with a swing lock device for stopping swinging of a pair of left and right rear wheels. The vehicle may be a three-wheeled vehicle including a single front wheel and two right and left rear wheels, or may be a four-wheeled vehicle including two front wheels and two rear wheels.

  Conventionally, there is known a tricycle in which left and right rear wheels are inclined in the same direction as the vehicle body is inclined (Patent Document 1). In this tricycle, since the vehicle body and the left and right rear wheels are inclined in the same direction, the ground contact state of the rear wheels is maintained even when the vehicle is running without curving. For this reason, it is said that a driving feeling similar to that of a normal motorcycle can be obtained.

  Specifically, the tricycle described in Patent Document 1 includes a single front wheel, a pair of left and right rear wheels, and a rear suspension that suspends the rear wheels. The rear suspension has left and right suspension arms, a balancer lever, and left and right springs. The left and right suspension arms can rotate independently of each other about a swing axis that supports each rear wheel and extends in the left-right direction of the vehicle body. The balancer lever is provided to be rotatable with respect to the vehicle body at a position higher than the swing axis. The left and right springs are respectively connected between the left and right ends sandwiching the rotation axis of the balancer lever and the left and right suspension arms.

  As described above, the tricycle of Patent Document 1 is characterized in that the left and right springs are connected via the balancer lever. With this configuration, the spring force is equalized by the balancer lever. Therefore, the tricycle of Patent Document 1 can maintain the ground contact state of the left and right rear wheels even when the vehicle body runs while curving and the left and right rear wheels are inclined.

Utility model registration No. 3161882

  As in the tricycle of Patent Document 1, springs are attached to the left and right ends of the balancer lever, and each spring is connected to a suspension arm attached to the left and right rear wheels. The part swings left and right. For this reason, it is possible to improve the running performance of the tricycle.

  However, the three-wheeled vehicle configured as described above can run smoothly by swinging the rear part of the vehicle body when traveling, but becomes unstable because the rear part of the vehicle body swings when stopping. In particular, while the driver is in the tricycle, the tricycle can be kept stable by the driver's independence, but when the driver is away from the tricycle (that is, in the parked state), the vehicle body is swung. It was difficult to stabilize without letting

  For this reason, at present, there is a demand for a technology capable of stopping the swinging of the rear part of the vehicle body during parking while maintaining the running performance of the conventional vehicle (tricycle) in which the vehicle body swings backward. In particular, an object of the present invention is to realize such a swing lock of a vehicle body with good operability and a simple configuration.

The inventor of the present invention, as a result of earnestly examining the means for solving the conventional problems, has found that a stopper provided with a fitting portion (eg, notch or hole) is provided in a vehicle having a balancer lever and swinging rearward of the vehicle body. In addition to fixing to the balancer lever, a configuration was proposed in which a mechanism for operating a lock pin fitted into the fitting portion was fixed to the vehicle body. According to such a configuration, the position and inclination of the balancer lever can be fixed and the swinging of the vehicle body can be stopped by engaging the lock pin with the balancer lever serving as a fulcrum for the swinging of the vehicle body. it can. Further, when the engagement of the lock pin is released, the rear portion of the vehicle body can be swung again, so that the running performance of the vehicle is not hindered. Therefore, while maintaining the running performance of the vehicle, the vehicle body can be stabilized by stopping the swinging of the rear portion of the vehicle body during parking. The inventor has conceived that the problems of the prior art can be solved based on the above knowledge, and has completed the present invention.
Specifically, the present invention has the following configuration.

The 1st side of the present invention is related with vehicles provided with the swing lock device.
The vehicle 1 includes at least a pair of left and right rear wheels 30 and a rear suspension 20 that suspends the rear wheels 30.
The rear suspension 20 has a pair of left and right suspension arms 21, a balancer lever 40, and a pair of left and right dampers 35.
The pair of left and right suspension arms 21 support the left and right rear wheels 30 and are rotatably attached to the vehicle body of the vehicle.
The balancer lever 40 is rotatably attached to the vehicle body.
The pair of left and right dampers 35 are connected between the left and right ends sandwiching the rotation axis (A) of the balancer lever 40 and the suspension arm 21, respectively.
As a result, the rear portion of the vehicle tilts in the same direction as the vehicle body tilts with the balancer lever 40 as a fulcrum.
Furthermore, in the present invention, the swing lock device 60 includes a swing lock device 60 that stops the swinging of the rear wheel 30.
The swing lock device 60 basically includes a stopper 70 and a lock pin operating mechanism 80.
The stopper 70 is a member fixed to the balancer lever 40, and one or a plurality of fitting portions 71 are formed.
The lock pin operating mechanism 80 is fixed to the vehicle body, and can be operated to fit the lock pin 81 into the fitting portion 71 in accordance with a predetermined operation.

  According to the above configuration, the position and inclination of the balancer lever 40 are fixed by operating the lock pin 81 by the lock pin operating mechanism 80 and fitting the lock pin 81 into the fitting portion 71 of the stopper 70. Therefore, the swinging of the vehicle rear portion can be stopped, and the parking state of the vehicle can be stabilized.

  In the vehicle of the present invention, the stopper 70 has fixing portions 72 for the balancer lever 40 on both left and right sides sandwiching the center line (C) perpendicular to the vertical direction with respect to the rotation axis (A) of the balancer lever 40. Is preferred.

  By fixing the stopper 70 to the balancer lever 40 as described above, the stopper 70 can be provided at a position close to the rotation axis of the balancer lever 40. By fixing the stopper 70 near the rotating shaft of the balancer lever 40, a large load is applied to the lock pin 81 in a state where the lock pin 81 is inserted into the fitting portion 71 of the stopper 70. Can be prevented. Therefore, the state in which the stopper 70 and the lock pin 81 are engaged can be stabilized, and the configuration of the lock pin 81 itself can be reduced in size. If the lock pin 81 can be reduced in size, the operation for operating the lock pin 81 can be simplified, and the configuration of the swing lock device 60 itself can be simplified.

  In the vehicle of the present invention, the fitting portion 71 of the stopper 70 preferably includes a center fitting portion 71c, a left fitting portion 71l, and a right fitting portion 71r. The center fitting part 71 is provided on the above-mentioned center line (C). The left fitting portion 71l and the right fitting portion 71r are provided on left and right inclined lines (L, R) inclined in the left-right direction at a predetermined angle with respect to the center line (C).

  By providing the stopper 70 with the center fitting portion 71c, the left fitting portion 71l, and the right fitting portion 71r, the state of the vehicle body when the vehicle is parked can be appropriately selected. That is. If it is determined that it is preferable to park the vehicle with the vehicle body upright, the lock pin 81 may be inserted into the center fitting portion 71c of the stopper 70. In addition, when it is determined that it is preferable to park with the vehicle body tilted to the left or right, the lock pin 81 may be inserted into the left fitting portion 71l or the right fitting portion 71r of the stopper 70. As a result, a state suitable for parking the vehicle can be arbitrarily selected according to the situation of parking the vehicle and geographical characteristics.

  In the vehicle of the present invention, each of the plurality of fitting portions 71 may be any one of a notch, a hole, or a groove formed in the stopper 70.

  In the present invention, the fitting portion 71 of the stopper 70 may be any as long as the lock pin 81 can be fitted therein. As a form for that, a notch, a hole, or a groove is conceivable.

In the vehicle of the present invention, the lock pin operating mechanism 80 preferably includes a housing 82, an urging means 83, and a tension means 84 in addition to the lock pin 81.
The housing 82 is a member fixed to the vehicle body.
The urging means 83 is a means for urging the lock pin 81 in a direction away from the housing 82 and can be realized by, for example, a spring member.
The pulling means 84 is a means for pulling the lock pin 81 in a direction approaching the housing 82, and can be realized by, for example, a hydraulic or wire pulling system.
In the above structure, the stopper 70 is provided between the lock pin 81 and the housing 82.

The above-described configuration is a structure in which the lock pin 81 is fitted to the fitting portion 71 provided in the stopper 70 by pulling the lock pin 81. By adopting such a tension type structure, the configuration of the swing lock device 60 can be simplified. Further, the driver, when the vehicle is parked, the (pull the wire, for example, hand locking lever) performs an operation to pull the locking pin 81 only, it is possible to easily operate the swing locking device 60. For this reason, the operation of the swing lock device 60 is simplified.

In the vehicle of the present invention, it is preferable that the lock pin operating mechanism 80 further includes a piston rod 85 inserted through a through hole formed in the housing 82.
One end of the piston rod 85 is fixed to the lock pin 81, and the other end of the piston rod 85 is fixed to the tension means 84. In this case, the urging means 83 is preferably a spring member fitted into the piston rod 85.

  With the above configuration, the number of articles constituting the swing lock device 60 can be reduced, so that the structure of the swing lock device 60 can be simplified. Thereby, the swing lock device 60 excellent in operability and manufacturing efficiency can be realized.

The second aspect of the present invention relates to a swing lock device 60 attached to the vehicle 1. The swing lock device 60 of the present invention has a function of stopping the swing of the rear wheel 30 of the vehicle 1.
The vehicle 1 includes a rear suspension 20 that suspends a rear wheel 30. The rear suspension 20 supports each of the rear wheels 30 and a pair of left and right suspension arms 21 that are rotatably attached to the vehicle body and a balancer that is rotatably attached to the vehicle body. The lever 40 and a pair of left and right dampers 35 respectively connected between the left and right ends sandwiching the rotating shaft of the balancer lever 40 and the suspension arm.
In the swing lock device 60 of the present invention, one or a plurality of fitting portions 71 are formed, a stopper 70 fixed to the balancer lever 40, and a lock pin 81 according to a predetermined operation are fitted to the fitting portions 71. A lock pin actuating mechanism 80 which is actuated so as to be fitted and fixed to the vehicle body.

  According to the present invention, in a conventional vehicle (tricycle) in which the rear of the vehicle body swings, the swing of the rear portion of the vehicle body can be stopped during parking while maintaining its running performance. In particular, the present invention can realize swing lock at the rear portion of the vehicle body with good operability and a simple configuration.

FIG. 1 is a side view schematically showing a vehicle according to a position embodiment of the present invention. FIG. 2 is an enlarged plan view showing the periphery of the rear suspension of the vehicle. FIG. 3 is an enlarged rear view of the vehicle, showing a state where the vehicle is upright. FIG. 4 is a rear view in which the rear side of the vehicle is enlarged, and shows a state in which the vehicle is inclined. FIG. 5 is a rear view schematically showing the structure of the swing lock device. FIG. 6 is a rear view showing the stopper attached to the balancer lever. FIG. 7 is a cross-sectional view showing the structure of the swing lock device. FIG. 7 (a) shows a state before the lock pin is activated, and FIG. 7 (b) shows a state where the lock pin is activated. FIG. 8 is a schematic diagram showing the mounting position of the lock pin operating mechanism. FIG. 9 is a schematic diagram showing wiring of wires.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. The present invention is not limited to the embodiments described below, but includes those appropriately modified by those skilled in the art from the following embodiments.

  In the present specification, a case where the vehicle according to the present invention is an electric tricycle will be described as an example. However, the vehicle according to the present invention only needs to have at least a pair of left and right rear wheels, and may be a four-wheeled vehicle or the like. The power source of the vehicle can be, for example, an electric motor, an engine, or a hybrid thereof. The vehicle according to the present invention may be driven by human power.

[1. Tricycle structure]
FIG. 1 is a side view schematically showing the appearance of a tricycle 1 according to the present embodiment.
As shown in FIG. 1, the main skeleton of the vehicle body 2 of the tricycle 1 is composed of left and right side frames 3 extending from the front upper part through the intermediate bottom part to the rear upper part, and a cross frame provided between the left and right side frames 3. (Not shown). A handle shaft 9 is rotatably supported on a head pipe 8 provided at the front end of the vehicle body 2. A front wheel 11 is supported at the lower end of a front fork 10 that extends downward from the handle shaft 9. Further, a steering handle 12 is attached to the upper end of the handle shaft 9. The front fork 10 may include a spring and a shock absorber and constitute a front suspension.

  As shown in FIG. 1, a storage box 4 is formed at the upper rear end of the vehicle body 2, and a seat 5 is disposed on the storage box 4. A battery storage chamber 6 is provided between the left and right side frames 3 at the bottom in the middle of the vehicle body 2 in the front-rear direction. One or a plurality of batteries can be stored in the battery storage chamber 6. The electric power from the battery is supplied to the in-wheel motor 31 attached to the rear wheel 30 via the control device. A rear suspension 20 is connected to the rear portion of the vehicle body 2. Further, a loading platform 50 is coupled to the rear upper end portion of the side frame 3, and the loading platform 50 extends rearward.

  As shown in FIG. 1, the rear suspension 20 includes a pair of left and right suspension arms 21, a pair of left and right spring damper units 35, and a balancer lever 40. The suspension arm 21 is swingably supported at a position behind the battery storage chamber 6 of the vehicle body 2, and a rear wheel 30 is supported at the tip of the suspension arm 21. The spring damper unit 35 includes a spring and a damper, and is connected between the balancer lever 40 and the suspension arm 21 that are rotatably supported on the vehicle body 2 side. A shock absorber may be attached to the damper. The balancer lever 40 is a member that bridges the spring damper unit 35 on the left rear wheel side and the spring damper unit 35 on the right rear wheel side, and is rotatably fixed to the vehicle body 2. The balancer lever 40 serves as a fulcrum for swinging (swing) behind the vehicle body.

Next, details of the rear suspension 20 will be described.
FIG. 2 is an enlarged plan view showing the periphery of the rear suspension 20, and FIG. 3 is a view of the rear suspension 20 as viewed from the back. As shown in FIGS. 2 and 3, the left and right rear suspensions 20 have suspension arms 21 (21L, 21R), respectively. The left and right suspension arms 21 (21L, 21R) are independent from each other and are provided symmetrically. The left and right suspension arms 21 are constituted by a main arm 22 and a sub arm 23, respectively. A rear wheel 30 is supported at the rear end portion of the main arm 22. The sub arm 23 is connected to the main arm 22 and is configured to support the main arm 22 in an auxiliary manner. That is, the sub arm 23 is configured to be coupled obliquely near the middle tip of the main arm 22 and to be coupled to the shaft member 24 while being separated from each other on the base side. Here, a square pipe having a rectangular cross section is used for the main arm 22, and a round pipe having a circular cross section is used for the sub arm 23. The main arm 22 extends vertically from the shaft member 24 on the outer side in the left-right direction, and the sub arm 23 is located on the inner side of the main arm 22.

  As shown in FIGS. 2 and 3, the vehicle body 2 is provided with a bracket mount 13, and both ends of the bracket mount 13 are coupled to the left and right side frames 3. The bracket mount 13 is configured by arranging a pair of hinge brackets 15 (15o, 15i) on the surface facing the rear side of the base plate 14 in the left-right direction. The hinge brackets 15 (15o, 15i) are arranged at intervals corresponding to the length of the shaft member 24 of the suspension arm 21, and each have a pin hole. The left and right outermost hinge brackets 15o extend forward from the base plate 14 and also serve as a coupling member to the side frame 3. The left and right suspension arms 21 are supported on the hinge bracket 15 i of the bracket mount 13 by hinge pins 45 that penetrate the shaft member 24. Each pin hole of the hinge bracket 15 that supports the hinge pin 45 is arranged on a straight line extending horizontally in the left-right direction. As a result, the left and right suspension arms 21L and 21R can swing up and down with respect to the vehicle body 2 independently of each other with a straight line in which pin holes are arranged as a common swing axis S.

  As shown in FIGS. 2 and 3, a hinge bracket 26 for connecting the spring / damper unit 35 (35 </ b> L, 35 </ b> R) is provided on the upper wall in the middle of the main arm 22 constituting the suspension arm 21. The hinge bracket 26 is a U-shaped member having two flanges that are parallel to and opposed to the longitudinal direction of the main arm 22. A lower end portion of a spring / damper unit 35 is connected to the main arm 22 via a hinge bracket 26. Further, a wheel support shaft 25 that extends horizontally outward in the left-right direction is provided at the tip of the suspension arm 21 (main arm 22). A rear wheel 30 (30L, 30R) to which the in-wheel motor 31 is assembled is attached to the wheel support shaft 25. The wheel support shaft 25 has a cylindrical shape, and the cylindrical hole 25a serves as a path for wiring (not shown) for supplying power to the in-wheel motor 31 of the rear wheel 30. Further, a caliper 28 constituting a brake device 29 in combination with a rear-wheel brake disc 32 is attached to the upper wall of the main arm 22 near the wheel support shaft 25.

  In addition, as shown in FIG. 2, subframes 16 protrude from the left and right side frames 3. As shown in FIG. 3, the subframe 16 is positioned at an intermediate height between the rear upper ends of the left and right side frames 3 and the bracket mount 13. The subframe 16 is provided so as to connect the left and right side frames 3, and the rear wall 16 a of the subframe 16 extends along the left-right direction. A support shaft 17 for rotatably supporting the balancer lever 40 is provided at the center in the left-right direction of the rear wall 16a of the subframe 16. The balancer lever 40 has a shaft hole 41 through which the support shaft 17 of the subframe 16 passes in the center. Thereby, the center part of the balancer lever 40 can be fixed to the subframe 16. Further, even after the balancer lever 40 is fixed to the sub-frame 16, the balancer lever 40 can rotate about the support shaft 17 as a rotation shaft. In addition, hinge brackets 42 (42L, 42R) made of two opposing flanges are formed on the left and right ends of the balancer lever 40 so as to extend outward. The flange of the hinge bracket 42 is parallel to the rotation surface of the balancer lever 40 around the support shaft 17.

  As shown in FIGS. 2 and 3, each spring / damper unit 35 includes ball joints 36 (36a, 36b) at both ends thereof. The ball joint 36a at one end is connected to the hinge bracket 42 of the balancer lever 40 by a connecting pin, and the ball joint 36b at the other end is connected to the hinge bracket 26 of the suspension arm 21 by a connecting pin. . The pin holes of the hinge brackets 42L and 42R of the balancer lever 40 (connection points with the ball joints 36a of the spring / damper units 35L and 35R) are set at equal distances from the rotation center (support shaft 17) of the balancer lever 40. Has been.

  The support shaft 17 that supports the balancer lever 40 is set to be substantially perpendicular to the axis of the spring / damper unit 35 when viewed from the side. Further, a screw hole is formed in the distal end surface of the support shaft 17 that supports the balancer lever 40. A loading platform auxiliary stay 52 for supporting the loading platform 50 as an auxiliary can be attached to the screw hole. The loading platform auxiliary stay 52 is configured by connecting the front end of a pipe 53 extending from the rear left and right ends of the loading platform 50 toward the lower center to a bracket 54, and the bracket 54 is attached to the distal end of the support shaft 17 by a bolt. In FIG. 2, the loading platform 50 and the loading platform auxiliary stay 52 are not shown. Further, in FIG. 4, the illustration of the loading platform auxiliary stay 52 is omitted.

  The tricycle 1 configured as described above is in a state as shown in FIG. 3 when the vehicle is traveling straight on a flat road surface. That is, in a state where the vehicle travels straight on a flat road surface, the tricycle 1 has the vehicle body 2 in a vertical posture with respect to the ground, and the wheel support shafts 25 of the left and right suspension arms 21L and 221R are aligned on a horizontal straight line. Accordingly, the left and right rear wheels 30L and 30R are symmetrical with each other with respect to the vertical center line of the vehicle body 2 and are in a state of standing vertically.

  On the other hand, the tricycle 1 is in a state as shown in FIG. 4 when it is traveling on a curve on a flat road surface. That is, when the tricycle 1 reaches the curve and the vehicle body 2 is inclined, the bracket mount 13 supporting the suspension arms 21L and 21R is inclined together with the vehicle body 2. Therefore, as shown in FIG. 5, the rear wheels 30L and 30R supported by the suspension arms 21L and 221R are also inclined in the same direction and the same angle as the vehicle body 2.

  Also, the left and right spring / damper units 35L, 35R that receive the rear wheel load, which is a reaction force from the road surface, are connected to the balancer lever 40, so that either the left or right rear wheel (for example, the left rear wheel 30L) When the rear wheel load increases and is input to the spring damper unit 35L, the load is transmitted to the other spring damper unit 35R via the balancer lever 40. As a result, the rear wheel loads received by the left and right spring / damper units 35L, 35R are equalized. The rear wheel load is equivalent to the spring force of the spring damper unit 35. Therefore, even if the left and right rear wheels 30L and 30R are inclined, the uniform grounding state can be maintained by the uniform spring force. The left and right spring / damper units 35L, 35R, in which the input load is equalized, have the same expansion / contraction amount.

  Further, as shown in FIG. 5, since the left and right rear wheels 30L and 30R are grounded, the angles around the swing axis S of the left and right suspension arms 21L and 21R that support the rear wheels change. As a result, when the vehicle body 2 is tilted to the left, the left suspension arm 21L relatively pivots upward and the right suspension arm 21R pivots downward. On the other hand, when the vehicle body 2 is tilted to the right, the opposite is true. In either case, since the rear wheel loads received by the left and right spring / damper units 35L and 35R are the same, their lengths do not change. Therefore, the balancer lever 40 rotates with respect to the vehicle body 2.

  In the tricycle 1 (vehicle) of the present invention, since the rear wheel side mechanism is configured as described above, the rear wheels 30L and 30R tilt in the same direction as the vehicle body 2 tilts when approaching a curve. Therefore, it is possible to obtain a driving feeling similar to that of a normal motorcycle. Since the left and right spring / damper units 35L and 35R are connected via the balancer lever 40, the spring force is equalized. The grounding state can be maintained.

[2. Structure of swing lock device]
Next, the swing lock device 60 attached to the tricycle 1 (vehicle) having the above-described structure will be described.
As described above, in the tricycle 1 of the present invention, the spring damper unit 35 is attached to the left and right ends of the balancer lever 40, and each spring damper unit 35 is connected to the suspension arm 21 attached to the left and right rear wheels 30. Thus, the rear portion of the vehicle body swings left and right (swings) with the balancer lever 40 as a fulcrum. For this reason, the traveling performance of the tricycle can be improved. However, the tricycle 1 can run smoothly due to the swing of the rear part of the vehicle body, but becomes unstable because the rear part of the vehicle body swings when the vehicle is stopped. In particular, in a state where the driver is away from the tricycle (that is, in a parking state), it is difficult to stabilize the vehicle body without swinging. Therefore, the tricycle 1 of the present invention is provided with the swing lock device 60 at the rear part of the vehicle body, thereby preventing the rear part of the vehicle body from swinging during parking. Thus, the swing lock device 60 is a device for stopping the swinging of the vehicle body and stabilizing the vehicle body when parked.

As shown in FIGS. 3 to 5, the swing lock device 60 is disposed in the vicinity of the balancer lever 40. As shown in each drawing, the swing lock device 60 includes a stopper 70 and a lock pin operating mechanism 80. FIG. 5 is a view of the stopper 70 and the lock pin operating mechanism 80 constituting the swing lock device 60 as viewed from the back side of the tricycle 1. As shown in each drawing, the stopper 70 is formed with a plurality of fitting portions 71. In the illustrated embodiment, the fitting portion 71 of the stopper 70 is formed as a notch. The lock pin operating mechanism 80 has a lock pin 81 having a shape that fits into the fitting portion 71 (notch) of the stopper 70. Then, the lock pin operating mechanism 80 operates the lock pin 81 so that the lock pin 81 is operated to be inserted into the fitting portion 71 of the stopper 70 or the lock pin 81 is released from the fitting portion 71 of the stopper 70. It has a function to let you.
Hereinafter, the stopper 70 and the lock pin operating mechanism 80 constituting the swing lock device 60 will be specifically described.

First, the stopper 70 will be described in detail.
FIG. 6 is a schematic diagram conceptually extracting and showing the periphery of the balancer lever 40 and the stopper 70. As shown in FIG. 6, the stopper 70 is fixed to the balancer lever 40. At this time, the stopper 70 is fixed to the balancer lever 40 in a stationary state. Specifically, in FIG. 6, the rotation axis of the balancer lever 40 is indicated by a symbol A. The rotation axis (A) of the balancer lever 40 is a portion in which the support shaft 17 (see FIGS. 2 and 4) of the subframe 16 is inserted into a shaft hole 41 formed at the center of the balancer lever 40 in the left-right direction. It corresponds to. In FIG. 6, a center line perpendicular to the vertical direction with respect to the rotation axis (A) of the balancer lever 40 is indicated by a symbol C. The center line (C) of the balancer lever 40 is formed at a position that bisects the balancer lever 40 at the center. The stopper 70 has a plurality of fixing portions 72 for the balancer lever 40 on both the left and right sides with the center line (C) of the balancer lever 40 interposed therebetween. As the fixing portion 72, a known fixing member such as a bolt and a nut may be employed. In the example illustrated in FIG. 6, the stopper 70 is fixed to the balancer lever 40 so as not to rotate by four fixing portions 72. Further, the stopper 70 extends from the balancer lever 40 at least from a part in a state where it is fixed to the balancer lever 40. In the example shown in FIG. 6, the lower portion of the stopper 70 extends from the lower end of the balancer lever 40. In this way, by attaching the stopper 70 to the balancer lever 40, if the movement of the stopper 70 is stopped, the movement (rotation) of the balancer lever 40 is stopped in conjunction therewith.

  Further, as shown in FIG. 6, the stopper 70 has a symmetrical shape. At this time, in a state where the stopper 70 is fixed to the balancer lever 40, the center line (symmetric line) of the stopper 70 preferably coincides with the center line (C) of the balancer lever 40.

  The stopper 70 has at least one, preferably a plurality of fitting portions 71 formed therein. In the illustrated example, the fitting portion 71 is a notch formed at the lower edge of the stopper 70. However, the fitting portion 71 may have any form as long as a lock pin 81 described later is fitted therein, and can be formed as a hole or a groove in addition to the notch. Further, when a plurality of fitting portions 71 are formed in the stopper 70, the shapes of the fitting portions 71 do not have to be unified, and the shapes of the fitting portions 71 may be cutouts, holes, or What was arbitrarily selected from the groove | channel etc. can be employ | adopted.

  As shown in FIG. 6, the stopper 70 is provided with a total of five fitting portions 71. The fitting portion 71 includes one center fitting portion 71c, two left fitting portions 71l, and two right fitting portions 71r. As shown in FIG. 6, the center fitting portion 71 is formed on the center line (symmetric line) of the stopper 70. As a result, the center fitting portion 71 is positioned on the center line (C) of the balancer lever 40 in a state where the stopper 70 is fixed to the balancer lever 40. FIG. 6 also shows a left inclined line (L) inclined leftward and a right inclined line (R) inclined rightward with respect to the center line (C) of the balancer lever 40. The left inclined line (L) and the right inclined line (R) are straight lines passing through the rotation axis (A) of the balancer lever 40, respectively. In the embodiment shown in FIG. 6, the angle formed by the left inclined line (L) and the center line (C) and the angle formed by the right inclined line (R) and the center line (C) are set equal. It is preferable that (θ) formed by the left and right inclined lines (L, R) and the center line (C) is, for example, 5 to 45 degrees, or 10 to 30 degrees. In this case, the left fitting portion 71l is located on the left inclined line (L), and the right fitting portion 71r is located on the right inclined line (R). Furthermore, the left fitting portion 71l and the right fitting portion 71r are formed at two locations at the same interval. As described above, it is preferable that the stopper 70 is formed with a plurality of fitting portions 71 at the center position and the left and right side positions.

  Furthermore, as shown in FIG. 6, the stopper 70 is preferably formed in a circular arc shape (fan shape) at the lower edge portion. In the present embodiment, a plurality of notches are formed as fitting portions 71 in the arc-shaped lower edge portion of the stopper 70.

Next, the lock pin operating mechanism 80 will be described in detail.
FIG. 7 schematically shows the cross-sectional shapes of the lock pin operating mechanism 80 and the stopper 70. FIG. 7A shows a state before the lock pin 81 is fitted to the fitting portion 71 of the stopper 70, and FIG. 7B shows the state where the lock pin 81 is actuated to the fitting portion 71 of the stopper 70. The state is shown by fitting. However, the embodiment shown in FIG. 7 is an example.

  As shown in FIG. 7, the lock pin operating mechanism 80 includes a lock pin 81. Further, the shape of the lock pin 81 viewed from the front is shown in FIG. As shown in FIG. 5, the lock pin 81 includes a relatively wide base portion 81a and a relatively narrow pin portion 81b protruding upward from the base portion 81a. Of the lock pin 81, the pin portion 81 b is designed to be fitted into the fitting portion 71 (notch) of the stopper 70.

  The lock pin actuating mechanism 80 moves the lock pin 81 forward and backward so that the lock pin 81 is fitted in the fitting portion 71 of the stopper 70 and the lock pin 81 is fitted in the fitting portion 71 of the stopper 70. It has a configuration that can switch the release state that is not. In this embodiment, the lock pin operating mechanism 80 includes a housing 82, an urging means 83, and a tension means 84 in addition to the lock pin 81 as shown in FIG. 7. The housing 82 is a member that is fixed to the vehicle body 2 (specifically, the subframe 16) of the tricycle 1 in a stationary state. The biasing means 83 is disposed between the housing 82 and the lock pin 81 and biases the lock pin 81 in a direction away from the housing 82. An example of the urging means 83 is a spring member (spring). The pulling means 84 pulls the lock pin 81 in a direction approaching the housing 82 against the urging force of the urging means 83 according to a predetermined operation. An example of the pulling means 84 is a wire. For example, the pulling means 84 is configured to pull the lock pin 81 via a wire in conjunction with a driver pulling a lever provided around the handle at hand. As shown in FIG. 7, the fitting portion 71 of the stopper 70 is designed to be positioned between the housing 82 and the lock pin 81.

  According to such a structure, in a normal state where the lock pin 81 is not pulled by the pulling means 84, the lock pin 81 is urged away from the housing 82 by the urging means 83. The pin 81 does not fit into the fitting portion 71 of the stopper 70. For this reason, the balancer lever 40 to which the stopper 70 is fixed can freely rotate. Accordingly, the rear portion of the vehicle 2 is swingable with the balancer lever 40 as a fulcrum. On the other hand, when the lock pin 81 is pulled by the pulling means 84, the lock pin 81 is pulled in a direction approaching the housing 82, so that the lock pin 81 is fitted into the fitting portion 71 of the stopper 70. Then, the balancer lever 40 to which the stopper 70 is fixed cannot be freely rotated. Accordingly, the position of the balancer lever 40 is fixed, and the swinging of the rear portion of the vehicle 2 is stopped. Thereby, the rocking | swiveling (swing) of a vehicle body rear part can be locked.

  More specifically, as shown in FIGS. 5 and 6, the housing 82 is formed with a fixed portion 82 a that protrudes upward. A fixed portion 82 a of the housing 82 is fixed to the subframe 16 provided on the vehicle body 2 of the tricycle 1. A more detailed view of the mounting position of the housing 82 is shown in FIG. FIG. 8 schematically shows a positional relationship in which the fixing portion 82a of the housing 82 is attached to the subframe 16. As shown in FIG. 8, the fixed portion 82 a of the housing 82 can be fixed to the subframe 16 provided on the vehicle body 2 of the tricycle 1. In this way, the lock pin operating mechanism 80 is fixed at a position different from the stopper 70. That is, the lock pin operating mechanism 80 is a mechanism for fixing the stopper 70 via the lock pin 81 and thereby stopping the rotation of the balancer lever 40. For this reason, while the stopper 70 is fixed to the balancer lever 40, the lock pin operating mechanism 80 is fixed to any position of the vehicle body 2 different from the balancer lever 40. For example, in the illustrated example, the lock pin operating mechanism 80 is fixed to the subframe 16. However, the lock pin operating mechanism 80 can be attached to an appropriate position of the other vehicle body 2. For example, the lock pin operating mechanism 80 may be fixed to the rear portion of the side frame 3 or may be fixed to the bracket mount 13. In other words, the lock pin operating mechanism 80 may be fixed anywhere as long as it is a portion other than the balancer lever 40 and does not swing together with the balancer lever 40.

  As shown in FIG. 7, the housing 82 has a through hole 82b, and a piston rod 85 is inserted into the through hole 82b. The piston rod 85 is inserted through the through hole 82 of the housing 82, and both front and rear ends protrude from the housing 82. One end of the piston rod 85 is fixed to the base portion 81 a of the lock pin 81. The other end of the piston rod 85 is fixed to the pulling means 84. A bolt or the like may be used for fixing the piston rod 85 and the lock pin 81 and fixing the piston rod 85 and the pulling means 84.

  The housing 82 has a flange 82c formed around a piston rod 85 disposed in the through hole 82b. Further, a spring member constituting the biasing means 83 is fitted into the piston rod 85. That is, the piston rod 85 is accommodated in the through hole 82 b of the housing 82 in a state where the piston rod 85 is inserted into the center hole of the spring member 83. At this time, one end of the spring member 83 abuts against a flange formed on the housing 82 against the 82c, and the arrangement thereof is fixed. As a result, the spring member 83 is housed in the through hole 82b of the housing 82 while being fitted to the piston rod 85, and is interposed between the flange 82c and the lock pin 81. As a result, the spring member 83 biases the lock pin 81 in a direction away from the housing 82.

  On the other hand, a tension means 84 is fixed to the other end side of the piston rod 85. As shown in FIG. 7, the pulling means 84 includes, for example, a link 84a, a wire 84b, and a bridge 84c. One end of the link 84a is fixed to the piston rod 85, and the other end is connected to the wire 84b. The wire 84b connects the lock lever at the driver's hand and the link 84a. For this reason, when the driver performs an operation of pulling the wire 84b via the lock lever, the wire 84b transmits this tensile force to the link 84a and pulls the piston rod 85 via the link 84a. As described above, the tensile force is applied to the wire 84b, whereby the piston rod 85 is pulled. As a result, the wire 84b is pulled in a direction approaching the lock pin 81 housing 82 against the urging force of the spring member 83. One end of the bridge 84c is fixed to the housing 82, and the other end of the bridge 84c supports the link 84a so that the link 84a advances and retreats linearly. By supporting the link 84a by the bridge 84c in this way, the link 84a linearly advances and retracts when the link 84a is pulled by the wire 84b, so that a linear tensile force can be correctly transmitted to the piston rod 85. it can.

  In the above-described example, the pulling means 84 pulls the piston rod 85 by a wire type (mechanical type). For example, the pulling means 84 may be a hydraulic type (hydraulic type) or a pneumatic type that pulls the piston rod 85. It may be a pulling system.

  Further, as shown in FIGS. 5 and 7, the lock pin operating mechanism 80 has a pair of left and right pressing members 86 attached to the housing 82. The pair of pressing members 86 are attached to the housing 82 at positions adjacent to both sides of the pin portion 81a when the pin portion 81b of the lock pin 81 contacts the housing 82. Therefore, the pin portion 81b of the lock pin 81 is fitted between the pair of pressing members 86 provided on the housing 82 at the same time as the fitting portion 71 of the stopper 70 is fitted. Thereby, the rotation of the pin portion 81 b of the lock pin 81 is prevented by both the stopper 70 and the pressing member 86. Thus, by providing the pressing member 86 in the housing 82, the lock pin 81 operates stably, and the locked state of the stopper 70 fixed by the lock pin 81 is also stabilized.

  In addition, as shown in FIG. 7, the lock pin operating mechanism 80 may include an auxiliary piston rod 87. One end of the auxiliary piston rod 87 is fixed to the base portion 81a of the lock pin 81 via a bolt or the like. In addition, a slide hole 82d is formed in the housing 82, and the other end side of the auxiliary piston rod 87 is inserted into the slide hole 82d. For this reason, the lock pin 81 moves forward and backward with respect to the housing 82 along the piston rod 85 and the auxiliary piston rod 87. In this way, by connecting the two or more rods 85 and 87 to the lock pin 81 and moving them forward and backward, the lock pin 81 does not rotate but only performs a linear operation. That is, when the lock pin 81 is pulled through the pulling means 84 (wire 84b), the lock pin 81 is pulled straight.

  The lock pin operating mechanism 80 having the above structure is fixed to the subframe 16 of the vehicle body 2 of the tricycle 1 as shown in FIGS. 3 and 4. The state in which the lock pin operating mechanism 80 is fixed to the subframe 16 is also shown in FIG. As shown in FIG. 3, when the vehicle body 2 is in an upright state, the lock pin 81 is operated by the lock pin operating mechanism 80, and the lock pin 81 is fixed to the balancer lever 40. It is made to fit in the fitting part 71. In particular, when the vehicle body 2 is upright, the lock pin 81 is fitted to the center fitting portion 71 c of the stopper 70. As a result, the balancer lever 40 cannot rotate, the position is fixed, and the swinging stops. As a result, the left and right spring / damper units 35 connected to both ends of the balancer lever 40 and the suspension arm 21 connected to each spring / damper unit 35 are sequentially immobilized. As a result, the left and right rear wheels 30 are fixed in an upright state and do not tilt. Accordingly, the left and right rear wheels 30 can be kept upright and can be parked and stopped safely.

  Further, as shown in FIG. 4, the lock pin 81 can be operated by the lock pin operating mechanism 80 even when the vehicle body 2 is tilted. Thus, when the vehicle body 2 is tilted, the lock pin 81 is fitted to the left fitting portion 71l or the right fitting portion 71r, not the center fitting portion 71c of the stopper 70. As a result, the vehicle body 2 is held in a tilted state. For example, in a situation where it is difficult to erect the vehicle body 2 such as when the terrain where the tricycle 1 is parked is distorted or on a slope, the vehicle body 2 is held in a tilted state as described above. It is effective to stabilize. In this way, by forming the plurality of fitting portions 71 in the stopper 70, a state suitable for parking the tricycle 1 can be arbitrarily selected according to the situation of parking the tricycle 1 and geographical characteristics. It becomes like this.

  Subsequently, FIG. 9 schematically shows the relationship between the lock lever 12a provided on the operation handle 12 at the driver's hand, the swing lock device 60, and the brake device 29 provided on the rear wheel. . The side view of FIG. 1 also shows the relevance of the lock lever 12a, the swing lock device 60, and the brake device 29. As shown in FIGS. 1 and 9, the main wire 91 extends from the lock lever 12 a toward the relay box 90. The main wire 91 is connected to two wires in the relay box 90, that is, a wire 84 b extending to the swing lock device 60 and a brake wire 92 extending to the brake device 29. Accordingly, by pulling the main wire 91 via the lock lever 12a, the wire 84b extending to the swing lock device 60 and the brake wire 92 extending to the brake device 29 are simultaneously pulled.

  The wire 84b extending to the swing lock device 60 is connected to the lock pin operating mechanism 80 as described above. When the wire 84b is pulled, the lock pin 81 is actuated and fitted into the fitting portion 71 of the stopper 70, so that the swinging of the rear portion of the vehicle body is stopped. On the other hand, the brake wire 92 extending to the brake device 29 is connected to a caliper 28 that sandwiches the brake disk 32 of the rear wheel 30 and stops the rotation. For this reason, when the brake wire 92 is pulled, the caliper 28 is operated to sandwich the brake disc 32, so that the rear wheel 30 does not rotate. Thus, the swing lock device 60 and the brake device are connected by connecting the wire 84b connected to the swing lock device 60 and the brake wire 92 connected to the brake device 29 to the main wire 91 extending from the lock lever 12a. 29 can be operated in conjunction with each other. As a result, the driver can perform both the swing lock and the brake only by operating the lock lever 12a. Therefore, the operability when parking and stopping is improved.

  As mentioned above, in this specification, in order to express the content of this invention, embodiment of this invention was described, referring drawings. However, the present invention is not limited to the above-described embodiments, but includes modifications and improvements obvious to those skilled in the art based on the matters described in the present specification.

  The present invention relates to a vehicle with a swing lock device, and more particularly to a tricycle. Therefore, the present invention can be suitably used in the manufacturing industry of tricycles.

DESCRIPTION OF SYMBOLS 1 ... Tricycle 2 ... Car body 3 ... Side frame 4 ... Storage box 5 ... Seat 6 ... Battery storage chamber 8 ... Head pipe 9 ... Handle shaft 10 ... Front fork 11 ... Front wheel 12 ... Steering handle 12a ... Lock lever 13 ... Bracket mount DESCRIPTION OF SYMBOLS 14 ... Base plate 15 ... Hinge bracket 16 ... Sub-frame 16a ... Rear wall 17 ... Support shaft 18 ... Screw hole 20 ... Rear suspension 21 ... Suspension arm 22 ... Main arm 23 ... Sub arm 24 ... Shaft member 25 ... Wheel support shaft 25a ... Cylinder hole 26 ... Hinge bracket 28 ... Caliper 29 ... Brake device 30 ... Rear wheel 31 ... In-wheel motor 32 ... Brake disk 35 ... Damper 36 ... Ball joint 40 ... Balancer lever 41 ... Shaft hole 42 ... Hinge bracket 45 ... Hinge pin 50 ... loading platform 52 ... loading platform Auxiliary stay 53 ... pipe 54 ... bracket 55 ... bolt 60 ... swing lock device 70 ... stopper 71 ... fitting portion 71c ... center fitting portion 71l ... left fitting portion 71r ... right fitting portion 72 ... fixing portion 80 ... lock pin Actuating mechanism 81 ... Lock pin 81a ... Basic part 1b ... Pin part 82 ... Housing 82a ... Fixed part 82b ... Through hole 82c ... Flange 82d ... Slide hole 83 ... Biasing means (spring member)
84 ... Tensioning means 84a ... Link 84b ... Wire 84c ... Bridge 85 ... Piston rod 86 ... Pressing member 87 ... Auxiliary piston rod 90 ... Relay box 91 ... Main wire 92 ... Brake wire S ... Oscillating axis A ... Rotating shaft C ... Center Line L ... Left slope line R ... Right slope line

Claims (5)

A vehicle (1) comprising at least a pair of left and right rear wheels (30),
A rear suspension (20) for suspending the rear wheel (30);
A swing lock device (60) for stopping the swinging of the rear wheel (30),
The rear suspension (20)
A pair of left and right suspension arms (21) supporting each of the rear wheels (30) and rotatably attached to the vehicle body of the vehicle independently of each other;
A balancer lever (40) rotatably attached to the vehicle body;
A pair of left and right dampers (35) respectively connected between the left and right ends sandwiching the rotation axis (A) of the balancer lever (40) and the suspension arm (21);
The swing lock device (60)
A stopper (70) fixed to the balancer lever (40) and having one or more fitting portions (71) formed thereon;
A lock pin actuating mechanism (80) fixed to the vehicle body and actuating so as to fit the lock pin (81) into the fitting portion (71) according to a predetermined operation;
The lock pin operating mechanism (80)
The lock pin (81) configured to include a base portion (81a) and a pin portion (81b) protruding from the base portion (81a);
A piston rod (85) having one end side fixed to the base portion (81a) of the lock pin (81);
A housing (82) fixed to the vehicle body, having a through hole (82b), and having the piston rod (85) inserted through the through hole (82b);
Biasing means (83) for biasing the lock pin (81) in a direction away from the housing (82);
Tensioning means (84) fixed to the other end of the piston rod (85) and pulling the lock pin (81) in a direction approaching the housing (82) by pulling the piston rod (85) And
The stopper (70) is located between the lock pin (81) and the housing (82),
By pulling the piston rod (85) by the pulling means (84), the lock pin (81) is pulled in a direction approaching the housing (82), and the fitting portion (71) of the stopper (70) is pulled. ), The pin portion (81b) contacts the housing (82) when the pin portion (81b) of the lock pin (81) is fitted. The stopper (70) is fixed to the balancer lever (40) at left and right side portions sandwiching a center line (C) perpendicular to the vertical direction with respect to the rotation axis (A) of the balancer lever (40). 72) The vehicle according to claim 1. In the fitting portion (71) of the stopper (70),
A center fitting portion (71c) provided on the center line (C);
A left fitting portion (71l) and a right fitting portion (71r) provided on left and right inclined lines (L, R) inclined in the left-right direction at a predetermined angle with respect to the center line (C). The vehicle according to claim 2. The vehicle according to any one of claims 1 to 3, wherein each of the plurality of fitting portions (71) is one of a notch, a hole, and a groove formed in the stopper (70). A swing lock device (60) attached to a vehicle (1) having at least a pair of left and right rear wheels (30) and stopping swinging of the rear wheels (30),
The vehicle (1)
A rear suspension (20) for suspending the rear wheel (30);
The rear suspension (20)
A pair of left and right suspension arms (21) supporting each of the rear wheels (30) and rotatably attached to the vehicle body of the vehicle independently of each other;
A balancer lever (40) rotatably attached to the vehicle body;
A pair of left and right dampers (35) respectively connected between the left and right ends sandwiching the rotation axis (A) of the balancer lever (40) and the suspension arm (21);
The swing lock device (60)
One or a plurality of fitting portions (71) are formed, and a stopper (70) fixed to the balancer lever (40);
A lock pin operating mechanism (80) for operating the lock pin (81) so as to be fitted into the fitting portion (71) in accordance with a predetermined operation; ,
The lock pin operating mechanism (80)
The lock pin (81) configured to include a base portion (81a) and a pin portion (81b) protruding from the base portion (81a);
A piston rod (85) having one end side fixed to the base portion (81a) of the lock pin (81);
A housing (82) fixed to the vehicle body, having a through hole (82b), and having the piston rod (85) inserted through the through hole (82b);
Biasing means (83) for biasing the lock pin (81) in a direction away from the housing (82);
Tensioning means (84) fixed to the other end of the piston rod (85) and pulling the lock pin (81) in a direction approaching the housing (82) by pulling the piston rod (85) And
The stopper (70) is located between the lock pin (81) and the housing (82),
By pulling the piston rod (85) by the pulling means (84), the lock pin (81) is pulled in a direction approaching the housing (82), and the fitting portion (71) of the stopper (70) is pulled. ), The pin portion (81b) contacts the housing (82) when the pin portion (81b) of the lock pin (81) is fitted.

Images