JP2020073369A - Mounting structure of inertia sensor - Google Patents

Abstract

To achieve sufficient suppression of vibration propagation to an inertia sensor in a simple configuration.SOLUTION: An inertia sensor (70) includes a floating bracket (51) for supporting the inertia sensor through a vibration absorbing material (61) absorbing the vibration propagated from a vehicle body frame (1). The inertia sensor is structured to be mounted on the floating bracket together with another component (20) making it difficult to vibrate the floating bracket by lowering a characteristic frequency through an increased weight supported by the floating bracket. By suppressing vibration of the floating bracket, countermeasure against vibration can be taken effectively for the inertia sensor supported by the floating bracket.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a mounting structure for an inertial sensor used for ABS control.

  Generally, a motorcycle is equipped with an ABS (Antilock Brake System) unit to prevent the wheels from being locked during sudden braking. Detection signals and the like from a wheel speed sensor that detects a wheel speed and an inertial sensor that detects acceleration and angular velocity are input to the ABS unit, and the brake pressures for the front and rear wheels are controlled based on the detection signals (for example, Patent Document 1). 1). This type of inertial sensor has severe vibration conditions, and as a measure against vibration, the bracket of the inertial sensor is floatingly supported on the vehicle body frame via a vibration absorbing material. Vibrations from the body frame are absorbed by the vibration absorbing material, and the vibrations transmitted to the inertial sensor are suppressed.

JP, 2009-292350, A

  However, there are some vehicles that do not satisfy the vibration condition of the inertial sensor only by the floating support using the vibration absorbing material as described above. In this case, it is necessary to reconsider the layout of the inertial sensor so that the inertial sensor is attached to a portion where vibration is difficult to be transmitted from the body frame. Therefore, the layout of the inertial sensor may be limited.

  The present invention has been made in view of the above points, and an object of the present invention is to provide an inertial sensor mounting structure capable of sufficiently suppressing vibration propagation to the inertial sensor with a simple configuration.

  The mounting structure for an inertial sensor according to the present invention includes a floating bracket that supports the inertial sensor via a vibration absorber that absorbs vibrations transmitted from the vehicle body frame, and the inertial sensor increases the weight supported by the floating bracket. It is characterized by being attached to the floating bracket along with other parts that lower the natural frequency and make it difficult for the floating bracket to vibrate.

  According to the inertia sensor mounting structure of the present invention, by mounting the inertia sensor and the other parts such as the ABS unit to the floating bracket, it is possible to effectively prevent vibration from occurring in the inertia sensor, and the saddle riding The degree of freedom in the layout of the inertial sensor in the model vehicle can be improved.

FIG. 3 is a perspective view of a vehicle body frame according to the present embodiment. It is a system image diagram of the ABS according to the present embodiment. It is a perspective view of the attachment structure of the ABS unit which concerns on this Embodiment. It is a cross-sectional schematic diagram of the attachment structure of the ABS unit which concerns on this Embodiment. It is a perspective view of the attachment structure of the inertial sensor which concerns on this Embodiment. It is a cross-sectional schematic diagram of the attachment structure of the inertial sensor which concerns on this Embodiment.

  Hereinafter, the present embodiment will be described in detail with reference to the accompanying drawings. In the following, the mounting structure of the inertial sensor according to the present invention will be described as an example applied to a motorcycle, but the invention is not limited to a motorcycle, and may be applied to a straddle-type vehicle such as a motorcycle. You can FIG. 1 is a perspective view of a vehicle body frame according to the present embodiment. FIG. 2 is a system image diagram of the ABS according to the present embodiment.

  As shown in FIG. 1, a vehicle body frame 1 is configured by attaching a seat rail 18 and a sub frame 19 to a twin-spar frame 10 made of steel or aluminum alloy on which various parts such as an electric component system are mounted. In the twin spar frame 10, a pair of tank rails 12 branch left and right from a head frame 11 located at the front end and extend rearward, and a pair of body frames 13 extend downward from the rear end of each tank rail 12. Existence A housing space for an engine (not shown) or the like is formed by the head frame 11, the tank rail 12, and the body frame 13, and the body frame 1 is reinforced by suspending the engine on these.

  The pair of body frames 13 are connected by an upper bridge 14 on the upper side and are connected by a lower bridge 15 on the lower side. A swing arm pivot 16 is formed on each of the pair of body frames 13, and a swing arm 17 supporting a rear wheel (not shown) is connected to the swing arm pivot 16 so as to be vertically swingable. An upper portion of a rear cushion unit (not shown) for suspending rear wheels is connected to the upper bridge 14, and a lower portion of the rear cushion unit is connected to the lower bridge 15 and the swing arm 17 via a link mechanism.

  A pair of seat rails 18 extending rearward and upward are connected to upper portions of the pair of body frames 13. The pair of seat rails 18 are auxiliary supported by a pair of sub-frames 19 that connect the middle portion of each body frame 13 in the height direction and the rear end portion of each seat rail 18. An ABS unit 20 is accommodated in a front space surrounded by the pair of seat rails 18 and the pair of subframes 19. The ABS unit 20 is arranged in the accommodation space, and is further arranged in the front-rear direction of the vehicle, behind the rear cushion unit and in front of the front end of the rear wheel. Each sub-frame 19 is provided with a pair of frame brackets 50 so as to project inside the vehicle body. The ABS unit 20 is attached to the surface (upper surface) of a floating bracket 51, which is a plate-like member installed so as to connect the pair of frame brackets 50 to each other. A pair of or one of the frame brackets 50 may be provided on the seat rail 18 so as to project to the inside of the vehicle body.

  As shown in FIG. 2, the ABS unit 20 detects the wheel speed by the wheel speed sensors 32 and 42 attached to the front wheels 31 and the rear wheels 41 and automatically controls the brake to prevent the wheels from being locked. ing. The ABS unit 20 has a control unit 21 and a hydraulic unit (HU: Hydraulic Unit) 22 integrated therein. The hydraulic circuit of the hydraulic unit 22 is divided into a front system and a rear system, and the front and rear wheels have different systems. Each system includes inlet solenoid valves 23a and 23b, outlet solenoid valves 24a and 24b, one-way valves 25a and 25b, reservoirs 26a and 26b, and pumps 27a and 27b.

  In the front system, hydraulic pressure from the master cylinder 34 of the front brake lever 33 is applied to the front brake caliper 35 through the inlet solenoid valve 23a. When a sudden decrease in the rotation of the front wheel 31 is detected, the hydraulic pressure from the master cylinder 34 is shut off by the inlet solenoid valve 23a, the outlet solenoid valve 24a is opened, and the brake fluid is drained from the front brake caliper 35 to the reservoir 26a. Then, reduce the hydraulic pressure. The hydraulic pressure temporarily stored in the reservoir 26a is sucked by the pump 27a and returned to the master cylinder 34 side. Also in the rear system, the hydraulic pressure from the master cylinder 44 of the rear brake pedal 43 is controlled as in the front system.

  The control unit 21 is composed of an input side interface, an output side interface, a processor, a memory and the like. The memory is configured by one or a plurality of storage media such as a ROM (Read Only Memory) and a RAM (Random Access Memory) according to the application. Various programs for ABS control and various parameters are stored in the memory. A brake light switch, wheel speed sensors 32 and 42, an inertial sensor 70, etc. are connected to the input side interface. Solenoid valves 23a, 23b, 24a, 24b, an indicator lamp 49, a motor 29, etc. are connected to the output side interface.

  The ABS unit 20 controls the solenoid valves 23a, 23b, 24a, 24b and the motor 29 based on the wheel speeds of the front and rear wheels 31, 41 detected by the wheel speed sensors 32, 42, the accelerations and angular velocities detected by the inertial sensor 70, and the like. Control. That is, when the wheel speed of the front and rear wheels 31, 41 decreases with respect to the vehicle speed, the ABS unit 20 controls the maintenance and reduction of the brake pressure to prevent the wheels from locking. On the other hand, when the wheel speeds of the front and rear wheels 31, 41 approach the vehicle speed, the brake pressure is controlled to be increased. By repeating this control, it is possible to appropriately decelerate the front and rear wheels 31, 41 without locking them on a slippery road surface or the like.

  By the way, as a measure against vibration of the ABS unit 20, a floating bracket 51 to which the ABS unit 20 is attached is floatingly supported by a pair of frame brackets 50 via a rubber bush 61 (see FIG. 3). Further, since the inertial sensor 70 used in the ABS unit 20 is subject to severe vibration conditions, it is preferable that the inertial sensor 70 also be supported in a floating manner with respect to the vehicle body frame 1. However, the vibrations propagated from the vehicle body frame 1 to the inertial sensor 70 cannot be sufficiently reduced only by the floating support, and the vibration condition of the inertial sensor 70 may not be satisfied in some cases. Further, in order to attach the inertial sensor 70 to the vehicle body frame 1, a bracket must be prepared separately.

  Therefore, in the present embodiment, the inertia sensor 70 is attached to the floating bracket 51 used in the ABS unit 20 to share the bracket, and the weight supported by the floating bracket 51 is increased to lower the natural frequency. The floating bracket 51 is made difficult to vibrate. As a result, it is possible not only to take measures against vibration for the ABS unit 20, but also to take effective measures against vibration for the inertial sensor 70. In addition, since the ABS unit 20 and the inertia sensor 70 also serve as brackets, the individual brackets are not required, and it is possible to reduce the number of parts, reduce the weight, and reduce the cost.

  Hereinafter, the attachment structure of the ABS unit and the inertial sensor will be described with reference to FIGS. 3 to 6. FIG. 3 is a perspective view of the ABS unit mounting structure according to the present embodiment. FIG. 4 is a schematic sectional view of the ABS unit mounting structure according to the present embodiment. FIG. 5 is a perspective view of the inertia sensor mounting structure according to the present embodiment. FIG. 6 is a schematic cross-sectional view of the attachment structure for the inertial sensor according to the present embodiment.

  As shown in FIGS. 3 and 4, the pair of frame brackets 50 of the vehicle body frame 1 fixed to the vehicle body frame 1 by welding or the like so as to project inward of the vehicle are provided with a plurality of rubber bushes 61. The floating bracket 51 is fixed by a plurality of bolts 62. In detail, the end portion of the floating bracket 51 and the rubber bush 61 attached to the end portion are arranged and attached on the upper side of the frame bracket 50. A through hole 54 into which a tubular rubber bush 61 is mounted is formed at the left and right ends of the floating bracket 51, and a recess 55 is formed on the back surface 53 side of the floating bracket 51 so as to be continuous with the through hole 54. .. When the rubber bush 61 is mounted in the through hole 54, the upper half of the rubber bush 61 projects from the surface 52 of the floating bracket 51, and the lower half of the rubber bush 61 projects into the recess 55. At this time, the lower half portion of the rubber bush 61 protrudes below the back surface 53 of the floating bracket 51.

  A cylindrical collar 63 is attached to the inner peripheral surface of the rubber bush 61, and a male screw of a bolt 62 is inserted inside the collar 63 and fixed to a female screw of the frame bracket 50. Since the lower half portion of the rubber bush 61 projects below the back surface 53, a gap is formed between the floating bracket 51 and the frame bracket 50. Since the upper half of the rubber bush 61 projects above the surface 52, the head of the bolt 62 does not come into direct contact with the floating bracket 51. In this way, the floating bracket 51 is floatingly supported by the frame bracket 50 via the rubber bush 61.

  As shown in FIG. 5 and FIG. 6, the front surface 52 (upper surface) of the floating bracket 51 is a second mounting surface on which the ABS unit 20 is mounted, and a plurality of the mounting surfaces inserted from the rear surface 53 side of the floating bracket 51. The ABS unit 20 is fixed by the bolts 64. The back surface 53 (lower surface) of the floating bracket 51 is a first mounting surface to which the inertial sensor 70 is mounted, and a part 56 of the floating bracket 51 partially extends rearward to enlarge the mounting surface. The installation surface of the sensor 70 is secured. The inertial sensor 70 has a pair of arms 71 extending forward and backward from the sensor body 72, and is floated by the pair of arms 71 so that the sensor body 72 does not directly contact the back surface 53 of the floating bracket 51. Further, the inertial sensor 70 is offset to the right with respect to the width center of the vehicle body on the opposite side with respect to the rear cushion unit which is offset to the left side with respect to the vehicle body width center. It is routed from 70 to the right.

  A rubber sheet 73 is interposed between the back surface 53 of the floating bracket 51 and the inertial sensor 70 as another vibration absorbing material. The inertial sensor 70 is fixed to the back surface 53 of the floating bracket 51 by a bolt 65 inserted through a pair of arm portions 71 extending in the front-rear direction of the vehicle with the rubber sheet 73 sandwiched between the inertial sensor 70 and the floating bracket 51. Thus, the rubber bush 61 is interposed between the frame bracket 50 and the floating bracket 51, and the rubber sheet 73 is interposed between the floating bracket 51 and the inertia sensor 70. Therefore, the inertial sensor 70 is doubly supported by the rubber bush 61 and the rubber sheet 73 in a double manner with respect to the vehicle body frame 1.

  Further, the inertial sensor 70 outputs the detection result to the ABS unit 20 via a harness (not shown) connected to the coupler 74. Since the inertial sensor 70 is positioned on the back side of the ABS unit 20 with the floating bracket 51 interposed therebetween, the length of the harness connecting the coupler 74 and the ABS unit 20 is shortened. Since the floating bracket 51 is shared by the ABS unit 20 and the inertial sensor 70, it is not necessary to separately prepare a bracket for the ABS unit 20 and the inertial sensor 70. Specifically, the coupler 74 of the inertial sensor 70 is arranged in a direction in which the coupler 74 is connected by being inserted from the side of the vehicle as shown in FIGS. 3 and 5. Then, the harness connected to the inertial sensor 70 is routed below the rubber bush 61 and below the frame bracket 50. As a result, the harness can be installed at a position where the relative movement of the floating bracket 51 due to the vibration is small.

  Thus, the inertial sensor 70 is attached to the floating bracket 51 in addition to the ABS unit 20. Since both the ABS unit 20 and the inertial sensor 70 are fixed to the vehicle body frame 1 with the rubber bush 61 interposed, vibrations from the vehicle body frame 1 can be absorbed by the rubber bush 61. In addition, since the ABS unit 20 and the inertial sensor 70 are attached to the floating bracket 51 to increase the weight, the floating bracket 51 becomes difficult to vibrate, and the vibration propagated from the vehicle body frame 1 to the ABS unit 20 and the inertial sensor 70 is increased. Can be effectively suppressed.

  The ABS unit 20 is attached to the front surface 52 of the floating bracket 51, and the inertial sensor 70 is attached to the back surface 53 of the floating bracket 51. Since the ABS unit 20 and the inertial sensor 70 are arranged so as to vertically overlap with each other, the center of gravity O2 of the inertial sensor 70 is brought closer to the center of gravity O1 of the ABS unit 20, thereby more effectively vibrating the ABS unit 20 and the inertial sensor 70. Can be suppressed. Further, a female screw may be formed on the ABS unit 20, and the inertia sensor 70 may be fixed by screwing a bolt into the female screw. As a result, the number of parts can be further reduced and the cost can be reduced.

  The ABS unit 20 is fixed so as to be in contact with the front surface 52 of the floating bracket 51, and the inertia sensor 70 has a rubber sheet 73 interposed between the inertia sensor 70 and the back surface 53 of the floating bracket 51. Since the ABS unit 20 itself also vibrates at the time of driving, by interposing the rubber sheet 73 on the back surface 53 of the floating bracket 51, the vibration at the time of driving the ABS unit 20 is absorbed by the rubber sheet 73 so that the ABS unit 20 can be absorbed. The vibration propagating from the inertial sensor 70 to the inertial sensor 70 can be suppressed. Further, as described above, since the inertial sensor 70 is doubly supported by the rubber bush 61 and the rubber sheet 73 with respect to the vehicle body frame 1, vibration propagation from the vehicle body frame 1 to the inertial sensor 70 is suppressed more effectively. be able to.

  Since the floating bracket 51 suppresses the vibration of the ABS unit 20, the ABS unit 20 can be arranged at a position where the vibration condition is severe. On the other hand, also with respect to the inertial sensor 70, the vibration is suppressed by the floating bracket 51 as in the ABS unit 20, and it is possible to dispose the inertial sensor 70 at a position with severe vibration conditions. However, considering the detection accuracy of the inertial sensor 70, The floating bracket 51 is preferably arranged near the center of the vehicle body frame 1 (see FIG. 1). Therefore, in the present embodiment, the floating bracket 51 is arranged behind the rear cushion unit (not shown) with the ABS unit 20 and the inertial sensor 70 attached.

  By fixing the floating bracket 51 near the center of the vehicle body frame 1, the inertial sensor 70 is arranged near the center of gravity of the vehicle body, and the detection accuracy of the inertial sensor 70 can be improved. Further, the floating bracket 51 is arranged on a center line that passes through the width center of the vehicle body and extends in the vehicle front-rear direction. Therefore, since the ABS unit 20 and the inertial sensor 70 are positioned on the center line, the weight balance of the vehicle body is evenly approached in the width direction, and the steering stability is improved. Since the ABS unit 20 and the inertial sensor 70 are unitized by the floating bracket 51, the attachment work becomes easier than the case where the ABS unit 20 and the inertial sensor 70 are individually attached to the body frame 1.

  As described above, according to the present embodiment, the floating bracket 51 is floatingly supported by the vehicle body frame 1 via the rubber bush 61, and the vibration from the vehicle body frame 1 is absorbed by the rubber bush 61. In addition, since the inertial sensor 70 and the ABS unit 20 are attached to the floating bracket 51, the weight of the entire body supported by the floating bracket 51 is increased and vibration is less likely to occur. Therefore, the vibration from the body frame 1 is less likely to be transmitted to the inertial sensor 70, and the inertial sensor 70 can effectively take measures against vibration. Further, the layout of the inertial sensor 70 is not restricted by the measures against vibration, and the degree of freedom of layout can be improved. Further, since the inertial sensor 70 and the ABS unit 20 also serve as the floating brackets 51, the individual brackets are not required, and the number of parts can be reduced, and the weight and cost can be reduced.

  The present invention is not limited to the above-mentioned embodiment, but can be implemented with various modifications. In the above embodiment, the size and shape shown in the accompanying drawings are not limited to this, and can be appropriately changed within the range where the effect of the present invention is exhibited. Other than the above, the present invention can be appropriately modified and implemented without departing from the scope of the object of the present invention.

  For example, in the above-described embodiment, the inertial sensor 70 is attached to the back surface 53 as the first attachment surface of the floating bracket 51, and the ABS unit 20 is attached to the surface 52 as the second attachment surface of the floating bracket 51. Although the configuration is adopted, the configuration is not limited to this. The inertial sensor 70 may be attached to the front surface 52 of the floating bracket 51, and the ABS unit 20 may be attached to the back surface 53 of the floating bracket 51.

  In the above-described embodiment, the floating bracket 51 is formed in a flat plate shape parallel to the left-right direction with the back surface 53 as the first mounting surface and the front surface 52 as the second mounting surface. Not limited. The shape of the floating bracket 51 is not particularly limited, and is, for example, a plate shape bent in an L shape having a surface parallel to the left and right direction and a surface extending in the up and down direction from the edge of this surface and parallel to the up and down direction. It may be formed. In this case, the side surface of the floating bracket 51 which is a surface perpendicular to the vehicle left-right direction may be the first mounting surface or the second mounting surface.

  Further, in the above-described embodiment, the inertial sensor 70 used in the ABS unit 20 is described as an example, but the present invention is not limited to this configuration. The inertial sensor 70 may be a sensor used for vehicle body control such as trunk control or wheelie control or engine control. That is, the inertial sensor 70 is a concept including an acceleration sensor, an angular velocity sensor, a yaw rate sensor, and the like.

  Further, in the above-described embodiment, the floating bracket 51 is fixed to the vehicle body frame 1 via the rubber bush 61 as a vibration absorbing material, but the configuration is not limited to this. The vibration absorber may be made of a material capable of absorbing the vibration transmitted from the vehicle body frame 1 to the floating bracket 51, and may be made of an elastic body such as a spring or a foam body such as a sponge. ..

  Further, in the above-described embodiment, the inertial sensor 70 is fixed to the floating bracket 51 via the rubber sheet 73 as another vibration absorbing material, but the configuration is not limited to this. The other vibration absorbing material may be made of a material that can absorb the vibration transmitted from the floating bracket 51 to the inertial sensor 70, and is made of, for example, an elastic body such as a spring or a foam body such as a sponge. Alternatively, a vibration absorbing material similar to the rubber bush 61 described above may be used to attach the arm portion 71 of the inertial sensor 70.

  Further, although the inertia sensor 70 is attached to the floating bracket 51 of the ABS unit 20 in the above-described embodiment, the configuration is not limited to this. The ABS unit 20 may be attached to the floating bracket of the inertial sensor 70. In addition to the ABS unit 20 and the inertial sensor 70, the floating bracket 51 may be formed so that an ECU (Engine Control Unit) or an exhaust valve actuator can be attached.

  Further, in the above-described embodiment, the inertial sensor 70 is fixed to the back surface 53 of the floating bracket 51 via the rubber sheet 73, but the present invention is not limited to this structure. If the vibration propagated from the vehicle body frame 1 to the inertial sensor 70 can be sufficiently absorbed by the rubber bush 61 and the vibration generated when the ABS unit 20 is driven does not pose a problem, the floating bracket 51 is fixed to the floating bracket 51 without the rubber sheet 73. The inertial sensor 70 may be fixed.

  Further, in the above-described embodiment, the configuration in which the floating bracket 51 is fixed near the center of the body frame 1 has been described, but the configuration is not limited to this. The floating bracket 51 may be installed at any position on the body frame 1 as long as the inertial sensor 70 can ensure a predetermined detection accuracy.

  As described above, the present invention has an effect that vibration propagation to the inertial sensor can be sufficiently suppressed, and is particularly useful for an inertial sensor attachment structure of a motorcycle.

1 Body frame 20 ABS unit 51 Floating bracket 52 Surface of floating bracket (second mounting surface)
53 Back side of floating bracket (first mounting surface)
61 Rubber bush (vibration absorber)
70 Inertial sensor 73 Rubber sheet (other vibration absorbing material)

Claims (7)

A floating bracket that supports the inertial sensor via a vibration absorbing material that absorbs the vibration transmitted from the body frame,
The inertial sensor is attached to the floating bracket together with other components that increase the weight supported by the floating bracket to lower the natural frequency and make the floating bracket less likely to vibrate. Mounting structure.   The inertial sensor mounting structure according to claim 1, wherein the floating bracket is supported by the vehicle body frame via a separate component fixed to the vehicle body frame.   An inertial sensor mounting structure for a saddle-ride type vehicle, wherein the vehicle body frame is a seat rail or a sub-frame.   The inertial sensor mounting structure according to any one of claims 1 to 3, wherein the floating bracket is arranged behind a rear cushion unit for rear wheel suspension.   The inertia sensor mounting structure according to claim 1, wherein the other component is an ABS unit.   The inertia sensor mounting structure according to claim 5, wherein the ABS unit is arranged in front of the front end of the rear wheel.   The inertia sensor mounting structure according to claim 1, wherein another vibration absorbing material is interposed between the floating bracket and the inertia sensor.

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