BR112019012671B1 - SUPPORT POSITION DETECTION DEVICE - Google Patents

Abstract

a support switch 5 having a housing member 31, and a rotor member 32 which is rotatably housed in an inner side thereof. the housing member 31 comprises a cylindrical section 33 having an open bottom surface, a clamping section 34 which is provided to one side of the cylindrical section 33, and a coupler section 35 for externally transmitting a signal from a magnetic sensor 37. magnet 37 comprises a magnetic sensor body 37a and main terminals 37b, 37c. main terminals 37b, 37c are fixed by and electrically connected to clamping slots 40c, 40c which are provided to input ports 40a, 40a of a terminal 40. the magnetic sensor 37 and the terminal are thus directly connected, and thus allowing for conservation space and a small number of components.

Description

TECHNICAL FIELD

[0001] The present invention relates to a device that detects the position of a main support or oscillating support sidebar attached to a two-wheeled vehicle.

[0002] BACKGROUND

[0003] As with a side support attached to a two-wheeled vehicle, when the two-wheeled vehicle is stationary, a side support bar will be lowered to a standing position and supporting the two-wheeled vehicle. While the two-wheeled vehicle is operating, the side support bar is held in place and maintained in a state in which travel is not impaired. For a motorcycle, it is known that the position of the side support bar is detected so that the motorcycle will not rotate while the side support bar is in the standing position, and if the side support bar is in the standing position, the engine will be controlled to prevent the motorcycle from rolling.

[0004] For example, in the LPT 1 document, a position sensing device is shown having an attachment member attached to the body frame of the two-wheeled vehicle, the attached member having an upper housing member and a lower housing member and having also a movable member that moves along with the swing of a side support bar. Either a magnet and a magnetic sensor are attached to the upper case member and the lower case member.

[0005] With the position sensing device on LPT 1, the movable limb is placed between the upper case limb and the lower case limb. The position sensing device detects the standing position and storage position of the side support by placing the movable member in a state in which the movable member intervenes between the magnet and the magnetic sensor and protects a magnetic field when the support bar side is in the upright position and not shielding a magnetic field when the side support bar is in the stowed position.

[0006] Citation List

[0007] Patent Literature

[0008] LPT 1: Unexamined Japanese Patent Application Publication No. 2012-166702

SUMMARY OF THE INVENTION TECHNICAL PROBLEM

[0009] With the position detection device described in LPT 1, the magnetic sensor is placed on a printed circuit board in a substantially rectangular shape. In addition, a decisive circuit, an output circuit and an external output terminal are placed on the printed circuit board in addition to the magnetic sensor. The device is structured so that the position of the magnet is detected by the magnetic sensor and a decisive result for the detection is output from the external output terminal through the decisive circuit and the output circuit.

[00010] In addition, with the position sensing device described in Figure 1 on LPT 1, a housing member is provided above the oscillating axis of the side bracket and the printed circuit board on which the magnetic sensor and others are placed and held in the sheath member, as described in Figure 1 in LPT 1.

[00011] With the device, the sheath member widely protrudes from the circumference of the swivel axis of the support bar. When the user of the two-wheeled vehicle begins to manipulate the support bar, there will be fear that the sheath member will interfere. Also, in a structure such as the device, in which a magnetic sensor and other circuits are placed on a printed circuit board, the size of the device being increased causing a problem in material costs used for electronic services and a circuit board. circuit to be used are high. Furthermore, there is a problem that when the device is manufactured, the number of man-hours will be increased in the assembly operations so that the assembly of electronic devices on a printed circuit board and embedding, carried out after the assembly of the circuit board printed circuit in the case member.

[00012] The present invention addresses the above problems in order to provide a support bar position detection device that has fewer parts and allows for space-spacing.

[00013] Another objective of the present invention is to provide a support bar position detection device that can be easily mounted during manufacturing.

Solution to the Problem

[00014] To achieve the objectives described above, a support position detection device in the present invention is a device used for a support that has a fixed part attached to the side of a vehicle frame and that also has a support bar. oscillating around an oscillating axis with respect to the fixed part, the device sensing the position of the support bar. The support position sensing device is characterized in that it has a movable member that moves along with the swing of the support bar, a magnet generating member attached to the movable member, and a housing member attached to the side of the fixed part. The support position sensing device is further characterized in that the case member has a magnetic sensor that can detect a change in the position of the member generating magnetism and an external connection terminal which has an input end and an output end, the terminal external connection producing a member detection result generating magnetism to the outside; the magnetic sensor having a sensor body and a main terminal projecting from the sensor body; the sensor body being placed so as to face the member generating magnetism in the axial direction of the oscillating axis; and the main terminal and the input end of the external connection terminal being directly joined.

[00015] According to the support position detection device of the present invention, the magnetic sensor is placed so as to be facing the member generating magnetism in the axial direction of the oscillating axis. Therefore, a part of the member generating magnetism, which projects in the circumferential direction as in the past, can be reduced. Also, since the input end of the external connection terminal and the main terminal of the auto switch are directly joined, other members such as cables, wires and circuit board are not needed. Therefore, according to the present invention, the number of parts can be reduced and space saving can also be possible.

[00016] In addition, the support position sensing device of the present invention will be preferable for the output end of the outer connection terminal to be placed so as to be displaced towards the same side as the magnet generating member with respect to to the auto switch and it is also preferable for the input end to project towards the main terminal in the axial direction of the oscillating shaft.

[00017] According to the structure, since the input end is shifted towards the same side as the member generating magnetism, members placed from the member generating magnetism in the axial direction of the oscillating axis can be reduced. This offset placement can be easily achieved by making the input end protrude into the main terminal.

[00018] Furthermore, in the holder position sensing device of the present invention, it will be preferable for the case member to have a retaining protrusion that retains the main terminal between the sensor body and the inlet end. Due to the structure, the magnetic sensor can be firmly fixed to the case member.

[00019] Furthermore, in the holder position sensing device of the present invention, it will be preferable for the inlet end to have a retaining groove to retain the main terminal so that when the magnetic sensor is attached to the housing member, the terminal main is held by the retaining slot at the inlet end. According to the structure, since the auto switch is held by the retaining groove at the inlet end, the auto switch can be firmly fixed to the housing member.

[00020] Furthermore, in the holder position sensing device of the present invention, it will be preferable that the inlet end protrudes from the case member, the case member having a concave storage part that stores the magnetic sensor, and the concave part storage tank being filled with insulation resin. According to the structure, the magnetic sensor is firmly fixed to the case member, improving resistance to changes in the external environment.

[00021] ADVANTAGEOUS EFFECTS OF THE INVENTION

[00022] According to the present invention, in a support position detection device, the number of parts can be reduced and space saving is possible. Furthermore, according to the present invention, the incorporation of a magnetic sensor in a case member is easily done, so that assembly operations during manufacture are easily done.

BRIEF DESCRIPTION OF THE DRAWINGS

[00023] For a better understanding of the invention, a detailed description will be made of it, with respect to the attached drawings, presented as an example and not a limitation, in which: - Figure 1 is a perspective view of a side of the device of side support according to an embodiment of the present invention;- Figure 2 is an exploded perspective view of the side support device according to an embodiment of the present invention;- Figure 3 is a partial cross-sectional view of the side support device according to an embodiment of the present invention;- Figure 4 is a perspective view indicating a state in a storage concave part in a switch of the side bracket according to an embodiment of the present invention;- Figure 5 is a view in exploded perspective of a sensor part in the side support switch according to an embodiment of the present invention.

CONFIGURATION DESCRIPTION

[00024] An embodiment of the present invention, especially an example of a side support will be described in detail below with reference to the accompanying drawings. The entire structure of a side support device will be described with reference to Fig. 1 and Fig. 2. Fig. 1 is a perspective view of a side support device in accordance with an embodiment of the present invention. Figure 2 is an exploded perspective view of the side support device in accordance with an embodiment of the present invention.

[00025] The side support device 1 according to this configuration supports a motorcycle in a standing state during parking, as indicated in Figures 1 and 2. The side support device 1 is structured by having a support (fixed part) 2 attached to a body frame, which is not illustrated, and a side support bar and a side support bar 3 swiveling on a support 2 via a pivot bolt (swing axle) 4, In addition, with the device support switch 1, a side support switch is fixed to the pivot bolt 4 by means of a set screw. The swinging position of the side support bar 3 is detected by the side support switch 5.

[00026] The support 2 is structured by having a plate-like part 11 and a through pin 12 which passes through the plate-like part 11 in the thickness direction and being fixed. In the plate-like part 11, a shaft hole 13 is formed to pass through the plate-like part 11 in the thickness direction in a position in which the side support bar 3 is fixed. One extreme side of the through pin 12 functions as a positioning pin that positions the side support switch 5. Another extreme side of the through pin 12 functions as a locking pin locked to a return spring, which is not illustrated.

[00027] The side support bar 3 is fixed to the support 2 as the pivot bolt 4. The side support bar 3 is structured so as to be pivotable around the pivot bolt 4 between a standing position in which the support bar 3 is in contact with the ground and a storage position in which the side support bar 3 is substantially parallel to the ground. A pair of connecting parts 15 and 16 formed in a double fork shape so as to press the plate-like part 11 into the lower extreme side of the side support bar 3. Shaft holes 17 and 18 are formed to pass through this. pair of connecting parts 15 and 16. An engagement hole 19, which is engaged with the rotor member (movement member) 32 of the switch of the side support 5, is formed as a through hole in the vicinity of the shaft hole 17 in the connecting part 15, which is one of the connecting parts.

[00028] The pivot bolt 4 is inserted through the shaft holes 17 and 18 in the pair of connecting parts 15 and 16 and through the shaft hole 13 in the bracket 2 in a state in which the bracket 2 is sandwiched between the pair of connecting parts 15 and 16. In this case, an intermediate part of the pivot bolt 4 being inserted through the axle hole 17 in the connecting part 15, which is one of the paired connecting parts, and the axle hole 13 in the bracket , and a threaded part 24 on the uppermost side being inserted through the shaft hole 18 into the connecting part 16, which is the other of the parts paired with the threaded part 24 exposed to the outside.

[00029] A nut 7 is screwed onto this exposed threaded part 24. When the fixing nut is tightened, the pivot bolt 4 is fixed to the pair of connecting parts 15 and 16. Thus, the side support bar 3 is pivoted together with pivot screw 4 with respect to bracket 2. Furthermore, a screw hole 22, into which the fixing screw is screwed, is formed in the head of the pivot screw 4.

[00030] The side support switch 5 detects that the side of the standing position and the side of the storage position is positioned on the side support bar, The side support switch 5 is fixed to the head 21 of the pivot bolt 4 with the fixing screw. A retaining part 34 is formed on a socket member 31 of the switch of the side support 5. By capturing an extreme side of the through pin 12 with this retaining part 34, the switch of the side support 5 is positioned. Incidentally, details of the side bracket switch 5 will be described later.

[00031] Fixing screw 4 fixes the side bracket switch 5 to the pivot bolt 6 by being inserted through the side bracket switch 5 and being tightened in a state in which the fixing screw 6 is screwed into the screw hole 22 in the pivot screw 6. The fixing screw 6 has a flange part 27 in a rounded shape at the head. The side support switch 5 is stably pressed by this flange part 27.

[00032] In the following, the detailed structure of the side support switch will be described with reference to Figures 3 and 5. Figure 3 is a partial cross-sectional view of the side structure device according to an embodiment of the present invention. Figure 4 is a perspective view indicating a state in a storage concave portion of a side support switch in accordance with an embodiment of the present invention. Figure 5 is an exploded perspective view of a sensor part on the side support switch in accordance with an embodiment of the present invention.

[00033] As indicated in Figure 3, the side support switch 5 is structured to have a housing member 31, the rotation of which is restricted, at an extreme side of the through pin 12 and also having the rotor member 32 rotatably stored in the case member 31. The case member 31 is formed of an aesthetic resin or the like, and having a cylindrical part 33, the lower surface of which being open, the retaining part 34, described above, which is provided on the side of the cylindrical part 33 , and a coupler part 35 for transmitting a signal from a magnetic sensor 37 to the outside.

[00034] As indicated in Figures 3 and 4, a concave storage part of a sensor use 38 to secure the magnetic sensor 37 being formed on the surface side (in Figure 3, the upper side) of the housing member 31, the sensor magnetic being stored in the concave storage part of the wear sensor 38, and the concave storage part of the wear sensor being filled with an insulating resin 38d (see Fig. 1). Furthermore, the lower surface of the concave storage part of the wear sensor 38 intervenes between the magnetic sensor 37 and a plastic magnet (member generating magnetism) 36, which will be described below, in the rotor member 32, and a slot 38a being formed. on this lower surface and the plastic magnet 36.

[00035] The magnetic sensor 37 has a magnetism sensor body 37a and main leads 37b and 37c protruding from the magnetism sensor body 37a. In addition, input ends 40a and 40a of a terminal 40, which is an external connection terminal of the coupling part 35, protruding from the lower surface of the concave storage part of the wear sensor 38. The output ends 40b and 40b of this terminal project into the coupling part 35 through the interior of the housing member 31.

[00036] Inlet ends 40a and 40a, retention slots 40c and 40c are formed as shown in Figures 3 to Figure 5. When main terminals 37b and 37c are inserted from above, main terminals 37b and 37c are retained by retention slots 40c and 40c and electrically connected.

[00037] In addition, as indicated in Figure 4, a retaining protrusion 38b which retains the main terminals 37b and 37c protrudes from the lower surface of the storage concave portion 38. In addition, a positioning protrusion 38c for positioning the sensor body of magnetism 37a is provided in the concave storage part of the wear sensor 38.

[00038] Figure 5 is an exploded perspective view that indicates a positional relationship between the plastic magnet 36, the magnetic sensor 37, and the terminal 40. The magnetic sensor body 37a is positioned on the side of the upper surface in Fig. 5 of the plastic magnet 36 and being positioned so as to face the plastic magnet 36 in the axial direction of the pivot bolt 4. In addition, the main terminals 37b and 37c projecting from the body of the magnetic sensor 37a are placed so as to project from the circumferential wall of the plastic magnet 36 in its radial direction.

[00039] On the other hand, the terminal 40 is placed so that the output ends 40b and 40b are adjacent to the circumferential wall of the plastic magnet 36 in the radial direction, and being displaced with respect to the body of the magnetic sensor 37a in the axial direction of the pivot screw 4. Lead-in ends 40a and 40a of the terminal are curved so as to protrude from the main body of the terminal 40 towards the main terminals 37b and 37c. Thus, the main terminals 37b and 37c are retained by retaining slots 40c and 40c provided at the inlet ends 40a and 40a. In this configuration, the input ends 40a and 40a and the main terminals 37b and 37c are more reliably connected to each other by being further soldered.

[00040] Here, the assembly process for the side bracket switch 5 during manufacturing will be described. The terminal 40 is fixed to the case member 31 in advance by being inserted molded. Due to molding, the wear sensor storage concave portion 38, retaining lug 38b, positioning lug 38c, and others are formed. When the magnetic sensor 37 is to be mounted to the case member 31, a worker or a robot worker mounts the magnetic sensor 37 to a location where the positioning lug 38c for positioning the body of the magnetic sensor 37a is present. Thus, the magnetic sensor body 37a is positioned on the positioning lug 38c in the concave storage part of the wear sensor 38. In addition, the main terminals 37b and 37c are retained by the detent lug 38b and the detent slots 40c and 40c. at the inlet ends 40a and 40a.

[00041] After that, input ends 40a and 40a and main terminals 37b and 37c are soldered and connected. After that, the insulating resin 38d (see Figure 1) is provided in the concave storage part of the wear sensor 38, protecting the magnetic sensor 37 and the connected parts. As a result, according to the switch of the side bracket 5 in this configuration, the number of parts is small, a space-saving configuration being achieved, and in addition, assembly operations can be carried out easily and safely.

[00042] The cylindrical part 33 in the case member 31 has an opening part 41 through which the fixing screw 6 is inserted, a small diameter part 41a described below, in which the plastic magnet 36 in the rotor member 32 is stored , and a large diameter part 41 to be described below, the diameter of which is increased by starting the small diameter part 41a in a direction of the side support bar 3, as indicated in Fig. 3. A stepping part 41c generated due to the difference between the small diameter part 41a and the large diameter part 41b is formed therebetween. Furthermore, a sliding part 41d in a rim shape, which slides on the outer circumferential surface of a bearing part 9b on a flange member 9 described below, being provided on the inner circumferential surface of the opening part 41.

[00043] The housing member 31 having the structure described above is rotatably supported by the fixing screw 6, a rim 8, made of a metal, which is fixed to the periphery of the fixing screw, and the flange member 9, made of a resin which is fixed to the periphery of the ring 8, as indicated in Fig. 3.

[00044] The rim 8, which is a cylindrical body made of a metal, has the same height (length of the set screw 6 in the axial direction) as the flange member 9). The flange member 9 has a flange part 9a to prevent the casing member 31 from coming off, the bearing part 9b formed to have a smaller diameter than the flange part 9a, and a rotor member fixing part 9c formed so as to have a smaller diameter than the bearing part 9b, the fixing part of the rotor member 9c being configured to fix the rotor member 32, as indicated in Fig. 4.

[00045] As indicated in Fig. 3, the rim 8 and the flange member 9 are fixed to the head 21 of the pivot bolt 4 by the flange part 27 of the fixing screw 6. The rotor member 32 is fixed to the head 21 of the pivot bolt 4 by the fixing part of the rotor member 9c of flange member 9. The rotor member swings together with the side support bar 3.

[00046] As indicated in Fig. 3, the rotor member 32 has a rotor body 32a in a rim shape, an engagement pin 32b in a cylindrical shape, which projects from the rotor body 32a towards the engagement hole 19 in the side support bar 36. Rotor body 32a, engagement pin 32b, and locking jaw 32c are integrally formed of a synthetic resin material.

[00047] The rotor body 32a has an outer diameter that is slightly smaller than the inner diameter of the large diameter part 41b in the cylindrical part 33 of the casing member 31, and being formed to have a larger diameter than the outer surface of lock 32c and the outside diameter of the plastic magnet 36. Furthermore, a recessed part 32d is formed in the rotor body 32a towards the same side as the side support bar 3 for weight reduction and improved strength.

[00048] Engagement pin 32b is formed into a cylindrical shape having a recessed part 32e in the center. Engagement pin 32b is formed integrally with rotor body 32a. This engagement pin 32b is provided to extend from the end face of the rotor body 32 a on the same side as the side support bar 3 towards the same side as the side support bar 3.

[00049] The outside diameter of this engagement pin 32b is substantially the same size as the thickness of the rotor body 32a in the radial direction to improve strength. Furthermore, since the shape of the engagement pin 32b itself has a cylindrical shape having the recessed part 32e in the center, weight reduction and improvement in strength will be achieved compared to a case in which the engagement pin 32b is formed into a columnar shape whose interior is solid.

[00050] The plastic magnet 36 is a magnet generating member formed into a rim shape. As indicated in Fig. 5, the plastic magnet 36 is structured to be divided into four segments at 90 degree intervals when viewed from the axial direction of the pivot bolt 4; the members 36a and 36b having different polarities being alternatively connected. Due to this structure, when the side support bar 3 is swung, the magnetic sensor 37 will be able to detect the position of the sway.

[00051] In addition, as indicated in Fig. 3 and Fig. 5, a locking groove 36c is formed in the plastic magnet 36 in its circumferential direction so as to be substantially the same width as the locking jaw 32c. The plastic magnet 36 is formed so that its outer circumferential surface and the outer circumferential surface of the locking jaw 32c are substantially aligned with each other in a state in which the plastic magnet 36 is locked by the locking jaw 32c of the rotor member 32. In addition addition, as indicated in Fig. 3, the outer circumference of the plastic magnet 36 is formed to have a smaller diameter than the outer circumference of the rotor body 32a. A stepwise part 32f generated depending on the difference between the outside diameters of the plastic magnet 36 and the rotor body 32a is formed.

[00052] In the side support device 1 structured like this, when a motorcycle starts riding, the side support bar 3 is lifted by the rider and the side support bar 3 being swung from the standing position to the storage position with pivot bolt 4 acting as a fulcrum. Thus, the rotor body 32a oscillates together with the side support bar 3 through the engagement pin 32b and the plastic magnet 36 provided in the rotor body 32a oscillates.

[00053] This movement of the plastic magnet 36 is detected by the magnetic sensor 37 provided in the housing member 31. Here, if the region of the plastic magnet 36 which turns to the magnetic sensor 37 being a member 36a with the side support bar 3 in the standing position, when the side support bar 3 swings to a storage position, the region of the plastic magnet 36 which turns to the magnetic sensor 37 changes to a member 36b. Thus, the polarity of a region, facing the magnetic sensor 37, of the plastic magnet changes. This change in the polarity of the plastic magnet 36 is detected by the magnetic sensor 37, so that the bar of the side support 3 is positioned in the storage position.

[00054] On the other hand, when the motorcycle starts to be parked, the side support bar 3 is lowered by the rider and the side support bar 3 being swung from the stowed position to the standing position as pivot bolt 4 acting as a fulcrum. Thus, the rotor body 32a swings together with the side support bar 3 through the engagement pin 32b and the plastic magnet provided in the rotor body rotates. This movement of the plastic magnet is detected by the magnetic sensor 37. Thus it will be detected by the side support switch 5 that the side support bar 3 is positioned in the standing position.

[00055] Incidentally, although in the above configuration a side support has been used as an example of a support, the support could be a main support. Furthermore, in the above configuration, the rotor body 32a has been molded with a resin. This may increase levels of freedom in the configuration and reduce manufacturing costs in the molding as compared to a case in which the rotor body 32a is formed. of a metal. In addition, the weight of the side bracket switch 5 can be reduced. Furthermore, since the metal surfaces of the switch of the side bracket 5 are reduced, it will be possible to reduce the expense of coating for rust prevention.

[00056] Furthermore, although in the above configuration, the input ends 40a and 40a and the main terminals 37b and 37c are soldered, this is not a limitation. In a state in which both are retained, an insulating resin may be filled or both may be welded by spot welding or the like.LIST OF REFERENCE SIGNS1 side support device,2 support,3 side support bar,4 pivot bolt (swing shaft), 5 side bracket switch (position sensing device), 6 set screw, 7 set screw, 19 engagement hole, 21 head, 31 housing member, 32 rotor member (movement member), 32b engagement pin,36 plastic magnet (magnetism generating member),37 magnetic sensor,37a magnetic sensor body,37b, 37c main terminal,38 wear sensor storage concave part,38a slot,38b retention protrusion,38c positioning protrusion,38d insulation resin,40 terminal (external connection terminal),40c retaining slot,41 opening part,41a small diameter part,41b large diameter part,41c stepping part,41d sliding part.

Claims (2)

1 .- “SUPPORT POSITION DETECTION DEVICE”, used for a support (2) which has a part fixed to the side of a vehicle structure and which also has a support bar that can be swung around an oscillating axis with respect to to the fixed part, characterized in that it comprises a movement member (32) which moves along the oscillation of the support bar (3), a magnet generating member (36) fixed to the movement member (32), and a housing member fixed to the side of the fixed part, where the case member has a magnetic sensor (37) capable of detecting a change in a position of the member generating magnetism (36) and an external connection terminal (40) having an inlet end and a output end, the external connection terminal (40) emitting a detection result from the member generating magnetism (36) to the outside, and in that the magnetic sensor (37) has a sensor body (37a) and a main terminal (37b, 37c) projecting from the sensor body (37a), the sensor body sensor (37a) being placed so as to face the member generating magnetism (36) in an axial direction of the oscillating axis, and in that the main terminal (37b, 37c) and the input end of the external connection terminal (40) are directly joined, the housing member (31) has a retaining protrusion (38b) which retains the main terminal (37b, 37c) between the sensor body (37) and the inlet end, the inlet end has a retaining groove (40c) to retain the main terminal (37b, 37c) so that when the auto switch (37) is attached to the housing member (31), the main terminal (37b, 37c) is retained by the retention slot (40c) in the inlet end, inlet end protruding from the housing member (31), the housing member (31) having a concave storage portion (38) that stores the magnetic sensor (37), and the concave storage portion (38) being filled with an insulating resin (38d). 2 .- "SUPPORT POSITION DETECTION DEVICE", according to claim 1, characterized in that the output end of the external connection terminal (40) is placed so as to be moved towards the same side of the generating member of magnetism (36) with respect to the auto switch (37) and the input end projecting towards the main terminal (37b, 37c) in the axial direction of the oscillating shaft (4).

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