JP4716966B2 - Rotation detecting device and manufacturing method thereof - Google Patents

Description

  The present invention relates to a rotation detection device applied to, for example, an antilock brake system (ABS) sensor for automobiles and a manufacturing method thereof.

  A technique for manufacturing a sensor and peripheral parts by resin overmolding (insert molding) has been put to practical use (see Patent Document 1). In an axle rotation sensor (ABS sensor) used for mounting on a hub bearing of an automobile, a magnet body or a metal body is disposed on a rotating wheel of the hub bearing, and a magnetic type such as a magnetic pickup, a hall sensor, or a magnetoresistive element is opposed thereto. It is the structure which arrange | positions a sensor. The ABS sensor is used as a sensor unit structure by overmolding sensor components.

  In the prior art, a sensor component is fixed in advance to a sensor holder for fixing a sensor, and resin is overmolded (secondary molding). In automobile parts, performances such as mechanical strength, waterproofness, weather resistance, chemical resistance and the like are required, and such a mold is required.

JP 2000-88984 A

The prior art has the following problems.
(1) Adhesiveness between the molding material and the component to be incorporated cannot be expected.
(2) Due to the self-heating of the built-in electronic component and the change in the environmental temperature, a gap is generated between the mold material and the built-in component due to a difference in thermal expansion, and there is a problem in waterproofness.
(3) Even when an external force is applied to the molded sensor unit and plastic deformation occurs in the molding material, a gap is generated between the molding material and the built-in component, and there is a problem in waterproofness.
(4) When an external force is applied to the molded sensor unit, the molding material made of resin is unlikely to be deformed. Therefore, a force acts directly on the built-in components, causing damage to the sensor unit.
(5) The molding material made of resin does not have vibration absorption performance and has a problem in durability against external vibration.
(6) The mold by the conventional injection molding requires a nozzle that allows molten resin to flow in, a runner that guides the molten resin to a hollow portion that becomes a molded product, and an inlet (gate) to the hollow portion. In order to smooth the flow of the molten resin and increase the yield, it is appropriate that the number of production at one time is several to about 10, and the number of molding at one time is limited.
(7) When the sensor is assembled, there is a risk that an excessive tensile force is applied to the cable electrically connected to the sensor.

  In rotation detection devices such as ABS sensors that are mounted on automobile parts, especially hub bearings, they are exposed to the road surface and exposed to salt mud water, and in severe environments where large temperature changes from 100 degrees to minus tens of degrees occur. In addition, it is located below the suspension and is greatly affected by vibrations caused by vehicle travel. The malfunction of the ABS sensor has a great influence on the safety of vehicle travel. Therefore, it is necessary to avoid as much as possible the deterioration of waterproofness due to the adhesiveness between the molding material and the built-in parts, the difference in thermal expansion, the generation of gaps due to external force, etc., and the durability against damage and vibration due to external force It is strongly desired that the property be excellent. Such various severe demands cannot be satisfied by a conventional rotation detection device using a resin mold.

  The purpose of the present invention is to absorb differences in thermal expansion due to environmental temperature and self-heating of the sensor parts, and is excellent in waterproofness, and even if vibration or external force is applied, damage to the sensor parts can be avoided and excellent in durability. Further, when the sensor is assembled, a rotation detecting device capable of preventing an excessive tensile force from being applied to peripheral components electrically connected to the sensor and reducing the manufacturing cost, and a method for manufacturing the same Is to provide.

  The rotation detection device according to the present invention includes a magnetic sensor disposed opposite to a magnet body or a metal body provided on a rotating member, and peripheral components electrically or mechanically connected to the magnetic sensor. A cable clamp attached to a fixed part for positioning the magnetic sensor, and a metal cable clamp for gripping a cable electrically connected to the magnetic sensor among the peripheral parts. A fixed part including a magnetic sensor, a peripheral part, and a cable clamp is integrally molded in a covered state with a thermoplastic elastomer or a material exhibiting rubber elasticity.

  According to this configuration, the magnetic sensor, peripheral parts, and cable clamp (these are called sensor parts) are molded in a state of being covered with a thermoplastic elastomer or a material exhibiting rubber elasticity, so that vibration and external force are applied to the sensor parts. Even when it acts, the mold material having rubber elasticity is deformed, and it is possible to prevent problems such as breakage of sensor parts.

  Even if the sensor component is covered with an elastomer or rubber material that has elasticity, the sensor component and the molding material may experience different thermal expansion due to environmental temperature and self-heating of the electronic component. The elasticity of the material absorbs the difference in thermal expansion. Therefore, it is possible to prevent water or the like from entering between the sensor component and the molding material, and the waterproofness of the sensor component can be maintained.

  When at least a part of the fixing part for positioning the magnetic sensor is made of a metal having adhesiveness to the rubber material, and this metal body has a function of a cable clamp for gripping the cable, the magnetic sensor and The cable can be integrally molded firmly. When a mechanism for clamping the cable is provided in a part of the fixed component for fixing the sensor component, the structure can be simplified by suppressing an increase in the number of components, and the number of manufacturing steps can be reduced. Therefore, it is advantageous in reducing the manufacturing cost. By mechanically gripping the cable with a metal cable clamp, it is possible to prevent an excessive tensile force from being applied to the cable when the sensor is assembled.

  In the present invention, the molding is preferably performed by compression molding using a mold. According to this configuration, since a large number of rotation detection devices can be manufactured by a single molding, the number of sensor parts manufactured per unit time is increased from that of the prior art in which injection molding is performed, thereby reducing the manufacturing cost. be able to.

  In the present invention, the cable clamp and the rubber elastic material are preferably vulcanized and bonded. According to this configuration, it is possible to prevent an undesired gap from being formed between the cable clamp and the molding material and to prevent water or the like from entering. The magnetic sensor is preferably configured by a Hall sensor, a magnetoresistive element, a giant magnetoresistive element, or a coil. The magnetic sensor is preferably configured to be attachable to a wheel bearing device of an automobile. According to this configuration, it is possible to realize an automobile part having performances such as mechanical strength, waterproofness, weather resistance, and chemical resistance.

  The method of manufacturing a rotation detecting device according to the present invention includes a magnetic sensor to be disposed opposite to a magnet body or a metal body provided on a rotating member, and an electrical or mechanical connection to the magnetic sensor. A peripheral part, and a cable clamp attached to a fixed part for positioning the magnetic sensor, and a metal cable clamp for gripping a cable electrically connected to the magnetic sensor among the peripheral parts. And a step of compression-molding integrally with a mold together with a thermoplastic elastomer or a material exhibiting rubber elasticity.

  According to this manufacturing method, the sensor component is integrally compression molded by a mold together with a thermoplastic elastomer or a material exhibiting rubber elasticity. Therefore, even if vibration or external force is applied to the sensor component, problems such as breakage are caused. Can be prevented, and the durability of the sensor component can be enhanced. Even if the sensor component and the molding material are subjected to compression molding, especially with an elastomer material or rubber material having elasticity, even if the thermal expansion differs between the sensor component and the molding material due to the environmental temperature and the self-heating of the electronic component, The difference in thermal expansion can be absorbed by the elasticity of the material. Therefore, it is possible to prevent water or the like from entering between the sensor component and the molding material, and the waterproofness of the sensor component can be maintained. Since the molding is mold compression molding, a large amount of rotation detection device can be manufactured by one molding. Therefore, according to this manufacturing method, the manufacturing cost can be reduced as compared with the prior art of injection molding. By mechanically gripping the cable with a metal cable clamp, it is possible to prevent an excessive tensile force from being applied to the cable when the sensor is assembled.

  Since the rotation detection device of the present invention is formed by covering the sensor component with a thermoplastic elastomer or a material exhibiting rubber elasticity, the mold material having rubber elasticity even when vibration or external force is applied to the sensor component. Can be deformed to prevent problems such as breakage of sensor parts. Even when different thermal expansion occurs between the sensor component and the molding material due to the environmental temperature and self-heating of the electronic component, the thermal expansion difference can be absorbed by the elasticity of the molding material. Therefore, an undesired gap can be prevented from being generated between the sensor component and the molding material, and the waterproofness of the sensor component can be maintained. Since the molding can be compression molding using a mold, a large number of rotation detection devices can be manufactured by one molding.

  When at least a part of the member for positioning the magnetic sensor is made of a metal having adhesiveness to the rubber material, and this metal body has a function of a cable clamp for gripping the cable, the magnetic sensor and the cable Can be integrally molded. When a mechanism for clamping the cable is provided in a part of the fixing bracket for fixing the sensor component, the structure can be simplified by suppressing an increase in the number of component parts of the apparatus, and the number of manufacturing steps can be reduced. Therefore, it is advantageous in reducing the manufacturing cost. By mechanically gripping the cable with a metal cable clamp, it is possible to prevent an excessive tensile force from being applied to the cable when the sensor is assembled.

  Hereinafter, a plurality of embodiments for carrying out the present invention will be described with reference to the drawings. In the following description, the same reference numerals are given to portions corresponding to the matters described in the preceding forms in each embodiment, and overlapping description may be omitted. When only a part of the configuration is described, the other parts of the configuration are the same as those described in the preceding section. Not only the combination of the parts specifically described in each embodiment, but also the embodiments can be partially combined as long as the combination does not hinder.

  The rotation detection device according to the present embodiment is applied to, for example, an automobile antilock brake system (ABS) sensor. However, the present invention is not necessarily limited to automobiles, and can be applied to various vehicles such as two-wheeled vehicles, railway vehicles, and transport vehicles, and can be attached to various bearings and peripheral members of the bearings. The following description also includes a description of a method for manufacturing the rotation detection device.

  FIG. 1 is a cross-sectional view of the rotation detection device according to the first embodiment of the present invention. The rotation detection device 1 includes a sensor assembly 3 and an elastic member 11 </ b> A that covers a main part of the sensor assembly 3. The sensor assembly 3 processes the sensor 4, which is a magnetic sensor, the electrode terminal 5, the cable core wire 6, the cable insulation coating 7, the cable cover 8, the fixing bracket 21 as a fixing component, and a part of the fixing bracket 21. And a cable clamp 25 formed. The sensor 4 is realized by a magnetic sensor composed of a Hall sensor, a magnetoresistive element (MR sensor, MR: Magneto Resistance Effect), a giant magnetoresistive element (GMR sensor, GMR: Giant Magneto Resistive), or a coil.

  The front end 4a of the sensor 4 is disposed at a predetermined small distance from the magnet or metal body provided on a rotating member (not shown). The magnet body is, for example, a magnetic encoder magnetized alternately in the circumferential direction. The metal body is, for example, a gear-shaped pulsar ring. An electric terminal 4b is attached to the base end portion of the sensor 4, and an electrode terminal 5 made of a metal having good electrical conductivity is electrically connected to the electric terminal 4b by crimping, soldering or other joining methods. ing. The extending direction of these electric terminals 4b and electrode terminals 5 is defined as the y direction, and the thickness direction of the electrode terminals 5 is defined as the z direction. The direction orthogonal to the y and z directions is defined as the x direction. In each figure, the x, y, and z directions are represented by arrows x, y, and z.

  The cable core wire 6 is electrically connected to the tip end portion of the electrode terminal 5 in the y direction by crimping, soldering, or other joining method, and a cable insulation coating 7 is provided to ensure electrical insulation of the cable core wire 6. Yes. Further, a cable cover 8 that covers the outside of the cable insulation coating 7 is provided. The electrode terminal 5 excluding the sensor 4, the cable core wire 6, the cable insulation coating 7, and the cable cover 8 correspond to peripheral components.

  The elastic member 11A is made of, for example, a rubber material 11 mixed with a vulcanizing agent and exhibiting rubber elasticity. The elastic member 11 </ b> A covers a part of the sensor 4, the electrode terminal 5, the cable core wire 6, the cable insulation coating 7, a part of the fixing bracket 21, and the cable clamp 25 in a tight contact state without a gap. Further, the elastic member 11 </ b> A is configured to cover most of the cable cover 8 except for one end in the y direction in a tight contact state without a gap.

  For the rubber material 11, for example, nitrile rubber and fluororubber are preferable because they are excellent in heat resistance, low temperature characteristics and oil resistance, but other rubber materials may be used. Instead of these rubber materials, thermoplastic elastomers may be used. Of these, vinyl chloride, ester, and amide are particularly preferable because of their excellent heat resistance and oil resistance. In any case, the material for molding the sensor assembly 3 may be a material exhibiting rubber elasticity, and is a mold compression molding described later shown in FIGS. 3 and 4.

  The fixing bracket 21 is made of a metal having good adhesion to a rubber material, for example, steel, aluminum, copper, brass or the like. In consideration of corrosion resistance, it is desirable to use an austenitic stainless steel plate, steel with a surface treatment based on zinc, or anodized aluminum. The fixing bracket 21 has a function of positioning the sensor 4 and peripheral components. However, applicable metals are not limited to these. The fixing bracket 21 has a function of positioning the sensor 4 and peripheral components, and is configured to mechanically hold the cable core wire 6, the cable insulation coating 7, and the cable cover 8. The cable core wire 6, the cable insulation coating 7, and the cable cover 8 correspond to cables.

  The fixing bracket 21 mainly includes a concave portion 22 having a concave shape when viewed from the side, a cable fixing portion 23 provided integrally with one side edge of the concave portion 22, and the other side edge of the concave portion 22. And a sensor fixing part 24 for positioning the sensor 4 in the y direction. The side view is synonymous with viewing the sensor assembly 3 in the x direction. A cable clamp 25 is integrally attached to a part of the sensor fixing portion 24.

  The concave portion 22 of the fixing bracket 21 is disposed in the vicinity of the middle of the entire sensor assembly 3 in the longitudinal direction. The concave portion 22 has a bottom portion 22a, a first wall portion 22b including the one side edge portion, and a second wall portion 22c including the other side edge portion. The elastic member 11A is fixed to one surface portion of the bottom portion 22a, and the other surface portion of the bottom portion 22a is exposed outward (that is, the elastic member 11A is not fixed). The first wall portion 22b is erected from one end portion of the bottom portion 22a in the y direction and is formed in parallel with the xz plane (virtual plane parallel to the x and z directions), and is supported by fitting the cable insulation coating 7 therethrough. A hole 22h is formed.

  The cable fixing portion 23 is provided integrally with the first wall portion 22b along the xy plane (a virtual plane parallel to the x and y directions) from one side edge portion of the first wall portion 22b. The elastic member 11A is fixed to one surface portion of the cable fixing portion 23, and the cable cover 8 is fixed to most of the other surface portion of the cable fixing portion 23. On the other surface portion of the cable fixing portion 23, the cable clamp 25 is bent so as to protrude in one direction in the z direction from the middle portion in the longitudinal direction to one end portion in the y direction. However, it is not limited to bending.

  The cable clamp 25 has a pair of clamp portions, and each clamp portion includes a clamp body 25a and a grip piece 25b. The pair of clamp portions are disposed so as to face each other in the x direction. Each clamp main body 25a is integrally fixed along a predetermined outer edge portion of the other surface portion of the cable fixing portion 23. Each clamp body 25a protrudes from the outer edge in one direction in the z direction and is formed along the yz plane.

  A grip piece 25b (see FIG. 2) for gripping the cable cover 8 together with the other surface portion of the cable fixing portion 23 is integrally provided from the front end edge portion of each clamp body 25a. The grip piece 25b on one side is formed along the xy plane so as to protrude toward the grip piece 25b on the other side. These grip pieces 25b are formed by bending one end and the other in the x direction from the front end edge of the clamp body 25a. However, it is not limited to bending. The tip portions 25bs of the one and the other gripping pieces 25b are formed in a sawtooth shape when viewed from the bottom in order to be mechanically firmly fixed to the cable cover 8. The tip portions 25bs are arranged with a predetermined small distance gap δ2 so as not to contact each other.

  In particular, the sensor assembly 3 is compression-molded into a state in which the sensor assembly 3 is covered with a rubber material 11 by a mold to be described later in a state where the sawtooth of the tip 25bs of the one and the other gripping pieces 25b bites the outer surface of the cable cover 8. As a result, the sensor 4 and the cable can be integrally molded firmly. In the present embodiment, the distal end portion 25bs of the gripping piece 25b is formed in a sawtooth shape, but the distal end portion 25bs of the gripping piece 25b is not necessarily limited to the sawtooth shape. The distal end portion 25bs may be, for example, a concavo-convex shape having a continuous concavo-convex shape along the y direction, a wave shape, or a shape obtained by combining these shapes. Even in these cases, the same effects as in the present embodiment can be obtained.

  In the present embodiment, the cable clamp 25 having a pair of clamp portions is applied, but a cable clamp including only one clamp portion can also be applied. In this case, the grip piece protruding from the tip edge of the clamp body 25 a is formed to extend slightly in the x direction so as to cover the cable cover 8. As described above, the first wall portion 22b of the concave portion 22 and the cable fixing portion 23, particularly the cable clamp 25, cooperate to position and fix the cable and the like. In the cable clamp 25, the elastic member 11A is firmly fixed except for the portion holding the cable cover 8.

  The second wall portion 22c is formed to stand a predetermined small distance from the other end portion in the y direction of the bottom portion 22a. The sensor fixing portion 24 is provided integrally with the second wall portion 22c along the external shape of the sensor 4 from the other side edge portion of the second wall portion 22c. The sensor 4 has a rectangular shape in a side view and a rectangular shape in a plan view. The planar view is synonymous with viewing the sensor assembly 3 in the z direction. The elastic member 11A is fixed to one surface portion of the second wall portion 22c, and the other surface portion of the second wall portion 22c is exposed to the outside. The elastic member 11A is fixed to one surface portion of the sensor fixing portion 24, and the other surface portion of the sensor fixing portion 24 is exposed outward. As described above, the fixing bracket 21 positions the sensor 4 and peripheral components.

  2A and 2B are diagrams of the sensor assembly. FIG. 2A is a sectional view of the sensor assembly, and FIG. 2B is a bottom view of the sensor assembly. Referring to FIG. 2, the fixing bracket 21 and the sensor 4 are positioned by contacting the side wall portion 50, the standing wall portion 51, and the other side wall portion 52 of the fixing bracket 21. The one side wall part 50, the standing wall part 51, and the other side wall part 52 are the same members as the fixing bracket 21, and are formed by bending, cutting, or the like in the z direction by sheet metal processing, for example. Among these, the standing wall portion 51 is formed by forming a U-shaped slit in the plan view in the fixing bracket 21 and bending it in the z direction. The sensor 4 is positioned in the x direction by the one side wall portion 50 and the other side wall portion 52, and the sensor 4 is positioned in the y direction by the standing wall portion 51. By attaching rubber to this portion by a rectangular hole 51a formed by bending the standing wall portion 51, the adhesion strength of the rubber to the sensor fixing portion 24 can be increased. FIG. 3 is a cross-sectional view illustrating a stage before compression molding using an upper mold, a lower mold, a rubber material, and a sensor assembly mold. FIG. 4 is a cross-sectional view illustrating a state in which a sensor assembly and a rubber material are interposed between an upper mold and a lower mold. This will be described with reference to FIG.

  The above-described sensor assembly 3 is sandwiched and molded with a rubber material 11 mixed with a vulcanizing agent by a mold 2 including an upper mold 9 and a lower mold 10. That is, as shown in FIG. 3, the sensor assembly 3 is sandwiched between the upper mold 9 and the lower mold 10 together with the rubber material 11 mixed with a vulcanizing agent, and the sensor assembly 3 is connected by the upper mold 9 and the lower mold 10 as shown in FIG. The upper die 9 and the lower die 10 are heated for a predetermined time with the pressure between the sensor assembly 3 and the like, and the compression molding is performed.

  In this case, if pressure is applied to the sensor assembly 3 or the like before heating, the electronic components including the sensor 4 may be damaged. Therefore, it is desirable to pressurize the rubber material 11 in a softened state by heating in advance. In other words, in the present embodiment, in the mold molding process, the upper mold 9 and the lower mold 10 are heated to soften the rubber material 11, and then pressure is applied between the upper mold 9 and the lower mold 10. Therefore, it is possible to prevent the electronic component including the sensor 4 from being pressed and damaged by the hard rubber.

  The applicable mold is not limited to a mold composed of an upper mold and a lower mold, and a mold including an upper mold and a lower mold is sufficient. In the present embodiment, the upper mold 9 and the lower mold 10 are heated for a certain period of time. However, depending on the ambient temperature, the elapsed time from the end of the previous heating, etc., only one of the upper mold 9 and the lower mold 10 is used. May be heated for a certain period of time. The heating time of the mold 2 is not limited to a continuous constant time, and can be intermittently performed.

  Further, since only a predetermined volume is formed between the upper mold 9 and the lower mold 10, a nest is generated inside the elastic member if the amount of the rubber material is small, or conversely if the rubber material is too large, the rubber material is contained in the mold 2. There is a possibility that it can not be molded well. Therefore, it is desirable to form a gap δ (see FIG. 4) through which excess rubber material 11 flows out of the mold 2 when pressure is applied to the sensor assembly 3 or the like to be pressurized.

  In the present embodiment, the upper mold 9 and the lower mold 10 are configured so that a predetermined minute gap δ is formed between the upper mold 9 and the lower mold 10 in a state where pressure is applied to a predetermined pressurization target. As a result, the excess rubber material 11 can smoothly flow out of the mold 2 when pressure is applied to the sensor assembly 3 or the like that is the object of pressurization. Therefore, it is possible to prevent the formation of a nest inside the elastic member due to the small amount of the rubber material 11. On the contrary, it is possible to prevent a problem that the rubber material 11 does not fit in the mold 2 and cannot be molded well due to the excessive amount of the rubber material 11.

  According to the rotation detection device 1 and the manufacturing method thereof according to the first embodiment described above, since the sensor assembly 3 is molded from the thermoplastic elastomer or the material 11 showing rubber elasticity, the sensor assembly 3 is subjected to vibration and external force. Even when it acts, it is possible to prevent problems such as breakage. Even when different thermal expansion occurs between the sensor assembly 3 and the elastic member 11A that is the molding material due to the environmental temperature and the self-heating of the electronic component, the difference in thermal expansion can be absorbed by the elasticity of the elastic member 11A. . Therefore, it is possible to prevent an undesired gap from being generated between the sensor assembly 3 and the elastic member 11 </ b> A, and the waterproofness of the sensor assembly 3 can be maintained. Since the molding is compression molding using a mold, a large amount of rotation detection device 1 can be manufactured by one molding. Therefore, it is possible to reduce the manufacturing cost of the rotation detection device 1 per unit time as compared with the prior art in which injection molding is performed.

  According to the rotation detection device 1 and the manufacturing method thereof, the entire sensor assembly 3 can be easily formed into a strong structure by using the fixing bracket 21 having good adhesion to the rubber material 11. Therefore, when the sensor assembly 3 and the rubber material 11 are compression-molded by the mold 2, the relative positions of the component parts of the sensor assembly 3 are not undesirably shifted, and it is possible to prevent the quality of the rotation detector 1 from being deteriorated. Become. Therefore, the yield can be improved. By using the fixing bracket 21 having good adhesion to the rubber material 11, the seal between the rubber material 11 and the fixing bracket 21 is strengthened, so that the waterproof performance is also excellent.

  The entire fixing bracket 21 that is a member for positioning the sensor 4 is made of a metal having adhesiveness to the rubber material 11 and is disposed on the fixing bracket 21 for supplying input power to the sensor 4 or for signal output. A clamp mechanism for fixing cables was constructed. As a result, the sensor 4 and the cable can be firmly integrally formed. Since a mechanism for clamping the cable is provided in a part of the fixing bracket 21, it is possible to suppress an increase in the number of parts of the apparatus, simplify the structure, and reduce the number of manufacturing steps. Therefore, it is advantageous in reducing the manufacturing cost. By mechanically holding the cable with the metal cable clamp 25, it is possible to prevent an excessive tensile force from being applied to the cable and the electric terminal 5 or sensor 4 connected to the cable when the sensor is assembled. Disconnection can be prevented in advance.

  The fixing bracket 21 allows the entire sensor assembly 3 to be constructed in a strong structure without complicating the structure of the sensor assembly 3, so that the increase in the number of parts of the entire rotation detection device can be suppressed as much as possible, and man-hours can be reduced. Become. Therefore, the manufacturing cost can be reduced.

  According to the method for manufacturing the rotation detecting device 1 described above, after the sensor assembly 3 and the rubber material 11 are interposed between the upper die 9 and the lower die 10, the upper die 9 and the lower die 10 are heated at a predetermined temperature. Since the rubber material 11 is softened and then pressure is applied between the upper die 9 and the lower die 10, the electronic component including the sensor 4 is pressed against the hard rubber (before softening) and is damaged. It can be prevented in advance. Since the upper mold 9 and the lower mold 10 are configured so that a predetermined minute gap δ is formed between the upper mold 9 and the lower mold 10 in a state where pressure is applied to the pressurizing target, the sensor assembly 3 or the like that is the pressurizing target The excess rubber material 11 can be smoothly flowed out of the mold 2 at a stage where pressure is applied to the mold 2.

  FIG. 5 is a cross-sectional view showing a state in which the rotation detection device according to the embodiment of the present invention is attached to a wheel bearing device for an automobile. In the wheel bearing device 12 of this automobile, in order to control various controls such as an anti-lock brake system (ABS) and a traction control system (TCS), the rotation detecting device 1 is included in the wheel bearing device 12. Mounted. That is, the wheel bearing device 12 includes an outer member 13, an inner member 14, a double row rolling element 15, a cage 16, a seal 17, a cover 18, a magnetic encoder 19 (may be pulsar ring), and the rotation detection device 1. Have.

  The outer member 13 is fixed to a vehicle body not shown, and the inner member 14 is attached to the wheel. Between the outer member 13 and the inner member 14, double row rolling elements 15 are interposed by a cage 16 at regular intervals in the circumferential direction to realize a hub bearing. One end of the inner member 14 and the outer member 13 in the axial direction is provided with a contact-type seal 17 such as an oil seal that seals the annular space formed between the inner member 14 and the outer member 13. ing. The magnetic encoder 19 is provided on an inner ring 20 that is a component of the inner member 14.

  A closing cover 18 is provided at one axial end of the outer member 13, and the rotation detection device 1 is attached to the cover 18 so as to face the magnetic encoder 19. The cover 18 is detachably provided with a rotation detection device main body using bolts, nuts and the like not shown in the state in which at least the sensor portion 4A of the rotation detection device 1 is fitted. In the state where the sensor portion 4A is fitted in the cover 18, the annular gap of the cover 18 that can be formed with the rotation detection device main body is tightly sealed by the elasticity of the molding material (elastic member) that covers the sensor portion 4A. It is the composition which becomes.

  Even when the wheel bearing device 12 is installed in a severe environment in which a large temperature change occurs from 100 degrees or more to minus several tens of degrees, the elastic member of the rotation detecting device 1 is elastically deformed following the temperature change. To do. Even if the wheel bearing device 12 is subjected to vibration associated with vehicle travel, the elastic member of the rotation detecting device 1 is elastically deformed following the vibration. Therefore, it is possible to prevent water or the like from entering the apparatus through the annular gap. Even in such a severe environment, in the rotation detection device 1, when different thermal expansion occurs between the sensor assembly 3 and the elastic member 11A that is the molding material, the difference in thermal expansion can be absorbed by the elasticity of the elastic member 11A. . Therefore, it is possible to prevent an undesired gap from being generated between the sensor assembly 3 and the elastic member 11A, and the waterproofness of the sensor assembly 3 itself can be maintained. Therefore, it is possible to realize a wheel bearing device that satisfies the performance required for automobile parts, such as mechanical strength, waterproofness, weather resistance, and chemical resistance.

  In the present embodiment, the rotation detection device 1 is attached to the wheel bearing device, but the fixing bracket 21 of the rotation detection device 1 can be attached to a peripheral member of the wheel bearing device. In the present embodiment, the rotation detection device 1 is opposed to the magnetic encoder 19 in the axial direction, but the rotation detection device 1 may be opposed to the magnetic encoder 19 in the radial direction. Further, in the present embodiment, for example, a double-row angular contact ball bearing type wheel bearing device for supporting a driven wheel has been described as an example. However, the present invention relates to a wheel bearing device for driving wheel support, a tapered roller, and the like. The present invention can also be applied to a wheel bearing device such as a type. Even in this case, the same effects as in the present embodiment can be obtained.

It is sectional drawing of the rotation detection apparatus which concerns on 1st embodiment of this invention. FIG. 2A is a sectional view of the sensor assembly, and FIG. 2B is a bottom view of the sensor assembly. It is sectional drawing showing the stage before the compression molding by the metal mold | die of an upper mold | type, a lower mold | type, a rubber material, and a sensor assembly. FIG. 5 is a cross-sectional view illustrating a state in which a sensor assembly and a rubber material are interposed between an upper mold and a lower mold. It is sectional drawing showing the state which attached the rotation detection apparatus which concerns on the said embodiment of this invention to the wheel bearing apparatus of a motor vehicle.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Rotation detector 2 Mold 3 Sensor assembly 4 Sensor 5 Electrode terminal 6 Cable core wire 7 Cable insulation coating 8 Cable cover 9 Upper mold 10 Lower mold 11 Rubber material 11A Elastic member 12 Wheel bearing device 21 Fixing bracket 25 Cable clamp

Claims (6)

A magnetic sensor disposed opposite to a magnet or metal provided on a rotating member;
Peripheral components electrically or mechanically connected to the magnetic sensor;
A cable clamp attached to a fixed part for positioning the magnetic sensor, and a metal cable clamp for gripping a cable electrically connected to the magnetic sensor among the peripheral parts,
A rotation detection device comprising: a fixed part including a magnetic sensor, peripheral parts, and a cable clamp, which is integrally molded with a thermoplastic elastomer or a material exhibiting rubber elasticity. 2. The rotation detecting device according to claim 1, wherein the molding is compression molding using a mold. 3. The rotation detection device according to claim 1, wherein the cable clamp and the rubber elastic material are bonded by vulcanization. The rotation detection device according to claim 1, wherein the magnetic sensor includes a Hall sensor, a magnetoresistive element, a giant magnetoresistive element, or a coil. 5. The rotation detection device according to claim 1, wherein the magnetic sensor is configured to be attachable to a wheel bearing device of an automobile. A magnetic sensor to be disposed opposite to a magnet body or metal body provided on a rotating member, peripheral parts electrically or mechanically connected to the magnetic sensor, and positioning the magnetic sensor A cable clamp attached to a fixed part, and a metal cable clamp for gripping a cable electrically connected to a magnetic sensor among the peripheral parts, together with a thermoplastic elastomer or a material exhibiting rubber elasticity A method for manufacturing a rotation detecting device, comprising a step of integrally compression-molding with a mold.

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