JP4221000B2 - Rotation sensor - Google Patents

Description

  The present invention is used to detect a rotational speed and the like, and is a spacer in which a recess is formed that is locked to the tip of a positioning pin when a cover is formed on the outer periphery of a case by injection molding in a molding die. The present invention relates to a rotation sensor having

  Conventionally, a coil formed by winding a lead wire through a cylindrical case made of resin on an iron core, a magnet provided on the iron core in contact with the iron core, and a magnet on the iron core axis. A spacer provided in contact with the cover, a cover formed by injection molding on the outer periphery of the case in the molding die, and positioning of the case in the molding die when the cover is formed by injection molding on the end surface of the spacer. When the cover is formed by injection molding, one end of the iron core comes into contact with the molding die, and the concave portion is engaged by the positioning pin provided on the molding die. There is known a rotation sensor that can be held and supported at two points of one end of the iron core and the recessed portion of the spacer to determine the position of each component of the rotation sensor in the molding die and suppress the eccentricity of the case ( For example, Patent Document 1 Irradiation).

JP-A-4-1493

  However, in this case, if the axial dimension of the case becomes longer due to the change in the specification of the rotation sensor, the dimension of the positioning pin also becomes longer.When the cover is formed by injecting resin into the molding die, As a result, a large pressure is received from the injected resin, and as a result, the positioning pin is inclined and the center axis of the case after molding is decentered.

  An object of the present invention is to solve the above-described problems. The purpose of the present invention is to make a cylindrical case longer in the axial direction, and to inject a resin into a molding die to cover the cover. Even when the positioning pin is subjected to pressure from the injected resin, the inclination of the positioning pin is reduced, so that a rotation sensor capable of suppressing the eccentricity of the central axis of the formed case is provided.

  A rotation sensor according to the present invention includes a case, an iron core provided inside the case, a coil formed by winding a conductive wire around the outer periphery of the iron core, and an axis of the iron core inside the case. A magnet that is in contact with the iron core, a spacer that is provided on the axis of the iron core inside the case and that is in contact with the anti-core side of the magnet, and an outer periphery of the case in the molding die. A cover formed by injection molding, and the spacer is formed with a recess that is locked to a tip of a positioning pin that positions the case within the molding die when the cover is formed. A cylindrical sensor that is provided on the axis of the iron core inside the case, has an end surface abutting on the non-magnet side of the spacer, and holds the positioning pin when the cover is formed. holder Those that had.

  According to the rotation sensor according to the present invention, even if the cylindrical case becomes longer in the axial direction, even if it receives pressure from the resin injected when the resin is injected into the molding die to form the cover, Since the inclination of the positioning pin is reduced, the eccentricity of the central axis of the formed case can be suppressed.

Embodiment 1 FIG.
1 is an overall cross-sectional view of the rotation sensor according to Embodiment 1, FIG. 2A is a plan view of the holder 8 of FIG. 1, FIG. 2B is a side view of FIG. 1A, and FIG. FIG. 3A is a cross-sectional view when the rotation sensor of FIG. 1 is set in the molding die 12.

  This rotation sensor is provided with a cylindrical case 1 having a bobbin portion including a small diameter portion 1a and a flange portion 1b at one end. The case 1 is a member formed primarily using a nylon 66-based synthetic resin.

  A relay terminal 2 is provided on the outer surface of the other end of the case 1. One end portion of the relay terminal 2 has a bent portion 2a bent outward in the radial direction of the case 1, and the other end portion has a connecting terminal 2b bent outward in the radial direction of the case 1. Yes.

  A coil 3 around which a conducting wire is wound is formed in the small diameter portion 1a, and the leading end of the conducting wire extends to the bent portion 2a of the relay terminal 2 and is soldered. Further, the outer surface of the relay terminal 2 is covered with a tape such as a glass cloth (not shown).

  An iron core 4 is inserted inside the small diameter portion 1a. One end portion of the iron core 4 has a flat portion 4a facing a rotation detector (not shown), and the other end portion has a large-diameter portion 4b that increases in the radial direction.

  Inside the case 1, a cylindrical magnet 5 is provided on the axis of the iron core 4 in contact with the large-diameter portion 4 b of the iron core 4. The magnet 5 is magnetized in the axial direction.

Inside the case 1, a columnar spacer 6 is provided on the axis of the iron core 4 on the side of the anti-core 4 of the magnet 5 in contact with the magnet 5.
Further, in the vicinity of the center of both surfaces of the spacer 6, when the cover 10 is formed by injection molding on the outer periphery of the case 1 in the molding die 12, it can be taken in and out on the axis of the iron core 4 in the molding die 12. Recessed portions 6a and 6b that are locked to the provided positioning pins 7 are formed.

  The spacer 6 is made of iron, which is a ferromagnetic material. By sandwiching the magnet 5 in the axial direction between the iron core 4 and the spacer 6, a magnetic circuit through which magnetic lines of force pass is formed in the iron core 4, the magnet 5, and the spacer 6. ing.

Inside the case 1, the end surface of the cylindrical holder 8 is in contact with the spacer 6 on the side opposite to the magnet 5 of the spacer 6 and is provided on the axis of the iron core 4. This holder 8 is made of a nylon 66 series synthetic resin.
In addition, as shown in FIG. 2, an uneven portion 8 a is provided on the outer peripheral surface of the holder 8 over the entire surface in the circumferential direction.

  One end of a wire harness 9 that is twisted with two stranded wires and coated with a sheath is crimped and fixed to the connection terminal 2b and soldered. A removable connector (not shown) is provided at the other end of the wire harness 9.

  Around the one end of the case 1, the relay terminal 2, the coil 3, and the wire harness 9, a cover 10 that is secondarily formed in the molding die 12 is provided. The cover 10 is made of a nylon 66 series synthetic resin.

  The hole 8b of the holder 8 and the hole 10a of the cover 10 formed by the positioning pins 7 when the cover 10 is formed in the molding die 12 are provided with a filling portion 11 filled with a potting material. .

Next, a method for forming the cover 10 of the rotation sensor according to the first embodiment will be described.
First, the relay terminal 2 and the coil 3 are attached to the case 1, and the iron core 4 is inserted into the small diameter portion 1 a of the case 1.
Next, the spacer 6 and the holder 8 are attached on the iron core 4 in this order.
Furthermore, after connecting the wire harness 9 to the connection terminal 2b, the assembly assembled as described above is put into the molding die 12.
As shown in FIG. 3, a recess 12a is formed in the molding die 12 so as to contact the flat portion 4a of the iron core 4. The flat portion 4a of the iron core 4 is in contact with the recess 12a. Yes. Further, a positioning pin 7 is provided in the molding die 12 so as to lock the recessed portion 6 a of the spacer 6, and the recessed portion 6 a of the spacer 6 is locked to the positioning pin 7.
Thus, the position of the case 1 in the molding die 12 is determined by supporting at two points of the flat part 4a and the recessed part 6a. Further, the positioning pin 7 is held by the holder 8 and the movement in the radial direction is suppressed.
Next, a synthetic resin is injected into the molding die 12.
Since the positioning pin 7 is held by the holder 8 and the movement in the radial direction is suppressed, the inclination of the positioning pin 7 can be suppressed even when the pressure of the injected synthetic resin is applied.
After the cover 10 is formed, the hole 8b of the holder 8 and the hole 10a of the cover 10 formed by the positioning pins 7 when the cover 10 is formed in the molding die 12 are filled with potting material. 11 is filled.

  As described above, according to the rotation sensor having the above-described configuration, the holder 8 holds the positioning pin 7, so that when the cover 10 is formed in the molding die 12, the positioning pin is not affected even if it receives the pressure of the injected synthetic resin. 7 can be reduced, and the central axis of the case 1 can be prevented from being eccentric.

  In addition, since the concavo-convex portion 8a is formed on the entire outer circumferential surface of the holder 8 along the circumferential direction, sink marks and warpage are reduced when the holder 8 is formed, and as a result, the cylindrical shape becomes a perfect circle. And the backlash with the inner peripheral surface of the case 1 can be reduced.

Further, since the holder 8 is made of synthetic resin, even if the axial dimension of the case 1 is changed due to the change in the specification of the rotation sensor, the outer shape of the holder 8 is changed without changing the dimension of the spacer 6. do it. As a result, it is possible to standardize the outer shape of the spacer 6 made of iron, which is a ferromagnetic material, and to reduce the cost for changing the outer shape of the rotation sensor.
Moreover, since the dimension of the holder 6 comprised from the synthetic resin whose density is small compared with iron is lengthened without changing the dimension of the spacer 6 comprised from iron, the increase in the mass of a rotation sensor can also be suppressed. it can.

  In the first embodiment, the synthetic resin has been described as nylon 66. However, the present invention is not limited to this and may be a synthetic resin such as PBT (polybutylene terephthalate).

1 is an overall cross-sectional view of a rotation sensor according to Embodiment 1. FIG. (A) is a top view of the holder of FIG. 1, (b) is a side view of (a), and (c) is a sectional view of (a). It is sectional drawing when the rotation sensor of FIG. 1 is set in a shaping die.

Explanation of symbols

  1 Case, 2 Relay terminal, 2a Bent part, 2b Connection terminal, 3 Coil, 4 Iron core, 4a Flat part, 4b Large diameter part, 5 Magnet, 6 Spacer, 6a, 6b Recessed part, 7 Positioning pin, 8 Holder, 8a Uneven portion, 8b hole, 9 wire harness, 10 cover, 10a hole, 11 filling portion, 12 molding die, 12a recessed portion.

Claims (3)

Case and
An iron core provided inside the case;
A coil formed by winding a conductive wire around the outer periphery of the iron core;
A magnet provided on the axis of the iron core inside the case and in contact with the iron core;
A spacer provided on the axis of the iron core inside the case and abutting on the anti-iron side of the magnet;
A cover formed by injection molding on the outer periphery of the case in a molding die,
In the rotation sensor in which the recess is formed in the spacer, which is locked to the tip of a positioning pin for positioning the case in the molding die when the cover is formed.
A cylindrical holder provided on the axis of the iron core inside the case, having an end surface abutting on the opposite magnet side of the spacer, and holding the positioning pin when the cover is formed, Rotation sensor.   2. The rotation sensor according to claim 1, wherein an uneven portion is formed on the outer peripheral surface of the holder over the entire surface along a circumferential direction.   The rotation sensor according to claim 1, wherein the holder is made of resin.

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