JP5703970B2 - Velocity detector in eddy current type instrument. - Google Patents

Description

  The present invention relates to an eddy current type instrument provided with a speed detection device.

  A speed detecting device in a conventional eddy current type instrument includes a rotating shaft that transmits rotation of a vehicle wheel pivotally attached to a frame of the eddy current type instrument, a magnet provided at an upper end of the rotating shaft, A pointer shaft that is disposed on the frame and changes its angle in proportion to the rotation speed of the rotary shaft, a mustache spring that controls the rotation of the pointer shaft, and a magnet that is provided below the pointer shaft and is disposed through a small clearance. An eddy current type instrument comprising an induced plate provided with a magnetoelectric conversion element provided in the magnetic circuit of the magnet (for example, see Patent Document 1).

Japanese Utility Model Publication No. 63-88752

  Conventionally, the structure for fixing the magnetoelectric conversion element to the frame is a circuit in which a mounting plate is screwed to the frame, a case made of an insulating material is screwed to the mounting plate, and the magnetic detection element is mounted on the case The structure is such that the board is fastened with screws, and the number of parts is complicated and the cost is high. Further, since the number of parts is large, there is a problem that the position of the magnetoelectric transducer varies due to the assembly accuracy and it is difficult to maintain stable detection accuracy.

  Therefore, the present invention has been made in view of such problems, and an object of the present invention is to reduce the cost by reducing the number of parts and to provide an eddy current type instrument capable of maintaining stable detection accuracy. An object of the present invention is to provide a speed detection device.

  A speed detecting device in an eddy current type instrument of the present invention fixes a magnet rotor that rotates with a main shaft, a rotor that rotates as the magnet rotor rotates, a pointer shaft that is fixed to the rotor and on which a pointer is mounted, and a main shaft. And an eddy current type instrument comprising a magnet rotor and a frame on which the rotor is disposed, a magnetic detection element provided in the vicinity of the magnet rotor, a circuit board on which the magnetic detection element is disposed, and the circuit board. A holder for holding the frame, and the holder is provided with a pair of arm pieces, each of which is fixed to the frame body via first and second screws, and the first piece. The magnetic detection element is positioned on a line connecting the mounting position by the second screw and the mounting position by the second screw.

  In the eddy current measuring instrument according to the present invention, the height of the magnet rotor in the rotational axis direction differs between the mounting position by the first screw and the mounting position by the second screw.

  Further, in the eddy current type instrument according to the present invention, the speed detecting device is different in that the position of the mounting position by the first screw and the position of the mounting position by the second screw are perpendicular to the rotation axis of the magnet rotor. It is.

  ADVANTAGE OF THE INVENTION According to this invention, the speed detection apparatus in the eddy current type meter which can reduce the cost by reduction of a number of parts, and can maintain the stable detection accuracy can be provided.

The side view of the speed detection apparatus in the eddy current type meter which concerns on 1st Embodiment of this invention. The principal part front view of the speed detection apparatus in the eddy current type instrument which concerns on the same embodiment. Sectional drawing of the AA line of FIG. Sectional drawing of the BB line of FIG. The perspective view of a holder.

  Hereinafter, a first embodiment of a speed detection device W in an eddy current type instrument C according to the present invention will be specifically described with reference to the accompanying drawings.

  The eddy current type instrument C of the present embodiment includes a main shaft 1, a magnet rotor 2, a rotor 3, a pointer 4, a pointer shaft 5, and a frame body 6. The speed detection device W includes a magnetic detection element 7, a circuit board 8, and a holder 9. The speed detection device W is fixed to the eddy current type instrument C with screws 10.

  The main shaft 1 transmits the rotation of the vehicle wheel transmitted via a flexible cable (not shown) to the magnet rotor 2. The frame body 6 is rotatably supported by a bottom wall, which will be described later, via a cylindrical body 1a and a bearing member 1b.

  The magnet rotor 2 includes a magnet 2a, a ring-shaped soft magnetic body 2b facing the magnet 2a, and a nonmagnetic cover 2c that holds the soft magnetic body 2b. The magnet rotor 2 is fixed to the upper end of the main shaft 1.

  The rotor 3 is disposed via a magnet 2a of the magnet rotor 2 and a small clearance. The rotor 3 is rotated by an eddy current action generated by the rotation of the magnet rotor 2, and generates a rotational torque proportional to the rotational speed of the magnet rotor 2. In the center of the rotor 3, a pointer shaft 5 for mounting the pointer 4 is provided.

  The pointer 4 is press-fitted and fixed to the upper end of the pointer shaft 5 and rotates together with the pointer shaft 5 mounted on the rotor 3 to display the speed of the vehicle.

  The pointer shaft 5 is provided with a later-described plate of the frame 6, and is pivotally supported by an upper bearing (not shown) of the plate and a lower bearing 1 c provided at the center of the upper end of the main shaft 1. The inner end of the beard spring 11 is fixed at a position below the center of the pointer shaft 5, and the outer end is fixed to the beard holding 12 provided on the plate.

  The frame 6 is made of a metal material such as a cold-rolled steel plate (for example, SPCC), and the cross-sectional shape having two side walls 6a and a bottom wall 6b is substantially U-shaped, and is formed at the upper ends of the two side walls 6a. A plate 6c is installed. The frame 6 holds each component such as the main shaft 1, the magnet rotor 2, and the rotor 3.

  The magnetism detecting element 7 is positioned between the magnet rotor 2 and the bottom wall 6b of the frame 6 in the vicinity of the magnet rotor 2, in this embodiment, so as to oppose the lower surface of the magnet rotor 2. It is mounted on the circuit board 8 so that the detection surfaces face each other. The magnetic detection element 7 is disposed on the frame body 6 via the holder 9. The magnetic detection element 7 detects a change in the magnetic field accompanying the rotation of the magnet rotor 2, converts the change in the magnetic field into an electric signal, and this electric signal is installed in a control device (engine control unit: Hereinafter, this is output to the ECU).

  The circuit board 8 is mounted with a magnetic detection element 7 and electronic components (not shown) such as a resistor and a capacitor that protect the magnetic detection element 7 from external noise and the like, and is connected to the ECU via an electric cord (not shown). The The circuit board 8 is fixed to the holder 9 with screws 9i.

  The holder 9 connects the base portion 9a, first and second arm pieces 9b and 9c provided at both ends of the base portion 9a, and the base portion 9a and the first and second arm pieces 9b and 9c. It is comprised by the standing parts 9d and 9e. The arm pieces 9b and 9c are fixed to the side wall 6a of the frame 6 with the first and second screws 10a and 10b. The standing portions 9 d and 9 e are also in contact with the side wall 6 a of the frame body 6, and the frame body 6 is less likely to be displaced with respect to the holder 9 when being fixed with the screws 10 a and 10 b.

  On the lower side of the base portion 9a, a step portion 9f that rides on the bottom wall 6b of the frame body 6 is formed. The base portion 9a is provided with two pins 9g as positioning members for determining the mounting position of the circuit board 8. The pin 9g penetrates the hole provided in the circuit board 8, so that the mounting position of the circuit board 8 with respect to the base portion 9a can be determined.

  The first arm piece 9b is lower than the second arm piece 9c, for example, in the direction of the rotation axis of the magnet rotor 2, as shown in FIGS. 4, the first arm piece 9b is longer than the second arm piece 9c, that is, perpendicular to the longitudinal direction of the base portion 9a and with respect to the rotation axis direction of the magnet rotor 2. It is formed long in the vertical direction. Each arm piece 9b, 9c is provided with a hole 9h through which each screw 10 passes.

  The holder 9 is arranged on the frame body 6 so that the magnetic detection element 7 is positioned on a line L connecting the attachment position X by the first screw 10a and the attachment position Y by the second screw 10b.

  The height in the rotation axis direction of the magnet rotor 2 is different between the mounting position X by the first screw 10a and the mounting position Y by the second screw 10b.

  Further, the attachment position X by the first screw 10a and the attachment position Y by the second screw 10b are different in the position in the direction perpendicular to the rotation axis of the magnet rotor 2.

  With the configuration described above, it is possible to reduce costs by reducing the number of parts and maintain stable detection accuracy. Also, the rotation axis when turning the first screw 10a and the rotation axis when turning the second screw 10b are not aligned on the same straight line, that is, the first screw 10a and the second screw 10b are The displacement of the magnetic detection element 7 due to the rotation of the screws 10a, 10b for tightening the screws when the holder 9 is fixed to the frame 6 can be suppressed, and the distance between the magnetic detection element 7 and the magnet rotor 2 is always constant. Therefore, it is possible to detect the speed stably in quality.

  Further, since the standing portions 9d and 9e are provided, the holder 9 comes into contact with the side wall 6a of the frame 6 with respect to the frame body 6 and the side wall 6a of the frame body 6 comes into contact with the screws. Displacement in the rotational direction due to the rotation of the holder 9 that occurs can be suppressed.

  Further, the position of the magnetic detection element 7 provided on the circuit board 8 is arranged on a line L connecting the two screws 10a and 10b for fixing the holder 9 to the frame body 6, so that the screws 10a and 10b Even if the holder 9 is rotated along with the rotation, since the magnetic detection element 7 is arranged on the rotation shafts of the screws 10a and 10b, the displacement of the magnetic detection element 7 can be suppressed, and stable magnetic detection accuracy is achieved. It is possible to provide a velocity detection device in an eddy current type instrument that can maintain the above.

DESCRIPTION OF SYMBOLS 1 Main shaft 2 Magnet rotor 3 Rotor 4 Pointer 5 Pointer shaft 6 Frame 7 Magnetic detection element 8 Circuit board 9 Holder 9b, 9c Arm piece 9d, 9e Standing part 10a First screw 10b Second screw C Eddy current type instrument W Speed detector X, Y Mounting position

Claims (3)

A magnet rotor that rotates together with the main shaft, a rotor that rotates as the magnet rotor rotates, a pointer shaft that is fixed to the rotor and on which the pointer is mounted, and a frame that fixes the main shaft and places the magnet rotor and the rotor. In the eddy current type instrument provided, comprising: a magnetic detection element provided in the vicinity of the magnet rotor; a circuit board on which the magnetic detection element is disposed; and a holder for holding the circuit board on the frame, The holder is provided with a pair of arm pieces, and each arm piece is fixed to the frame body via first and second screws, and the attachment position by the first screw and the attachment by the second screw. Velocity detecting device in an eddy current type instrument, wherein the magnetic sensing element is located on a line connecting the positions 2. The speed detection device for an eddy current type instrument according to claim 1, wherein a height of the magnet rotor in a rotation axis direction is different between an attachment position by the first screw and an attachment position by the second screw. . 3. The eddy current type according to claim 1, wherein an attachment position by the first screw and an attachment position by the second screw are different from each other in a direction perpendicular to a rotation axis of the magnet rotor. Speed detection device in the instrument.

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