JP2008131180A - Manufacturing method for speaker, speaker, and speaker manufacturing tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To incorporate a damper, a connection member, etc., while a coil portion of a VC (voice coil) bobbin is disposed at a predetermined position for a magnetic circuit device in a driving direction of the VC bobbin. <P>SOLUTION: A manufacturing method of a speaker includes a driving-directional positioning stage of positioning a driving unit 4, which is driven through the operation of magnetic force of a magnetic circuit formed by the magnetic circuit device 8 to vibrate a diaphragm 3, in a driving direction by making a driving-directional abutting tool (first VC setting tool 16) abut in the driving direction of the driving unit 4 against the driving unit 4; and a fixing stage of fixing at least one of the damper 6 and diaphragm 3 to the driving unit 4 while the driving unit 4 is disposed at the predetermined position for the magnetic circuit device 8 in the driving-directional positioning stage. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a speaker manufacturing method, a speaker, and a speaker manufacturing jig.

Conventionally, a speaker having a configuration in which a voice coil bobbin (hereinafter referred to as a VC bobbin) around which a diaphragm and a coil are wound is connected by a connecting member (holder) is known (for example, Patent Document 1). Manufacture of such a speaker is performed as follows. First, the VC bobbin is positioned using a jig with respect to the magnetic circuit device in a direction orthogonal to the driving direction of the VC bobbin. Then, the damper is bonded and fixed to the VC bobbin and the frame with an adhesive while the jig is positioned. Next, the jig is removed and a connecting member is attached to the VC bobbin. Finally, the diaphragm is bonded and fixed to the connection member, and is also fixed to the frame via the edge. In this way, the speaker is completed.
JP-A-10-271597

  However, in the above-described speaker manufacturing method, when a damper, a connection member, or the like is attached to the VC bobbin, the VC bobbin is movable in the driving direction of the VC bobbin. For this reason, the VC bobbin moves when the damper or the connecting member is attached to the VC bobbin, and the coil part of the VC bobbin is displaced from a predetermined position with respect to the magnetic circuit device. There is a problem that installation of will be performed. As a result, even in the completed speaker, the coil portion of the VC bobbin is shifted from a predetermined mounting position with respect to the magnetic circuit device. And, since the operating point of the VC shifts in this way, it becomes difficult to convert and reproduce the acoustic energy faithfully with respect to the music signal or the like. For this reason, the speaker manufactured in this manufacturing process cannot be expanded by lowering F0 (minimum reproducible frequency) due to restrictions on damper and edge compliance, and the acoustic characteristics of the speaker are improved. It was difficult.

  Therefore, in order to solve the above-described problems, the present invention incorporates a damper, a connecting member, and the like in a state where the coil portion of the VC bobbin is positioned at a predetermined position in the drive direction of the VC bobbin with respect to the magnetic circuit device. An object of the present invention is to provide a speaker manufacturing method, a speaker, and a speaker manufacturing jig.

  In order to solve the above-described problems, a driving direction abutting jig is provided for a driving unit that is driven by the magnetic force of a magnetic circuit formed by a magnetic circuit device and vibrates a vibration plate, and the driving direction of the driving unit. In the state where the drive unit is positioned at a predetermined position with respect to the magnetic circuit device by the drive direction positioning step for positioning the drive unit in the drive direction and the drive direction positioning step, the damper or the diaphragm A fixing step of fixing at least one to the driving unit is provided.

  In addition, in addition to the above-described invention, another invention may be configured such that an orthogonal contact jig is brought into contact with the drive unit in a direction orthogonal to the drive direction of the drive unit, thereby positioning the drive unit in the orthogonal direction. The fixing step is performed in a state where the drive unit is positioned at a predetermined position with respect to the magnetic circuit device by the driving direction positioning step and the orthogonal direction positioning step.

  In addition to the above-described invention, another invention is a connection member that connects the drive unit and the diaphragm by a connection member positioning jig that is positioned in the drive direction and the orthogonal direction with respect to the orthogonal direction contact jig. Suppose that it has a connection member positioning process which positions to a drive part about a drive direction and a perpendicular direction.

  In another aspect of the invention, in addition to the above-described invention, the driving direction positioning step is performed through the driving portion abutting member of the driving direction abutting jig through the hole communicating with the driving portion formed in the magnetic circuit device. .

  In order to solve the above-described problem, the driving unit is brought into contact with the driving unit driven by the magnetic force of the magnetic circuit formed by the magnetic circuit device to vibrate the diaphragm in the driving direction of the driving unit. It is assumed that a hole through which the driving direction contact jig for positioning in the driving direction passes from the outside of the magnetic circuit device to the driving unit side is formed.

  In order to solve the above-described problem, a drive unit that is inserted through a hole formed in a magnetic circuit device of a speaker and is driven by the magnetic force of a magnetic circuit formed by the magnetic circuit device to vibrate the diaphragm. Then, by abutting in the driving direction of the driving unit, the driving unit abutting member that positions the driving unit in the driving direction and the magnetic circuit device that abuts the magnetic circuit device in a direction orthogonal to the driving direction. And a contact member.

  According to the speaker manufacturing method, the speaker, and the jig of the present invention, the coil portion of the VC bobbin is positioned at a predetermined position in the driving direction of the VC bobbin with respect to the magnetic circuit device. Can be built in.

  Hereinafter, a speaker manufacturing method, a speaker, and a speaker manufacturing jig according to an embodiment of the present invention will be described with reference to the drawings. First, the structure of the speaker 1 according to the embodiment of the present invention will be described with reference to FIG.

  FIG. 1 is a schematic view of a cross section of a speaker 1 according to an embodiment of the present invention. In FIG. 1, the arrow X direction is the direction in which the sound of the speaker 1 is emitted. Here, the explanation will be made with the arrow X direction as the upper side (upper side) and the arrow Y direction as the lower side (lower side). The speaker 1 includes a frame 2, a diaphragm 3, a voice coil (hereinafter referred to as VC) 4 as a drive unit, and a voice coil bobbin (VC bobbin) around which the VC 4 is wound. 5, a damper 6, a connecting member 7 that connects the diaphragm 3 and the VC bobbin 5, a magnetic circuit device 8 that applies an electromagnetic force to the VC 4, and the like. The connecting member 7 may be referred to as a sub cone.

  The frame 2 is made of a material having rigidity, such as metal or synthetic resin, and has a substantially truncated cone shape as a whole hollow. Various components constituting the speaker 1 such as the above-described diaphragm 3 and VC 4 are held inside the frame 2.

  The diaphragm 3 is made of resin, paper, wood, or the like, has a hollow dome shape that expands upward, and is supported by the frame 2 with the edge portion 9 as a mediating member.

  The edge portion 9 is formed by an arcuate portion 9a having an annular shape as viewed from above. That is, the arc-shaped portion 9a has an arc shape that bulges upward in the cross-sectional shape, and the inside of the arc is a hollow portion 9b. The arcuate portion 9 a is formed in an annular shape along the outer side of the peripheral edge portion 3 a above the diaphragm 3. Therefore, as described above, the edge portion 9 has an annular shape as viewed from above.

  The edge portion 9 has an outer peripheral edge portion 9c bonded and fixed to the frame 2 by bonding or the like, and an inner peripheral edge portion 9d bonded and fixed to the peripheral edge portion 3a of the diaphragm 3 by bonding or the like. As a result, the diaphragm 3 is supported with respect to the frame 2 via the edge portion 9.

  The VC bobbin 5 has a cylindrical shape having an opening in the vertical direction. The VC bobbin 5 is made of a light and rigid material such as glass fiber or synthetic resin. You may form with a metal or paper. Around the lower side of the VC bobbin 5, there is provided a VC 4 in which a conducting wire such as a metal wire is wound spirally. The VC bobbin 5 is extrapolated outside the cylindrical portion 10a disposed at the center of the yoke 10 configured as a part of the magnetic circuit device 8, and the VC 4 and the yoke 10 (cylindrical portion 10a) are connected to each other. Preventing contact. The terminal of the conducting wire which comprises VC4 is connected to the terminal part 11. FIG. The terminal portion 11 is disposed on the outer surface of the frame 2 and is covered with a terminal case 12.

  The magnetic circuit device 8 includes a yoke 10, a magnet 13, a plate 14, and the like. The yoke 10 is made of a magnetic material such as iron.

  The yoke 10 has a flange portion 10b having a circular shape when viewed from above on the lower side, and has a cylindrical portion 10a having an opening in the vertical direction at the center. The flange portion 10b and the cylindrical portion 10b are integrally formed. The yoke 10 is placed on the bottom surface portion 2 a that is the bottom surface of the frame 2. On the bottom surface portion 2a of the frame 2, a rib-like protruding portion 2b standing upward is formed in an annular shape. The inner diameter of the annular protruding portion 2b is substantially the same as the outer diameter of the flange portion 10b of the yoke 10, and the flange portion 10b just fits into the protruding portion 2b. For this reason, the yoke 10 is placed on the bottom surface portion 2a in a state where the projection portion 2b is positioned in the direction orthogonal to the vertical direction, that is, in the radial direction. In the bottom surface portion 2a, an opening 2c is formed that opens in a slightly wider range than the portion of the yoke 10 that faces the cylindrical portion 10a. Therefore, in a state where the yoke 10 is placed on the bottom surface portion 2a, the yoke 10 is not covered with the frame 2 at the opening 2c. Further, the flange portion 10b of the yoke 10 is formed with a hole portion 10c penetrating from the lower surface side of the flange portion 10b to a position along the outer peripheral surface of the cylindrical portion 10a. The holes 10c are formed at two positions that are symmetrical with respect to the cylindrical portion 10a.

  The magnet 13 is composed of a ferrite magnet, an alnico magnet, a neodymium magnet, or the like, and has a ring shape having a hole portion 13a extending vertically. The magnet 13 is placed on the upper surface 10d of the flange portion 10b with the hole portion 13a inserted through the cylindrical portion 10a of the yoke 10. The magnet 13 is positioned with respect to the yoke 10 so as to be in non-contact with a gap 13b having a uniform interval around the cylindrical portion 10a of the yoke 10. The upper surface 13c of the magnet 13 is one pole (for example, N pole), and the lower surface 13d of the magnet 13 is the other pole (for example, S pole).

  The plate 14 is made of a magnetic material such as iron, like the yoke 10, and has a ring shape having a hole portion 14a extending vertically. The plate 14 is placed on the upper surface 13 c of the magnet 13 with the hole portion 14 a inserted through the cylindrical portion 10 a of the yoke 10. The plate 14 is positioned with respect to the cylindrical portion 10a of the yoke 10 so as to be in non-contact with a gap 14b having a uniform interval around it.

  The plate 14, the magnet 13, and the flange portion 10 b of the yoke 10 are fixed to the frame 2 by screwing screws 15 penetrating them vertically to the bottom surface portion 2 a of the frame 2. Three screws 15 are arranged at equal intervals around the cylindrical portion 10a.

  The magnetic field formed by the magnetic poles on the lower surface 13 d of the magnet 13 is guided to the upper side of the cylindrical portion 10 a via the flange portion 10 b of the yoke 10. On the other hand, the magnetic field formed by the magnetic poles on the upper surface 13 c of the magnet 13 is guided to the plate 14. That is, the magnetic circuit device 8 is formed with a magnetic circuit that passes through the flange portion 10 b, the cylindrical portion 10 a, the plate 14, and the magnet 13. A strong magnetic field in one direction is formed in the gap between the outer peripheral surface of the cylindrical portion 10 a of the yoke 10 and the inner peripheral surface of the hole portion 14 a of the plate 14.

  A damper 6 is disposed above the magnetic circuit device 8. The damper 6 has an annular shape having a hole 6a at the center when viewed from above. The damper 6 is supported with respect to the frame 2 by the outer peripheral portion 6 b being bonded and fixed to the frame 2. The damper 6 is provided with two conductive wires (not shown) from the hole 6a to the outer periphery 6b. That is, the damper 6 is configured as a so-called conductive damper.

  The VC bobbin 5 inserted outside the cylindrical portion 10a of the yoke 10 is inserted into the hole 6a of the damper 6, and the inner peripheral portion of the hole 6a and the outer surface of the VC bobbin 5 are bonded and fixed. Yes. Therefore, the VC bobbin 5 is supported with respect to the frame 2 via the damper 6 while being movable in the vertical direction with respect to the cylindrical portion 10 a inserted inside the VC bobbin 5.

  The damper 6 is formed by injecting a woven fabric or the like impregnated with a phenol resin or the like into a molding die and heat molding. The damper 6 may be made of a heat resistant resin such as a polyamide resin instead of the woven fabric impregnated with a phenol resin.

  A connection member 7 is disposed above the damper 6. FIG. 2 shows the configuration of the connecting member 7 and shows a form in which the connecting member 7 is viewed obliquely from above. The connecting member 7 has an annular shape, and includes a connecting surface 7 a that fixes the diaphragm 3, and a cylindrical portion 7 b that is formed at the center of the connecting surface 7 a and opens in the vertical direction for fixing the VC bobbin 5. The connection surface 7a is formed in a bowl shape from the upper end of the cylindrical portion 7b toward the outside, and a portion connecting the connection surface 7a and the cylindrical surface 7b is an inclined surface 7c that extends upward.

  The connecting member 7 is inserted and fixed to the VC bobbin 5 by inserting the VC bobbin 5 into the cylindrical portion 7 b. The inner peripheral surface of the cylindrical portion 7b is formed by a plurality of small diameter portions 7b1 projecting toward the center and concave portions 7b2 provided between the small diameter portions 7b1. The inner peripheral diameter of the cylindrical portion 7 b of the connecting member 7 and the outer peripheral diameter of the VC bobbin 5 are set so that the cylindrical portion 7 b just fits into the VC bobbin 5.

  A diaphragm 3 is disposed above the connecting member 7. The diaphragm 3 is bonded and fixed to the connection surface 7a with an adhesive in a state where the center of the connecting member 7 and the center of the diaphragm 3 are aligned in the vertical direction. Therefore, the diaphragm 3 is supported by the frame 2 through the edge portion 9 at the peripheral edge portion 3 a and is connected to the VC bobbin 5 by the connecting member 7.

  As described above, the VC bobbin 5 is supported on the frame 2 by the damper 6, and the diaphragm 3 is also supported on the frame 2 by the edge portion 9. Further, the diaphragm 3 and the VC bobbin 5 are connected to each other. 7, the strength of the damper 6, the position where the VC 4 is disposed, and the like are set so that the VC 4 is disposed at a predetermined position of the magnetic circuit device 8.

  Next, the operation of the speaker 1 will be described.

  An electrical signal corresponding to the sound is input to the VC 4 via the terminal unit 11 from an output circuit such as an amplifier (not shown) of an audio device (not shown) outside the speaker 1. Then, VC4 receives a magnetic force from the magnetic field formed in the gap 14b between the yoke 10 and the plate 14 of the magnetic circuit device 8 in accordance with the change with time of the current of the electric signal input to the VC4. The gap 14b formed between the hole portion 14a of the plate 14 and the cylindrical portion 10a of the yoke 10 is formed at an interval at which the inner peripheral surface of the hole portion 14a does not interfere with VC4 disposed in the gap 14b. ing. Therefore, when VC4 receives a magnetic force from the magnetic field formed in the gap 14b between the yoke 10 and the plate 14 of the magnetic circuit device 8, a force that moves in the vertical direction acts on the VC4. Then, the VC bobbin 5 moves up and down by this force, and is transmitted to the diaphragm 3 connected to the VC bobbin 5 by the connecting member 7. As a result, the diaphragm 3 vibrates in the vertical direction, and the vibration of the diaphragm 3 vibrates surrounding air, thereby generating sound waves.

  Next, a method for manufacturing the speaker 1 according to the embodiment of the present invention will be described with reference to FIGS.

  First, as shown in FIG. 3, the yoke 10 is placed on the bottom surface 2 a of the frame 2. At that time, the yoke 10 is placed on the bottom surface portion 2 a so that the outer peripheral portion of the flange portion 10 b of the yoke 10 fits inside the protruding portion 2 b provided on the frame 2. The yoke 10 is positioned with respect to the direction orthogonal to the up-down direction by the protrusion 2b. Further, the magnet 13 and the plate 14 are placed on the flange portion 10b.

  The flange portion 10b of the yoke 10, the magnet 13, and the plate 14 are formed with screw holes (not shown) penetrating in the vertical direction. When the magnet 13 and the plate 14 are placed on the flange portion 10b, the magnet 13 and the plate 14 are placed on the flange portion 10b so that the respective screw holes are aligned in the vertical direction. Then, the screw 15 is passed through the screw hole (not shown), and the screw 15 is screwed to the bottom surface portion 2a of the frame 2 to fix the yoke 10, the magnet 13 and the plate 14 to the bottom surface portion 2a of the frame 2. To do.

  Note that three screw holes (not shown) are arranged at equal intervals around the cylindrical portion 10a. In addition, when the magnet 13 is fixed to the frame 2 by the screw 15 together with the yoke 10, the magnet 13 has a uniform gap 13b around the cylindrical portion 10a of the yoke 10 and is not in contact with the cylindrical portion 10a. Thus, the screw hole (not shown) of the flange portion 10b of the yoke 10 and the screw hole (not shown) of the magnet 13 are positioned with respect to each other. Similarly, the plate 14 is fixed to the frame 2 with screws 15 and has a uniform gap 14b around the cylindrical portion 10a of the yoke 10, and is not in contact with the cylindrical portion 10a. Thus, the screw hole (not shown) of the plate 14 and the screw hole (not shown) of the magnet 13 are positioned with respect to each other.

  Next, as shown in FIG. 3, the first VC setting jig 16 (see FIG. 6) as a driving direction contact jig which is a jig for positioning the VC 4 in the driving direction is attached to the magnetic circuit device 8. Install. As shown in FIG. 6, the first VC setting jig 16 is parallel to both sides sandwiching the columnar portion 16b, a base portion 16a having a disk shape, a columnar portion 16b standing at the center thereof. It has the circular-arc-shaped projection parts 16c and 16c erected, and they are comprised integrally. The protrusions 16c and 16c have the inner peripheral surfaces 16d and 16d, which are the center of curvature of the arc, opposed to the cylindrical part 16b.

  The first VC setting jig 16 configured as described above inserts the columnar portion 16b inside the inner peripheral portion 10c of the cylindrical portion 10a of the yoke 10, and the protruding portions 16c and 16c as holes of the yoke 10. The magnetic circuit device 8 is attached so as to be inserted into the gap 13b between the cylindrical portion 10a and the magnet 13 from 10c. The outer diameter of the cylindrical portion 16b and the inner diameter of the inner peripheral portion 10c of the cylindrical portion 10a are set so that the cylindrical portion 16b inserted into the inner peripheral portion 10c does not rattle in a direction perpendicular to the vertical direction. Yes. Accordingly, the cylindrical portion 16b functions as a magnetic circuit device abutting member that abuts the magnetic circuit device 8 in a direction perpendicular to the vertical direction (driving direction), and the first VC setting jig 16 serves as the magnetic circuit device. 8 is positioned in a direction perpendicular to the driving direction.

  Further, the arcs of the protrusions 16 c and 16 c are formed in the same arc as that of the VC 4 wound around the VC bobbin 5. Moreover, the space | interval between the projection part 16c and the projection part 16c is set slightly larger than the outer diameter of parts other than VC4 of the VC bobbin 5. FIG. The protrusions 16c and 16c are formed at a central angle of 30 degrees in the circumferential direction (around the cylindrical portion 16b). The holes 10c and 10c are formed in a size and shape that allow the projections 16c and 16c to be inserted therethrough.

  Next, with the second VC setting jig 17 as an orthogonal contact jig inserted in the cylinder of the VC bobbin 5, a part of the lower side of the VC bobbin 5 is connected to the cylindrical part of the yoke 10. The second VC setting jig 17 is placed on the upper end edge of the cylindrical portion 10a of the yoke 10 while being extrapolated outside the outer side 10a. As shown in FIG. 3, the second VC setting jig 17 has a cylindrical shape having an opening in the vertical direction, and a thick portion 17a is formed on the outside in the range of about 3/4 of the lower side. Has been. The upper part of the thick part 17a is formed as a thin part 17b. The outer peripheral diameter of the thick portion 17a is set so as to be fitted to the inner peripheral portion of the VC bobbin 5 without rattling. Therefore, the second VC setting jig 17 is inserted into the cylinder of the VC bobbin 5 so as to come into contact with the VC bobbin 5 in a direction orthogonal to the center line Mv.

  Subsequently, the second VC setting jig 17 placed on the cylindrical portion 10a is inserted, and the damper 6 is placed on the VC bobbin 5 partially inserted on the cylindrical portion 10a of the yoke 10. The damper 6 is inserted into the VC bobbin 5 through the hole 6a. The damper 6 is accommodated in the frame 2 in a state of being extrapolated to the VC bobbin 5. Then, the second VC setting jig 17 placed on the upper end of the cylindrical portion 10a is moved in the direction perpendicular to the center line Mv of the VC bobbin 5, and the cylindrical portion 10a of the yoke 10 and the inner surface of the VC bobbin 5 are moved. The step of positioning the VC bobbin 5 with respect to the cylindrical portion 10a is performed so that the gap distance between the cylindrical portion 10a and the cylindrical portion 10a is uniform. That is, a positioning step in a direction orthogonal to the center line Mv of VC4 is performed.

  By the way, when the VC bobbin 5 is extrapolated to the cylindrical portion 10a of the yoke 10, the lower end portion 4a of the VC 4 wound around the VC bobbin 5 is connected to the cylindrical portion 10a and the magnet 13 from the hole portion 10c of the flange portion 10b. The first VC setting jig 16 inserted into the gap 13b contacts the upper edges 16e, 16e of the protrusions 16c, 16c. That is, the VC bobbin 5 is extrapolated to the cylindrical portion 10a of the yoke 10 while being supported by the protrusions 16c and 16c. Therefore, VC4 contacts the upper end edges 16e, 16e of the protrusions 16c, 16c of the first VC setting jig 16, so that the VC4 is positioned in the vertical direction as the driving direction by the protrusions 16c, 16c. It will be in a state of being broken. In short, the first VC setting jig 16 is attached to the magnetic circuit device 8, and the lower end edge 4a of VC4 is brought into contact with the upper end edges 16e, 16e of the protrusions 16c, 16c of the first VC setting jig 16. The step of positioning the VC4 in the driving direction is performed. That is, the protrusions 16c and 16c function as a driving unit abutting member that positions the VC 4 in the driving direction. The lengths of the positioning projections 16c and 16c are such that the VC4 is positioned at a predetermined position with respect to the magnetic circuit device 8, that is, the speaker 1 is at a predetermined position with the upper end edges 16e and 16e in contact with the lower end edge 4a of the VC4. It is set to be positioned at a position where the acoustic characteristics can be exhibited.

  Since the arc shape of the protrusions 16c and 16c is the same as the arc shape of VC4, the upper end edges 16e and 16e of the protrusions 16c and 16c are in contact with the entire surface of VC4 or close to the entire surface. Therefore, VC4 and the projection parts 16c and 16c can be contact | abutted reliably. Further, as described above, the interval between the protrusion 16c and the protrusion 16c is set to be slightly larger than the outer diameter of the portion other than VC4 of the VC bobbin 5. Therefore, even when the VC bobbin 5 protrudes from the lower end edge 4a of the VC 4, the protruding portion is inserted into the gap between the cylindrical portion 10a of the yoke 10 and the protruding portions 16c and 16c. Therefore, the VC bobbin 5 at the portion protruding from the lower end edge 4a of the VC4 does not come into contact with the protrusions 16c and 16c, and the protrusions 16c and 16c reliably come into contact with the VC4. That is, the protrusions 16c and 16c are in contact with the VC4, whereby the VC4 can be accurately positioned in the vertical direction.

  As described above, the position of the VC bobbin 5 is adjusted by the second VC setting jig 17 so that the gap between the cylindrical portion 10a and the inner surface of the VC bobbin 5 is even around the cylindrical portion 10a. At the same time, the first VC setting jig 16 positions the VC4 in the driving direction at a predetermined position. In this state, the outer peripheral portion 6 b of the damper 6 is bonded and fixed to a predetermined position on the inner peripheral surface of the frame 2, and the inner peripheral surface of the hole 6 a is bonded and fixed to the outer peripheral surface of the VC bobbin 5.

  The VC4 is fixed to the magnetic circuit device 8 by attaching the damper 6 to the VC bobbin 5 in a state where the VC4 is positioned at a predetermined position with respect to the magnetic circuit device 8 by the first VC setting jig 16. Can be attached in position. Furthermore, the position of the VC bobbin 5 is positioned by the second VC setting jig 17 so that the gap between the cylindrical part 10a and the inner side surface of the VC bobbin 5 is even around the cylindrical part 10a. Thus, by attaching the damper 6 to the VC bobbin 5, the VC bobbin 5 can be attached to the cylindrical portion 10a of the yoke 10 at a predetermined position. Then, after the damper 6 is fixed to the VC bobbin 5 and the frame 2, one end of a conductive wire (not shown) provided in the damper 6 configured as a conductive damper is connected to the terminal portion of the VC4. The other end of the conductive wire (not shown) is connected to the terminal portion 11.

  Next, as shown in FIG. 4, the connecting member positioning jig 18 performs a step of positioning the connecting member 7 with respect to the VC bobbin 5 at a predetermined position in the driving direction and the orthogonal direction. Then, the connection member 7 and the VC bobbin 5 are fixed with the connection member 7 positioned at a predetermined position.

  The connecting member positioning jig 18 has a disk part 18a and two concentric ring-shaped protrusions 18b and 18c that hang down (drop in FIG. 4) with respect to the disk part 18a. The inner diameter of the protruding portion 18b is set so that the thin portion 17b of the second VC setting jig 17 just fits. That is, the connecting member positioning jig 18 has a center line with respect to the second VC setting jig 17 by the protrusion 18b coming into contact with the outer peripheral side of the thin part 17b of the second VC setting jig 17. It is positioned in a direction orthogonal to Mv.

  The other protrusion 18c is longer than the protrusion 18b, and a recess 18d for holding the connecting member 7 is formed on the inner periphery of the lower end of the protrusion 18c over the entire circumference. . The recess 18d is formed so as to hold the connection member 7 so that the peripheral portion 7c of the connection member 7 has a constant distance from the disk portion 18a.

  First, the connecting member 7 is held in the concave portion 18d of the connecting member positioning jig 18 configured as described above. Thereafter, the second VC setting jig 17 and the VC bobbin 5 are inserted into the cylindrical portion 7 b of the connecting member 7. Then, as shown in FIG. 4, the upper end portion of the thin portion 17 b of the second VC setting jig 17 is fitted inside the protruding portion 18 b of the connecting member positioning jig 18. Thereby, the connecting member positioning jig 18 can be positioned in the driving direction with respect to the VC bobbin 5 and in the direction orthogonal to the driving direction. Therefore, the connecting member 7 can be positioned with respect to the VC bobbin 5 in the driving direction and the direction orthogonal to the driving direction. Note that the length of the protrusion 18c from the disk portion 18a is set so that the connecting member 7 is positioned at a predetermined position in the vertical direction of the VC bobbin 5.

  Prior to positioning the connection member 7 held by the connection member positioning jig 18 on the VC bobbin 5, an adhesive is applied in advance to the inner peripheral surface of the cylindrical portion 7b. As a result, the connection member 7 is bonded and fixed to the VC bobbin 5 in a state where the connection member 7 is positioned on the VC bobbin 5 by the connection member positioning jig 18.

  The connecting member positioning jig 18 is connected in a state where the adhesive between the inner peripheral surface of the cylindrical portion 7b and the VC bobbin 5 is cured and the connecting member 7 is securely bonded and fixed to the VC bobbin 5. Remove from the member 7 and the second VC setting jig 17. Subsequently, the second VC setting jig 17 is extracted from the VC bobbin 5.

  Even in this state, since the first VC setting jig 16 is attached to the magnetic circuit device 8, VC4 is supported by the protrusions 16c and 16c of the first VC setting jig 16, and VC4 Is positioned at a predetermined position with respect to the magnetic circuit device 8.

  Next, as shown in FIG. 5, the diaphragm 3 is incorporated into the frame 2. Prior to mounting the diaphragm 3, the inner peripheral edge portion 9 d of the edge portion 9 is bonded and fixed to the peripheral edge portion 3 a of the diaphragm 3, and the diaphragm 3 and the edge portion 9 are configured integrally. In assembling the diaphragm 3 into the frame 2, first, an adhesive is applied to the connection surface 7 a of the connection member 7. Then, the outer peripheral edge portion 9c of the edge portion 9 bonded and fixed to the peripheral edge portion 3a of the vibration plate 3 is bonded and fixed to the frame 2 in advance, and the vibration plate is attached to the connection surface 7a to which the adhesive is applied. The lower surface of 3 is bonded and fixed. Finally, a gasket 19 is assembled around the edge portion 9 of the frame 2. The adhesive applied to the connection surface 7a is cured, the adhesive between the outer peripheral portion of the edge portion 9 and the frame 2 is also cured, and the diaphragm 3 is reliably supported with respect to the connection member 7 and the frame 2 Then, the first VC setting jig 16 is removed from the magnetic circuit device 8. Thereby, the speaker 1 is completed.

  According to the manufacturing method described above, the components constituting the speaker 1 such as the damper 6 and the diaphragm 3 are obtained in a state where the VC 4 is positioned at a predetermined position with respect to the magnetic circuit device 8 by the first VC setting jig 16. Can be assembled.

  Further, a hole 10c through which the protrusions 16c and 16c are inserted is formed in the flange portion 10b of the yoke 10. For this reason, the VC4 can be easily positioned in the driving direction simply by passing the protrusions 16c and 16c through the hole 10c and bringing the protrusions 16c and 16c into contact with the VC4.

  Sound is output from the speaker 1 by inputting an electrical signal related to sound to the terminal portion 11 of the speaker 1 manufactured as described above.

  In this embodiment, with the VC bobbin 5 positioned by the first VC setting jig 16, the damper 6 is bonded and fixed to the VC bobbin 5, and the diaphragm 3 is bonded and fixed to the connecting member 7. ing. However, if the predetermined position in the vertical direction (driving direction) of the VC 4 can be maintained only by the rigidity of the damper 6, the first VC setting jig 16 is magnetically attached when the damper 6 is bonded and fixed to the VC bobbin 5 and the frame 2. The diaphragm 3 may be removed from the circuit device 8, and thereafter, the diaphragm 3 may be bonded and fixed to the connection member 7. Further, in a speaker without the damper 6, the diaphragm 3 is bonded and fixed to the connecting member 7 with the VC bobbin 5 supported by the first VC setting jig 16.

  The first VC setting jig 16 has two protrusions 16c and 16c in the present embodiment, but may be three or more. In this case, the VC bobbin 5 can be stably supported by arranging the plurality of protrusions at equal intervals around the center line Mv. Further, by setting the size and shape of the protrusions 16c, 16c and the holes 10c, 10c so that the protrusions 16c, 16c are inserted through the holes 10c, 10c without any difficulty, the cylindrical part 16b. The first VC setting jig 16 can be positioned with respect to the magnetic circuit device 8 in the direction orthogonal to the driving direction.

  The present invention can be used for speakers used in audio equipment and the like.

It is a section schematic diagram of a speaker concerning an embodiment of the invention. It is a perspective view which shows the connection member of the speaker shown in FIG. It is a figure explaining the manufacturing method of the speaker concerning an embodiment of the invention, and is a figure showing the state where the 1st VC setting jig and the 2nd VC setting jig were installed. It is a figure explaining the manufacturing method of the speaker which concerns on embodiment of this invention, and is a figure which shows the state which attaches a connection member to a VC bobbin with a connection member positioning jig. It is a figure explaining the manufacturing method of the speaker concerning an embodiment of the invention, and is a figure showing the state where a diaphragm is adhered and fixed to a connection member. It is a perspective view showing the 1st VC setting jig concerning an embodiment of the invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Speaker 3 ... Diaphragm 4 ... VC (drive part)
6 ... damper 7 ... connecting member 8 ... magnetic circuit device 10c ... hole 16 ... first VC setting jig (driving direction contact jig)
16b ... Cylindrical part (magnetic circuit device contact member)
16c: Projection (drive unit contact member)
17 ... 2nd VC setting jig (orthogonal contact jig)
18 ... Connection member positioning jig

Claims (6)

By abutting a driving direction abutting jig in the driving direction of the driving unit against a driving unit driven by the magnetic force of a magnetic circuit formed by the magnetic circuit device and vibrating the diaphragm, A driving direction positioning step for positioning the driving unit in the driving direction;
A fixing step of fixing at least one of the damper and the diaphragm to the driving unit in a state where the driving unit is positioned at a predetermined position with respect to the magnetic circuit device by the driving direction positioning step;
A method for manufacturing a speaker, comprising: An orthogonal direction positioning step of positioning the drive unit in the orthogonal direction by bringing the orthogonal contact jig in contact with the drive unit in a direction orthogonal to the drive direction of the drive unit;
Performing the fixing step in a state where the driving unit is positioned at a predetermined position with respect to the magnetic circuit device by the driving direction positioning step and the orthogonal direction positioning step;
The method for manufacturing a speaker according to claim 1.   A connection member that connects the drive unit and the diaphragm to the drive unit by a connection member positioning jig that is positioned in the drive direction and the orthogonal direction with respect to the orthogonal direction contact jig. The speaker manufacturing method according to claim 2, further comprising a connecting member positioning step for positioning the driving direction and the orthogonal direction.   4. The drive direction positioning step is performed by passing a drive unit contact member of the drive direction contact jig through a hole communicating with the drive unit formed in the magnetic circuit device. 5. A method for manufacturing the speaker according to claim 1.   Positioning of the driving unit in the driving direction is performed by contacting the driving unit driven by the magnetic force of the magnetic circuit formed by the magnetic circuit device and vibrating the diaphragm in the driving direction of the driving unit. A speaker having a hole through which a driving direction abutting jig to be passed from the outside of the magnetic circuit device to the side of the driving unit is formed.   This drive unit is driven against a drive unit that is inserted through a hole formed in the magnetic circuit device of the speaker and driven by the magnetic force of the magnetic circuit formed by the magnetic circuit device to vibrate the diaphragm. A driving unit abutting member that positions the driving unit in the driving direction by abutting in a direction; and a magnetic circuit device abutting member that abuts the magnetic circuit device in a direction orthogonal to the driving direction. A speaker manufacturing jig.

Images