JP6111751B2 - Electronic device and manufacturing method thereof - Google Patents

Description

  The present invention relates to an electronic device and a manufacturing method thereof, and more particularly, to an electronic device including a cord for electrically connecting to an external device and having a sealing resin formed inside a case member, and a manufacturing method thereof.

  Japanese Patent Application Laid-Open No. 09-092105 (Patent Document 1) discloses a proximity sensor that includes a case member that accommodates an electronic component, and the inside of the case member is resin-sealed. A cord is inserted through an opening provided in the case member. The cord is connected to an electronic component disposed inside the case member. In order to prevent the resin from entering the sheath of the cord when the case member is filled with the resin, the resin is integrally formed in a ring shape at the end of the cord.

JP 09-092105 A

  The present invention relates to an electronic device including a ring cord having a ring member formed at an end thereof and having a sealing resin formed inside the case member, and a method for manufacturing the electronic device, which improves water resistance of the electronic device. Objective.

  An electronic apparatus according to the present invention has an opening, a case member that accommodates an electronic component, a ring cord that is inserted through the opening, and an inside of the case member between the case member and the ring cord. The ring cord has a core wire and a covering material that covers the core wire, and the core wire extends from an end portion in the longitudinal direction of the covering material toward the electronic component. A cable that is electrically connected to a component, and a ring member that is formed so as to cover the end of the covering material by injection molding and has a shape corresponding to the opening. The end portion and the ring member are welded to each other.

Upper Symbol ring member, form positioned within mold gate is less -1.5mm or + 1.5 mm of the end portion of the covering member as a reference in the longitudinal direction of the covering material for the injection molding It has been done.

  Preferably, in the ring member, the molding gate for the injection molding is located within a range of −1.0 mm or more and +1.0 mm or less with respect to the end portion of the coating material in the longitudinal direction of the coating material. Is formed.

  Preferably, the coating material has a hardness (shore A) of 85 or less. Preferably, the covering material includes polyvinyl chloride. Preferably, the resin part includes a thermoplastic resin part having a hardness (shore D) of 60 or less.

  Preferably, the ring member has a concave portion formed by supporting the covering material on a convex portion of a mold during the injection molding, and the concave portion is formed by the injection molding in the longitudinal direction. The core wire is located on the opposite side of the direction in which the core wire extends toward the electronic component from the position of the injection port of the molding gate used at the time.

  Preferably, the concave portion has a portion overlapping the injection port when the concave portion is virtually projected toward the injection port of the molding gate along the longitudinal direction.

  Preferably, the ring member includes at least one selected from the group consisting of polybutylene terephthalate, polyethylene terephthalate, polycarbonate, and polyamide.

  An electronic device manufacturing method according to the present invention includes a case member having an opening and accommodating an electronic component, a ring cord inserted through the opening, and the case member between the case member and the ring cord. The ring cord includes a core wire and a covering material that covers the core wire, and the core wire extends from an end portion in the longitudinal direction of the covering material. A ring member including a cable extending toward the electronic component and electrically connected to the electronic component, and having a shape corresponding to the opening so as to cover the end of the covering material by injection molding; A step of welding the end of the covering material and the ring member to each other.

Forming gates for the upper Symbol injection molding, in the longitudinal direction of the covering member is located within said end range of -1.5mm or + 1.5 mm or less, based on the above coating material.

  Preferably, the molding gate for the injection molding is located within a range of −1.0 mm or more and +1.0 mm or less with respect to the end portion of the coating material in the longitudinal direction of the coating material. .

  According to the present invention, there are provided an electronic device including a ring cord having a ring member formed at an end thereof, and a sealing resin formed inside the case member, and a method for manufacturing the electronic device, which improves the water resistance of the electronic device. It becomes possible.

It is a perspective view which shows the proximity sensor in embodiment. It is a perspective view which shows the state which the proximity sensor in embodiment disassembled. It is arrow sectional drawing along the III-III line in FIG. FIG. 4 is a cross-sectional perspective view corresponding to FIG. 3. It is arrow sectional drawing along the VV line in FIG. FIG. 6 is a cross-sectional perspective view corresponding to FIG. 5. It is sectional drawing which expands and shows the vicinity of the detection coil part with which the proximity sensor in embodiment is equipped. It is a perspective view which shows typically the internal structure of the detection coil part with which the proximity sensor in embodiment is equipped. It is a 1st perspective view which shows the ring cord used for the proximity sensor of embodiment. It is a 2nd perspective view which shows the ring cord used for the proximity sensor of embodiment. It is a perspective view which shows the ring member of the ring cords used for the proximity sensor of embodiment. It is arrow sectional drawing along the XII-XII line | wire in FIG. It is sectional drawing which shows a mode when the ring cord used for the proximity sensor of embodiment is manufactured. It is sectional drawing which shows a mode when the ring cord which concerns on a comparative example is manufactured. It is sectional drawing which shows a mode when the ring cord which concerns on another comparative example is manufactured. It is a perspective view which shows a mode when the ring cord used for the proximity sensor of embodiment is manufactured. It is a figure which shows the 1st process of the manufacturing method of the proximity sensor in embodiment. It is a figure which shows the 2nd process of the manufacturing method of the proximity sensor in embodiment. It is a figure which shows the 3rd process of the manufacturing method of the proximity sensor in embodiment. It is a figure which shows the 4th process of the manufacturing method of the proximity sensor in embodiment. It is a figure which shows the 5th process of the manufacturing method of the proximity sensor in embodiment. It is a figure which shows the 6th process of the manufacturing method of the proximity sensor in embodiment. It is sectional drawing for demonstrating the effect | action and effect of a proximity sensor in embodiment. It is other sectional drawing for demonstrating the effect | action and effect of a proximity sensor in embodiment. It is a figure which shows the experimental condition and result of Experimental example 1 performed regarding embodiment. It is a figure which shows the experimental condition and result of Experimental example 2 performed regarding embodiment.

  Embodiments and examples based on the present invention will be described below with reference to the drawings. In the description of the embodiments and examples, when the number and amount are referred to, the scope of the present invention is not necessarily limited to the number and amount unless otherwise specified. In the description of the embodiments and the respective examples, the same reference numerals are assigned to the same parts and corresponding parts, and redundant description may not be repeated.

[Embodiment]
(overall structure)
With reference to FIGS. 1-8, the whole structure of the proximity sensor 510 in embodiment is demonstrated. FIG. 1 is a perspective view showing the proximity sensor 510. FIG. 2 is a perspective view showing the proximity sensor 510 in an exploded state. 3 is a cross-sectional view taken along the line III-III in FIG. FIG. 4 is a cross-sectional perspective view corresponding to FIG. FIG. 5 is a cross-sectional view taken along the line VV in FIG. 6 is a cross-sectional perspective view corresponding to FIG. FIG. 7 is an enlarged cross-sectional view showing the vicinity of the detection coil unit 210 provided in the proximity sensor 510. FIG. 8 is a perspective view schematically showing the internal structure of the detection coil unit 210 provided in the proximity sensor 510.

  Referring to FIGS. 1 to 8, proximity sensor 510 (FIG. 1) is an inductive proximity sensor that generates a magnetic field in a detection region to detect the approach or presence of a detection target. The detection target detected by the proximity sensor 510 is a conductive object. The detection target detected by the proximity sensor 510 is typically a magnetic metal such as iron, but may be a nonmagnetic metal such as copper or aluminum.

  The proximity sensor 510 has an appearance that extends in a cylindrical shape along the virtual central axis 102 (FIGS. 3 and 5). The proximity sensor 510 includes a detection coil unit 210 (FIGS. 3, 5, 7, and 8), a front cover 20 (coil case) (FIGS. 2, 3, 5, 7, and 8), a print A substrate 50, a base metal fitting 60, a clamp 80, and a ring cord 70 are provided.

  The detection coil unit 210 is provided as a detection unit that detects the approach or presence of a detection target. The detection coil unit 210 generates a magnetic field. The detection coil unit 210 is provided on the front end side of the proximity sensor 510 that faces the detection region. The detection coil unit 210 is a combination of the core body 40, the electromagnetic coil 36 (FIGS. 7 and 8), the coil spool 30 (FIGS. 2, 7 and 8), and the coil pin 46 (FIGS. 7 and 8). It is configured.

  The core body 40 is made of a material having good high frequency characteristics, for example, ferrite. The core body 40 has a function of enhancing the coil characteristics of the detection coil unit 210 and concentrating the magnetic flux in the detection region. The electromagnetic coil 36 is a coil wire and is wound around the coil spool 30. The electromagnetic coil 36 is wound around the central axis 102. The central axis 102 is also a winding central axis of the electromagnetic coil 36.

  The coil spool 30 (spool body) is formed from a resin having electrical insulation. The coil spool 30 is accommodated in a core body 40 and an annular groove formed in the core body 40. The coil pin 46 is made of a conductive metal. The coil pin 46 is supported by the coil spool 30. The coil pin 46 has a shape that extends from the detection coil unit 210 toward the printed circuit board 50. The extending end of the coil pin 46 is connected to a pattern 50P (see FIG. 8) formed on the printed board 50 using solder (not shown).

  A distal end 37 (FIGS. 7 and 8) of the electromagnetic coil 36 drawn from the outer periphery of the coil spool 30 is wound around the root portion of the coil pin 46 extending from the detection coil portion 210. The electromagnetic coil 36 and the printed board 50 are electrically connected to each other via a coil pin 46 and solder (not shown).

  The detection coil unit 210 is accommodated in the front cover 20 (coil case). The front cover 20 is made of resin. The front cover 20 is made of a thermoplastic resin. The front cover 20 is formed of a material having good adhesiveness with a thermoplastic resin forming the thermoplastic resin portion 122, such as PBT (polybutylene terephthalate). The front cover 20 is provided as a front end cover that houses the detection coil unit 210. The front cover 20 closes the front end of the base metal fitting 60 having a cylindrical shape. The front cover 20 is mainly provided to shield and protect the detection coil unit 210 from the external atmosphere.

  The front cover 20 has a bottomed cylindrical shape. The front cover 20 extends in a cylindrical shape around the central axis 102 and is closed at one end and opened at the other end. An end surface of the front cover 20 on the closed end side constitutes a detection surface of the proximity sensor 510.

  The printed circuit board 50 has a long flat plate shape. The printed circuit board 50 extends with the axial direction of the central axis 102 as the longitudinal direction. Various types of electronic components (not shown) such as transistors, diodes, resistors, and capacitors are mounted on the printed circuit board 50. The electronic components include those that are electrically connected to the detection coil unit 210. A light emitting diode (LED) (not shown) is mounted on the printed circuit board 50. The light emitting diodes are provided on the front and back surfaces of the printed circuit board 50 and function as a light emitting unit for notifying the detection state.

  The base metal fitting 60 is provided as a main body case that houses electronic components such as transistors, diodes, resistors, and capacitors. The base metal fitting 60 forms an outline of the proximity sensor 510 on the outer periphery of the central shaft 102. The base metal fitting 60 has a shape extending in a cylindrical shape around the central axis 102. The base metal fitting 60 is opened at both ends extending along the central axis 102. The front cover 20 is fixed to the base metal fitting 60 by being inserted inside one open end of the base metal fitting 60. The inner diameter of the base metal fitting 60 is, for example, 5 mm, preferably 5 mm or more.

  The base metal fitting 60 is made of metal. A screw used to fix the proximity sensor 510 to an external facility is formed on the outer surface of the base metal fitting 60. Proximity sensor 510 in the embodiment is a so-called shield type proximity sensor, and metal base fitting 60 is arranged on the outer periphery of detection coil unit 210. The proximity sensor 510 may be applied to a so-called non-shielded proximity sensor in which the metal base fitting 60 is disposed at a position shifted in the axial direction of the central shaft 102 from the outer periphery of the detection coil unit 210.

  The clamp 80 is provided as a connection member connected to the base metal fitting 60 from the rear end side of the proximity sensor 510. The clamp 80 is connected to the rear end of the base metal fitting 60 having a cylindrical shape. The clamp 80 is inserted inside the rear end of the base metal fitting 60. The clamp 80 has an opening 82, is integrated with the base metal fitting 60, and extends in a cylindrical shape around the central axis 102. The base metal fitting 60 and the clamp 80 constitute a cylindrical case 310 that extends in a cylindrical shape around the central axis 102. The cylindrical case 310 accommodates the printed circuit board 50 and electronic components mounted on the printed circuit board 50.

  The light emitting diode mounted on the printed circuit board 50 is positioned inside the clamp 80. The clamp 80 is made of resin. The clamp 80 is made of a transparent or translucent resin so that the light emission of the light emitting diode can be visually recognized from the outside of the proximity sensor 510. The clamp 80 is made of polyamide, for example. A gate 81 is formed in the clamp 80. The gate 81 is provided as a through hole for injecting resin into the cylindrical case 310 when the proximity sensor 510 is manufactured.

  The ring cord 70 has an internal conductor (not shown), and one end thereof is electrically connected to the printed circuit board 50 inside the cylindrical case 310. The ring cord 70 is inserted through the opening 82 of the clamp 80, and the other end is drawn out from the rear end side of the cylindrical case 310. The ring cord 70 is provided as a rear end cover that closes the rear end of the cylindrical case 310.

  The ring cord 70 has a cable 71 and a ring member 72. The ring member 72 is provided so as to cover the end of the cable 71. The ring member 72 is made of a thermoplastic resin including at least one selected from the group consisting of polybutylene terephthalate (PBT), polyethylene terephthalate (PET), polycarbonate (PC), and polyamide (PA). Further details of the ring cord 70 will be described later with reference to FIGS.

  Inside the cylindrical case 310, a sealing resin 120 (see FIG. 7) is formed by resin filling. In the proximity sensor 510, the cylindrical case 310 and the front cover 20 constitute a case member that accommodates the detection coil unit 210 and the printed board 50. The sealing resin 120 is provided so as to fill a space in the case member surrounded by the cylindrical case 310 and the front cover 20 and the ring cord 70 that close the front and rear ends thereof. The sealing resin 120 closes the space between the case member and the ring cord 70 from the inside of the case member, and the detection coil unit 210 accommodated in the front cover 20, the printed circuit board 50 accommodated in the cylindrical case 310, and the electronic component Is sealed.

(Sealing resin 120)
The sealing resin 120 includes a thermosetting resin part 121 and a thermoplastic resin part 122. The thermosetting resin part 121 is made of a thermosetting resin and seals the detection coil part 210 (the core body 40, the electromagnetic coil 36, and the coil spool 30). The thermoplastic resin portion 122 is formed of a thermoplastic resin in a portion of the case member (the cylindrical case 310, the ring cord 70, and the front cover 20) where the thermosetting resin portion 121 is not formed. The substrate 50 and the electronic component are sealed. As the thermoplastic resin used for forming the thermoplastic resin portion 122, a resin having a hardness (shore D) of 60 or less is selected as will be described later in detail.

  The thermosetting resin portion 121 and the thermoplastic resin portion 122 are provided so as to form a boundary inside the front cover 20 indicated by a two-dot chain line 101 in FIGS. Referring to FIG. 8, thermosetting resin portion 121 is formed on the side indicated by arrow AR121 when viewed from two-dot chain line 101, and heat is applied on the side indicated by arrow AR122 when viewed from two-dot chain line 101. A plastic resin portion 122 is formed.

  The thermosetting resin portion 121 seals at least the core body 40, the electromagnetic coil 36, and the coil spool 30 and also seals a part of the coil pin 46 (portion on the root side of the coil pin 46). A portion of the coil pin 46 that is not sealed by the thermosetting resin portion 121 is sealed by the thermoplastic resin portion 122. A portion of the coil pin 46 that extends further than the portion around which the tip 37 of the electromagnetic coil 36 (coil wire) is wound (on the side of the tip 46J) is sealed with the thermoplastic resin portion 122 (FIG. 7). reference). A portion of the coil pin 46 soldered to the pattern 50 </ b> P of the printed circuit board 50 is sealed with a thermoplastic resin portion 122. Not limited to this configuration, the portion of the coil pin 46 that extends further than the portion around which the tip 37 of the electromagnetic coil 36 (coil wire) is wound (the side of the tip 46J) is sealed by the thermosetting resin portion 121. It may be stopped. In this case, a portion of the coil pin 46 soldered to the pattern 50 </ b> P of the printed board 50 is sealed with the thermosetting resin portion 121.

  The thermoplastic resin used for forming the thermoplastic resin portion 122 is preferably one that can be molded at a low temperature and low pressure, and includes at least one selected from the group consisting of polyolefin, polyester, and polyamide. The thermoplastic resin used for forming the thermoplastic resin portion 122 may include various additives such as a flame retardant, an organic / inorganic filler, a plasticizer, a colorant, and an antioxidant. By using a thermoplastic resin having a hardness (shore D) of 60 or less, it is possible to reduce stress on the internal equipment due to heat and pressure when filling the resin, there is no need for reaction curing, and the process tact time is shortened. You can also.

  As a molding machine that can be filled with the thermoplastic resin that forms the thermoplastic resin portion 122, it is preferable that the resin filling pressure can be arbitrarily adjusted within a range of 0.1 MPa to 10 MPa. From the viewpoint of the resin filling property to the structural details of the proximity sensor 510, the resin filling pressure may be set to 0.1 MPa or more, more preferably 1 MPa or more. From the viewpoint of suppressing damage to the internal parts, the resin filling pressure may be set to a range of 10 MPa or less, more preferably 6 MPa or less.

  As the thermosetting resin used for forming the thermosetting resin portion 121, an epoxy resin is typically used. The thermosetting resin part 121 preferably has a small resin stress fluctuation (stress relaxation) acting on the detection coil part 210. The thermosetting resin portion 121 preferably has an elastic modulus at room temperature of 800 MPa or more. The thermosetting resin used for forming the thermosetting resin portion 121 may include various additives such as a flame retardant, an organic / inorganic filler, a plasticizer, a colorant, and an antioxidant.

  The sealing resin 120 is not limited to a two-stage divided structure including the thermosetting resin portion 121 and the thermoplastic resin portion 122, and may have a three-stage or higher divided structure. In the case where the sealing resin 120 has a divided structure, the resin forming each layer may be a combination of the same type of resin among the thermoplastic resin and the thermosetting resin. The sealing resin 120 is not limited to the above-described divided structure, and has a structure in which the detection coil unit 210, the printed circuit board 50, and the electronic components are collectively sealed with either one of a thermoplastic resin and a thermosetting resin. Also good.

  Preferably, when the viscosity of the thermoplastic resin portion 122 is measured using a rheometer AR2000EX manufactured by TA Instruments, the shear rate during measurement is 10 (1 / s), and the temperature during measurement is 190 ° C. Then, it is good that it is 500 mPa · s or more and 10,000 mPa · s or less. More preferably, when the viscosity of the thermoplastic resin part 122 is measured using a rheometer AR2000EX manufactured by TA Instruments, the shear rate at the time of measurement is 10 (1 / s), and the temperature at the time of measurement is 190. If it is set as ° C, it is good in it being 500 mPa * s or more and 8000 mPa * s or less.

(Ring code 70)
FIG. 9 is a first perspective view showing the ring cord 70. FIG. 10 is a second perspective view showing the ring cord 70. FIG. 11 is a perspective view showing the ring member 72 of the ring cord 70. 12 is a cross-sectional view taken along line XII-XII in FIG.

  As described above, the ring cord 70 includes the cable 71 and the ring member 72. The cable 71 has a so-called three-wire structure, and includes three core wires 73 and a covering material 75 that covers these core wires 73 from the outside. For convenience in illustration, the core wire 73 is not shown in FIGS. 4 to 7, but the core wire 73 actually extends from the end portion 75T to the end portion 75S inside the covering material 75 as shown in FIG. It extends toward the end (or from the end 75S toward the end 75T). The cable 71 may have a structure other than the three-wire type, and the optimum configuration is selected as necessary for the thickness, number, number of twisted wires, and conductor plating treatment of the single conductor.

  The covering material 75 has a columnar shape as a whole, and extends in the longitudinal direction from the end portion 75T on the side where the ring member 72 is provided toward the opposite end portion 75S. The covering material 75 is made of, for example, a resin containing polyvinyl chloride (PVC). The hardness (shore A) of the covering material 75 is preferably 85 or less.

  By using the cable 71 (so-called soft cable) having the covering material 75 having a hardness (shore A) of 85 or less for the proximity sensor 510, it is possible to improve the wiring performance when the proximity sensor 510 is installed. The cable 71 having the covering material 75 having a hardness (shore A) of 85 or less can improve usability.

  The three core wires 73 each have an internal conductor 73a and an insulator 73b (internal coating) covering the internal conductor 73a. The insulator 73b is not an essential component and may be provided as necessary. In the longitudinal direction of the ring cord 70, the core wire 73 has a length longer than the covering material 75.

  A portion of the core wire 73 that extends toward the end portion 75T of the covering material 75 extends further from the end portion 75T through the ring member 72 toward the printed circuit board 50, and the inner conductor 73a extends to the printed circuit board 50. It is connected to the printed circuit board 50 (see FIG. 6). A portion of the core wire 73 extending toward the end portion 75S of the covering material 75 is a portion connected to a control device or the like (not shown) (see FIG. 1).

  The ring member 72 ensures the bondability between the sealing resin 120 (thermoplastic resin portion 122) provided in the cylindrical case 310 and the cable 71 (covering material 75). The ring member 72 is formed so as to cover the end portion 75T of the cable 71 (covering material 75) by injection molding using a thermoplastic resin. The end portion 75T of the cable 71 (covering material 75) and the ring member 72 are They are welded together.

  The length L10 (see FIG. 12) of the region in which the ring member 72 covers the covering material 75 in the longitudinal direction of the covering material 75 increases the adhesion area and prevents the water from entering from the cable side surface. It is good that it is 2 mm or more from 75 edge part 75T. The thickness TH (see FIG. 12) of the portion where the ring member 72 covers the side surface of the covering material 75 is preferably 0.5 mm or more from the viewpoint of resin moldability, and more preferably from the viewpoint of increasing the molding yield rate. To 0.6 mm or more.

  When the ring member 72 is filled with resin in the cylindrical case 310 (details will be described later with reference to FIGS. 21 and 22), the inner surface of the covering material 75 and the outer surface of the core wire 73 (insulator 73b) It is possible to suppress or prevent water from entering from the end 75T side. In the ring member 72, after the start of use of the proximity sensor 510, the water that has entered the space between the outer surface of the covering member 75 and the inner surface of the ring member 72 from the end 72 </ b> S side of the ring member 72 Further intrusion between the inner surface and the outer surface of the core wire 73 (insulator 73b) is suppressed or prevented.

  The ring member 72 has a bottomed cylindrical shape as a whole. The ring member 72 extends in a cylindrical shape around the cable 71, and a portion formed in the cylindrical shape is closed at one end 72T and opened at the other end 72S. In a state where the ring member 72 is formed so as to cover the end portion 75T of the cable 71, in the longitudinal direction of the cable 71, the end portion 75T of the covering material 75 is the end portion 72T of the ring member 72 and the end portion of the ring member 72. 72S (see FIG. 12).

  Although details will be described later, in the ring member 72, the molding gate 74Q for injection molding (see FIG. 13) has a length of −1.5 mm or more and +1.5 mm with respect to the end portion 75T of the covering material 75 in the longitudinal direction of the covering material 75. It is formed within a range of 5 mm or less. Preferably, in the ring member 72, a molding gate 74Q (see FIG. 13) for injection molding has a length of −1.0 mm or more and +1.0 mm or less with respect to the end portion 75T of the coating material 75 in the longitudinal direction of the coating material 75. It is formed within the range.

  Referring to FIG. 11, as described above, end portion 75T of cable 71 (covering material 75) and ring member 72 are welded together. The inner surface of the ring member 72 includes a side surface 72U and an end surface 72V. The side surface 72U has an annular shape and is joined to the outer surface of the cable 71 (covering material 75). The end surface 72V is joined to the end portion 75T of the cable 71 (covering material 75). Three through holes 72 </ b> W are formed in the end portion 72 </ b> T side of the ring member 72. These through-holes 72W are portions formed by the presence of the core wire 73 during injection molding.

  The outer surface of the ring member 72 has a shape corresponding to the opening 82 of the clamp 80 (the shape of the inner surface near the opening 82 of the clamp 80) (see FIGS. 3 to 6). When the proximity sensor 510 is manufactured (details will be described later with reference to FIGS. 20 and 21), the ring member 72 is disposed inside the clamp 80. The opening portion 82 of the clamp 80 is closed by the cable 71 and the ring member 72.

  The outer surface of the ring member 72 has a molding mark 74 and three recesses 76, 78M, 78N. The molding mark 74 is formed such that a part of the outer surface of the ring member 72 is recessed in a cylindrical shape, and is located closer to the end 72T than the recess 76. The molding mark 74 is formed at a position corresponding to the position of the molding gate 74Q (see FIG. 13) used when the ring member 72 is formed by injection molding.

  Referring to FIG. 12, the molding mark 74 has a diameter of, for example, 1.0 mm. This diameter corresponds to the value of the diameter DD (see FIG. 13) of the forming gate 74Q (see FIG. 13). In the longitudinal direction of the covering material 75 (cable 71), the distance between the center position of the forming gate 74Q (see FIG. 13) and the end 75T of the covering material 75 is, for example, +0.4 mm. In the longitudinal direction of the covering material 75 (cable 71), the distance LL1 between the center position of the molding mark 74 and the end portion 75T of the covering material 75 is also +0.4 mm, for example. Here, the position closer to the end 72T (printed circuit board 50) than the end 75T is set to-, and the position closer to the end 72S (covering material 75) than the end 75T is set to +.

  As described above, in the ring member 72, the molding gate 74Q for injection molding (see FIG. 13) has a length of −1.5 mm or more and +1.5 mm or less with respect to the end portion 75T of the coating material 75 in the longitudinal direction of the coating material 75. It is formed within the range. According to this configuration, when the molding mark 74 is based on the end portion 75T of the covering material 75, for example, the value of the distance LL1 in the longitudinal direction of the covering material 75 (cable 71) is −1.5 mm or more and +1.5 mm or less. It is formed to be within the range.

  Preferably, in the ring member 72, a molding gate 74Q (see FIG. 13) for injection molding has a length of −1.0 mm or more and +1.0 mm or less with respect to the end portion 75T of the coating material 75 in the longitudinal direction of the coating material 75. It is formed within the range. According to this configuration, when the molding mark 74 is based on the end portion 75T of the covering material 75, for example, the value of the distance LL1 in the longitudinal direction of the covering material 75 (cable 71) is −1.0 mm or more and +1.0 mm or less. It is formed to be within the range.

  The recesses 76, 78 </ b> M, and 78 </ b> N are formed so that a part of the outer surface of the ring member 72 is recessed, and have a fan-like shape extending along the circumferential direction of the covering material 75. The recesses 76, 78 </ b> M, and 78 </ b> N are formed at intervals in the circumferential direction of the covering material 75. The recesses 76, 78M, and 78N are formed by supporting the cable 71 (covering material 75) by the projections (projections 76Q, 79M, and 79N described later) of the mold during injection molding. In the longitudinal direction of the covering material 75, the concave portion 76 is positioned closer to the end portion 72S than the molding mark 74. When the concave portion 76 is viewed from the molding mark 74, the core wire 73 is the printed circuit board 50 (electronic component). It is located on the opposite side to the side in the direction extending toward the. In the state before the ring cord 70 is released from the molding die (die 79), the recess 76 has a core wire rather than the position of the injection port of the molding gate 74Q (see FIG. 13) used in the injection molding. 73 is located on the side opposite to the side extending in the direction toward the printed circuit board 50 (electronic component).

  The concave portion 76 of the present embodiment has a portion that overlaps the molding mark 74 when the concave portion 76 is virtually projected toward the molding mark 74 along the longitudinal direction of the covering material 75 (see FIG. 11). ). In other words, the angular range in which the recess 76 is formed in the circumferential direction of the outer surface of the ring member 72 has a portion that overlaps the angular range in which the molding mark 74 is formed in the circumferential direction of the outer surface of the ring member 72. ing. The concave portion 76 overlaps the injection port when the concave portion 76 is virtually projected toward the injection port of the molding gate 74Q (see FIG. 13) used at the time of injection molding (state before mold release). It has a part. The effect of this configuration will be described later with reference to FIG.

  Referring to FIG. 13, when ring member 72 is formed at end portion 75 </ b> T of cable 71, mold 79 is prepared. The mold 79 is composed of a plurality of parts such as an upper mold and a lower mold, and is arranged so as to surround a portion of the covering material 75 on the end 75T side. The inner surface of the mold 79 has a shape corresponding to the outer surface of the ring member 72 (see FIGS. 11 and 12). The inner surface 79 </ b> L of the mold 79 is a part that forms the end 72 </ b> T of the ring member 72. The inner surface 79 </ b> K of the mold 79 is a part that forms the end 72 </ b> S of the ring member 72.

  The inner surface of the mold 79 is further provided with a convex portion 76Q for forming the concave portion 76 of the ring member 72, and two convex portions 79M and 79N for forming the concave portions 78M and 78N of the ring member 72 (see FIG. 16). ). When the inner surface 79S of the mold 79 sandwiches the outer surface of the covering material 75, and the inner surface 79T of the mold 79 sandwiches the outer surface of the core wire 73, these convex portions are the inner surface 79L and the inner surface 79K. It functions as a support structure for supporting the covering material 75 between the two. These convex portions (support structures) are positioned on the main body side of the cable 71 (covering) with respect to the molding gate 74Q as a position for improving the melt-bonding property between the molding resin and the cable end (a position that does not hinder the flow of the resin). It may be arranged on the material 75 side). These convex portions (support structures) are not essential components and may be provided as necessary.

  In this state (the state shown in FIG. 13), the distance LL2 between the center position of the molding gate 74Q and the end 75T of the covering material 75 in the longitudinal direction of the covering material 75 (cable 71) is, for example, 0.4 mm. It is. The molding gate 74Q is arranged so that the value of the distance LL2 is in the range of −1.5 mm or more and +1.5 mm or less in the longitudinal direction of the coating material 75 (cable 71) when the end portion 75T of the coating material 75 is used as a reference. Is done. Preferably, the molding gate 74Q has a value of the distance LL2 in the range of −1.0 mm or more and +1.0 mm or less in the longitudinal direction of the coating material 75 (cable 71), based on the end portion 75T of the coating material 75. It is arranged to become.

  The diameter DD of the molding gate 74Q is, for example, 1.0 mm. The diameter DD of the forming gate 74Q is φ0.5 mm (or equivalent square shape) or more from the viewpoint of runner cutability and filling pressure loss (formability) in addition to the cable melt bondability and misalignment prevention. , Φ1.5 mm (or equivalent square shape) or less. When the diameter DD of the molding gate 74Q is φ0.5 mm or more, molding pressure loss at the gate portion is reduced, and a person with high quality can be obtained. If the diameter DD of the forming gate 74Q is φ1.5 mm or less, the runner cutability is improved and the production efficiency is also improved.

  The mold 79 is filled with a high-temperature and high-pressure thermoplastic resin through the molding gate 74Q. The thermoplastic resin is filled in a direction orthogonal to the longitudinal direction of the covering material 75. The filling conditions of the thermoplastic resin by the molding machine may be, for example, a melting temperature of 200 ° C. or higher and 305 ° C. or lower and an injection pressure of 5 MPa or higher and 120 MPa or lower.

  When the resin temperature is 200 ° C. or higher, sufficient melt bonding strength and water resistance can be obtained. When the resin temperature is 305 ° C. or lower, the amount of thermal deformation of the cable is reduced and a higher quality product is obtained. When the injection pressure is 5 MPa or more, the pressure loss in the molding flow path is reduced, and the pressure necessary for melt bonding can be secured. When the injection pressure is 120 MPa or less, the positional deviation of the cable can be reliably suppressed.

  The thermoplastic resin used to form the ring member 72 includes at least one selected from the group consisting of polybutylene terephthalate (PBT), polyethylene terephthalate (PET), polycarbonate (PC), and polyamide (PA). A thing should be adopted. The resin may be alloyed and may contain various additives.

  With reference to FIGS. 14 and 15, a case will be described in which the forming gate 74 </ b> Q is arranged so that the value of the distance LL <b> 2 does not fall within the range of −1.5 mm to +1.5 mm. In FIG. 14, the relative position of the forming gate 74Q and the end portion 75T of the covering material 75 is not included in the above range, and the forming gate 74Q is disposed closer to the inner surface 79K (the covering material 75). It is sectional drawing for demonstrating. FIG. 15 shows a case where the relative position of the forming gate 74Q and the end portion 75T of the covering material 75 is not included in the above range, and the forming gate 74Q is disposed closer to the inner surface 79L (the core wire 73). It is sectional drawing for demonstrating.

  Referring to FIG. 14, when the molding gate 74 </ b> Q is arranged in a form approaching the coating material 75, the resin filled from the molding gate 74 </ b> Q comes into strong contact with the outer surface of the coating material 75, and then the coating material. 75 is supplied to the end 75T. The temperature of the resin filled from the molding gate 74Q decreases sharply after leaving the molding gate 74Q. The resin that has reached the end portion 75T cannot sufficiently melt the surface of the end portion 75T, and it becomes difficult to obtain a strong adhesive force between the resin and the end portion 75T. When the thermal cycle repeatedly acts on the end portion 75T after the cable 71 is manufactured, the interface of the portion where the covering material 75 and the ring member 72 are joined at the end portion 75T opens due to the effect of thermal shrinkage, and the water resistance It becomes easy to fall.

  Referring to FIG. 15, when the molding gate 74 </ b> Q is arranged so as to approach the core wire 73, the resin filled from the molding gate 74 </ b> Q is applied to the end portion 75 </ b> T of the coating material 75 in the longitudinal direction of the coating material 75. Make strong contact. The covering material 75 is strongly subjected to the flow stress in the longitudinal direction of the covering material 75 (force toward the left in FIG. 15) through the end portion 75T, and the position of the covering material 75 is easily displaced in the same direction. When the position of the covering material 75 is shifted in the left direction in the figure, the core wire 73 is sandwiched by the inner surface 79T of the mold 79, so that the insulator 73b of the core wire 73 extends and the internal conductor 73a is exposed. There is a possibility.

  Referring to FIG. 13 again, in contrast to the forms shown in FIGS. 14 and 15, in the present embodiment, the value of distance LL2 is configured to be within a range of −1.5 mm to +1.5 mm. Yes. Since the resin filled from the molding gate 74Q flows along the end portion 75T of the covering material 75, the flow stress in the longitudinal direction of the covering material 75 does not act strongly on the end portion 75T. It is also possible to sufficiently melt the surface of the portion 75T. Almost no displacement of the covering material 75 occurs, and a strong adhesive force between the filled resin and the end portion 75T can be obtained.

  Since the flow stress in the longitudinal direction of the covering material 75 does not act strongly on the end portion 75T, the cable 71 (so-called soft cable) having the covering material 75 having a hardness (shore A) of 85 or less is used. Even if it exists, the position shift of the coating | covering material 75 hardly generate | occur | produces and it becomes possible to obtain the strong adhesive force between resin with which it was filled, and the edge part 75T. As described above, the cable 71 (so-called soft cable) having the covering material 75 having a hardness (shore A) of 85 or less is used for the proximity sensor 510, thereby improving the wiring performance when the proximity sensor 510 is installed. Can do. The cable 71 having the covering material 75 having a hardness (shore A) of 85 or less can improve usability.

  FIG. 16 is a perspective view schematically showing a state in which the mold 79 is filled with resin. In FIG. 16, the molding surface (inner surface) of the mold 79 is shown. After the resin is filled into the mold 79 from the molding gate 74Q, the resin spreads in contact with the outer surface of the covering material 75. The convex portion 76Q for forming the concave portion 76 of the ring member 72 is formed at the discharge port of the molding gate 74Q when the convex portion 76Q is virtually projected toward the molding gate 74Q along the longitudinal direction of the covering material 75. It has an overlapping part.

  The resin filled in the mold 79 from the molding gate 74Q is restrained from flowing in the direction away from the end portion 75T due to the presence of the convex portion 76Q (dammed), and actively toward the end portion 75T side. Will be supplied. The convex portions 79M and 79N also prevent the resin supplied to the end portion 75T from flowing in a direction away from the end portion 75T. The end portion 75T is easily supplied with high-temperature and high-pressure resin. There is almost no displacement of the covering material 75 in the longitudinal direction of the covering material 75, and a stronger adhesive force can be obtained between the filled resin and the end portion 75T. The concave portion 76 formed by the configuration has a portion overlapping the molding mark 74 when the concave portion 76 is virtually projected toward the molding mark 74 along the longitudinal direction of the covering material 75.

(Production method)
A manufacturing method of the proximity sensor 510 (see FIG. 1) will be described with reference to FIGS. Referring to FIG. 17, first, sub-assembly 116 including detection coil unit 210 and printed circuit board 50 is assembled. Specifically, the core body 40 and the coil spool 30 around which the electromagnetic coil 36 is wound are combined, and the printed board 50 is connected to the core body 40. The electromagnetic coil 36 and the printed board 50 are electrically connected by soldering the tips of the coil pins 46 onto the surface of the printed board 50 (pattern 50P in FIG. 8).

  Next, referring to FIG. 18, the front cover 20 is assembled to the subassembly 116. Specifically, first, the front cover 20 is filled with a thermosetting resin as a primary casting resin. The detection coil unit 210 is immersed in the thermosetting resin in the front cover 20 by inserting and arranging the subassembly 116 from the side of the detection coil unit 210 that detects the approach or presence of the detection target in the front cover 20. The thermosetting resin in the front cover 20 is cured by heating.

  Referring to FIG. 19, next, the ring cord 70 is assembled to the subassembly 116. Specifically, the tip of the cable of the ring cord 70 (inner conductor 73a) is soldered onto the surface of the printed circuit board 50. Next, referring to FIG. 20, the base metal fitting 60 is assembled to the front cover 20. Specifically, the ring cord 70 and the printed board 50 are sequentially passed from the front end side of the base metal fitting 60, and the front cover 20 is press-fitted inside the front end side of the base metal fitting 60.

  Next, referring to FIG. 21, the clamp 80 is assembled to the base metal fitting 60. Specifically, the ring cord 70 is passed through the opening 82 on the front end side of the clamp 80, and the clamp 80 is press-fitted inside the rear end side of the base metal fitting 60. Then, the base metal fitting 60 and the clamp 80 are fixed using fixing means such as dents, caulking, adhesion, or welding. An assembly 117 is obtained. The step of fixing the base metal fitting 60 and the clamp 80 may be performed after the subsequent secondary resin filling step.

  Referring to FIG. 22, next, a thermoplastic resin as a secondary filling resin is filled into a cylindrical case 310 composed of a base metal fitting 60 and a clamp 80. More specifically, the assembly 117 obtained in the previous step is set in a mold using a positioning jig. High temperature resin is injected into the cylindrical case 310 through the gate 81 (see FIGS. 1 to 4 and the like). The thermoplastic resin part 122 is formed by cooling and solidifying the thermoplastic resin. The printed circuit board 50 and various electronic components in the cylindrical case 310 are sealed with resin. Through the above steps, the proximity sensor 510 in FIG. 1 is completed.

(Action / Effect)
In the proximity sensor 510, the detection coil unit 210 is sealed with the thermosetting resin unit 121. An epoxy resin or the like is used as the thermosetting resin portion 121. The core body 40 of the detection coil unit 210 includes a fired body such as ferrite. Assuming that the detection coil unit 210 is sealed with a thermoplastic resin unit, the core body 40 and the electromagnetic coil 36 constituting the detection coil unit 210 are likely to change with time the stress received from the outside. . When the stress received from the outside increases or decreases, the strength (magnetic flux density) of the magnetic field formed by the core body 40 and the electromagnetic coil 36 tends to become unstable. Specifically, when the stress applied to the core body 40 changes, the magnetic characteristics of the core body 40 change due to the influence of magnetoelastic coupling (magnetostriction). When the stress applied to the core body 40 changes, the magnetic domain constituting the core body 40 changes, and the magnetic flux changes accordingly. When the stress applied to the core body 40 changes, the coil diameter and the distance between the coil wires may change. In this case, the L value of the coil changes or the C value of the coil changes. These characteristic fluctuations cause fluctuations in the detection sensitivity of the proximity sensor.

  In the embodiment, when a thermosetting resin is used as the resin for sealing the detection coil unit 210, the stress acting on the detection coil unit 210 is stabilized in the long term as compared with the case where a thermoplastic resin is used. For example, the stress that the detection coil unit 210 receives from the thermosetting resin unit 121 at each time point immediately after the proximity sensor 510 is manufactured, after the proximity sensor 510 is inspected, after the proximity sensor 510 is shipped, and when the proximity sensor 510 is used. Almost no change. The proximity sensor 510 can detect the approach or presence of the detection target with stable sensitivity.

  On the other hand, the printed circuit board 50 and the like are sealed by the thermoplastic resin portion 122. As the thermoplastic resin portion 122, a resin having a hardness (shore D) of 60 or less is used. When sealing is performed using a thermoplastic resin having low hardness, stress remaining inside the electronic device after sealing can be relaxed. Even when the printed circuit board 50 is sealed using the thermoplastic resin portion 122, the stress acting on the printed circuit board 50 after sealing is greater than when the printed circuit board 50 is sealed using the thermosetting resin portion 121. Get smaller. According to the proximity sensor 510, the stress acting on the printed circuit board 50 and each electronic component mounted thereon can be relieved.

  In the proximity sensor 510, the inside is sealed using the thermosetting resin portion 121 and the thermoplastic resin portion 122. The proximity sensor 510 can be manufactured in a shorter manufacturing time than when all the inside of the proximity sensor is sealed using a thermosetting resin portion.

  As described above, preferably, when the viscosity of the thermoplastic resin portion 122 is measured using a rheometer AR2000EX manufactured by TA Instruments, the shear rate at the time of measurement is 10 (1 / s), If the temperature is 190 ° C., it is preferably 500 mPa · s or more and 10,000 mPa · s or less. More preferably, when the viscosity of the thermoplastic resin part 122 is measured using a rheometer AR2000EX manufactured by TA Instruments, the shear rate at the time of measurement is 10 (1 / s), and the temperature at the time of measurement is 190. If it is set as ° C, it is good in it being 500 mPa * s or more and 8000 mPa * s or less. According to these configurations, the thermoplastic resin portion 122 can be favorably bonded to the thermosetting resin portion 121 at the interface between the thermosetting resin portion 121 and the thermoplastic resin portion 122.

  Referring to FIG. 23, as described above, the ring cord 70 used in the proximity sensor 510 has a distance LL2 (FIG. 13) between the center position of the molding gate 74Q and the end portion 75T of the covering material 75 at the time of manufacture. Reference) is within a range of −1.5 mm to +1.5 mm. Thereby, the distance LL1 (see FIG. 12) between the center position of the molding mark 74 and the end portion 75T of the covering material 75 is formed, for example, within a range of −1.5 mm to +1.5 mm. ing. The cable 71 (covering material 75) and the ring member 72 constituting the ring cord 70 are welded at the end portion 75T of the covering material 75 with a sufficient fusion bonding force.

  The ring cord 70 is strongly bonded at the end portion 75T of the covering material 75, and a portion where the outer surface of the side surface of the covering material 75 and the inner surface of the ring member 72 are bonded (white arrow in FIG. 23). ) And a portion formed between the end 72T of the ring member 72 and the portion where the thermoplastic resin portions 122 are joined together (portion indicated by the black arrow in FIG. 23), moisture enters ( In and out) is sufficiently suppressed or prevented.

  Referring to FIG. 24, according to the joining surface 75V welded with a sufficient melt joining force at the end portion 75T of the covering material 75, for example, a dotted line in FIG. 24 formed through this joining surface 75V. It is possible to sufficiently suppress the intrusion (in / out) of moisture through the path as shown. Therefore, the proximity sensor 510 provided with such a ring cord 70 can achieve high water resistance.

  In the proximity sensor 510, a thermoplastic resin portion 122 is formed in a case member (the cylindrical case 310, the ring cord 70, and the front cover 20). For forming the thermoplastic resin portion 122, for example, a soft thermoplastic resin containing at least one selected from the group consisting of polyolefin, polyester and polyamide is used. Even when the thermoplastic resin portion 122 is employed as the filling resin, the ring member 72 of the ring cord 70 is formed of the sealing resin 120 (thermoplastic resin portion 122) provided in the cylindrical case 310 and the cable 71 ( Sufficient bondability (water resistance) can be ensured with the covering material 75).

  Even in the case where a cable 71 (so-called soft cable) having a covering material 75 having a hardness (shore A) of 85 or less is used, the end portion 75T of the covering material 75 is used as a reference in the longitudinal direction of the covering material 75 (cable 71). The cable 71 can exhibit high water resistance by being formed so that the position of the forming gate 74Q (see FIG. 13) is within a range of −1.5 mm to +1.5 mm. Wiring handling when installing the proximity sensor 510 can be improved. The cable 71 having the covering material 75 having a hardness (shore A) of 85 or less can improve usability.

[Experimental Example 1]
With reference to FIG. 25, the experimental example 1 performed regarding embodiment is demonstrated. The experimental example includes Comparative Examples 1A and 2A and Examples 1A to 7A. In this experimental example, a plurality of types of ring cords were prepared. Each of the ring members of the ring cord is formed by filling a mold with a thermoplastic resin from a molding gate having a diameter of 0.5 mm. The temperature of the filling resin forming the ring member of the ring cord is set to 290 ° C., and the filling pressure (injection pressure) is set to 20 MPa. The ring cord cable 71 (covering material) has a hardness (shorA) of 75 in all cases. The gate position in FIG. 25 is defined as a position closer to the end 72T (printed circuit board 50) than the end 75T (see FIGS. 12 and 13), and the end 72S (covering material 75) from the end 75T. The position on the side is +.

  In each of Comparative Examples 1A and 2A and Examples 1A to 7A, the melt bondability at the end 75T of the ring cord was evaluated, and the degree of positional deviation of the covering material 75 was evaluated. The evaluation of melt bondability was made into three stages of A, B, and C. A tensile test was performed on the ring cord 70 obtained after the formation of the ring member 72, and a case where a cohesive failure mode was observed over the entire circumference of the end portion (end portion 75T) of the cable 71 was evaluated as A. (The cohesive failure mode is manifested when a good melt bond is formed). The case where both forms of cohesive failure and interface peeling were observed at the end portion (end portion 75T) of the cable 71 was evaluated as B. The case where the interface peeling form was observed at the end portion (end portion 75T) of the cable 71 was evaluated as C (the interface peeling form appears when a good melt-bonding is not formed).

  The cable position deviation was evaluated in three stages A, B, and C. Specifically, even if the insulator 73b is pulled due to the positional deviation, the internal conductor 73a is not exposed, the deterioration of the melt bondability at the end portion 75T of the cable 71 is not observed, and the water resistance test (IP67 In the test, an insulation resistance value> 50 MΩ was evaluated as A. Due to the displacement, the insulator 73b is pulled to expose the inner conductor 73a, and the melt-bonding property is deteriorated at the end portion 75T of the cable 71. Insulation resistance value> 50 MΩ in the water resistance test (IP67 test) Was shown as evaluation B. Due to the displacement, the insulator 73b is pulled to cause the internal conductor 73a to be exposed, and a decrease in the melt bonding property at the end portion 75T of the cable 71 is observed. Insulation resistance value ≦ 50MΩ in the water resistance test (IP67 test) Was shown as evaluation C.

  In Comparative Example 1A, a ring cord 70 formed with the gate position (distance LL2 in FIG. 13) set to −2.0 mm is used, and the position of the molding mark 74 (distance LL1 in FIG. 12) is -2.0 mm. Evaluation A was obtained as the melt bondability after the tensile test, and evaluation C was obtained as the positional deviation of the cable. In the gate position in Comparative Example 1A, although the end portion 75T of the covering material 75 can be melted, it is considered that the flow stress with respect to the end portion 75T is large, the displacement occurs, and the water resistance is also lowered.

  In Example 1A, the ring cord 70 formed by setting the value of the gate position (distance LL2 in FIG. 13) to −1.5 mm is used, and the value of the position of the molding mark 74 (distance LL1 in FIG. 12) is -1.5 mm. The evaluation A was obtained as the melt bondability after the tensile test, and the evaluation B was obtained as the displacement of the cable. It can be seen that the gate position in Example 1A can melt the end portion 75T of the covering material 75, and a predetermined water resistance can be obtained.

  In Examples 2A, 3A, 4A, 5A, and 6A, the gate positions (distance LL2 in FIG. 13) are set to −1.0 mm, −0.5 mm, 0 mm, 0.5 mm, and 1.0 mm, respectively. The value of the position of the molding mark 74 (distance LL1 in FIG. 12) is −1.0 mm, −0.5 mm, 0 mm, 0.5 mm, and 1.0 mm, respectively. Evaluation A was obtained as the melt bondability after the tensile test, and evaluation A was obtained as the positional deviation of the cable. In the gate positions in Examples 2A, 3A, 4A, 5A, and 6A, the end portion 75T of the covering material 75 can be sufficiently melted, the flow stress with respect to the end portion 75T is small, and displacement hardly occurs. It can be seen that water resistance is also obtained.

  In Example 7A, the ring cord 70 formed by setting the value of the gate position (distance LL2 in FIG. 13) to 1.5 mm is used, and the value of the position of the molding mark 74 (distance LL1 in FIG. 12) is 1. .5 mm. Evaluation B was obtained as the melt bondability after the tensile test, and evaluation A was obtained as the displacement of the cable. In the gate position in Example 7A, it can be seen that the flow stress with respect to the end portion 75T is small, no positional deviation occurs, and a predetermined water resistance is obtained.

  In Comparative Example 2A, the ring cord 70 formed with the gate position (distance LL2 in FIG. 13) set to 2.0 mm is used, and the position of the molding mark 74 (distance LL1 in FIG. 12) is 2. 0.0 mm. Evaluation C was obtained as the melt bondability after the tensile test, and evaluation A was obtained as the positional deviation of the cable. As for the gate position in Comparative Example 2A, it was found that although the end portion 75T of the covering material 75 could not be melted, the flow stress with respect to the end portion 75T was small and no displacement occurred.

  From the result of Experimental Example 1, the distance LL2 (see FIG. 13) between the center position of the molding gate 74Q and the end portion 75T of the covering material 75 at the time of manufacture is within the range of −1.5 mm to +1.5 mm. The distance LL1 (see FIG. 12) between the center position of the molding mark 74 and the end portion 75T of the covering material 75 is within a range of −1.5 mm to +1.5 mm. It can be seen that the ring code 70 is preferably used. By configuring the distance LL2 (see FIG. 13) to be within the range of −1.0 mm or more and +1.0 mm or less, the end portion 75T of the covering material 75 can be sufficiently melted, and the flow with respect to the end portion 75T can be performed. It can be seen that a higher stress can be obtained such that the stress is small, the positional displacement hardly occurs, and the water resistance is also obtained.

[Experiment 2]
With reference to FIG. 26, the experimental example 2 performed regarding embodiment is demonstrated. The experimental example includes Comparative Examples 1B and 2B and Examples 1B to 7B. In the experimental example, unlike the experimental example 1 described above, each ring member of the ring cord is formed by filling a mold with a thermoplastic resin from a molding gate having a diameter of 1.5 mm. . The conditions that are the preconditions for the other experiments in Experimental Example 2 are the same as in Experimental Example 1 described above.

  In Comparative Example 1B, an evaluation A was obtained as the melt bondability after the tensile test, and an evaluation C was obtained as the cable misalignment. In the gate position in Comparative Example 1B, although the end portion 75T of the covering material 75 can be melted, it is considered that the flow stress with respect to the end portion 75T is large, the displacement occurs, and the water resistance is also lowered.

  In Example 1B, an evaluation A was obtained as the melt-bonding property after the tensile test, and an evaluation B was obtained as the displacement of the cable. It can be seen that the gate position in Example 1B can melt the end portion 75T of the covering material 75, and a predetermined water resistance can be obtained.

  In Examples 2B, 3B, 4B, 5B, and 6B, the evaluation A was obtained as the melt-bonding property after the tensile test, and the evaluation A was obtained as the positional deviation of the cables. In the gate positions in Examples 2B, 3B, 4B, 5B, and 6B, the end portion 75T of the covering material 75 can be sufficiently melted, the flow stress with respect to the end portion 75T is small, and displacement hardly occurs. It can be seen that water resistance is also obtained.

  In Example 7B, evaluation B was obtained as the melt bondability after the tensile test, and evaluation A was obtained as the positional deviation of the cable. In the gate position in Example 7B, it can be seen that the flow stress with respect to the end portion 75T is small, the position shift does not occur, and the predetermined water resistance is obtained.

  In Comparative Example 2B, an evaluation C was obtained as the melt bondability after the tensile test, and an evaluation A was obtained as the cable displacement. The gate position in Comparative Example 2B shows that although the end portion 75T of the covering material 75 could not be melted, the flow stress with respect to the end portion 75T was small, and no displacement occurred.

  Also from the result of Experimental Example 2, the distance LL2 (see FIG. 13) between the center position of the molding gate 74Q and the end portion 75T of the covering material 75 at the time of manufacture is within the range of −1.5 mm to +1.5 mm. The distance LL1 (see FIG. 12) between the center position of the molding mark 74 and the end portion 75T of the covering material 75 is in the range of −1.5 mm to +1.5 mm. It can be seen that the formed ring cord 70 may be used. By configuring the distance LL2 (see FIG. 13) to be within the range of −1.0 mm or more and +1.0 mm or less, the end portion 75T of the covering material 75 can be sufficiently melted, and the flow with respect to the end portion 75T can be performed. It can be seen that a higher stress can be obtained such that the stress is small, the positional displacement hardly occurs, and the water resistance is also obtained.

  Although the above-described embodiment has been described based on a proximity sensor as an example of an electronic device, the present invention is not limited to the proximity sensor. The present invention may be applied to a photoelectric sensor, a fiber sensor, a smart sensor, or the like. A photoelectric sensor detects the presence or absence of an object, a change in surface state, and the like using various properties of light emitted from a light source. The detection unit of the photoelectric sensor includes a light emitting diode or a semiconductor laser as a light source. The fiber sensor is a sensor in which an optical fiber is combined with a photoelectric sensor. The detection unit of the fiber sensor also includes a light emitting diode or a semiconductor laser as a light source. Smart sensors are sensors in which analysis and information processing capabilities are added to proximity sensors and photoelectric sensors. When the proximity sensor is used as a basic configuration, the detection unit of the smart sensor corresponds to the detection coil unit in the above embodiment, and when the photoelectric sensor is used as the basic configuration, a light emitting diode or a semiconductor laser is used as a light source. Including.

  Although the embodiments and examples based on the present invention have been described above, the embodiments and examples disclosed this time are examples in all respects and are not restrictive. The technical scope of the present invention is defined by the terms of the claims, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  The present invention can be applied to an electronic device that includes a ring cord and in which a sealing resin is formed inside a case member.

  20 Front cover, 30 Coil spool, 36 Electromagnetic coil, 37, 46J Tip, 40 Core body, 46 pins, 50 Printed circuit board, 50P pattern, 60 Base bracket, 70 Ring cord, 71 Cable, 72 Ring member, 72S, 75T End Part, 72U side surface, 72V end face, 72W through hole, 73 core wire, 73a inner conductor, 73b insulator, 74 molding mark, 74Q molding gate, 75 coating material, 75V joint surface, 76, 78M, 78N recess, 76Q, 79M, 79N convex part, 79 mold, 79K, 79L, 79S, 79T inner surface, 80 clamp, 81 gate, 82 opening, 101 chain line, 102 central axis, 116 subassembly, 117 assembly, 120 sealing resin, 121 thermosetting Resin part, 122 Thermoplastic resin part, 210 Detection coil part, 310 cylindrical case, 510 proximity sensor, AR121, AR122 arrow, DD diameter, L10 length, LL1, LL2 distance, TH thickness.

Claims (10)

A case member having an opening and accommodating an electronic component;
A ring cord inserted through the opening;
A resin portion for closing the space between the case member and the ring cord from the inside of the case member,
The ring cord is
A cable having a core wire and a covering material covering the core wire, the core wire extending from an end portion in the longitudinal direction of the covering material toward the electronic component and electrically connected to the electronic component;
A ring member formed so as to cover the end of the covering material by injection molding and having a shape corresponding to the opening,
The end portion of the covering material and the ring member are welded to each other ,
The ring member is formed such that a molding gate for the injection molding is located within a range of −1.5 mm to +1.5 mm with respect to the end of the coating material in the longitudinal direction of the coating material. Is,
Electronics. The ring member is formed such that the molding gate for the injection molding is positioned within a range of −1.0 mm or more and +1.0 mm or less with respect to the end portion of the coating material in the longitudinal direction of the coating material. Is
The electronic device according to claim 1 . The covering material has a hardness (shore A) of 85 or less.
The electronic device according to claim 1 or 2. The covering material includes polyvinyl chloride,
The electronic device in any one of Claim 1 to 3 . The resin part includes a thermoplastic resin part having a hardness (shore D) of 60 or less.
The electronic device according to any one of claims 1 to 4. The ring member has a recess formed by the covering material being supported by a convex portion of a mold during the injection molding,
In the longitudinal direction, the concave portion is located on a side opposite to the side in the direction in which the core wire extends toward the electronic component from the position of the injection port of the molding gate used in the injection molding. ing,
The electronic device according to claim 1 or 2. The recess has a portion overlapping the injection port when the recess is virtually projected toward the injection port of the molding gate along the longitudinal direction.
The electronic device according to claim 6 . The ring member includes at least one selected from the group consisting of polybutylene terephthalate, polyethylene terephthalate, polycarbonate, and polyamide.
The electronic device according to any one of claims 1 to 7. An electronic device comprising: a case member having an opening and accommodating an electronic component; a ring cord inserted through the opening; and a resin portion for closing a space between the case member and the ring cord from the inside of the case member A method of manufacturing a device,
The ring cord includes a core wire and a covering material that covers the core wire, and the core wire extends from an end portion in the longitudinal direction of the covering material toward the electronic component and is electrically connected to the electronic component. Including
Injection molding by have a step of mutually welded and said ring member and said end portion of said coating material to form a ring member having a shape corresponding to the opening so as to cover the end portion of the covering material,
The molding gate for the injection molding is located in a range of −1.5 mm or more and +1.5 mm or less with respect to the end portion of the coating material in the longitudinal direction of the coating material.
Manufacturing method of electronic equipment. The molding gate for the injection molding is located within a range of −1.0 mm or more and +1.0 mm or less with respect to the end portion of the coating material in the longitudinal direction of the coating material.
The manufacturing method of the electronic device of Claim 9 .

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