JP5160824B2 - Electric wire coating apparatus and electric wire coating method - Google Patents

Description

  The present invention relates to an electric wire coating apparatus and an electric wire coating method for forming a coating layer on an outer surface of an electric wire.

  Various electronic devices are mounted on automobiles or the like as moving bodies. For this reason, the automobile and the like route a wire harness in order to transmit electric power from a power source, a control signal from a computer, and the like to the electronic device. The wire harness includes a plurality of electric wires and connectors attached to the ends of the electric wires.

  The electric wire is a so-called covered electric wire and includes a conductive core wire and a covering portion made of an insulating synthetic resin that covers the core wire. The connector includes a conductive terminal fitting and an insulating connector housing. The terminal fitting is attached to the end of the electric wire and electrically connected to the core wire of the electric wire. The connector housing is formed in a box shape, and the terminal fitting is accommodated in a linear hole-shaped terminal accommodating chamber provided inside.

  When assembling the wire harness, the electric wire is first cut to a predetermined length, and then a terminal fitting is attached to the end of the electric wire. Connect multiple wires as needed. Thereafter, the terminal fitting is inserted into the connector housing. Thus, the wire harness described above is assembled.

  In order to add work instruction information such as which connector housing (terminal housing chamber of) the terminal fitting attached to the terminal should be accommodated on the terminal of the wire harness of the wire harness described above, for example, (For example, refer to Patent Document 1), since such a marking may deteriorate over time and peel off, the terminal is previously undercoated. Prevent the colorant from peeling off by forming a coating layer with a coating agent to improve the adhesion of the colorant, or forming a coating layer with a topcoat agent on the outer surface after marking the terminal. Yes.

As described above, when the marking is applied only to the terminal of the electric wire, the coating layer may be formed only on the terminal using the above-mentioned coating agent. A dip coating method is used in which a coating layer is formed by immersing an end of the electric wire in a coating direction and a coating solution composed of a coating agent and a solvent for dissolving the coating agent.
JP-A-5-217435

  However, as described above, when the electric wire is held in the vertical direction and the end of the electric wire is immersed in the coating liquid, the coating liquid enters between the core wire and the coating portion of the electric wire and adheres to the core wire. There was a problem of adversely affecting the mechanical properties and conductivity of the electric wire.

  The present invention aims to solve such problems. That is, an object of the present invention is to provide an electric wire coating apparatus and an electric wire coating method in which a coating layer is surely formed only on a covered portion of an electric wire to prevent deterioration of mechanical properties and electric conductivity of the electric wire.

  In order to solve the above problems and achieve the object, the invention described in claim 1 is a coating agent for forming a coating layer on the outer surface of the wire, and a coating agent for forming the coating layer and the coating agent. A porous member impregnated with a coating solution composed of a solvent that dissolves the inside, an elastic porous member, a containing tank that contains the porous member, a wire that holds the electric wire, and the electric wire and the containing tank are connected to the electric wire. Contacting / separating means for making contact and separation relative to each other along a direction intersecting the longitudinal direction, and an electric wire housing part that makes it possible to house the electric wire contacting and separating from the housing tank in the housing tank. This is a wire coating device.

  According to a second aspect of the present invention, in the wire coating apparatus according to the first aspect, the porous member includes a groove portion through which the electric wire is accommodated in the electric wire accommodating portion. This is a wire coating device.

  A third aspect of the present invention is the electric wire coating apparatus according to the second aspect, wherein a plurality of recesses are provided on the inner surface of the groove.

  According to a fourth aspect of the present invention, in the electric wire coating apparatus according to the second or third aspect, the portions located at both ends of the electric wire in the longitudinal direction of the electric wire receiving portion have elasticity. And when the said electric wire is accommodated in the said electric wire accommodating part, while elastically deforming and allowing it to communicate with the said groove part and allowing the said electric wire to pass through, it is elastic when the said electric wire is positioned outside the said electric wire accommodating part. An electric wire coating apparatus comprising a second porous member having a slit closed by a restoring force.

  According to a fifth aspect of the present invention, in the wire coating apparatus according to any one of the first to fourth aspects, a supply means for supplying the coating liquid to the porous member is provided. Is an electric wire coating apparatus characterized by

According to a sixth aspect of the present invention, there is provided an electric wire coating method for forming a coating layer on an outer surface of an electric wire, the coating liquid comprising the electric wire, a coating agent for forming the coating layer, and a solvent for dissolving the coating agent. a storage tank for accommodating the porous member having the impregnated and elasticity therein, the in longitudinal direction along the direction crossing was relatively tangent away of the electric wire, and out the wire to the housing tank And forming a coating layer on the outer surface of the electric wire.

  According to the invention described in claim 1, a porous member having a coating liquid made of a coating agent that forms a coating layer and a solvent that dissolves the coating agent and having elasticity therein, and a porous member are accommodated. A storage tank, a contact / separation means for holding the electric wire and relatively contacting and separating the electric wire and the storage tank along a direction intersecting the longitudinal direction of the electric wire, and an electric wire contacting and separating the storage tank in the storage tank. An electric wire accommodating portion that can be accommodated, so that a desired portion in the longitudinal direction of the electric wire can be accommodated in the accommodating tank and contacted with the porous member to form a coating layer. The coating agent is not attached to the tip of the wire, and the coating layer can be reliably formed only on the covering portion of the wire to prevent the mechanical properties and conductivity of the wire from being deteriorated.

  According to the invention described in claim 2, since the porous member includes the groove portion through which the electric wire accommodated in the electric wire accommodating portion passes, the electric wire is positioned in the porous member through the groove portion of the porous member. Therefore, the electric wire can be smoothly positioned in the porous member.

  According to the invention described in claim 3, since a plurality of recesses are provided on the inner surface of the groove part, it is possible to allow excess coating liquid attached to the outer surface of the electric wire to flow into the recesses. The amount of the coating liquid used can be reduced, and the coating layer can be uniformly formed on the outer surface of the electric wire.

  According to the invention described in claim 4, the portions located at both ends in the longitudinal direction of the electric wire in the electric wire housing portion have elasticity, and elastic deformation occurs when the electric wire is accommodated in the electric wire housing portion. Since the second porous member having a slit that closes by an elastic restoring force when the electric wire is positioned outside the electric wire housing portion is provided while being in communication with the groove portion, the porous portion is porous. It is possible to prevent the coating liquid impregnated in the member from flowing out of the housing tank from the electric wire housing portion.

  According to the invention described in claim 5, since the supply means for supplying the coating liquid to the porous member is provided, the coating liquid can be automatically supplied to the porous member, so that the work efficiency can be improved. Can be improved.

  According to the sixth aspect of the present invention, the housing contains an elastic porous member impregnated with a coating liquid comprising an electric wire, a coating agent for forming a coating layer, and a solvent for dissolving the coating agent. Because the coating is formed on the outer surface of the electric wire by moving the electric wire into and out of the storage tank relative to and away from the tank, a desired portion in the longitudinal direction of the electric wire is stored in the storage tank and is porous. The coating layer can be formed in contact with the member, and therefore, the coating agent is not attached to the tip of the wire, and the coating layer is surely formed only on the coated portion of the wire to ensure the mechanical properties and conductivity of the wire. Can be prevented.

  A wire coating apparatus according to an embodiment of the present invention will be described below with reference to FIGS. An electric wire coating apparatus 1 according to an embodiment of the present invention forms a coating layer 23 on an outer surface 22 a of an electric wire 2.

  As shown in FIG. 1, the electric wire coating apparatus 1 includes a pair of sponge portions (porous materials) that are impregnated inside and coated with a coating liquid comprising a coating agent for forming the coating layer 23 and a solvent for dissolving the coating agent. 3 (corresponding to a member), a storage tank 4 for storing the pair of sponge parts 3, and holding the electric wire 2 and relatively connecting the electric wire 2 and the storage tank 4 along the direction intersecting the longitudinal direction of the electric wire 2. Contacting / separating means 5 for contacting / separating, a notch portion (corresponding to an electric wire accommodating portion) 6 for allowing the electric wire 2 contacting / separating to the accommodating tank 4 to be accommodated in the accommodating tank 4, and a pair of sponge portions 3 with a coating liquid Supply means 7 (FIG. 4 etc.).

  The electric wire 2 comprises the wire harness routed by the motor vehicle etc. as a moving body. As shown in FIGS. 2 and 3, the electric wire 2 includes a conductive core wire 21 and an insulating covering portion 22. The core wire 21 is formed by twisting a plurality of strands. The strand which comprises the core wire 21 consists of an electroconductive metal material. Moreover, the core wire 21 may be comprised from one strand.

  The covering portion 22 is made of, for example, a synthetic resin such as polyvinyl chloride (PVC). The covering portion 22 covers the core wire 21. The electric wire 2 is formed in a circular cross section by the core wire 21 and the covering portion 22 that covers the core wire 21. The electric wire coating apparatus 1 according to the present embodiment forms the coating layer 23 on the outer surface 22 a of the electric wire 2, that is, the outer surface 22 a of the covering portion 22.

  The coating layer 23 is made of methacrylic resin or acrylic resin as a coating agent. In the illustrated example, the coating agent is made of polymethylmethacrylate (PMMA). The methacrylic resin described in this specification is a resin obtained by polymerizing methacrylic acid or methacrylic acid ester. Moreover, the acrylic resin described in this specification is a resin obtained by polymerizing acrylic acid or an acrylic ester.

  In particular, methyl methacrylate polymer is the best among all plastics in terms of transparency and weather resistance, and is widely used in architecture, lighting, signboards, miscellaneous goods, and other industrial parts. In addition, various methacrylate esters such as ethyl methacrylate, n-butyl, iso-butyl, hexyl, lauryl and the like are in increasing demand for finishing paints, adhesives, fibers, leather and paper. Further, when methacrylic acid is copolymerized to introduce a carboxyl group into the polymer, properties such as improved adhesiveness, water solubility, and crosslinkability are imparted, which is widely used.

  The coating layer 23 made of such a coating agent covers the covering portion 22 of the electric wire 2 over the entire circumference. The coating layer 23 is formed on the one end 2 a excluding the tip 2 b of the electric wire 2. The thickness T of the coating layer 23 is uniform and is about 50 μm to 200 μm. For this reason, the cross-sectional shape of the electric wire 2 and the coating layer 23 formed on the outer surface 22a of the covering portion 22 of the electric wire 2 is circular.

  The outer surface 23a of the coating layer 23 having the above-described configuration is colored with a coloring material. The coloring material is reliably held on the outer surface 23 a of the coating layer 23 by the coating layer 23. Such a coloring material adds work instruction information such as which connector housing (terminal housing chamber) the terminal fitting attached to the terminal should be accommodated in.

  The coloring material is a liquid material in which a coloring material (industrial organic material) is dissolved and dispersed in water or other solvent. Examples of organic substances include dyes and pigments (mostly organic substances and synthetic products). Sometimes dyes are used as pigments and pigments are used as dyes. As a more specific example, the coloring material referred to in the present specification indicates both a coloring liquid and a paint.

  The coloring liquid indicates that the dye is dissolved or dispersed in the solvent, and the paint indicates that the pigment is dispersed in the dispersion. For this reason, when the electric wire 2 on which the coating layer 23 is formed is colored with the coloring liquid, the dye soaks into the coating layer 23, and when the electric wire 2 on which the coating layer 23 is formed is colored with the paint, the pigment enters the coating layer 23. It adheres to the outer surface 23a of the coating layer 23 without soaking.

  The solvent and the dispersion are preferably those having a high affinity for the coating agent constituting the coating layer 23. In this case, the dye surely penetrates into the coating layer 23, and the pigment adheres securely to the outer surface 23 a of the coating layer 23.

  The coating liquid includes the above-described coating agent and a solvent that dissolves the coating agent. As the solvent, known alcohols, polyhydric alcohols, ketones, and esters can be used. A solvent that evaporates at room temperature is desirable. In the illustrated example, acetone as an example of a ketone is used as the solvent.

  The pair of sponge portions 3 is made of, for example, a porous material such as a synthetic sponge obtained by foaming plastic such as polyurethane or rubber. An infinite number of fine holes are formed inside the sponge part 3, and when the sponge part 3 is immersed in the coating liquid, the air in the holes is replaced with the coating liquid and the sponge part 3 is impregnated with the coating liquid. In addition, the coating liquid is easily released by an external force. Such a sponge part 3 is preferably formed from a porous material having low reactivity with the coating liquid.

  The pair of sponge portions 3 are each formed in a substantially rectangular parallelepiped shape having the same shape. The pair of sponge parts 3 are arranged in the storage tank 4 so that a pair of notch parts 6 to be described later of the storage tank 4 are positioned between each other. The pair of sponge portions 3 are at least elastically deformed and accommodated in the accommodating tank 4, and when accommodated in the accommodating tank 4, the electric wires 2 are interposed between each other (that is, a groove portion 32 described later). It is formed in a size that allows it to pass through.

  The pair of sponge portions 3 includes a groove portion 32 through which the electric wire 2 accommodated in the pair of notch portions 6 is passed. The groove portion 32 is formed between the pair of sponge portions 3 arranged in the storage tank 4 as described above. The groove part 32 is formed over the whole longitudinal direction of the bottom wall 41a of the storage tank main body 41 mentioned later. Further, the width of the groove 32 is provided to be narrower than the thickness of the electric wire 2. In addition, a pair of sponge part 3 consists of one sponge part, and the groove part 32 may be provided in the center of this sponge part.

  As shown in FIGS. 5 to 7, the one end 2 a of the electric wire 2 is inserted into the groove 32 having the above-described configuration. One end portion 2a of the electric wire 2 is passed through the groove portion 32 by the contacting / separating means 5 and contacts the inner surface 32a of the groove portion 32 when reciprocating in the groove portion 32, thereby elastically deforming the groove portion 32 (in FIG. The inner surface 32a of the groove 32 is drawn in a state before elastic deformation). When the groove portion 32 is elastically deformed, the coating agent impregnated in the sponge portion 3 is released, and the coating agent held in the sponge portion 3 is applied to the outer surface 22 a of the electric wire 2.

  A plurality of concave portions 33 are provided on the inner surface 32 a of the groove portion 32. The recess 33 extends in a direction orthogonal to the longitudinal direction of the groove 32. The plurality of recesses 33 are provided at intervals, and are provided in parallel to each other. When the one end portion 2 a of the electric wire 2 inserted into the groove portion 32 is taken out from the groove portion 32, an excess coating liquid applied to the outer surface 22 a of the electric wire 2 flows into the concave portion 33, and the outer surface of the electric wire 2. This excess coating agent is removed from 22a.

  As shown in FIG. 6 and the like, the storage tank 4 includes a storage tank main body 41 provided in a bottomed cylindrical shape, and an attachment portion 42. The storage tank body 41 includes a rectangular flat bottom wall 41a, a pair of peripheral walls 41b erected from both ends in the longitudinal direction of the bottom wall 41a, and a pair of peripheral walls 41b erected from both ends in the width direction of the bottom wall 41a. And a pair of second peripheral walls 41c, which are open upward. The pair of peripheral walls 41b are opposed to each other with a space therebetween and are provided in parallel to each other. The pair of second peripheral walls 41c are opposed to each other with a space therebetween and are provided in parallel to each other. The pair of peripheral walls 41b and the pair of second peripheral walls 41c are provided so as to be orthogonal to each other. The pair of peripheral walls 41b are each provided with a notch 6. The notch 6 will be described in detail later.

  As shown in FIGS. 1 and 7, the attachment portion 42 is provided over the entire inner edge of each of the notch portions 6 of the pair of notch portions 6. The attachment portion 42 is connected to the entire inner edge of the notch portion 6 and is cut out from both ends in the width direction of the orthogonal portion 42a, and an orthogonal portion 42a erected toward the both surfaces of the peripheral wall 41b in a direction orthogonal to the peripheral wall 41b. A pair of edge portions 42 b erected toward the inside of the portion 6, and is formed in a groove shape having a U-shaped cross section along the inner edge of the notch portion 6. Then, a second sponge part 43 described later is attached in the groove-like attachment part 42.

  As shown in FIG. 1 and the like, the contact / separation means 5 includes a clamp 51 as a holding member for holding the electric wire 2, a second holding member 52 for holding the storage tank 4, and a drive mechanism (not shown). I have. The clamp 51 clamps a portion (hereinafter referred to as a sandwiched portion) 2c that is separated from the distal end 2b of the electric wire 2 by more than the length in the longitudinal direction of the housing tank body 41, and ends from the distal end 2b to the sandwiched portion 2c. The part 2a is held horizontally. In addition, when the electric wire 2 is bent by its own weight or the like and the one end 2a of the electric wire 2 cannot be held horizontally only by the clamp 51, a second clamp 51 for holding the tip 2b of the electric wire 2 may be provided.

  The second holding member 52 is formed in a flat plate shape, for example, and the storage tank 4 is fixed to the upper surface side. The second holding member 52 is disposed below the clamp 51. As will be described later, when the second holding member 52 moves upward, the second holding member 52 passes through one end portion 2a of the electric wire 2 held by the clamp 51 in the pair of notch portions 6 of the storage tank 4. To be fixed.

  The drive mechanism includes, for example, an air cylinder having a telescopic rod, a lever, and the like. The drive mechanism displaces the second holding member 52 disposed below to the clamp 51 disposed above. In other words, the drive mechanism moves the second holding member 52 toward and away from the clamp 51 to bring the housing tank 4 into and away from the electric wire 2.

  As shown in FIG. 1 and the like, a pair of notches 6 is provided, and is provided at the center in the width direction of each peripheral wall 41 b of the pair of peripheral walls 41 b of the storage tank 4. The cutout portion 6 is formed by cutting the peripheral wall 41b linearly along the direction approaching the bottom wall 41a from the upper end of the peripheral wall 41b, and the pair of straight cutout portions 6 are formed in parallel to each other. ing. The pair of notches 6 are provided side by side along a direction parallel to the second peripheral wall 41c. And the groove part 32 is distribute | arranged on the straight line which connects a pair of notch parts 6. FIG. The width of the notch 6 is wider than the thickness of the electric wire 2. The length of the cutout portion 6 is provided such that the back portion 6a near the bottom wall 41a is positioned below the upper surface 31a of the sponge portion 3.

  The electric wires 2 are passed through the pair of cutout portions 6 having the above-described configuration. Since the electric wire 2 passes through both of the notch portions 6, the electric wire 2 passes through the notch portions 6 and is distributed from the inside of the storage tank 4 to the outside of the storage tank 4. 4 and the coating agent does not adhere to the tip 2 b of the electric wire 2.

  The portions of the pair of cutout portions 6 located at both ends in the longitudinal direction of the electric wire 2 are each provided with a second sponge portion (corresponding to a second porous member) 43 having elasticity. The second sponge portion 43 is formed in a long prismatic shape, is made of a porous material, and can be impregnated with a coating liquid. Since the porous material is the same porous material as that of the sponge part 3 described above, detailed description thereof is omitted. The length of the second sponge part 43 is approximately twice the length of the notch part 6. The second sponge part 43 is bent at the center in the longitudinal direction so that the one end part 43a and the other end part 43b in the longitudinal direction come into contact with each other, and then is pushed into the attachment part 42 to be elastically deformed to enter into the attachment part 42. Inserted, elastically restored, and held in the attachment portion 42. The second sponge parts 43 are each arranged so as to close the notch part 6. The second sponge part 43 has a slit 45.

  The slit 45 is formed between the one end part 43a and the other end part 43b of the second sponge part 43 bent as described above. The slit 45 is provided in parallel with the notch 6 over substantially the entire length of the notch 6. The slit 45 is elastically deformed in a direction in which the one end portion 43a and the other end portion 43b of the second sponge portion 43 are separated from each other when the electric wire 2 is accommodated in the pair of cutout portions 6, and communicates with the groove portion 32. The electric wire 2 is allowed to pass inside. In addition, when the electric wire 2 is positioned outside the pair of notches 6, the slit 45 is elastically restored by the second sponge 43 and the one end 43 a and the other end 43 b of the second sponge 43 are brought into contact with each other. Close.

  The supply means 7 supplies the coating liquid to the sponge part 3 in the storage tank 4. As shown in FIG. 4 and the like, the supply means 7 includes a dispenser 71 and a barrel 72 having one end connected to the dispenser 71 and the other end connected to the inside of the storage tank main body 41. The inside of the dispenser 71 and the inside of the barrel 72 and the inside of the barrel 72 and the inside of the storage tank body 41 are connected to each other by a connecting member such as a hose 73.

  The dispenser 71 is connected to a control device (not shown), and discharges a constant amount of air at a predetermined timing in accordance with a control signal from the control device. The discharged air flows into the barrel 72 through the hose 73. The barrel 72 contains a coating liquid. The coating liquid stored in the barrel 72 is pushed out by the air discharged from the dispenser 71 and flows into the storage tank body 41 through the hose 73.

  When the coating layer 23 is formed on the outer surface 22a of the electric wire 2 using the electric wire coating apparatus 1 having the above-described configuration, first, the one end 2a of the electric wire 2 is held by the clamp 51, and the housing tank 4 is held in the second state. The holding member 52 is fixed. Then, a coating agent is supplied from the supply means 7 to the sponge portion 3 in the storage tank 4 so that the sponge portion 3 is impregnated with the coating agent. Next, the second holding member 52 to which the storage tank 4 is fixed by the drive mechanism is brought closer to the clamp 51.

  Then, the one end portion 2 a of the electric wire 2 is inserted into the housing tank 4 through the slit 45 provided in the pair of cutout portions 6. Then, it is inserted into the groove portion 32 of the sponge portion 3 and reaches the lower end of the slit 45, that is, the vicinity of the back portion 6 a of the notch portion 6. During this time, the coating agent impregnated in the sponge portion 3 is applied to the outer surface 22 a of the electric wire 2.

  Thereafter, the drive mechanism moves the second holding member 52 away from the clamp 51, and the electric wire 2 is positioned outside the storage tank 4. During this time, excess coating agent is removed by the recess 33 provided in the inner surface 32a of the groove 32. Thus, the electric wire 2 having the coating agent applied to the outer surface 22a is dried to evaporate the solvent in the coating liquid, and the coating layer 23 made of the coating agent is formed on the outer surface 22a of the electric wire 2.

  According to the present embodiment, a pair of sponge portions 3 that are impregnated and elastically coated with a coating solution comprising a coating agent that forms the coating layer 23 and a solvent that dissolves the coating agent, and a pair of sponge portions 3 are accommodated. The storage tank 4, the contact / separation means 5 that holds the electric wire 2 and relatively contacts and separates the electric wire 2 and the storage tank 4 along the direction intersecting the longitudinal direction of the electric wire 2, and the storage tank 4 A pair of notches 6 that can accommodate the electric wire 2 to be accommodated in the accommodating tank 4, so that a desired portion in the longitudinal direction of the electric wire 2 is accommodated in the accommodating tank 4 and the pair of sponge parts 3. The coating layer 23 can be formed in contact with the wire 2, and thus the coating layer 23 can be reliably formed only on the covering portion 22 of the electric wire 2 without attaching a coating agent to the tip 2 b of the electric wire 2. Of mechanical properties and conductivity It is possible to prevent the bottom.

  Since the pair of sponge parts 3 includes the groove part 32 through which the electric wire 2 accommodated in the pair of notch parts 6 passes, the electric wire 2 can be positioned in the pair of sponge parts 3 through the groove part 32. The electric wire 2 can be smoothly positioned in the pair of sponge portions 3.

  Since a plurality of recesses 33 are provided on the inner surface 32a of the groove portion 32, excess coating liquid adhering to the outer surface 22a of the electric wire 2 can be caused to flow into the recess 33, thereby reducing the amount of coating liquid used. While being able to reduce, the coating layer 23 can be uniformly formed in the outer surface 22a of the electric wire 2. FIG.

  The portions of the pair of cutout portions 6 located at both ends in the longitudinal direction of the electric wire 2 have elasticity, and when the electric wire 2 is accommodated in the pair of cutout portions 6, it is elastically deformed and the groove portion 32. Since the second sponge part 43 having a slit 45 that is closed by elastic restoring force when the electric wire 2 is positioned outside the pair of cutout parts 6 is provided. The coating liquid impregnated in the pair of sponge portions 3 can be prevented from flowing out of the storage tank 4 from the pair of cutout portions 6.

  Since the supply means 7 for supplying the coating liquid to the pair of sponge parts 3 is provided, the coating liquid can be automatically supplied to the pair of sponge parts 3, thereby improving the working efficiency.

  Relative contact between the electric wire 2 and the container 4 containing a pair of elastic sponge parts 3 impregnated with a coating liquid composed of a coating agent for forming the coating layer 23 and a solvent for dissolving the coating agent. Since the coating layer 23 is formed on the outer surface 22a of the electric wire 2 by putting the electric wire 2 in and out of the accommodating tank 4, the desired portion in the longitudinal direction of the electric wire 2 is accommodated in the accommodating tank 4 and a pair of The coating layer 23 can be formed in contact with the sponge portion 3, and thus the coating layer 23 can be reliably formed only on the covering portion 22 of the electric wire 2 without attaching a coating agent to the tip 2 b of the electric wire 2. Thus, it is possible to prevent the mechanical properties and conductivity of the electric wire 2 from being lowered.

  In the present embodiment, the wire coating apparatus 1 forms the coating layer 23 on the outer surface 22a of the covering portion 22 of the wire 2 before the colorant is applied by a coating agent (that is, a so-called undercoat agent). It was. However, in the present invention, the coating layer 23 may be formed on the outer surface of the covering portion 22 after the colorant is applied by using a coating agent (that is, a so-called topcoat agent).

  Further, in the present embodiment, the drive mechanism contacts and separates the housing tank 4 from the electric wire 2, but the electric wire 2 may be contacted and separated from the housing tank 4. Further, as shown in FIG. 8, the holding member 55 that holds the electric wire 2 includes a band plate-like holding portion main body 56 and a plurality of clamps 51 fixed to the holding portion main body 56. A second drive mechanism (not shown) for holding the plurality of electric wires 2 and displacing the holding member 55 or the second holding member 52 so as to sequentially position the plurality of electric wires 2 above the storage tank 4 is provided. Also good.

  In addition, embodiment mentioned above only showed the typical form of this invention, and this invention is not limited to embodiment. That is, various modifications can be made without departing from the scope of the present invention.

It is a perspective view which shows a part of coating apparatus of the electric wire concerning one Embodiment of this invention. It is a perspective view of the electric wire in which the coating layer was formed with the coating apparatus of the electric wire of this invention. It is sectional drawing along the III-III line in FIG. It is a front view of the coating apparatus of the electric wire shown by FIG. It is a front view which shows the state by which the electric wire shown by FIG. 4 was accommodated in the storage tank. 6 is a cross-sectional view of the electric wire coating apparatus shown in FIG. 5 along a plane parallel to the paper surface of FIG. 5. FIG. 6 is a top view of the electric wire coating apparatus shown in FIG. 5. It is a perspective view which shows a part of coating apparatus of the electric wire concerning other embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Electric wire coating apparatus 2 Electric wire 3 A pair of sponge parts (porous member)
4 Storage tank 5 Contact / separation means 6 Notch (wire storage part)
7 Supply means 22a Outer surface 23 Coating layer 32 Groove 32a Inner surface 33 Recess 43 Second sponge part (second porous member)
45 slits

Claims (6)

In a wire coating device that forms a coating layer on the outer surface of the wire,
A porous member impregnated inside with a coating liquid comprising a coating agent for forming the coating layer and a solvent for dissolving the coating agent, and having elasticity;
A storage tank for storing the porous member;
Contact / separation means for holding the electric wire and relatively contacting and separating the electric wire and the housing tank along a direction intersecting a longitudinal direction of the electric wire;
An electric wire coating device comprising: an electric wire accommodating portion that allows the electric wire contacting and separating from the accommodating tank to be accommodated in the accommodating tank.   The said porous member was provided with the groove part which lets the said electric wire accommodated in the said electric wire accommodating part pass, The coating apparatus of the electric wire of Claim 1 characterized by the above-mentioned.   The wire coating apparatus according to claim 2, wherein a plurality of recesses are provided on the inner surface of the groove.   The portions of the electric wire housing portion located at both ends in the longitudinal direction of the electric wire have elasticity, and when the electric wire is accommodated in the electric wire housing portion, it is elastically deformed and communicates with the groove portion. The second porous member having a slit that allows a passage of the electric wire and has a slit that closes by an elastic restoring force when the electric wire is positioned outside the electric wire housing portion. Item 4. The electric wire coating apparatus according to Item 3.   The wire coating apparatus according to any one of claims 1 to 4, further comprising supply means for supplying the coating liquid to the porous member. In the method of coating an electric wire in which a coating layer is formed on the outer surface of the electric wire,
And the electric wire, and a storage tank for accommodating the porous member a coating solution having impregnated and elastic inside consisting of a coating agent for forming the coating layer with a solvent for dissolving the coating agent in the longitudinal direction of the wire A method for coating an electric wire, wherein the electric wire is taken in and out of the housing tank by forming a coating layer on an outer surface of the electric wire by being relatively moved along an intersecting direction .

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