JP6168600B2 - Electrode body connection structure - Google Patents

Description

  The present invention relates to an electrode body connection structure in which an electrode body that contacts a skin surface of a human body and a lead-out end of a lead wire led out from an operating device are electrically connected via a connector. The electrode body is used as an electrode in contact with the skin surface for iontophoresis, electrocardiogram measurement, low-frequency treatment, or the like.

  This type of electrode body connection structure can be seen, for example, in a facial mask according to Patent Document 1. There, the mask functioning as an electrode body and the lead-out end of the lead wire led out from the facial device are electrically connected via a connector. The mask includes a base cloth made of towel cloth, a conductive cloth sewn on the skin surface side of the base cloth, and a metal male hook that functions as an electrode-side connector, and the male hook is electrically connected to the conductive cloth. In the state, it is fixed to the outer surface side of the base fabric. The lead-side connector includes a metal female hook that is detachably connected to the male hook, and a housing that holds the female hook. Both hooks have a function as a conduction means for performing electrical connection between the connectors and a function as a connection means for maintaining an electrical connection state between the connectors. When the low frequency oscillation circuit built in the facial device is driven with the hooks connected and the facial conductor lead wire and the conductive fabric of the mask electrically connected, a pulse current is supplied from the conductive fabric to the face. And can perform facial care.

Registered Utility Model No. 3078100 (paragraph numbers 0006 to 0007, FIG. 3)

  In the facial mask of Patent Document 1, when the facial care is completed, the mask and lead wire connectors are separated from each other. In that case, for example, the base hook and the conductive cloth around the electrode side connector (male hook) are picked with the fingers of one hand and the lead side connector is picked with the fingers of the other hand. And separate the female hook. However, since the housing of the lead-side connector according to Patent Document 1 is small and the peripheral surface is rounded, it is difficult to securely pick the lead-side connector with a finger, and therefore it may take time to separate both hooks. In addition, when the coupling force between the male hook and female hook is large, a strong tensile force acts on the male hook during the separation operation, so the base fabric and conductive cloth around the male hook are deformed, Or it may break early.

  An object of the present invention is to provide an electrode body connection structure that can easily separate a lead-side connector from an electrode-side connector and that can effectively prevent deformation and breakage of the electrode body during the separation operation. There is.

  The present invention relates to an electrode body connection structure for electrically connecting an electrode body 3 in contact with the skin surface of a human body to a lead-out end of a lead wire 2 led out from an operating device 1 via connectors 5 and 6. Is targeted. The electrode body 3 includes an electrode main body 14 formed by forming an electrode layer 16 on one surface of the sheet base material 15, and an electrode-side connector 5 fixed to the outer surface side of the sheet base material 15 in a state of being electrically connected to the electrode layer 16. I have. The lead-side connector 6 includes a lead-side terminal 33 that is detachably connected to the electrode-side terminal 19 of the electrode-side connector 5 and a housing 34 that holds and fixes the lead-side terminal 33. A finger-hanging flange 44 is formed around the housing 34, and a plate-like reinforcing body 20 that reinforces the sheet surface around the base end of the electrode-side terminal 19 is fixed to the outer surface of the sheet base material 15. . In the present invention, the “electrode body 3 in contact with the skin surface of the human body” refers to the electrode body 3 in direct contact with the skin surface as shown in FIG. 9 and the face mask 10 as shown in FIG. And an electrode body 3 that indirectly contacts the skin surface.

  The electrode body 14 and the reinforcing body 20 have a higher flexibility than the finger flange 44.

  The thickness dimension T2 of the reinforcing body 20 is set to be larger than the thickness dimension T1 of the electrode body 14.

  The reinforcing body 20 includes a base 22 that surrounds the base end of the electrode-side terminal 19, and a protrusion 23 that protrudes from the periphery of the base 22 along the sheet surface of the electrode body 14. The protrusion 23 protrudes outward beyond the overhanging end of the finger flange 44.

  When the direction in which the lead-side terminal 33 is separated from the electrode-side terminal 19 is defined as the upward direction, the finger-hanging flange 44 is formed so as to protrude from the upper end of the side surface of the housing 34, so A clearance E is secured.

  The thickness dimension T3 of the finger hook flange 44 is set to be larger than the thickness dimension (T1 + T2) in which the electrode body 14 and the reinforcing body 20 are overlapped.

  The electrode layer 16 is composed of a laminate of a nonpolarizable electrode 46 having a single layer structure or a multilayer structure formed on the sheet base material 15 and a polarizable electrode 47 covering the nonpolarizable electrode 46. At least one layer of the nonpolarizable electrode 46 is configured as the display layer 48. On the outer surface of the polarizable electrode 47, a concavo-convex display surface 51 is formed which has the same concavo-convex shape as the display layer.

  The display layer 48 is formed on the sheet base material 15. A transparent display surface 52 through which the display layer 48 can be viewed through the sheet base material 15 is formed at least on the portion of the sheet base material 15 that faces the display layer 48.

  The non-polarizable electrode 46 is formed in a mesh shape.

  In the present invention, the finger-hanging flange 44 is formed so as to protrude around the housing 34 of the lead-side connector 6. According to this, the lead-side connector 6 can be quickly and reliably separated from the electrode-side connector 5 simply by hooking the finger-tip flange 44 and pulling the finger-hanging flange 44 away from the electrode-side connector 5. be able to. Therefore, an electrode body connection structure excellent in separation operability of the lead side connector 6 with respect to the electrode side connector 5 can be obtained. In addition, since the plate-like reinforcing body 20 is fixed around the base end of the electrode-side terminal 19, strong tensile force acting on the electrode-side terminal 19 during the separation operation is dispersed by the reinforcing body 20 and applied to the electrode body 14. In other words, it is possible to prevent the previous tensile force from being concentrated on the sheet surface around the base end of the electrode-side terminal 19. Accordingly, it is possible to effectively prevent the electrode main body 14 from being deformed or broken around the electrode side terminal 19 when the connectors 5 and 6 are separated.

  When the electrode body 14 and the reinforcing body 20 have higher flexibility than the finger-hanging flange 44, the electrode body 14 and the reinforcing body 20 are simultaneously bent in a direction away from the finger-hanging flange 44 with a smaller force. Can do. That is, the electrode main body 14 and the reinforcing body 20 can be bent with a smaller force, and the opposing distance between the electrode main body 14 and the reinforcing body 20 with respect to the finger hook flange 44 can be increased more easily. As described above, since the fingertip can be hooked on the finger-hanging flange 44 more quickly and reliably, the separation operability can be improved.

  When the thickness dimension T2 of the reinforcing body 20 is set to be larger than the thickness dimension T1 of the electrode body 14, the reinforcing effect by the reinforcing body 20 can be enhanced and the electrode body 14 can be more reliably prevented from being damaged. Further, since the reinforcing body 20 partially reinforces the periphery of the electrode side terminal 19 in the electrode main body 14, even if the thickness of the reinforcing body 20 is increased, the reinforcing body 20 is not around the electrode side terminal 19 in the electrode main body 14. The flexibility of the electrode body 14 is not impaired, and therefore the electrode body 14 can be closely adhered to the skin surface.

  When the protruding portion 23 of the reinforcing body 20 protrudes outward beyond the protruding end of the finger-hanging flange 44, the reinforcing body 20 can be easily grasped with fingers when the lead-side connector 6 is separated from the electrode-side connector 5. Become. Further, when the electrode body 14 is picked via the reinforcing body 20, the force acting on the electrode body 14 around the electrode-side terminal 19 can be reduced as compared with the case where the electrode body 14 is directly picked. 14 can be prevented more accurately.

  Since the finger-hanging flange 44 is formed so as to be extended from the upper end of the side surface of the housing 34 and the finger-hanging gap E is secured between the finger-hanging flange 44 and the reinforcing body 20, the finger-tip is easily hooked on the finger-hanging flange 44. 6 can be further reliably separated from the electrode-side connector 5.

  If the thickness dimension T3 of the finger hook flange 44 is set to be larger than the thickness dimension (T1 + T2) in which the electrode body 14 and the reinforcing body 20 are overlapped, the strength of the finger hook flange 44 is increased and the finger hook flange 44 is bent or broken. Can be reliably prevented.

  When the electrode layer 16 is formed of a laminate of the nonpolarizable electrode 46 and the polarizable electrode 47, the electric resistance of the entire electrode layer 16 can be reduced, and an electric current can be accurately supplied to the skin surface touching the electrode layer 16. it can. Even if a part of the polarizable electrode 47 is lost due to wear or the like, the nonpolarizable electrode 46 on the inside remains, so that the electrical resistance of the entire electrode layer 16 does not become excessive, and thus the function of the electrode body 3 is maintained. Is done. That is, when the electrode layer 16 is a laminate of the electrodes 46 and 47, the electrode body 3 that can withstand long-term use can be obtained. Further, when at least one layer of the non-polarizable electrode 46 is configured as the display layer 48 and the uneven display surface 51 having the same unevenness as the display layer 48 is formed on the outer surface of the polarizable electrode 47, the display layer 48 is polarizable. The electrode 47 and the sheet base material 15 can be covered and protected from both sides. Incidentally, when a display layer is formed on the outer surface of the sheet base material 15 by printing, the display layer is exposed and is easily lost due to wear. Furthermore, since the display layer 48 can be formed simultaneously with the formation of the non-polarizable electrode 46, the process of separately forming the display layer 48 can be omitted, and the manufacturing cost can be reduced.

  When the display layer 48 is formed on the sheet base material 15 and a transparent display surface 52 that allows the display layer 48 to be seen through the sheet base material 15 is formed on at least a portion of the sheet base material 15 that faces the display layer 48, In a state where the electrode layer 16 of the main body 14 is in contact with the skin surface, the content of the display unit 48 can be confirmed by the fluoroscopic display surface 52 without removing the electrode body 3 from the skin surface.

  When the nonpolarizable electrode 46 is formed in a mesh shape, the material cost required for the nonpolarizable electrode 46 can be reduced as compared with the case where the nonpolarizable electrode 46 is formed over the entire surface. Moreover, since the flexibility of the non-polarizable electrode 46 can be increased and the followability to the sheet base material 15 at the time of bending deformation can be improved, breakage such as division due to bending of the non-polarizable electrode 46 can be effectively prevented.

It is a longitudinal cross-sectional view of the electrode body connection structure of this invention which concerns on 1st Embodiment. It is use explanatory drawing of the beauty apparatus to which the electrode body connection structure which concerns on 1st Embodiment is applied. It is a perspective view in the state where the lead side connector concerning a 1st embodiment was separated from the electrode side connector. It is a top view in the state where the lead side connector concerning a 1st embodiment was connected with the electrode side connector. It is a bottom view of the electrode body which concerns on 1st Embodiment. It is the sectional view on the AA line in FIG. It is a figure which shows separation operation | movement from the electrode side connector of the lead side connector which concerns on 1st Embodiment. It is a bottom view of the electrode body which concerns on 2nd Embodiment. It is use explanatory drawing of the beauty equipment to which the electrode body connection structure concerning 3rd Embodiment is applied. It is a top view in the state where the lead side connector concerning a 3rd embodiment was connected with the electrode side connector. It is a fragmentary longitudinal cross-sectional view of the electrode body connection structure which concerns on 3rd Embodiment. It is a bottom view which shows the principal part of the electrode body which concerns on 3rd Embodiment. It is a longitudinal cross-sectional view of the electrode body connection structure which concerns on 4th Embodiment. It is a longitudinal cross-sectional view of the electrode body connection structure which concerns on 5th Embodiment. It is a top view in the state where the lead side connector concerning a 6th embodiment was connected with the electrode side connector. It is a top view in the state where the lead side connector concerning a 7th embodiment was connected with the electrode side connector.

First Embodiment FIGS. 1 to 7 show a first embodiment in which an electrode body connection structure according to the present invention is applied to a beauty device. In FIG. 2, the beauty device includes a communication terminal (actuating device) 1 formed of a touch panel type smartphone, a pair of electrode bodies 3 and 3 connected to the communication terminal 1 via a lead wire 2, and the communication terminal 1. It consists of applications installed on the system. By this application, the operating state of the pair of electrode bodies 3 and 3 can be controlled. A plug 4 for connecting to the output terminal of the communication terminal 1 is provided at one end of the lead wire 2. The other end of the lead wire 2 is bifurcated, and a lead-side connector 6 that is paired with the electrode-side connector 5 is provided at each branch end.

  The beauty device according to the present embodiment uses a pair of electrode bodies 3 and 3 attached to a commercially available face mask 10. The face mask 10 includes an upper mask 11 that covers the eyes and the forehead, and a lower mask 12 that covers the mouth and cheeks. Both masks 11 and 12 are made of non-woven fabric and impregnated with a lotion (skin external preparation) suitable for ion introduction.

  As shown in FIG. 3, the electrode body 3 includes a flexible sheet-like electrode main body 14, an electrode-side connector 5 fixed to the electrode main body 14, a reinforcing body 20, and the like. The electrode body 14 is formed by forming an electrode layer 16 on one side of the skin surface of the sheet base material 15. Hereinafter, as indicated by arrows and characters in FIGS. 1 and 6, the thickness direction of the electrode body 14 is defined as the vertical direction, the outer surface of the sheet base material 15 is defined as the upper surface, and the outer surface of the electrode layer 16 is defined as the lower surface. The electrode main body 14 has a shape in which a leaf-like portion having a shape similar to a ginkgo leaf and one tongue piece are integrated, and the electrode main body 14 is provided on both ends of the leaf-like portion and the lower surface of the tongue piece. A male surface fastener 24 for attaching to the surface of the face mask 10 is bonded and fixed (see FIG. 1).

  The electrode side connector 5 is made of a metal male hook, and the whole constitutes an electrode side terminal 19. The electrode-side terminal 19 is fixed to the upper surface side of the tongue piece of the electrode main body 14 and protrudes upward in a state of being electrically connected to the electrode layer 16 of the electrode main body 14. The reinforcing body 20 is fixed to the upper surface side of the electrode body 14 so as to surround the base end of the electrode side terminal 19 and reinforces the sheet surface around the base end of the electrode side terminal 19. As shown in FIG. 3, the reinforcing body 20 integrally includes a circular base portion 22 that surrounds the base end of the electrode-side terminal 19 and a protruding portion 23 that protrudes from the periphery of the base portion 22 along the sheet surface of the electrode body 14. The whole is formed in the plate shape which has high intensity | strength compared with the electrode main body 14. FIG. The reinforcing body 20 in plan view is entirely disposed inside the outline of the electrode body 14 (see FIG. 4).

  As shown in FIG. 1, the electrode side terminal 19 is configured by connecting a hook body 25 and a hook support body 26 both made of a metal molded product. The hook body 25 is formed in a hat shape integrally including an engaging convex portion 27 that engages with an engaging concave portion 39 of a lead side terminal 33 described later and a flange 28 that is in close contact with the outer surface of the reinforcing body 20. The hook support 26 includes a shaft portion 29 having a circular cross section that is connected to and fixed to the inner surface of the engagement convex portion 27 through the electrode body 14 and the reinforcing body 20, and a base portion 30 that is in close contact with the outer surface of the electrode layer 16. It is prepared as one. When the base portion 30 is in surface contact with the electrode layer 16, the electrode-side terminal 19 and the electrode layer 16 are electrically connected.

  The hook body 25 and the hook support 26 are fixed by caulking so that they cannot be separated from each other and cannot be rotated relative to each other. By fixing both 25 and 26, the electrode body 14 and the reinforcing body 20 are sandwiched and fixed from above and below by the flange 28 and the base portion 30, so that they cannot be separated from each other and are not relatively rotatable. The base portion 30 is entirely covered by the surface fastener 24 described above. The hook-and-loop fastener 24 is made of a material that is firmer than the electrode body 14 and functions as a reinforcing body that reinforces the periphery of the electrode-side terminal 19.

  The reinforcing body 20 is formed of a plate-like body made of a synthetic resin such as polypropylene or nylon and has flexibility similar to the electrode body 14, but is harder than the electrode body 14. A thickness dimension T2 of the reinforcing body 20 is set to be larger than a thickness dimension T1 of the electrode body 14. The sheet base material 15 of the electrode body 14 is formed of a synthetic resin such as PET (polyethylene terephthalate), polyimide, polyamide, or polypropylene. The sheet base material 15 and the reinforcing body 20 are formed of a transparent material, and the electrode layer 16 is formed of a colored conductive material. Details of the electrode layer 16 will be described later.

  As shown in FIGS. 1 and 3, the lead-side connector 6 includes a lead-side terminal 33 made of a metal female hook and a housing 34 that holds and fixes the lead-side terminal 33. The lead-side terminal 33 is integrally provided with a disk-shaped flat plate portion 38, an engagement recess 39 formed at the center of the lower surface of the flat plate portion 38, and a cylindrical wall 40 that rises upward from the peripheral edge of the flat plate portion 38. The lead-out end of the lead wire 2 is electrically connected to the outer peripheral surface of the cylindrical wall 40. The engagement recess 39 can be engaged with the engagement protrusion 27 of the electrode side terminal 19, and the opening edge of the engagement recess 39 is elastic to the constricted portion of the engagement protrusion 27 that has entered the recess 39. An engaging metal wire 41 is provided. On the upper surface side of the lead side terminal 33, a cover 42 that closes the upper surface opening of the cylindrical wall 40 is attached. The cover 42 is formed in a round dish shape that opens downward, and is fixed to the lead-side terminal 33 with its outer peripheral surface being in close contact with the inner peripheral surface of the cylindrical wall 40.

  The housing 34 is formed of a rigid plastic substantially disk-shaped injection-molded product, and the lead-side terminal 33, the cover 42, and the lead wire 2 are insert-fixed at the time of molding. Specifically, the cover 42 is attached to the lead side terminal 33, and the lead wire 2 connected to the lead end 2 is connected and integrated into the mold, and then molten resin is injected into the mold. By hardening, the lead-side terminal 33 and the like are embedded and fixed in the housing 34. The cover 42 is provided to prevent the molten resin from entering the inside of the cylindrical wall 40. When the molten resin enters the inside of the cylindrical wall 40, the molten resin adheres to the metal wire 41 and inhibits its elastic deformation, or the molten resin passes through the holes for attaching the metal wire 41 to the engagement recess 39. Inconvenience such as leakage into the inside occurs.

  When the engagement convex portion 27 of the electrode side terminal 19 is pushed into the engagement concave portion 39, the engagement convex portion 27 passes through the metal wire 41 while expanding the metal wire 41, and the metal wire 41 eventually becomes a constricted portion of the engagement convex portion 27. The electrode side terminal 19 and the lead side terminal 33 are connected by the drop engagement. In this connected state, the engaging convex portion 27 contacts the engaging concave portion 39 and the metal wire 41, and the flange 28 contacts the flat plate portion 38, so that the electrode side terminal 19 and the lead side terminal 33 are electrically connected. Connected. Thus, the electrode-side terminal 19 and the lead-side terminal 33 function as a conduction means for performing electrical connection between the connectors 5 and 6 and as a connection means for maintaining the electrical connection state between the connectors 5 and 6. Combines functionality. The contact surfaces of the engagement convex portion 27 and the engagement concave portion 39 are formed in a circular shape in cross section, so that both terminals 19 and 33 can be relatively rotated around the central axis of the engagement convex portion 27 in the connected state. . Therefore, after connecting both terminals 19 and 33, the electrode body 3 and the lead-side connector 6 can be relatively rotated around the central axis in the vertical direction to adjust the relative position around the central axis.

  In order to facilitate the separation of the connectors 5 and 6, a horizontal plate-like finger flange 44 extending in parallel with the electrode body 14 and the reinforcing body 20 is formed on the upper end portion of the outer peripheral surface of the housing 34. By arranging the finger hook flange 44 at the upper end of the housing 34, a finger hook gap E in the vertical direction is ensured between the finger hook flange 44 and the reinforcing body 20. The finger-hanging flange 44 is molded integrally with the housing 34, and the thickness dimension T3 is set larger than the thickness dimension (T1 + T2) in which the electrode body 14 and the reinforcing body 20 are overlapped. Therefore, the finger hook flange 44 has sufficiently higher strength than the electrode body 14 and the reinforcing body 20. As shown in FIG. 4, when the electrode body 3 and the lead-side connector 6 are relatively rotated so that the protruding portion 23 of the reinforcing body 20 and the finger-hanging flange 44 face each other, the protruding portion 23 is the protruding end of the finger-hanging flange 44. It protrudes outward beyond.

  As shown in FIGS. 5 and 6, the electrode layer 16 is configured by a laminate of a nonpolarizable electrode 46 formed on the sheet base material 15 and a polarizable electrode 47 covering the nonpolarizable electrode 46. The non-polarizable electrode 46 can have a single-layer structure or a multi-layer structure, and examples thereof include silver and copper. In this embodiment, the non-polarizable electrode 46 has a single-layer structure of silver. Examples of the material for forming the polarizable electrode 47 include carbon, platinum, gold, aluminum, and titanium. In this embodiment, carbon is used. Both the nonpolarizable electrode 46 and the polarizable electrode 47 have the same outline as the sheet base material 15. The entire non-polarizable electrode 46 is formed in a fine network. In order to form the electrode layer 16, for example, the nonpolarizable electrode 46 is formed on the sheet base material 15 by silk screen printing, and then the polarizable electrode 47 is formed on the nonpolarizable electrode 46 by gravure printing.

  The entire nonpolarizable electrode 46 according to this embodiment forms a display layer 48. Specifically, three display holes 49 having an alphabet “ABC” shape in plan view are formed in the center of the display layer 48 (non-polarizable electrode 46). Since FIG. 5 is a bottom view of the electrode body 3, the display hole 49 is obtained by inverting “ABC”. The polarizable electrode 47 is in close contact with the outer surface of the mesh-like display layer 48 and is in close contact with the inner surface of the sheet base material 15 through the three display holes 49 and a large number of fine holes constituting the mesh of the display layer 48. doing. Due to this adhesion, a display recess 50 having the same shape as the three display holes 49 is formed at the center of the outer surface of the polarizable electrode 47, and a large number of minute depressions are formed on the entire outer surface of the polarizable electrode 47 excluding the display recess 50. It is formed. As described above, the uneven display surface 51 including the display recess 50 is formed on the outer surface of the polarizable electrode 47, that is, the lower surface of the electrode body 14.

  In this embodiment, since the entire sheet base material 15 is formed of a transparent material, the display layer 48 (non-polarizable electrode 46) can be seen through the sheet base material 15, and three display holes can be seen. The polarizable electrode 47 can be seen through 49. That is, when the electrode main body 14 is viewed in plan as shown in FIG. 4, the character “ABC” of the color (black) of the polarizable electrode 47 against the color of the display layer 48 (silver) can be seen. Thus, on the outer surface of the sheet base material 15, that is, on the upper surface of the electrode body 14, a transparent display surface 52 through which the display layer 48 can be seen through the sheet base material 15 is formed. When the fluoroscopic display surface 52 is formed, the content of the display unit 48 is confirmed by the fluoroscopic display surface 52 without removing the electrode body 3 from the skin surface in a state where the electrode layer 16 of the electrode body 14 is in close contact with the face mask 10. can do. As described above, in this embodiment, since the uneven display surface 51 is formed on the lower surface of the electrode body 14 and the transparent display surface 52 is formed on the upper surface of the electrode body 14, the user can display the display layer from both the upper and lower surfaces of the electrode body 14. The contents of 48 can be confirmed.

  In order to perform a beauty treatment using the beauty device having the above-described configuration, as shown in FIG. 2, the plug 4 of the lead wire 2 and the lead side connectors 6 and 6 are respectively connected to the communication terminal 1 and the electrode side connectors 5 and 5. After connecting, the application of the communication terminal 1 is started and the operation mode and the operation time are selected. Next, in the state where the face mask 10 impregnated with the skin lotion is in close contact with the skin surface and the electrode bodies 3 and 3 are in close contact with the surface, the selected operation mode, for example, the ion derivation mode (ion cleansing mode) is performed. Start it. As a result, a low-frequency pulse current is supplied to the skin surface, and dirt that has entered the pores, wrinkles, or heels of the skin surface can be adsorbed to the face mask 10 to keep the skin surface clean. . When a predetermined time (3 to 5 minutes) elapses, the supply of the low frequency pulse current is automatically stopped.

  When a series of beauty treatments is completed, the face mask 10 is removed from the face skin, and the electrode body 3 is further removed from the face mask 10. In order to separate the lead-side connector 6 from the electrode-side connector 5 of the electrode body 3, as shown in FIG. 7, the vicinity of the electrode-side terminal 19 in the electrode body 3 can be separated with the thumb and index finger of one hand (for example, the left hand). In the picked state, the thumb of the other hand (for example, the right hand) is hooked on the finger flange 44 of the lead side connector 6 to separate the lead side terminal 33 of the lead side connector 6 from the electrode side terminal 19. At this time, the thumb and index finger of the left hand sandwich the electrode body 14 and the protruding portion 23 of the reinforcing body 20 from both sides in a stacked state.

  If the housing 34 of the lead-side connector 6 is provided with the finger-hanging flange 44, the finger-tip can be hooked on the finger-hanging flange 44 and the housing 34 can be reliably captured. Can be easily separated. When the plate-like reinforcing body 20 is fixed around the base end of the electrode-side terminal 19, a strong tensile force acting on the electrode-side terminal 19 during the separation operation is dispersed by the reinforcing body 20 and transmitted to the electrode body 14. Therefore, it is possible to eliminate the concentration of the previous tensile force on the sheet surface around the base end of the electrode side terminal 19. Accordingly, it is possible to effectively prevent the electrode body 14 from being deformed or damaged around the electrode side terminal 19 when the connectors 5 and 6 are separated.

Second Embodiment FIG. 8 shows a second embodiment in which the electrode body connection structure according to the present invention is applied to a beauty device. The present embodiment is different from the first embodiment in the structure of the electrode body 14 of the electrode body 3. Specifically, the non-polarizable electrode 46 of the electrode layer 16 has a two-layer structure of a base layer 56 and a display layer 48, and the display layer 48, the base layer 56, and the polarizable electrode from the sheet base material 15 side. 47 are stacked in the order of description. The display layer 48 itself has the shape of alphabets “A”, “B”, and “C”. The base layer 56 has the same outline as the sheet base material 15 and the polarizable electrode 47 and is formed in a fine mesh shape as a whole.

  When the polarizable electrode 47 is in close contact with the display layer 48 via the base layer 56, a display convex portion 57 having the same shape as the display layer 48 is formed at the center of the outer surface of the polarizable electrode 47, and further includes the display convex portion 57. A large number of fine depressions are formed on the entire outer surface of the polarizable electrode 47. As described above, the uneven display surface 51 including the display protrusion 57 is formed on the outer surface of the polarizable electrode 47, that is, the lower surface of the electrode body 14. Further, since the entire sheet base material 15 is formed of a transparent material, when the electrode main body 14 is viewed in plan, the character “ABC” of the color of the display layer 48 with the color of the base layer 56 as a background can be seen. Thus, on the outer surface of the sheet base material 15, that is, on the upper surface of the electrode body 14, a transparent display surface 52 through which the display layer 48 can be seen through the sheet base material 15 is formed. Since the other points are the same as those of the first embodiment, the same members are denoted by the same reference numerals and the description thereof is omitted. The same applies to the following embodiments.

Third Embodiment FIGS. 9 to 12 show a third embodiment in which the electrode body connection structure according to the present invention is applied to a beauty device. This embodiment is different from the first embodiment in the structure of the electrode body 3. As shown in FIG. 10, the electrode main body 14 is formed in a rectangular shape with rounded four corners, and the electrode-side connector 5 is disposed at a position biased from the center to the short side. As shown in FIG. 11, an adhesive sheet 60 having adhesiveness and conductivity is detachably attached to the outer surface of the electrode layer 16, that is, the lower surface of the electrode body 14 in place of the surface fastener 24 of the first embodiment. ing. By utilizing the adhesiveness of the adhesive sheet 60, the electrode body 3 can be directly attached to the skin surface as shown in FIG. Alternatively, the electrode body 3 can be attached to the face mask 10 as in the first embodiment. The pressure-sensitive adhesive sheet 60 can also be attached to the electrode body 14 in an inseparable manner.

  As shown in FIG. 12, the non-polarizable electrode 46 of the electrode layer 16 has a single layer structure, and the whole constitutes a display layer 48. The display layer 48 itself has the shape of alphabets “A”, “B”, and “C”, and is formed in a fine mesh shape as a whole. When the polarizable electrode 47 is in close contact with the display layer 48 and the sheet base material 15, a display convex portion 57 having the same shape as the display layer 48 is formed on a part of the outer surface of the polarizable electrode 47. A large number of fine depressions are formed on the surface. As described above, the uneven display surface 51 including the display protrusion 57 is formed on the outer surface of the polarizable electrode 47, that is, the lower surface of the electrode body 14. The uneven display surface 51 can be viewed in a state where the adhesive sheet 60 is separated. Further, since the entire sheet base material 15 is formed of a transparent material, when the electrode body 14 is viewed in plan as shown in FIG. 10, the character “ABC” of the color of the display layer 48 with the color of the polarizable electrode 47 as the background. Can see. Thus, on the outer surface of the sheet base material 15, that is, on the upper surface of the electrode body 14, a transparent display surface 52 through which the display layer 48 can be seen through the sheet base material 15 is formed.

(4th Embodiment) 4th Embodiment of the electrode body connection structure which concerns on this invention is shown in FIG. In this case, the electrode side terminal 19 and the lead side terminal 33 are connected by magnetic force (magnetic attraction force). Specifically, the electrode side terminal 19 is made of a disk-shaped ferromagnetic material having conductivity, and the lead side terminal 33 is made of a metal yoke in which a magnet 62 is built. Examples of the material constituting the electrode side terminal 19 include conductive ferrite and ferromagnetic stainless steel, such as martensitic stainless steel.

  The upper surface of the electrode side terminal 19 becomes a contact surface with the lead side terminal 33, and the lower surface of the electrode side terminal 19 is in close contact with the adhesive sheet 60. The electrode body 14 and the reinforcing body 20 are refracted along the outer surface of the electrode-side terminal 19, and the electrode layer 16 is in close contact with the peripheral side surface of the electrode-side terminal 19 and the peripheral portion of the upper surface. Due to this close contact structure, the contact area between the electrode layer 16 and the electrode-side terminal 19 is increased, and the energized state of both 16 and 19 is improved. Since the electrode side terminal 19 itself has conductivity, a current also flows between the electrode side terminal 19 and the adhesive sheet 60.

  The lead-side terminal 33 is formed in a bottomed cylindrical shape that opens downward toward the electrode-side terminal 19, and a restriction pin 63 is fixed along the central axis thereof. The protruding end of the restriction pin 63 protrudes downward from the opening surface of the lead-side terminal 33, and an accommodation hole 64 that can be engaged with the protruding end is formed in the center of the electrode-side terminal 19. When the lead-side terminal 33 is brought into close contact with the upper surface of the electrode-side terminal 19 by magnetic force, both the terminals 19 and 33 are electrically connected, and the protruding end of the regulation pin 63 enters the accommodation hole 64, so that the electrode-side connector The horizontal movement of the lead-side connector 6 with respect to 5 (electrode-side terminal 19) is restricted. Since the other points are the same as those of the third embodiment, the same members are denoted by the same reference numerals and the description thereof is omitted. The same applies to the following embodiments. As shown in this embodiment, the form of the electrode side terminal 19 and the lead side terminal 33 is not limited to a hook.

Fifth Embodiment FIG. 14 shows a fifth embodiment of an electrode body connection structure according to the present invention. There, the electrode side terminal 19 is composed of an electrode side conducting body 67 and electrode side connecting body 68 made of independent parts, and the lead side terminal 33 is made up of a lead side conducting body 69 and lead side connecting body 70 made of independent parts. It is configured. Specifically, the electrode-side conductive body 67 is composed of a metal rivet, and the electrode-side coupling body 68 is composed of a male hook similar to that in the first embodiment. The electrode-side conductive body 67 is disposed near the end of the base portion 22 farthest from the protruding portion 23 and is fixed by caulking in a state of penetrating the electrode main body 14 and the reinforcing body 20. The electrode-side conductive body 67 is electrically connected to the electrode layer 16 when the lower end portion thereof is in surface contact with the outer surface of the electrode layer 16.

  The lead-side conductive body 69 is composed of a leaf spring electrically connected to the lead-out end of the lead wire 2, and the lead-side coupling body 70 is composed of a female hook similar to the first embodiment. Yes. The lower end portion of the lead side conductive body 69 projects downward from the lower surface of the housing 34 around the cylindrical wall 40 of the lead side connecting body 70. The protruding end of the lead-side conductive body 69 is surrounded by a peripheral wall and a cylindrical wall 40 protruding downward from the lower surface of the housing 34. When the electrode-side connecting body 68 and the lead-side connecting body 70 are connected, the lead-side conducting body 69 comes into contact with the end face of the electrode-side conducting body 67 on the reinforcing body 20 side, and the both conductors 67 and 69 are interposed therebetween. Thus, the lead wire 2 and the electrode layer 16 are electrically connected.

  The electrode side conducting body 67 made of rivets sandwiches the electrode body 14 and the reinforcing body 20 in the same manner as the electrode side connecting body 68 made of a male hook. Thus, when the electrode body 14 and the reinforcing body 20 are sandwiched and fixed at a plurality of locations, the relative rotation of the electrode body 14 and the reinforcing body 20 can be prevented more reliably. Although not shown, between the electrode side connecting body 68 and the lead side connecting body 70, the electrode side conducting body 67 and the lead side conducting body 69 are in contact with each other to prevent relative rotation of both the connecting bodies 68 and 70. A positioning structure is provided. In this embodiment, the reinforcing body 20 is disposed around the electrode-side conductive body 67 and the electrode-side connection body 68, but it is the electrode-side connection body 68 that exerts a tensile force when the connectors 5 and 6 are separated. Therefore, it is sufficient that the reinforcing body 20 is disposed at least around the electrode side connecting body 68.

Sixth Embodiment FIG. 15 shows a sixth embodiment of the electrode body connection structure according to the present invention. There, the electrode body 14 is formed in a triangular shape with rounded corners, and an electrode-side terminal 19 is disposed at the center thereof. The reinforcing body 20 includes three Y-shaped projecting portions 23 that project from the peripheral edge of the base portion 22 along the sheet surface of the electrode body 14. The three protrusions 23 are arranged around the base portion 22 at equal intervals in the circumferential direction, and extend toward the center of each side of the electrode body 14.

(7th Embodiment) 7th Embodiment of the electrode body connection structure which concerns on this invention is shown in FIG. Here, the electrode body 14 is formed in a circular shape, and an electrode-side terminal 19 is disposed at the center thereof. Projections 23 are formed over the entire periphery of the base 22, and the entire reinforcing body 20 has a circular shape. An annular finger flange 44 is formed over the entire circumference of the outer peripheral surface of the housing 34.

  In each of the above-described embodiments, the electrode body connection structure including the electrode body 3 for ion introduction has been described. However, the present invention is applied to electrode bodies for electrocardiogram measurement and low-frequency treatment in addition to the ion introduction. be able to. The electrode side terminal 19 can be constituted by a female hook, and the lead side terminal 33 can be constituted by a male hook.

  The material of the sheet base material 15 is not limited to a transparent material, and the transparent display surface 52 can be formed on the outer surface of the sheet base material 15 even if it is formed of a translucent material. Further, even if the entire sheet base material 15 is not formed of a transparent material or a translucent material, for example, in the first embodiment, the portion facing the display holes 49 of the display layer 48 and its peripheral portion are made transparent or translucent. Then, the perspective display surface 52 can be formed on the outer surface of the sheet base material 15. In the second and third embodiments, at least a portion facing the display layer 48 and its peripheral portion are transparent or translucent, A perspective display surface 52 can be formed. The display content of the display layer 48 is not limited to “ABC”, but may be other characters or designs.

3 Electrode body 5 Electrode side connector 6 Lead side connector 14 Electrode body 15 Sheet base material 16 Electrode layer 19 Electrode side terminal 20 Reinforcing body 22 Base portion 23 Protruding portion 33 Lead side terminal 34 Housing 44 Finger hook flange 46 Non-polarizable electrode 47 minutes Polar electrode 48 Display layer 51 Concave and convex display surface 52 Perspective display surface

Claims (8)

For electrically connecting the electrode body (3) in contact with the skin surface of the human body to the lead-out end of the lead wire (2) led out from the operating device (1) via the connector (5.6). An electrode body connection structure,
The electrode body (3) includes an electrode body (14) formed with an electrode layer (16) on one side of the sheet substrate (15), and the sheet substrate (15) in a state of being electrically connected to the electrode layer (16). An electrode side connector (5) fixed to the outer surface side,
The lead-side connector (6) includes a lead-side terminal (33) that is detachably connected to the electrode-side terminal (19) of the electrode-side connector (5), and a housing (34) that holds and fixes the lead-side terminal (33). And
A finger-hanging flange (44) is formed overhanging the housing (34),
The outer surface of the sheet substrate (15), Ri plate-like reinforcing member for reinforcing the sheet surface of the proximal end around the electrode terminal (19) (20) is fixed tare,
A non-polarizable electrode (46) having a single-layer structure or a multi-layer structure in which an electrode layer (16) is formed on a sheet substrate (15), and a polarizable electrode (47) covering the non-polarizable electrode (46) It is composed of a laminate with
At least one layer of the non-polarizable electrode (46) is configured as a display layer (48);
An electrode body connection structure, wherein an uneven display surface (51) having unevenness of the same shape as the display layer (48) is formed on the outer surface of the polarizable electrode (47) .   The electrode body connection structure according to claim 1, wherein the electrode body (14) and the reinforcing body (20) have higher flexibility than the finger hook flange (44).   The electrode body connection structure according to claim 1 or 2, wherein a thickness dimension (T2) of the reinforcing body (20) is set to be larger than a thickness dimension (T1) of the electrode body (14). A reinforcing body (20) includes a base (22) surrounding the base end of the electrode side terminal (19), and a protrusion (23) protruding from the periphery of the base (22) along the sheet surface of the electrode body (14). With
The electrode body connection structure according to any one of claims 1 to 3, wherein the protruding portion (23) protrudes outward beyond the protruding end of the finger hook flange (44). When the direction in which the lead-side terminal (33) separates from the electrode-side terminal (19) is defined as the upward direction, the finger-hanging flange (44) is formed to project from the upper end of the side surface of the housing (34),
The electrode body connection structure according to any one of claims 1 to 4, wherein a finger hooking gap (E) is secured between the finger hook flange (44) and the reinforcing body (20).   The thickness dimension (T3) of the finger hook flange (44) is set to be larger than the thickness dimension (T1 + T2) in which the electrode body (14) and the reinforcing body (20) are overlapped. The electrode body connection structure described. A display layer (48) is formed on the sheet substrate (15);
The transparent display surface (52) through which the display layer (48) can be seen through the sheet base material (15) is formed at least on the portion of the sheet base material (15) that faces the display layer (48). The electrode body connection structure according to claim 1 . The electrode body connection structure according to any one of claims 1 to 7, wherein the non-polarizable electrode (46) is formed in a mesh shape .

Images