JP2007243785A - Optical coupling controller - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the equipment main body subjected to a specified controlled system from being controlled by external control signals which should not essentially control the equipment main body. <P>SOLUTION: For an optical transmission end main body 10 and an optical transmission end main body 20, both ends are turned to the same structure since only the attaching objects are different. Also, by attaching the optical transmission end main body 10 and the first optical transmission end main body 20 to the light receiving part 50 of a portable toilet 30 and the light emitting part 41 of a remote controller 40, the possibility that light from the outside enters the light receiving part 50 of the portable toilet 30 is eliminated and the possibility of the malfunction of the portable toilet 30 provided with the light receiving part 50 is eliminated. The portable toilet 30 is also controlled even from a position where normally the light can not be made to reach the light receiving part 50 of the portable toilet 30 and the control of the portable toilet 30 is difficult. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to the use of an optical cable that performs optical communication between a remote control device such as a remote control device such as a remote control device such as a television, a simple toilet, and an air conditioner controlled by remote operation. The present invention relates to an optical coupling control device that controls only a target device body.

  In general, this type of optical coupling control device includes a remote controller, an optical cable that is attached to an optical receiver that receives an optical signal from the remote controller, and guides an optical signal received by the optical receiver, and the optical cable. And a control device that is operated by an optical signal guided by.

Specifically, there is an invention of Patent Document 1 as a conventional optical coupling control device. That is, the invention of Patent Document 1 includes a light emitting member, an optical cable extended from the light emitting member, and a light receiving member attached to the tip of the optical cable. Specifically, the light receiving member is formed in a substantially cylindrical shape with, for example, metal, resin, or the like, and a condensing lens is attached to the inside of the distal end side. When an optical signal is transmitted toward the condenser lens, the optical signal is collected by the condenser lens and guided to the optical cable. The optical cable is constituted by a flexible optical cable which is generally used, and can transmit light with almost no attenuation therein. For this reason, the optical signal from the light receiving member is guided to the light emitting member via the optical cable. The light emitting member is formed, for example, in a substantially conical shape from metal, resin, or the like, and has a rod-shaped attachment portion protruding therefrom. An engagement piece slightly thicker than the attachment hole of the cabinet is formed at the tip of the attachment part. When the attachment part is pushed into the attachment hole, the engagement piece can be inserted by being slightly elastically deformed. Then, in a state where the attachment portion is completely inserted into the attachment hole, the engagement piece is elastically restored, and the attachment portion is prevented from being carelessly removed from the attachment hole.
JP 2001-95071 A

  In the above-mentioned Patent Document 1, it is possible to transmit light from the optical cable member toward the light receiving window while facing the light receiving window in a state where the light emitting member is attached to the cabinet while being inclined with respect to the cabinet. It will be. The technical idea described in Patent Document 1 can be used when an optical signal is transmitted from a remote place or a place where light is difficult to reach. However, when a plurality of other equipment bodies are installed near the target equipment body. It is difficult to receive an optical signal from another remote controller and avoid malfunction. Even if the installation conditions are not such, the optical signal from the remote controller may be incident on the light receiving window that is reflected and inclined by the ceiling, wall, curtain, or the like. In particular, current television remote controls have standardized optical signals for each manufacturer, so in hospital wards, elderly facilities, and disaster shelters, other remote control signals are picked up and targeted. There is a possibility that a device body such as a television may perform unrelated control.

  Accordingly, the present invention has been made to solve such a problem, and an optical coupling control device that is not controlled by an external control signal that should not originally control the device body of a specific control target. The issue is to provide

An optical coupling control device that is interposed between a light emitting unit of a remote controller according to claim 1 and a light receiving unit of a device body and that transmits an optical signal emitted from the light emitting unit to the light receiving unit is made of a synthetic resin. A first introduction part to which one end of the optical cable is connected, a first joining surface joined to the light emitting part to introduce the optical signal, and light incident between the one end of the optical cable and the first introduction part. And a first light transmission end main body comprising a first light shielding portion for blocking extraneous light, a second introduction portion to which the other end portion of the optical cable is connected, and the light receiving portion are joined to derive the optical signal. And a second optical transmission end main body comprising a second joint surface and a second light shielding portion that shields light incident between the other end portion of the optical cable and the second introduction portion and extraneous light. Is.
Here, the optical cable made of a synthetic resin that transmits an optical signal may be an optical cable excluding glass, and even if an amateur cuts it with pliers or the like, the generated powder does not harm the human body. The idea is that it only has to be. Moreover, the apparatus main body which controls a built-in apparatus with the optical signal received by the light-receiving part should just be mounting apparatuses, such as an electronic device which has a function which light-receives an optical signal by a light-receiving part. A remote controller that converts a mechanical input having a light emitting unit into an optical signal is usually called a remote controller, a remote controller, or the like, and determines whether it is surrounded by a single movable casing. It does not ask and does not specify its form. What is necessary is just to have the light emission part which converts a mechanical input into an optical signal.
Furthermore, the light shielding part that blocks the incidence of light from the outside and the emission of light from the inside forms a coating film or a texture, a metal foil, etc., and the leakage of the signal to the extent that the device does not malfunction as an optical signal, It is only necessary to block light to the extent that interference does not occur. Moreover, the introduction part to which the end part of the optical cable is connected may be any one that can guide the optical signal to the light receiving part or the optical signal from the light emitting part. Then, the bonding surface for deriving or introducing the optical signal may be directly bonded to the light receiving unit of the device main body and the light emitting unit of the remote controller with an adhesive, or the surface may be directly bonded with a double-sided tape. The periphery of the joint surface may be joined with a double-sided tape. Moreover, it can also be set as a suction disk, a magnet, etc. In addition, the optical transmission end main body only needs to include the introduction portion, the joint surface, and the light shielding portion.

  The optical signal of the optical coupling control device according to claim 2 is an infrared ray, and does not ask for a near infrared ray or a far infrared ray.

  The one end part of the optical cable of the optical coupling control device according to claim 3 is opposed to the light emitting part. What is necessary is just to oppose the edge part to the light emission part side, and it does not ask about the direction of the edge part of an optical cable.

  The other end portion of the optical cable of the optical coupling control device according to claim 4 is opposed to the light receiving portion. What is necessary is just to oppose an edge part to the light-receiving part side, and it does not ask the direction of the edge part of an optical cable.

  The first joint surface and the second joint surface of the optical coupling control device according to claim 5 can adjust the area of the light emitting unit and / or the area of the light receiving unit, respectively. The size of the end may be adjusted by sequentially connecting or cutting to reduce the size.

An optical coupling control device for transmitting an optical signal emitted from a light emitting unit according to claim 1 to the light receiving unit is provided in a first introduction unit to which one end of an optical cable made of synthetic resin is connected, and a light emitting unit of a remote controller. From a first optical transmission end main body comprising a first joint surface that is joined and introduces the optical signal, and a first light shielding portion that shields extraneous light between the one end portion of the optical cable and the first introduction portion. A second introduction portion to which the other end portion of the optical cable is connected, a second joining surface that is joined to the light receiving portion of the device main body to derive the optical signal, and the other end portion of the optical cable and the second introduction portion. The optical signal is transmitted to the second optical transmission end main body including the second light shielding portion that blocks light incident therebetween.
Here, the first introduction portion and the second introduction portion are connected to the end portions of the optical cable, and the first joining surface and the second joining surface are joined to the light emitting portion of the remote controller or the light receiving portion of the device main body. The optical signal is transmitted, and the first light shielding unit that blocks the extraneous light between the end portion of the optical cable and the first introduction unit cannot only block the extraneous light. Since the incident light is blocked, it is equal to the second light shielding portion that blocks the light incident between the end portion of the optical cable and the second introduction portion. Therefore, the first optical transmission end body and the second optical transmission end body have the same characteristics. Since the first optical transmission end main body and the second optical transmission end main body only differ in their attachment targets, both ends can have the same structure. In addition, by attaching the first light transmission end body and the second light transmission end body to the light emitting portion of the remote controller and the light receiving portion of the device main body, there is no possibility that light from the outside enters the light receiving portion of the device main body. The possibility of malfunction of the device body having the light receiving part is eliminated. Normally, the device main body can be controlled even from a position where it is difficult to control the device main body where light does not reach the light receiving portion of the device main body.
And since an optical cable transmits the optical signal which consists of synthetic resins, even if an amateur cuts with pliers etc., there is no fear of the processing of the powder. Further, since the loss is small even if the length of the optical cable is increased, versatility can be provided, and the reliability of control can be improved.

  Since the optical signal of the optical coupling control device according to claim 2 is an infrared ray, in addition to the effect of claim 1, since the infrared signal is used as an optical signal, it is used for an existing remote control device. A surface treatment that prevents the incidence of light from outside and the emission of light from inside can be selected at a low cost.

  Since the one end part of the optical cable of the optical coupling control device according to claim 3 faces the light emitting part, in addition to the effect of claim 1 or 2, the end part emits light from the remote controller. The light transmission efficiency can be improved.

  Since the other end portion of the optical cable of the optical coupling control device according to claim 4 is opposed to the light receiving portion, in addition to the effect of any one of claims 1 to 3, the end portion is Since it faces the light emitting part of the remote controller or the light receiving part side of the device body, the light transmission efficiency can be improved.

  Since the first joint surface and the second joint surface of the optical coupling control device according to claim 5 can adjust the area of the light emitting unit and / or the area of the light receiving unit, respectively. In addition to the effect of any one of item | item 4, it can attach to the light emission part of the said remote control device of arbitrary sizes, and the light-receiving part of the said apparatus main body.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In the figure, the same reference numerals and the same symbols as those in the first embodiment mean the same functional parts, the same kind of functional parts, or corresponding parts as those in the first embodiment. The description that has been made will be omitted.
[Embodiment 1]

FIG. 1 is an overall plan view (a) and a front view (b) having a partial cross section of an optical coupling control device according to Embodiment 1 of the present invention.
In FIG. 1, an optical cable 1 has a coating 3 around a core wire 2 made of a synthetic resin that transmits an optical signal. The coating 3 blocks light leaking from the periphery of the core wire 2 due to transmission loss, or conversely, incident light. The optical cable 1 for transmitting an optical signal in the present embodiment is made of synthetic resin, like an optical cable excluding a glass system, when an amateur cuts it with a tool such as pliers, It will prevent you from being stabbed. In other words, the optical cable 1 may be any material that does not harm the human body. Moreover, the coating 3 of the core wire 2 should just be interrupted | blocked to such an extent that the signal leakage and interference which an apparatus does not malfunction as an optical signal do not occur. Therefore, the core wire 2 may be provided with a texture or the like.

  The base 11 of the optical transmission end body 10 (the first optical transmission end main body of the present embodiment) is made of a transparent synthetic resin and is entirely cylindrical. Further, a hollow hole 12 is formed in the center of the base body 11, which is a hole having a hollow inside. One end of the optical cable 1 is insert-molded in the base body 11 in which the hollow hole 12 is formed, and the end portion of the core wire 2 is positioned at a substantially central portion of the hollow hole 12. That is, the end portion of the core wire 2 is positioned substantially at the center of the hollow hole 12 and is not integrated in the resin. However, when carrying out the present invention, the end of the core wire 2 may be integrated into the resin of the base 11. In the present embodiment, the end portions are not integrated into the resin so as not to deteriorate the optical transmission characteristics of the core wire 2 of the optical cable 1. In particular, when the end portion is integrated in the resin of the base 11, it is reflected at the end of the core wire 2, and the light transmission efficiency is deteriorated and the light is dispersed by the base 11. Et al. Open the end of the core wire 2, thereby reducing variations in characteristics. In addition, the hollow hole 12 comprises the 1st introduction part to which the one end part of the optical cable 1 in this Embodiment was connected.

  Since the covering 3 of the optical cable 1 is formed of a cloth, the molding resin can enter between the fibers and be integrated when the base 11 is molded. The diameter of the substrate 11 of the present embodiment is about 5 to 30 mm, and the diameter of the hollow hole 12 is about 2 to 15 mm. Under this condition, the curved surface formed by the diameter of the hollow hole 12 acts so as to collect or reflect the light of the base 11, and efficiently guide the optical signal from the base 11 to the core 2 of the optical cable 1. The optical signal can be guided from the core wire 2 to the base 11.

  In addition, the outer periphery of the substrate 11 is formed with a light shielding portion 13 (first light shielding portion of the present embodiment) made of a metal thin film as a surface treatment by sputtering except for one surface. The light shielding portion 13 can be a coating film made of a paint, or can be formed as a colored resin by two-color molding. Further, it is possible to cope with this by making it difficult for light to come out of the base 11 by forming a texture. In any case, the treatment of the light shielding portion 13 on the surface of the base 11 only needs to make it difficult for light to enter and exit the base 11.

  One surface of the substrate 11 that is not surface-treated is a bonding surface 15 (first bonding surface in the present embodiment), to which a double-sided tape 14 is bonded. The illustrated double-sided tape 14 shows a state where the release paper is peeled off. The double-sided tape 14 is stuck around the hollow hole 12. In this embodiment, the double-sided tape 14 is used. However, instead of the double-sided tape 14, an adhesive may be used, or a suction disk, a magnet, or the like may be used.

  On the other hand, the optical transmission end main body 20 (the second optical transmission end main body of the present embodiment) is provided at the other end of the optical cable 1. Basically, the optical transmission end body 20 is formed in the same structure as the optical transmission end body 10. The base 21 of the optical transmission end main body 20 is made of a transparent synthetic resin and has a cylindrical shape as a whole. A hollow hole 22 having a hollow inside is formed at the center thereof. The other end of the optical cable 1 is insert-molded into a base body 21 in which a hollow hole 22 is formed, and the other end portion of the core wire 2 is located on a substantially center line of the hollow hole 22. In addition, the hollow hole 22 comprises the 2nd introduction part to which the one end part of the optical cable 1 in this Embodiment was connected.

  A light shielding part 23 (second light shielding part of the present embodiment) made of a metal thin film is formed on the outer periphery of the base body 21 as a surface treatment by sputtering except for one surface, so that light does not easily enter and exit the base body 21. One surface of the substrate 21 that is not surface-treated is a bonding surface 25 (second bonding surface in the present embodiment), to which a double-sided tape 24 is bonded. The illustrated double-sided tape 24 shows a state in which the release paper is peeled off. The double-sided tape 24 is affixed around the hollow hole 22, but if the double-sided tape 24 is transparent, the entire bonding surface 25 including the hollow hole 22 can be used when the present invention is implemented.

FIG. 2 is an explanatory diagram of the pidal toilet and its remote control device, and FIG. 3 is an explanatory diagram of the pidal toilet and its remote control device using the optical coupling control device according to Embodiment 1 of the present invention.
The portable toilet 30 constituting the device body of the present embodiment is a portable toilet for elderly people. The toilet body 31 is on the upper surface of the pedestal plate 32 of the movable chair-shaped auxiliary member 35, and the toilet seat 33 is on the upper surface. The toilet seat support body 36 is provided so as to be openable and closable around a support shaft. Furthermore, a tank 34 is provided on the upper surface of the rear part, and cleaning water is accommodated therein. Further, the toilet body 31 is provided with a cleaning nozzle that sprays cleaning water (not shown) toward a local part of the human body so as to be able to protrude toward the inside of the toilet bowl. This cleaning nozzle is a control target of the remote controller 40. Further, control information such as “toilet seat opening / closing”, “drying”, “bidet”, “stop”, “washing strength” (not shown) is a control target of the remote controller 40.
In the portable toilet 30 shown in the figure, when the infrared sensor 37 detects the seating of a human body, control information such as “dry”, “bidet”, “stop”, and “washing strength” is taken in. They come to work with incoming signals.

  The light receiving unit 50 of the portable toilet 30 constituting the device main body is provided at the rear part of the toilet seat support main body 36, the surface is made of a synthetic resin plate, and has a circuit configuration for receiving infrared light having a phototransistor or the like inside. . The remote controller 40 has input keys for control information such as “toilet seat opening / closing”, “drying”, “bidet”, “stop”, “washing strength”, a volume, etc. The light-emitting unit 41 that accommodates an infrared light-emitting diode is provided inside. The surface of the light emitting unit 41 is made of a synthetic resin plate, and a circuit board that receives infrared rays is stored therein.

The optical coupling control device of this embodiment is used as follows.
First, as shown in FIG. 3, the light transmission end main body 10 is attached to the light emitting portion 41 of the remote controller 40 on the synthetic resin plate on the surface with the double-sided tape 14. In addition, the light transmission end main body 20 is attached to the light receiving unit 50 of the portable toilet 30 on the synthetic resin plate on the surface by the double-sided tape 24. At this time, the center line of the hollow hole 22 of the base body 21 is positioned at the center of the light receiving unit 50 of the portable toilet 30 and the hollow hole 12 of the base body 11 is positioned at the center line of the light emitting unit 41 of the remote controller 40. Let

  In other words, the optical coupling control device according to the present embodiment has a mechanical input of the optical cable 1 made of synthetic resin that transmits an optical signal and the light emitting unit 41 that outputs an optical signal for controlling a device body such as the portable toilet 30. It is attached to a remote controller 40 that converts it into an optical signal, performs a process for blocking the incidence of light from the outside and the emission of light from the inside, and introduces the optical signal from the light emitting section 41 into the other end of the optical cable 1. The optical transmission end main body 10 having the joint surface 15 and the light receiving portion 50 of the apparatus main body that controls the built-in apparatus such as the portable toilet 30 and the like, a process for blocking the incidence of light from the outside and the emission of light from the inside. The optical transmission end main body 20 having a joining surface 25 that radiates an optical signal introduced from the end of the optical cable 1 to the light receiving unit 50 is provided.

  Here, the optical transmission end main body 10 and the optical transmission end main body 20 are connected to the hollow hole 12 as the first introduction part and the hollow hole 22 as the second introduction part of the present embodiment at the ends of the optical cable 1. The joining surface 15 and the joining surface 25 are joined to the light emitting part 41 of the remote controller 40 or the light receiving part 50 of the device main body 30 to input or output an optical signal. The light shielding part 13 that blocks light that is external between the hollow hole 12 and the light shielding part 23 that blocks light incident between the end of the optical cable 1 and the hollow hole 22 have the same characteristics opposite to each other. Since the optical transmission end main body 10 and the optical transmission end main body 20 only differ in their attachment targets, both ends can have the same structure. That is, since the light transmission end body 10 and the light transmission end body 20 are only different in their attachment targets, both ends have the same structure, and the light emitting input / output device including the light transmission end body 10 and the light transmission end body 20 is used. It can be. Moreover, the light transmission end main body 10 and the light transmission end main body 20 are attached to the light receiving portion 50 of the device main body composed of the portable toilet 30 and the like and the light emitting portion 41 of the remote controller 40, so that light from the outside is transmitted to the portable toilet 30 and the like. Therefore, there is no possibility of entering the light receiving unit 50 of the device main body, and there is no possibility that the device main body including the portable toilet 30 having the light receiving unit 50 malfunctions. In general, it is possible to control from a position where it is difficult to control the apparatus main body where light does not reach the light receiving unit 50 of the apparatus main body including the portable toilet 30 or the like.

And since the optical cable 1 transmits the optical signal which consists of synthetic resins, even if an amateur cuts with pliers etc., there is no fear of the processing of the powder. Further, since the loss is small even if the length of the optical cable 1 is increased, versatility can be provided and the reliability of control can be improved.
Therefore, it is possible to prevent the device main body including the portable toilet 30 or the like to be controlled from being controlled by an external control signal that should not control the device main body including the original portable toilet 30 or the like. The toilet 30 is not operated.

  Thus, since the optical transmission end body 10 and the optical transmission end body 20 only differ in their attachment targets, both ends have the same structure, and the optical transmission end body and the first optical transmission end body are By attaching to the light receiving unit 50 of the portable toilet 30 and the device main body such as the TV and the light emitting unit 41 of the remote control device such as the remote control unit 40, the light from the outside is received by the light receiving unit 50 of the portable toilet 30 and the device main body such as the TV. There is no possibility of entering, and there is no possibility that the portable toilet 30 having the light receiving unit 50 or a device body such as a television malfunctions. Normally, the portable toilet 30 and the device main body such as the television can be controlled even from a position where the control of the device main body where light does not reach the light receiving unit 50 of the device main body such as the television is difficult.

[Embodiment 2.3]
In the first embodiment, the bonding surface 15 of the optical transmission end body 10 and the wiring direction with respect to the base 11 of the optical cable 1 are parallel to each other. However, when the present invention is implemented, the optical transmission end body 10 Light transmission efficiency is better when the angle of intersection of the joining surface 15 and the end of the optical cable 1 with respect to the base 11 is a right angle. 5 and 6 are examples.
FIG. 4 is a plan view (a) and a front view (b) including a partial cross section of the substrate forming the optical transmission end main body of the optical coupling control apparatus according to Embodiment 2 of the present invention, and FIG. It is the top view (a) of the base | substrate which forms the optical transmission end main body of the optical coupling control apparatus in the form 3, and a front view (b) including a partial cross section.

  The base 61 of the optical transmission end main body 60 shown in FIG. 4 is formed by joining and integrating the core wire 2 and the coating 3 of the optical cable 1 with an adhesive. For this reason, a hollow hole 62 for joining the core wire 2 and a coating accommodation hole 63 for joining the coating 3 are provided at the position of the center line of the base 61. By forming irregularities on the outer periphery of the base body 61, it is difficult for external light to enter and it is difficult for optical signals from the inside to be radiated to the outside. In particular, in the present embodiment, the base 61 can be a colored synthetic resin. The double-sided tape 64 joins the joining surface 65 of the base 61 to the light receiving unit 50 of the portable toilet 30 or the light emitting unit 41 of the remote controller 40.

  Similarly, the base 71 of the optical transmission end main body 70 shown in FIG. 5 is formed by joining and integrating the core wire 2 and the clothing 3 of the optical cable 1 with an adhesive. Therefore, at the center of the base 71, there is a hollow hole 72 for joining the core wire 2 and a coating accommodation hole 73 for joining the coating 3. By forming irregularities on the outer periphery of the base 71, it is difficult for external light to be incident and it is difficult for optical signals from the inside to be radiated to the outside. The base 71 can be a colored synthetic resin. The double-sided tape 74 is used to join the joining surface 75 of the base 71 to the light receiving unit 50 of the portable toilet 30 or the light emitting unit 41 of the remote controller 40. In particular, in this embodiment, an annular cavity 77 is formed around the coating accommodation hole 73 to which the coating 3 is joined, and a surface having a different refractive index is formed at the boundary surface. Since the transmission of light is blocked between the base 71 and the inside, the base 71 can be made transparent, and the irregularities on the outer periphery of the base 71 can be reduced or eliminated.

[Embodiment 4]
FIG. 6 is a plan view (a), a central cross-sectional view (b), and a left side view (c) of a substrate forming an optical transmission end main body of the optical coupling control device according to Embodiment 4 of the present invention.
In the first embodiment, the joint surface 15 of the optical transmission end body 10 and the joint of the optical cable 1 to the base body 11 are parallel to each other. In the second embodiment 2.3, the joint surface of the optical transmission end body 10 is used. 15 and the end of the optical cable 1 in the base 11 are perpendicular to each other. However, when the optical cable 1 is directional, people, animals, etc. are likely to come into contact with each other. It is desirable to use a rounded chamfered form.
The base body 81 of the optical transmission end main body 80 shown in FIG. 6 is formed by joining and integrating the core wire 2 and the coating 3 of the optical cable 1 with an adhesive. In the center of the base body 81, a hollow hole 82 for joining the core wire 2 and a coating accommodation hole 83 for joining the coating 3 are provided. The outer periphery of the base 81 is subjected to a surface treatment such as a light shielding portion 86 made of a metal thin film, which is difficult for external light to enter and for optical signals from the inside to hardly radiate to the outside. In addition, the double-sided tape 84 joins the joint surface 85 of the base body 81 to, for example, the light receiving unit 50 of the portable toilet 30 or the light emitting unit 41 of the remote controller 40. In particular, in the present embodiment, the cavity 87 is formed, and a surface having a different refractive index is formed at the boundary surface, thereby confining the infrared rays of the core wire 2.

[Embodiment 5]
In the first and fourth embodiments, the light transmission efficiency can be improved. Moreover, size matching with the light-receiving part 50 of the portable toilet 30 or the light-emitting part 41 of the remote controller 40 can be performed as follows.
FIG. 7 is a cross-sectional view of the main part of the optical transmission end body of the optical coupling control device according to Embodiment 5 of the present invention, and corresponds to the cross-sectional view of FIG.
On the outer periphery of the base 91 of the light transmission end body 90, a light shielding portion 93 made of a metal thin film is formed as a surface treatment by sputtering except for one surface. This surface treatment of the substrate 91 makes it difficult for light to enter and exit the substrate 91. A double-sided tape 94 is bonded to the bonding surface 95 of the lower surface of the base 91 that has not been surface-treated. The illustrated double-sided tape 94 shows a state where the release paper is peeled off. The double-sided tape 94 is stuck around the hollow hole 92.

  Here, the base 91 of the light transmission end main body 90 is made of a transparent synthetic resin, and has a cylindrical shape as a whole, and a hollow hole 92 that is a hollow inside is formed at the center. . One end of the optical cable 1 is insert-molded into a base 91 in which a hollow hole 92 is formed, and the end of the core wire 2 is arranged along the substantially center line of the hollow hole 92. That is, the end portion of the core wire 2 is bent and joined along the length direction of the hollow hole 92. That is, the core wire 2 is inserted into the base 91 and bonded with the tip bent. Therefore, the end portion of the core wire 2 is arranged along the substantially center line of the hollow hole 92, and the end portion of the optical cable 1 can be an end portion facing the joining surface side, thereby improving the light transmission characteristics. Can do.

In addition, the annular adjustment ring 90A and the adjustment ring 90B perform size adjustment with the light receiving unit 50 of the portable toilet 30 or the light emitting unit 41 of the remote controller 40, for example, and in this embodiment, the double-sided tape 94A and Although it is joined by the double-sided tape 94B, a screw may be formed on the base 91, the adjusting ring 90A, and the adjusting ring 90B, and the screws may be joined by the screw. Thereby, the diameter of the base 91 can be set to 5 to 10 mm and can be set to an arbitrary size by the plurality of adjustment rings 90A and adjustment rings 90B.
The plurality of adjustment rings 90A and adjustment rings 90B have been described in the two-stage embodiment, but the number of stages can be further increased. Moreover, it can also form with a synthetic resin, a metal, a magnet etc. as the material.

As in the above-described embodiments, the optical transmission end body 10, the optical transmission end body 20, and the optical transmission end bodies 60, 70, 80, 90 have the same structure, even if they have substantially the same structure. It may be different.
Further, the bonding surfaces 15, 25, 65, 75, 85, 95 of the bases 11, 21, 61, 71, 81, 91 in the above embodiment are the double-sided tapes 14, 24, 64, 74, 84, 94, 94A. , 94B has been described, but when the present invention is implemented, an adhesive, a suction disk, a magnet, a mechanical fixing means, or the like can be used.

  According to the optical coupling control device in the above-described embodiment, light is incident on one end of the optical cable 1 made of a synthetic resin that transmits an optical signal by the light shielding portions 13, 86, 93 made of a metal thin film or the like. The light transmission part 41 of a remote controller such as the remote controller 40 that has been subjected to a process for blocking light emission from the inside has an optical transmission end body 10 that receives light through the joint surfaces 15, 65, 75, 85, and 95. Similarly, at the other end of the optical cable 1, a portable toilet 30 for controlling a built-in device that has been subjected to a process for blocking the incidence of light from the outside and the emission of light from the inside, a light receiving unit of a device body such as a television 50 has an optical transmission end body 20 having joint surfaces 25, 65, 75, 85, and 95 for introducing an optical signal from 50 to the other end of the optical cable 1.

  That is, in the above-described embodiment, the light signal emitted from the light emitting unit 41 is received between the light emitting unit 41 of the remote controller 40 and the light receiving unit 50 of the apparatus main body including the portable toilet 30 and the like. The optical coupling control device for transmitting to the first light-introducing unit 41 is joined to the first introducing part, which is composed of hollow holes 12, 62, 72, 82, 92, etc. into which one end of the optical cable 1 made of synthetic resin is introduced. Light provided between the joint surfaces 15, 65, 75, 85, 95 for introducing the optical signal and one end portion of the optical cable 1 and the first introduction portion comprising the hollow holes 12, 62, 72, 82, 92, etc. A light transmission end main body 10, 60, 70, 80, 90 comprising the shielding part 13, a second introduction part comprising the hollow holes 22, 62, 72, 82, 92, etc. into which the other end of the optical cable 1 is introduced; Second that is joined to the light receiving unit 50 to derive an optical signal. Light comprising the mating surfaces 25, 65, 75, 85, 95 and the light shielding portion 23 provided between the other end portion of the optical cable 1 and the introduction portion comprising the hollow holes 22, 62, 72, 82, 92, etc. The transmission end main body 20, 60, 70, 80, 90 can be a constituent requirement.

And since the optical cable 1 transmits the optical signal which consists of synthetic resins, even if an amateur cuts with pliers etc., there is no fear of the processing of the powder. Further, since the loss is small even if the length of the optical cable 1 is increased, versatility can be provided and the reliability of control can be improved.
Furthermore, if the optical signal is infrared, it can be used for existing remote controls such as remote controllers, and surface treatment that prevents external light from entering and emitting light from the inside is inexpensively selected. it can.

  Furthermore, since the end of the optical cable 1 is the end facing the light emitting unit 41 and the portable toilet 30 of the remote controller 40 and the light receiving unit 50 of the main body of a device such as a television, the end is used as the portable toilet 30. Since the light receiving unit 50 of the device main body such as a television or the portable toilet 30 is opposed to the light receiving unit 50 side of the device main body such as the television, the light transmission efficiency can be improved. In particular, when one end of the optical cable 1 is opposed to the light emitting unit 40, the input efficiency is good, and when the other end of the optical cable 1 is opposed to the light receiving unit 50, the output efficiency is good. Of course, it is desirable that one end and the other end of the optical cable 1 face the light emitting unit 40 and the light receiving unit 50.

  In addition, the joint surfaces 15, 25, 65, 75, 85, and 95 at the end of the optical cable 1 receive light from the portable toilet 30 and the light receiving unit 50 of the device body such as a television and the light reception of the portable toilet 30 and the device body such as the television. Since it can be adjusted to the size of the end facing the unit 50 side, it can be attached to the light emitting unit 41 of the remote controller 40 of any size, the portable toilet 30, and the light receiving unit 50 of a device body such as a television. it can.

FIG. 1 is an overall plan view (a) and a front view (b) having a partial cross section of an optical coupling control device according to Embodiment 1 of the present invention. FIG. 2 is an explanatory diagram of a pidal toilet and its remote controller. FIG. 3 is an explanatory diagram of a podal toilet and its remote controller using the optical coupling control device according to Embodiment 1 of the present invention. 4 is a plan view (a) and a front view (b) including a partial cross-section of a substrate forming an optical transmission end main body of the optical coupling control device according to Embodiment 2 of the present invention. FIG. 5 is a plan view (a) and a front view (b) including a partial cross section of a base body forming an optical transmission end main body of the optical coupling control device according to Embodiment 3 of the present invention. FIG. 6 is a plan view (a), a central cross-sectional view (b), and a left side view (c) of a substrate forming an optical transmission end main body of the optical coupling control device according to Embodiment 4 of the present invention. FIG. 7 is a cross-sectional view of the main part of the optical transmission end body of the optical coupling control device according to the fifth embodiment of the present invention, corresponding to the cross-sectional view of FIG.

Explanation of symbols

1 optical cable 10 optical transmission end body (first optical transmission end body)
11, 21, 61, 71, 81, 91 Base 12 Hollow hole (first introduction part)
22 Hollow hole (2nd introduction part)
13, 23, 86, 93 Light shielding portion 15, 25, 65, 75, 85, 95 Joint surface 20 Optical transmission end main body (second optical transmission end main body)
30 Portable toilet 40 Remote controller 41 Light emitting part 50 Light receiving part 60, 70, 80, 90 Light transmission end main body 62, 72, 82, 92 Hollow hole (first introduction part, second introduction part)

Claims (5)

In the optical coupling control device that is interposed between the light emitting unit of the remote controller and the light receiving unit of the device main body and transmits an optical signal emitted from the light emitting unit to the light receiving unit,
An optical cable made of synthetic resin,
A first introduction part to which one end of the optical cable is connected, a first joining surface that is joined to the light emitting part and introduces the optical signal, and light that enters between the one end of the optical cable and the first introduction part. And a first light transmission end body comprising a first light shielding part for blocking extraneous light,
A second introduction part to which the other end of the optical cable is connected, a second joining surface joined to the light receiving part to derive the optical signal, and incident between the other end of the optical cable and the second introduction part An optical coupling control device comprising: a second light transmission end main body including a second light shielding portion that blocks light to be transmitted and light from outside.   The optical coupling control device according to claim 1, wherein the optical signal is an infrared ray.   The optical coupling control device according to claim 1, wherein one end of the optical cable is opposed to the light emitting unit.   The optical coupling control device according to claim 1, wherein the other end of the optical cable is opposed to the light receiving unit. The area of the light emitting part and / or the area of the light receiving part can be adjusted respectively for the first joint surface and the second joint surface. The optical coupling control device according to 1.

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