Abstract: A housing, a substrate accommodated in the housing, a needle electrode for generating ions through discharging, which is held by the substrate such that a tip end portion protrudes outside the housing, an insulating sealing portion insulating and sealing the substrate in the housing, and an electrode protection portion for protecting the needle electrode outside the housing are included. The housing is provided with an opening portion through which a side of the tip end portion of the needle electrode is inserted and which is sealed with the insulating sealing portion. The electrode protection portion has a first protection portion and a second protection portion which are provided to protrude from the housing relative to the tip end portion of the needle electrode and opposed to each other at a distance from each other on opposing sides of the needle electrode.

Abstract: The present invention has an object to reduce a risk of performance degradation caused to an ion generating device that is being manufactured. An ion generating device (1) includes: a discharge electrode (21) for generating ions by electric discharge, the discharge electrode having (i) a mounting part (33a) for mounting the discharge electrode on the ion generating device and (ii) a brush part including a plurality of linear electrically conductive members, and the mounting part (33a) binding a base end part of the brush part so as to hold the base end part, the ion generating device further including: an insulating sealing member (41) with which to seal the base end part of the mounting part (33a); and a protective resin (29) with which to cover at least a brush base end surface (25t).

Abstract: A housing, a substrate accommodated in the housing, a needle electrode for generating ions through discharging, which is held by the substrate such that a tip end portion protrudes outside the housing, an insulating sealing portion insulating and sealing the substrate in the housing, and an electrode protection portion for protecting the needle electrode outside the housing are included. The housing is provided with an opening portion through which a side of the tip end portion of the needle electrode is inserted and which is sealed with the insulating sealing portion. The electrode protection portion has a first protection portion and a second protection portion which are provided to protrude from the housing relative to the tip end portion of the needle electrode and opposed to each other at a distance from each other on opposing sides of the needle electrode.

Abstract: A housing, a substrate accommodated in the housing, a needle electrode for generating ions through discharging, which is held by the substrate such that a tip end portion protrudes outside the housing, an insulating sealing portion insulating and sealing the substrate in the housing, and an electrode protection portion for protecting the needle electrode outside the housing are included. The housing is provided with an opening portion through which a side of the tip end portion of the needle electrode is inserted and which is sealed with the insulating sealing portion. The electrode protection portion has a first protection portion and a second protection portion which are provided to protrude from the housing relative to the tip end portion of the needle electrode and opposed to each other at a distance from each other on opposing sides of the needle electrode.

Abstract: In an ion generation apparatus, induction electrodes are formed on a surface of a substrate, holes are provided inside the induction electrodes, respectively, needle electrodes are disposed in a substrate, and tip end portions of the needle electrodes are inserted into the holes, respectively. Furthermore, a part of each of the induction electrodes is removed, thereby reducing the size of the substrate for entire size reduction. By such a configuration, it becomes possible to provide an ion generation apparatus that can stably generate ions even in a high humidity environment and that can be mounted also in small-sized electrical equipment.

Abstract: A discharge device capable of maintaining a stable discharge performance even in a highly humid environment or an atmospheric environment containing salt includes a discharge electrode discharging when a voltage is applied thereto, a substrate supporting the discharge electrode, an induction electrode arranged apart from the discharge electrode, and an insulator enclosing all of the substrate and the induction electrode. The discharge electrode has a root portion supported by the substrate, a pointed end protruding from a surface of the insulator, and a taper portion tapering from the root portion toward the pointed end. An outer peripheral surface of the root portion is made of a material having an ionization tendency lower than that of hydrogen.

Abstract: An ion generation apparatus that can facilitate the separation of adhering materials from a discharge electrode and efficiently generate ions includes an induction electrode, and a discharge electrode for generating ions between the discharge electrode and the induction electrode. The discharge electrode has a plurality of filament-like conductors, and a joining portion to tie the bottoms of the conductors together. The induction electrode is arranged at the bottom side of the conductors.

Abstract: A housing, a substrate accommodated in the housing, a needle electrode for generating ions through discharging, which is held by the substrate such that a tip end portion protrudes outside the housing, an insulating sealing portion insulating and sealing the substrate in the housing, and an electrode protection portion for protecting the needle electrode outside the housing are included. The housing is provided with an opening portion through which a side of the tip end portion of the needle electrode is inserted and which is sealed with the insulating sealing portion. The electrode protection portion has a first protection portion and a second protection portion which are provided to protrude from the housing relative to the tip end portion of the needle electrode and opposed to each other at a distance from each other on opposing sides of the needle electrode.

Abstract: The portable telephone has an optical signal transmission section 100 for performing signal transmission between a first casing 101 and a second casing 102 by optical signals. A need for any complex electromagnetic shield structure can be eliminated. There is no occurrence of electromagnetic-wave noise from an optical signal transmission section 100. Thus, electromagnetic-wave noise of the whole portable telephone can be extremely reduced.

Abstract: An optical semiconductor device has an optical semiconductor element (2) such as an LED or PD, and a light-permeable resin (4) encapsulating the optical semiconductor element. The light-permeable resin contains a base resin and filler. The light-permeable resin (4) has a characteristic that its transmittance increases with a temperature rise within an operating temperature range (e.g., ?40° C.?+85° C.).

Abstract: An optical semiconductor device 1a includes a lead frame 4 having an aperture 7, a submount 8 disposed on one surface of the lead frame 4 to close the aperture 7, a semiconductor optical element 3 which has an optical portion 6 and which is mounted on a surface of the submount 8 opposite to a surface on a side of the aperture 7 with the optical portion 6 facing the aperture 7 through the submount 8, a molding portion 10 made of a non-transparent molding resin which exposes at least a region including the aperture 7 on the other surface side of the lead frame 4 and which encapsulates the lead frame 4, the semiconductor optical element 3 and the submount 8, and a lens 9 disposed on the other surface of the lead frame 4 to close the aperture 7.

Abstract: On one surface of a lead frame 4 having an aperture 7 passing through in thickness direction thereof, a submount having transparency for closing the aperture 7 of the lead frame 4 is disposed. On a surface of the submount opposite to a surface of the submount 8 facing the aperture 7 of the lead frame 4, a semiconductor optical device 3 is disposed in such a way that an optical portion thereof faces toward the aperture. The semiconductor optical device 3 is electrically connected to the lead frame 4 via wire 5. At least one surface of the lead frame 4, the semiconductor optical device 3 and the submount 8 are encapsulated with a molding portion 10 made of a non-transparent molding resin in a state that the aperture 7 on the other surface side of the lead frame 4 is exposed.

Abstract: The portable telephone has an optical signal transmission section 100 for performing signal transmission between a first casing 101 and a second casing 102 by optical signals. A need for any complex electromagnetic shield structure can be eliminated. There is no occurrence of electromagnetic-wave noise from an optical signal transmission section 100. Thus, electromagnetic-wave noise of the whole portable telephone can be extremely reduced.

Abstract: The present invention is composed of a mainframe 2 having a holder portion 2a for detachably holding an optical plug provided on an optical fiber end portion. An input/output board 6 is disposed on the lower side of the mainframe 2, and on the lower face of the input/output board 6, there is provided an electrode portion enabling electric connection by contact pressure. On the lower side of the mainframe 2, there are provided support portions 12, 13 and a peripheral portion 9 protruding downward from the lower face of the input/output board 6, and with use of a screw hole 7 provided on the side of the holder portion 2a of the mainframe 2, the mainframe 2 is fixed to a mounting board 21 with a screw 31.

Abstract: In order to be usable in combination with various receptacles without drawbacks, a plug for an optical connector has a plug tip section defining an optical reference plane that is to coincide with an optical reference plane in a receptacle, and at distances behind the optical reference plane with respect to an insertion direction, the plug has a first mechanical reference plane that is able to be brought into contact with an element within the receptacle, and a second mechanical reference plane that is able to be brought into contact with a front of the receptacle.

Abstract: An optical transmission device including: a connector housing having an insert hole through which an optical plug for transmitting an optical signal is inserted and detachably supporting the optical plug; an optical element including at least either a light emitting element or a light receiving element and being arranged in proximity to a tip of the optical plug supported in the housing to send and receive the optical signal to and from the optical plug; and a driving circuit section for driving the optical element, wherein the driving circuit section is arranged in a closer position to the insert hole than the optical element along the optical plug.

Abstract: A mechanical lock type connecter of the present invention is for a plug including a non-movable member connected to a cable, and a movable member that makes relative movement in an axial direction of the cable independently from the non-movable member and the cable. The mechanical lock type connecter has arm sections for (a) holding the non-movable member in accordance with movement of the movable member in a plug inserting direction caused by inserting the plug and (b) releasing the plug by movement of the movable member in a plug detaching direction. By thus using the mechanical lock plug, provided is a mechanical lock type connecter that is capable of stably connecting the plug with the connecter and that makes it possible to downsize connecting portions of the plug and the connecter.

Abstract: An optical semiconductor device has an optical semiconductor element (2) such as an LED or PD, and a light-permeable resin (4) encapsulating the optical semiconductor element. The light-permeable resin contains a base resin and filler. The light-permeable resin (4) has a characteristic that its transmittance increases with a temperature rise within an operating temperature range (e.g., ?40° C.?+85° C.

Abstract: An optical transmitter-receiver module has a light-emitting element for emitting transmission signal light and a light-receiving element for receiving reception signal light, and performs both transmission of the transmission signal light and reception of the reception signal light by means of a single-core optical fiber. A light-emitting device 91 having the light-emitting element is covered with an upper shield plate 93 and a lower shield plate 94 each provided by a conductive metal plate while being held between the plates. Connection terminals 95 and 96 of the upper shield plate 93 and the lower shield plate 94, which are extended in a direction in which lead terminals 99 of the light-emitting device 91 are extended, are connected to grounding terminals included in the lead terminals 99.

Abstract: An optical semiconductor device 1a includes a lead frame 4 having an aperture 7, a submount 8 disposed on one surface of the lead frame 4 to close the aperture 7, a semiconductor optical element 3 which has an optical portion 6 and which is mounted on a surface of the submount 8 opposite to a surface on a side of the aperture 7 with the optical portion 6 facing the aperture 7 through the submount 8, a molding portion 10 made of a non-transparent molding resin which exposes at least a region including the aperture 7 on the other surface side of the lead frame 4 and which encapsulates the lead frame 4, the semiconductor optical element 3 and the submount 8, and a lens 9 disposed on the other surface of the lead frame 4 to close the aperture 7.