초록 ▼

A self-centering line connector for insulated window spacer frame tubing. There is an elongate connector body having first and second ends. First and second ramps extend upwardly from the connector body towards a mid-point of the connector body. The base ends of the ramp portions are yieldingly moun

A self-centering line connector for insulated window spacer frame tubing. There is an elongate connector body having first and second ends. First and second ramps extend upwardly from the connector body towards a mid-point of the connector body. The base ends of the ramp portions are yieldingly mounted to the connector body, and the free ends have perpendicularly extending stop surfaces. Either end of the connector can be inserted into the open end of a section of spacer frame tubing. As this is done, the first ramp portion is depressed by the web of the tubing so as to permit the tubing to pass thereover until insertion is arrested by the end of the tubing coming up against the stop surface of the second ramp member, at approximately the mid-point of the connector body. The other end of the connector is then inserted into a second section of tubing, which depresses the second ramp member so that the end of the second section of tubing can be pressed into abutment with the end of the first, with the connector body being located centrally between the two sections of tubing.

대표청구항 ▼

A self-centering line connector for insulated window spacer frame tubing. There is an elongate connector body having first and second ends. First and second ramps extend upwardly from the connector body towards a mid-point of the connector body. The base ends of the ramp portions are yieldingly moun

A self-centering line connector for insulated window spacer frame tubing. There is an elongate connector body having first and second ends. First and second ramps extend upwardly from the connector body towards a mid-point of the connector body. The base ends of the ramp portions are yieldingly mounted to the connector body, and the free ends have perpendicularly extending stop surfaces. Either end of the connector can be inserted into the open end of a section of spacer frame tubing. As this is done, the first ramp portion is depressed by the web of the tubing so as to permit the tubing to pass thereover until insertion is arrested by the end of the tubing coming up against the stop surface of the second ramp member, at approximately the mid-point of the connector body. The other end of the connector is then inserted into a second section of tubing, which depresses the second ramp member so that the end of the second section of tubing can be pressed into abutment with the end of the first, with the connector body being located centrally between the two sections of tubing. g a platform as defined in claim 1, wherein the mold is formed with the first region projecting further than the second region, and wherein an indent corresponding to a shape of the mold is formed in the molding material. 11. The method of manufacturing a platform as defined in claim 1, wherein the mold has a projection, and the interconnecting line is adhered to a region in which the projection is formed, and wherein a recess is formed in the molding material. 12. The method of manufacturing a platform as defined in claim 11, further comprising a step of filling the recess with a conductive material. 13. The method of manufacturing a platform as defined in claim 1, wherein an electronic component electrically connected to the interconnecting line is mounted over the mold, and wherein the optical fiber and the interconnecting line, and the electronic component are sealed with the molding material. 14. The method of manufacturing a platform as defined in claim 1, wherein the mold has the first region, the second region provided in a position lower than the first region, and a third region provided between the first and the second regions, and wherein in the step of providing the interconnecting line, the interconnecting line is adhered to the first or second region, and the third region. 15. A method of manufacturing an optical module comprising steps of fabricating a platform by the method as defined in claim 1, mounting an optical element over the platform, and electrically connecting the optical element and the interconnecting line. 16. The method of manufacturing an optical module as defined in claim 15, comprising a step of providing a resin which seals the optical element. 17. The method of manufacturing an optical module as defined in claim 16, wherein at least between the optical fiber and the optical element, a resin having a light transmitting property is formed as the resin. 18. The method of manufacturing an optical module as defined in claim 15, wherein the mold has the first region, the second region provided in a position lower than the first region, and a third region provided between the first and the second regions, wherein in the step of providing the interconnecting line, the interconnecting line is adhered to the first or second region, and the third region, and wherein a semiconductor chip is mounted in the third region of the platform. 19. A platform comprising a resin molded component, and an interconnecting line at least part of which exposes from the molded component, the exposed surface of the at least part of the interconnecting line being level with a surface of the molded component, in which an optical fiber having one end surface exposed is fixed to the molded component. 20. The platform as defined in claim 19, wherein a metal support member embedded in the molded component is further comprised, and the optical fiber is supported by the support member. 21. The platform as defined in claim 19, wherein an indent is formed in the molded component, and wherein the optical fiber is fixed in the indent with the one end surface exposed. 22. The platform as defined in claim 21, wherein the exposed one end surface of the optical fiber is positioned without projecting from a bottom surface of the indent in the molded component. 23. The platform as defined in claim 19, wherein a recess is formed in the interconnecting line so that a bottom surface of the recess is exposed from the molded component. 24. The platform as defined in claim 23, wherein the recess formed in the interconnecting line is filled with a conductive material. 25. The platform as defined in claim 19, wherein an electronic component electrically connected to the interconnecting line is incorporated in the molded component. 26. An optical module comprising: the platform as defined in claim 19; and an optical element electrically connected to the interconnecting line and m ounted over the platform. 27. The optical module as defined in claim 26, further comprising a resin sealing the optical element. 28. The optical module as defined in claim 27, wherein at least between the optical fiber and the optical element, a resin having a light transmitting property is formed as the resin. 29. An optical transmission device comprising: a plurality of the platforms as defined in claim 19; an optical element mounted over each of the platforms; and the optical fiber attached to each of the platforms, wherein the optical element is a light-receiving element or a light-emitting element, and wherein the optical element is electrically connected to the exposed part of the interconnecting line. 30. The optical transmission device as defined in claim 29, further comprising a resin which seals the optical element. 31. The optical transmission device as defined in claim 30, wherein at least between the optical fiber and the optical element, a resin having a light transmitting property is formed as the resin. 32. The optical transmission device as defined in claim 29, further comprising: a plug connected to the optical element. 33. A platform comprising: a molded component, the molded component having an indent formed therein; an interconnecting line at least part of which exposes from the molded component; and an optical fiber fixed to the molded component, the optical fiber fixed in the indent with its end surface exposed, wherein the indent has a plurality of bottom surfaces forming steps, and wherein on each of the bottom surfaces, the at least part of the interconnecting line is exposed. 34. An optical module comprising: the platform as defined in claim 33; and an optical element electrically connected to the interconnecting line and mounted over the platform, wherein the optical element is mounted in the indent so as to face the one end surface of the optical fiber, and wherein a semiconductor chip, which is mounted so as to face a surface of the optical element opposite to a surface facing the optical fiber, and is electrically connected to the interconnecting line, is included in the indent. 35. An optical transmission device comprising: a plurality of platforms, each of the platforms having a molded component and an interconnecting line at least part of which exposes from the molded component; an optical fiber fixed to the molded component with its end surface exposed; and an optical element mounted over the molded component, the optical element being a light-receiving element or a light-emitting element, the optical element electrically connected to the exposed part of the interconnecting line, wherein an indent is formed in the molded component, wherein the optical fiber is fixed in the indent with the exposed end surface, wherein the indent has a plurality of bottom surfaces forming steps, wherein on each of the bottom surfaces, the at least part of the interconnecting line is exposed, wherein a semiconductor chip mounted over each of the platforms is further provided, wherein the optical element is mounted in the indent so as to face the one end surface of the optical fiber, and wherein the semiconductor chip is electrically connected to the interconnecting line, and is mounted within the indent so as to face a surface of the optical element opposite to a surface facing the optical fiber.