High switching speed, coaxial switch for R.F. signals |
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申请号 | EP89304931.2 | 申请日 | 1989-05-16 | 公开(公告)号 | EP0345954A2 | 公开(公告)日 | 1989-12-13 |
申请人 | Hewlett-Packard Company; | 发明人 | Jewell, Michael B.; | ||||
摘要 | A coaxial switch assembly includes a conventional reed switch (10) having a somewhat irregular enclosure (11) and protruding leads (20, 21). R.F. connectors (24, 25) are mounted at the ends of the leads, which are surrounded by predetermined lengths of dielectric tubular material (23). Electrically conductive flowable material (39) is injected within a surrounded shell (36) to fill the space remaining in shell aperture (37) to rigidify the assembly and provide a continuous coaxial electrical conductor joining the outer body (27, 31) of the R.F. connectors to one another. | ||||||
权利要求 | |||||||
说明书全文 | This disclosure relates to improvements in a relay for switching Radio Frequency (R.F.) signals in very short time periods. The resulting switch or relay might be used in circuits such as a reverse power protection scheme for a R.F. signal generator. In this example, the last component in the output signal path must be a switch or relay capable of opening the signal path very quickly in the event that a user inadvertently applies a high power energy source to the output of the instrument, which would otherwise damage delicate internal circuit components. A further requirement of such a protective switch, since the output signal of the instrument must pass through the switch under normal operations, is that the switch or relay must also have very good R.F. performance when closed. Small reed switches are used for applications where R.F. signals must be switched on or off in very short time periods. They typically consist of ferromagnetic contacts that are hermetically sealed in a glass vial or enclosure and are selectively activated by the magnetic field resulting from current flow in a coil wound around the enclosure. A prior art application of a reed switch is illustrated in Fig. 1, which is a sectional view cut through the switch assembly as mounted on a conventional circuit board. The reed switch 10 can be made into a coaxial structure by surrounding the glass vial or enclosure 11 of the switch with an electrically conductive and nonferromagnetic tube 14 that acts as the outer conductor of a coaxial transmission line including switch 10. Because of their small size, and the tight tolerance space between the two contacts provided within such a reed switch 10, these switches can be made to open and close very quickly. In the example shown in Fig. 1, the reed switch 10 is surrounded by a nonmagnetic bobbin 12 having an actuating coil 13 wrapped about it. Switch 10 is arranged parallel to the plane of the printed circuit board 15 and is located within an aperture cut out through the printed circuit board to receive the switch and surrounding bobbin. The leads 20 and 21 of reed switch 10 are directly joined to conductive transmission lines 16 on one side of the printed circuit board. The surrounding conductive tube 14 can be electrically connected to the ground plane 22 on the remaining side of the printed circuit board by short conductors 17. The main limitation encountered with respect to prior art use of reed relays in the manner shown in Fig. 1 is the impedance mismatches which occur at the ends of the reed switch 10 when mounted in the signal path on the printed circuit board. Because of manufacturing tolerances, there are always nominal gaps at the ends of the vial or enclosure 11 between its coaxial structure and the transmission lines 16 on the printed circuit board 15 (gaps 18 in Fig. 1). These gaps create an impedance mismatch which is random in nature and difficult to correct. In addition, since the diameter of the glass enclosure 11 is generally reduced at the ends of the reed switch 10 because it is melted during manufacture of the switch assembly, and since the conductive surrounding tube 14 cannot easily conform to this irregular and somewhat unpredictable enclosure shape, there is a further impedance mismatch introduced because of these gaps (gaps 19 in Fig. 1). The problem becomes more pronounced at higher frequencies, making the approach shown in Fig. 1 not practical for signals substantially above 2GHz. The present invention was designed to substantially eliminate both described sources of impedance mismatch inherent in past applications of reed relays to printed circuit board applications, thereby permitting the utilization of the reed relay technology for fast switching applications at much higher R.F. frequencies. The invention also permits the relay built about the reed switch technology to be manufactured as a complete, stand-alone component, not dependent upon the characteristics of a printed circuit board or specific mounting details for its performance specifications. The switch assembly comprises a switch having an electrically insulative tubular enclosure centered along an axis, with a pair of leads of predetermined length projecting outwardly from opposed ends of the enclosure. A pair of R.F. connectors each include a center contact mounted within an outer body of electrically conductive material, with each center contact being joined to the outer end of one of the leads at locations axially spaced from the switch casing. Tubular dielectric means of predetermined length abut the respective ends of the switch enclosure and and substantially cover the length of each lead extending between the enclosure and the center contact joined to it. A shell of electrically insulative material is arranged about the switch. The shell has an aperture formed through it that coaxially surrounds and is spaced radially from the switch and dieletric means. The assembly is completed by an electrically conductive mass that fills the remaining space within the aperture and forms a continuous coaxial electrical conductor joining the outer bodies of the R.F. connectors to one another. The described method of preparing an axial reed switch for insertion and use within a R.F. signal path in an electronic circuit is generally applicable to reed switches having a pair of movable ferromagnetic contacts located within an enclosure centered along an axis and having opposed sealed axial ends that support outwardly projecting leads. The method involves the following steps: partially covering each lead with a length of dielectric tubular material; mounting a coaxial R.F. connector to each lead by joining the center contact of the connector to the outer end of the lead; placing an electrically insulating shell about the switch by locating the switch within an aperture formed through the shell which surrounds the switch and is radially spaced outwardly from the switch and adjacent dielectric material; injecting a mass of curable electrically conductive liquid into the space remaining in the shell aperture; and curing the mass of liquid to a solid state to physically integrate the switch, dielectric material, shell and R.F. connectors by forming a coaxial electrical conductor linking the outer bodies of the two R.F. connectors. A magnetic coil is subsequently wrapped about a cylindrical surface on the shell to serve as a control member for the reed switch during its use.
The improved switch or relay assembly constructed according to this invention can best be understood by detailing its steps of construction as shown progressively in Figs. 3-5. It incorporates a conventional reed switch 10 of the type described with regard to the prior art illustration in Fig. 1. In this application, the leads 20 and 21 are trimmed to a predetermined length and are partially covered by a length of dielectric tubular material 23. Each length of dielectric tubular material also has a predetermined length and surrounds the lead in surface-to-surface engagement. The inner end of each length of dielectric tubular material 23 physically abuts the end of switch enclosure 11 from which the lead within it is projected. One source of the length of dielectric tubular material is the typical Teflon(TM) dielectric utilized in semirigid coaxial cable, which can be separated from the center conductor and outer tube of such cable for utilization in this assembly. The dielectric tubular material 23 can also be produced independently of any other application for the specific purpose of utilizing it within the present switch assembly. Referring first to Fig. 3, coaxial R.F. connectors 24 and 25 are mounted to the respective outer ends of leads 20 and 21. The connectors 24 and 25 are preferably of complementary male and female construction, but could be of identical construction if desired. Any conventional R.F. connectors of suitable size can be utilized. A typical male R.F. connector 24 includes a center contact 26 and a coaxial outer body 27 that supports the center contact 26 by an interposed insulator 28 (Fig. 5). The outer body 27 includes an internally threaded cover 29 that is free to rotate relative to the remainder of the outer body to rigidly join the R.F. connector 24 to a complementary female R.F. connector 25. A typical female R.F. connector 25 includes an apertured center contact 30 mounted within an outer body 31 that coaxially supports the center contact 30 by means of an interposed insulator 32. The outer body 31 is elongated in comparison to the outer body 27 of the male R.F. connector 24, since it includes an exterior threaded section in addition to the hexagonal exterior section used to facilitate the threaded attachment of R.F. connector 25 to the complementary male R.F. connector 24. The physical details of this type of R.F. connector are well-known and need not be further detailed here in order to facilitate an understanding of their application to the present invention. The initial construction of the present switch assembly, as shown in Fig. 3, is completed by soldering the removed center contacts 26 and 30 to the outer ends of the switch leads 20 and 21, respectively. Because the leads 20 and 21 have a known predetermined length, as do the lengths of dielectric tubular material 23, one can design the assembly to include a predetermined gap of known length as might be required between each center contact 26, 30 and the adjacent end of each length of dielectric tubular material 23. The impedance resulting from these gaps will be uniform and predictable. As shown in Fig. 4, the outer bodies 27 and 31 of the respective R.F. connectors 24 and 25 are soldered to short lengths of tubular electrically conductive material that surround an outer section of each length of dielectric tubular material 23. The conductive tubing 33 can be made from the solid copper tube that comprises the outer conductor in semirigid coaxial cable, or it can be a conductive tube fabricated expressly for incorporation within the present switch assembly. Each length of tubing 33 preferably extends inwardly from the R.F. connector 24 or 25 that surrounds it. The subassembly shown in Fig. 4 is completed by sealing the joint formed between each end of enclosure 11 and the length of dielectric tubular material 23 that abuts it. As shown, the sealing material is merely a nonconductive adhesive (Elmer's(TM) glue) that fills any crack or irregularity to assure that no gap exists between the enclosure 11 and the adjacent end of the dielectric material. The adhesive 34 temporarily keeps the lengths of dielectric material in abutting positions against the opposed ends of enclosure 11 and also assures against short-circuiting the switch assembly during the subsequent formation of the outer coaxial conductor along the switch assembly. Any electrically nonconductive flowable material capable of sealing the circumferential area at each end of enclosure 11 can be utilized for this purpose. Also shown in Fig. 4 is a wrap of wire 35 arranged about a circumference of tubing 33 adjacent to the male R.F. connector 24. It simply provides a "roughened" surface about the tubing 33 to assure bonding of the outer conductive material at the shorter R.F. connector structure. A washer 42 is preferably provided against the inner end of cover 29 to assure that subsequently injected flowable materials used in the assembly do not interfere with the rotatable mounting of cover 29. The completed switch assembly can best be understood by reference to Figs. 2 and 5. A two-piece rigid shell 36 of electrically insulating resin or other material is placed about the subassembly shown in Fig. 4 by locating the reed switch 10 within an aperture 37 formed through the shell 36. Aperture 37 surrounds the reed switch 10 and is radially spaced outwardly from the switch 10 and the adjacent lengths of dielectric tubular material 23. As shown, the axial length of shell 36 overlaps a portion of the outer body 27 of R.F. connector 24 and a portion of the outer body 31 of R.F. connector 25. As seen in Fig. 5, shell 36 includes a perpendicular opening 38 through which an electrically conductive resin 39 can be injected into the space remaining in the aperture 37. As an example, the resin 39 might be an electrically conductive epoxy resin, which, upon curing, provides mechanical rigidity by integrating the switch 10, the lengths of dielectrical tubular material 23, the shell 36, and the R.F. connectors 24, 25 and also provides a perfectly conformal outer conductor surrounding the switch assembly. This eliminates the second impedance mismatch indicated by gaps 19 in Fig. 1. The first mismatch that results from gaps 18 as shown in Fig. 1 is eliminated by use of the R.F. connectors 25 and 25 which can be used in conjunction with complementary connectors (not shown) to insert the switch assembly within a desired circuit structure. Shell 36 also serves as a bobbin for a relay coil 40 (Fig. 5) wound about shell 36 as the last step in the production of the switch assembly. Coil 40 is wound about a cylindrical surface formed coaxially on shell 36 to serve as a control member for selectively activating the reed switch 10 during use of the switch within an electronic circuit. The invention has been described in language more or less specific as to structural features. It is to be understood, however, that the invention is not limited to the specific features shown, since the means and construction herein disclosed comprise a preferred form of putting the invention into effect. The invention is, therefore, claimed in any of its forms or modifications within the proper scope of the appended claims, appropriately interpreted to encompass equivalents. |