JPH03179658A - Compact reflection type lamp unit - Google Patents

Abstract

PURPOSE: To provide a compact reflection type lamp unit which can be installed in an existing socket by arranging a sleeve member adhered to both a lower part of a reflector and a hollow screwing-in type base. CONSTITUTION: A lamp unit 10 has a reflector 12 fixed to a screwing-in type base 14 and a tungsten halogen lamp 16, and a lower part 20 of the reflector 12 is fixed to an upper end part of a hollow nonconductive sleeve 22. This sleeve is a cylindrical shape, and its lower end part is similarly fixed to the screwing-in type base 14. Therefore, while maintaining the total length of the lamp unit necessary to be installed in an existing R30 type socket by physical joining of the reflector 12 to the base 14 by adhesion to the intermediate sleeve 22, a length of the lower part 20 of the reflector can be substantially shortened.

Description

DETAILED DESCRIPTION OF THE INVENTION BACKGROUND OF THE INVENTION The present invention relates generally to the construction of reflective lamp units, and more particularly to modifying the construction of compact reflective lamp units so that they can be installed in existing sockets. Regarding things.

Parabolic aluminized reflector (PAR) lamps and beam control characteristics represented by reflector (R) lamps with low efficiency are generally already known for spot or flood lighting applications.

Initially designed PAR and R type lamps had relatively large physical dimensions compared to conventional incandescent light bulbs. The requirement to mount these lamps in relatively large sockets has particularly limited indoor applications. Accordingly, subsequent PAR and R-type lamp designs have reduced overall dimensions while maintaining accurate and efficient beam control to increase indoor applications.

In order to further increase the utilization of this more compact reflective lamp structure, it is likewise preferred that the lamp be mounted in the user's existing socket. For example, installation of compact PAR30 type lamps typically requires meeting the space requirements of the rR30ANS I BoxJ, which specifies maximum and minimum lamp space for the luminaire manufacturer. It can be seen that it is advantageous for lamp manufacturers to comply with the above-mentioned requirements for installed reflective lamp units in that neither the user nor the luminaire manufacturer has to adjust the lamp installation. Although the installation described above can meet the requirements by simply increasing the manufacturing length of the lamp parts for such lamp units, such a method requires an increase in the number of lamp parts and Many important considerations also make this impractical, including the increased cost and specialization of manufacturing equipment. Additionally, increasing the neck length of the lamp member for the compact PAR30 type lamp units currently manufactured creates even more serious problems. In particular, the aluminized reflective surface applied to the extended neck of the lamp member may be uneven enough to allow light leakage at the neck. It can also be appreciated that such light loss is unsightly when the attached lamp is in operation. It therefore proves preferable to extend the overall length of the reflective lamp unit by other means during manufacture.

Additionally, increasing this length does not require any changes to the structure of the lamp components already in use, or substantially alters the manufacturing procedures currently used to assemble these lamp components together. It is more preferable not to change the characteristics. A known means for physically joining the reflective member of a reflective lamp unit to a metal screw base by means of an intervening plastic skirt is disclosed in U.S. Pat. No. 4,658,178. Disclosed. Although the overall length of the reflective lamp unit is clearly increased in this way, this disclosed measure requires a change in the structure of the lamp parts that are joined in one piece, and also requires a change in the normal manufacturing process. It also requires changes to procedures. In the former case, the connection between the plastic skirt and the reflective element is such that the finger-like elements provided on the skirt structure engage reciprocally into the recesses formed on the reflective element. for joining the plastic skirt to the disclosed metal threaded base;
A similar fixed engagement between a recess formed in the metal base shell portion and a recess provided in the skirt member is used. Also, the method for assembling the lamp component thus modified in -Ri differs considerably from the conventional method of attaching the metal base shell part to the reflective member by means of adhesive cement. As disclosed therein, the plastic skirt needs to be screwed into the metal base shell part, thereby allowing the -
There is a risk of deformation or material damage to lamp parts that are joined together.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide an improved reflector lamp unit that can be installed in an existing socket.

Another object of the invention is to provide a means for improving the construction of a compact anti-41 type lamp unit so that substantially all of the light emission passes forward.

Yet another object of the present invention is to provide an improved compact reflective lamp unit structure that allows the reflective lamp unit to be relatively easily installed and removed by the user.

Yet another object of the present invention is to enable such an improved compact reflector lamp unit to be assembled on existing automated manufacturing equipment without requiring modification of the manufacturing equipment.

These and other objects of the invention will become apparent upon consideration of the following detailed description of the invention.

SUMMARY OF THE INVENTION In order to ameliorate the above-mentioned drawbacks associated with conventional reflective lamp units of this type, improved construction means are provided which further reduce the size of the compact reflective member.

This structural modification uses a non-conductive hollow sleeve that is glued at one end to the bottom of the reflective member and at the other end to the hollow metal threaded base of the reflective lamp unit. Overall, a reflector lamp unit with this modified structure includes (a) a reflector having an inner conductive opposing surface and a longitudinally extending bottom; (b)
Tungsten located approximately at the optical focus of the reflector.
A halogen lamp comprising an elongated sealed envelope of light-transparent material containing an inert gas fill and a halogen substance, and at least a pair of sealed envelopes projecting from the envelope in a squeeze-seal region at one end of the envelope. a tungsten-halogen lamp having a tungsten filament supported by a conductor; and (C) a hollow metal threaded base attached to the bottom of the reflector via a non-conductive sleeve member disposed therebetween. , the sleeve member has a hollow interior cavity, and - the inner contour of the end is sized and shaped to receive and physically support the base of the reflector; a hollow metal threaded screw whose outer profile is sized to allow insertion of the other end into the hollow threaded base, and wherein the sleeve member is bonded to both the base of the reflector and the hollow threaded base; (d) means for electrically connecting said protruding conductor to said threaded base. In this case, the hollow sleeve allows the length of the bottom of the reflector to be installed in an existing socket and avoids light spillage that would occur if the bottom of the reflector was long. Furthermore, this type of reflective lamp unit generally has a lamp element mounted on top of the reflector. Various mounting structures for physically supporting the tungsten-halogen lamp used in this improved reflective lamp unit are contemplated, as well as various structural arrangements for the light source itself. For example, the physical support of a tungsten-halogen lamp can be accomplished entirely by the above-mentioned protruding conductors. The well-known lamp mounting of this scale connects the ends of the lamp filament to a first pair of refractory gold-layered conductors, and the other end of this refractory metal conductor has a greater thermal expansion characteristic in the squeeze-sealed region of the lamp envelope. This is done by joining a second pair of larger diameter conductors having a . Alternative lamp mounting constructions are also known that utilize only a pair of refractory metal conductors connected to the lamp filament. U.S. Patent Application No. 30, filed January 30, 1989
No. 3,890 and U.S. Pat. It has auxiliary clamping means provided in the squeeze seal area of the lamp envelope to withstand it. Additionally, suitable tungsten-halogen lamp constructions include filament alignment means generally along and substantially transverse to the central or longitudinal axis of the lamp unit. Further possible modifications of this reflective lamp unit include:
At least a pair of openings are provided through the longitudinally extending bottom end of the reflector, and a pair of electrically conductive strut members extend through the openings for connecting to the pair of projecting conductors. There is. In this lamp embodiment, the outermost ends of both strut members are electrically connected to another conductor that is electrically connected to the threaded base and extends around the end of the hollow sleeve. terminating within the internal cavity of the hollow sleeve.

- In a preferred embodiment, the reflective lamp unit (
a) a pressed-molded glass concave reflector having a parabolic conductive inner reflective surface and a longitudinally extending conical bottom having a terminal end provided with at least one pair of apertures; an elongated sealed aluminosilicate having a coiled tungsten filament positioned approximately at the optical focus of the reflector and further encapsulating a charge of at least one noble gas and a vaporizable halogen compound at superatmospheric pressure; (c ) a non-conductive sleeve member having a hollow cavity and physically securing the bottom of the reflector to a hollow metal threaded base;
The inner contour of one end is sized and shaped to insert and physically support the base of the reflector therein, and the outer contour of the other end is sized and shaped to insert and physically support the base of the reflector therein; a non-conductive sleeve member sized to be inserted and further adhered to both the bottom of the reflector and the hollow threaded base; (d) electrically connecting said pair of projecting conductors to said threaded base; (e) a pair of conductive strut members extending through an opening in the reflector and connected to the pair of conductors; and means for securing said strut member with a non-conductive adhesive, the means comprising a barrier means for preventing the adhesive from entering the inner recess of the reflector. The hollow sleeve allows the bottom length of the reflector to be attached to an existing socket and prevents light leakage that would occur if the reflector bottom was long. The opening for the support member in this embodiment of the lamp is provided with a non-conductive wafer, which is bonded to the bottom end of the reflector by ceramic cement. Furthermore, in this embodiment the conductor means for electrically connecting said projecting conductors comprises a fuse lead, and the hollow sleeve in this lamp embodiment accommodates one of said projecting conductors. It has longitudinal groove means. Another possibility is to form the four parabolic parts of the reflector into a concave elliptical shape.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring now to the drawings, FIG. 1 shows an improved reflective lamp unit 10 having PAR30 dimensions in accordance with an embodiment of the present invention.

The lamp unit 10 includes a reflector 12 and a tungsten-halogen lamp 16 secured to a threaded base 14 as described below. The reflector 12 has a parabolic dihedral 1.1 surface 18, typically of silver, aluminum or gychroic type, and a longitudinally extending conical bottom 20 as shown.

The bottom portion 20 of the reflector 12 is secured to the top end of a hollow non-tetraconductive sleeve 22 . This sleeve has a cylindrical shape and its lower end is likewise fixed to the threaded base 14. Also, as shown in the figure, the bottom 20 of the reflector 12
further includes means 28 for a non-conductive heat resistant closure having a pair of openings 24 and 26 formed therein. This closure means 28 is fixed in a central opening 28 provided at the lower end of the bottom part 20. Furthermore, the upper end of the reflector recess 30 is closed by a conventional lens element 32. Physical joining of the reflector 12 to the base 14 by adhesion to the intermediate sleeve 22 reduces the length of the base 20 of the reflector while maintaining the overall length of the lamp unit required for installation in existing R30 type sockets. can be substantially shortened. For example, a reflector with a half inch shorter base can be used for the particular lamp unit described herein.

The tungsten-halogen lamp 16 has an axially collapsed tungsten coil filament 31. The filament 31 is sealed within an elongated envelope 33 with its center located approximately at the optical focus of the reflector 12.

The filament 31 is a "lead wire" type conductor 34.
36, 38 and 40 are physically suspended within the envelope 33.

More specifically, such a cooperating lead wire structure uses a first pair of conductors 34 and 36, one end of which is connected to filament 31;
The other end is the stem press area 42 of the lamp envelope 33.
They are individually connected to large diameter conductors 38 and 40 within. In the particular sized lamp embodiment shown, suitable inner conductors 34 and 38 are formed of a molybdenum alloy with a diameter of about 12-30 mils, and protruding suitable conductors 38 and 40 have a diameter of about 35 mils. - Constructed of a conductive metal with high thermal expansion characteristics, such as 60 mil nickel-plated iron or nickel-iron alloy. In other lamp embodiments, a single pair of molybdenum alloy conductors having a diameter of up to about 25 mils is used in combination with the external clamping support means disclosed in the aforementioned U.S. Patent Application No. 331,154. , the lamp envelope can be properly suspended. Fourth, the illustrated lamp envelope 33 contains a gaseous fill (not shown) containing at least one noble gas and a vaporizable halogen material, such as an alkyl halide.

Protruding conductor 3 in the illustrated embodiment of the lamp unit
8 and 40 are seen extending τE through openings 24 and 26, respectively, provided in the non-conductive heat resistant closure means 28. As shown, a suitable refractory closure means 28 comprises a glass or ceramic wafer 35 adhered to the opening 29 by a non-conductive refractory closure means 37 . The conductor is also secured within the opening of the wafer by the heat resistant, non-conductive cement, furthermore, heat resistant barrier means 43 prevent the adhesive from entering the inner recess of the reflector. Means are provided for electrically connecting the protruding lower end of the conductor to a conventional threaded base 14 within the central cavity of the hollow sleeve 22. More particularly, it includes a conductor 44 as a means for electrically interconnecting the protruding conductors 38 to the sides of the metal base 14, and the remaining protruding conductors 40.
are interconnected via a conductor 47 to the central eyelet 46 of the metal base shell portion. It is contemplated that this desired interconnection may be made by conventional metal fastening means such as soldering, welding or crimping, and that the parameters selected for conductor 47 may act as a fuse element. Although not shown in the illustrated lamp unit embodiment, the compact reflective lamp unit disclosed in the aforementioned U.S. patent application Ser. It is also possible. Such a modification requires a sleeve member 2 between the 11 unit and the threaded base member used therein.
2 may be provided and physically joined using adhesive cement or the like. A modification of such a lamp unit also involves providing a pair of strut elements extending upwardly through an opening provided in the bottom of the reflector, and connecting the struts from one end of the tungsten-halogen lamp. It will be clear that the connection can be made to the pair of protruding conductors.

Furthermore, as can be seen from the drawings showing a typical lamp unit according to the present invention after final assembly, the sleeve 22 has certain specific lateral features that enhance automatic assembly of the lamp parts (see FIG. 2(a)). and will be described in detail below with reference to FIG. 2(b)). More particularly, the upper tapered portion 48 of the hollow sleeve is adapted to fit therein such that the bottom portion 20 of the reflector is joined together by conventional adhesive means, whereas the cylindrical shape of the sleeve The lower portion 50 of the is adapted to be inserted into the hollow threaded base 14 and similarly joined. Furthermore, thermal surface roughening means are provided which cooperate when the lamp parts are joined together.

A ledge or shoulder 52 in the center of the sleeve 22 allows the sleeve to be seated in the hollow base shell portion during the assembly process.

Additionally, a groove or groove 54 is provided on the outer surface of the sleeve for inserting the conductor 44. Further ridges or rib elements 5 provided on the inner surface of the sleeve
6 is provided to hold the sleeve in alignment with the bottom of the reflector when assembled. For this reason,
The rib elements physically engage grooves or recesses provided on the outer surface of the bottom of the reflector.

FIG. 2(a) is a side view of the hollow cylindrical sleeve 22 used in the reflective lamp unit of FIG.
FIG. 2(b) is a top view of the same sleeve. Such a sleeve can easily be formed from a heat resistant synthetic organic polymer material, such as polyphenylene sulfide or liquid crystal polymer, to withstand wall temperatures of over 200 DEG C. when the illustrated lamp unit is in operation. As previously discussed, the sleeve has a lower cylindrical portion 50 and a -L tapered portion 48 joined at a central ledge or shoulder 52. The inner contour of the upper tapered portion 48 is sized to accommodate the insertion of the bottom portion 20 of the reflector for mating with each other, and further includes an inner protrusion provided to physically support the inserted reflector. 53. The outer profile of the lower cylindrical portion 50 is sized for insertion into the interior cavity of the metal base shell portion 14, and a shoulder 52 projecting outwardly therefrom provides structural support for the assembly. There is. A central opening or cavity 55 extends the entire length of the illustrated sleeve, allowing conductor means to pass therethrough for electrically interconnecting the tungsten-halogen lamp within the reflector to the metal base shell portion. can.

In addition, a vertical fillet or fillet 54 (as shown in FIG. 2(b)) is provided on the outer surface of the lower cylindrical portion 50.
A conductor 44 for terminal connection to the side of the metal base shell portion can be inserted therein. A second (b) projecting from the inner surface of the upper tapered portion 48
The illustrated rib elements 56 are provided to align with corresponding surface asperities provided on the outer surface of the base of the reflector to thereby hold the lamp components in alignment during the assembly process. to assist.

Fully automated manufacturing of the above-described reflective lamp units can be carried out using conventional lamp assembly equipment. In this case, the tungsten-halogen lamp 16 and the reflector 12
is first assembled in the usual way. Conductors 44 and 46 are then secured to protruding conductors 38 and 40 by conventional means such as soldering or welding. The sleeve 22 is then bonded to the reflector bottom 20 with a suitable epoxy cement. Threaded base 14 is then joined to the opposite end of sleeve 22 in a similar manner, and finally conductors 44 and 46 are electrically connected to said base in conventional manner.

Such lamp units can be installed in existing sockets.

It will be apparent from the above description that there has been provided an overall improved compact reflector lamp unit that can be installed without modification into existing sockets. However, it is contemplated that modifications may be made to the lamp embodiments shown herein without departing from the spirit and scope of the invention. For example, the sleeve member can be constructed of other non-conductive materials #1 including glass and ceramics. Similarly, the parabolic reflective surface of the reflector member shown here may be of other known shapes, and the reflective surface may be a stippled or diffusely reflective coating, or other well-known polygons. It may also be of anti-1/J shape.

Similarly, tungsten-halogen lamps can have tungsten filaments sized and shaped to suit the particular wattage and voltage requirements of the intended lamp unit application. Furthermore, already known heat shielding means can also be provided beside the lamp. Therefore,
The invention is limited by the scope of the claims that follow.

[Brief explanation of drawings]

FIG. 1 is a side view of one embodiment of a compact parabolic aluminized reflector (PAR) lamp unit according to the present invention. FIG. 2(a) is a side view showing one embodiment of a hollow cylindrical sleeve member used in the reflective lamp of FIG. 1. FIG. FIG. 2(b) is a top view of the sleeve portion shown in FIG. 2(a). 10... Reflective lamp unit, 12... Reflector,
14... Screw-in base, 15... Tungsten-halogen lamp, 18... Reflective surface, 20... Bottom, 22... Sleeve, 24. 26... Opening, 30
...four reflectors, 31...filament, 33...
・Envelope, 34.36.38.40...Conductor.

Claims (1)

Claims: 1. (a) a reflector having a conductive inner reflective surface and a longitudinally extending bottom; (b) a tungsten-halogen lamp positioned approximately at the optical focus of the reflector; an elongate sealed envelope of optically transparent material enclosing an inert gas fill and a halogen substance; and at least one pair of conductors protruding from the envelope and sealed at a squeeze seal region at one end of the envelope. a tungsten-halogen lamp having a tungsten filament supported within an envelope;
(c) having a hollow internal cavity, the inner contour of one end of which is sized and shaped to allow insertion and physical support of the bottom of the reflector therein, and the outer contour of the other end thereof; (d) a sleeve member sized to allow the other end to be inserted into a hollow threaded base and further adhered to both the bottom of the reflector and the hollow threaded base; (d) the protrusion; and means for electrically connecting both conductors of the reflector to the threaded base, the sleeve member allowing the bottom length of the reflector to be installed within an existing socket. A reflective lamp unit designed to prevent light leakage that may occur if the lamp is long. 2. The reflective lamp unit according to claim 1, further comprising a lens element attached to the upper part of the reflector. 3. A reflective lamp unit according to claim 1, wherein the physical support of the tungsten-halogen lamp is completely provided by the protruding conductor. 4. The reflective lamp unit of claim 1, wherein both ends of said tungsten filament are connected to a single pair of sealed refractory metal conductors in a squeeze seal region of said envelope. 5. Both ends of the tungsten filament are connected to a first pair of heat-resistant metal conductors, and the other ends of the heat-resistant metal conductors are joined to a second pair of conductors having a larger diameter and having larger thermal expansion characteristics. 2. The reflective lamp unit according to claim 1. 6. A longitudinally extending bottom portion of the reflector terminates in at least a pair of openings, and a pair of conductive strut members extend through the pair of openings for connecting to the pair of conductors. 2. The reflective lamp unit according to claim 1. 7. The outermost ends of said strut members terminate within the interior cavity of said sleeve member and connect to another conductor extending around the ends of said sleeve for electrical connection to said threaded base. 7. The reflective lamp unit according to claim 6, wherein the reflective lamp unit is electrically connected. 8. The reflective lamp unit according to claim 6, wherein no conductive reflective surface is provided above the opening. 9. Claim 6, wherein the strut member is secured to the opening by a non-conductive adhesive, and barrier means are provided to prevent the adhesive from entering the inner recess of the reflector.
Reflective lamp unit as described. 10. A reflective lamp unit as claimed in claim 1, wherein the bottom of the reflector and the sleeve are provided with cooperating surface roughening means to assist in joining and aligning them together. 11. The reflective lamp unit according to claim 1, wherein the tungsten filament is aligned with the central axis of the lamp unit and extends in the axial direction. 12. The reflective lamp unit of claim 1, wherein said sleeve member is formed from a heat resistant synthetic organic polymer material. 13. The reflective lamp unit of claim 1, wherein said sleeve member has a groove for passing said means for electrically connecting said protruding conductor to said threaded base. 14. (a) formed of press-formed glass and having a parabolic conductive inner reflective surface terminating in a longitudinally extending conical bottom with a pair of openings extending therethrough; (b) a superatmospheric pressure filling comprising a coiled tungsten filament positioned approximately at the optical focus of the reflector and comprising at least one noble gas and a vaporizable halogen compound; an elongated sealed aluminosilicate glass envelope enclosing a tungsten filament, the ends of the tungsten filament being supported by at least one pair of conductors sealed in a squeeze seal region of one end of the glass envelope and projecting from the envelope; (c) having a hollow internal cavity, the internal contour of one end of which is sized and shaped to receive and physically support the bottom of said reflector; a non-conductive sleeve, the outer contour of one end being sized to allow the other end to be inserted into a hollow threaded base, and further adhered to both the bottom of the reflector and the hollow threaded base; (d) means for electrically connecting said pair of projecting conductors to said threaded base within an interior cavity of said sleeve member, the means extending through an opening in said reflector; (e) means having at least a pair of conductive strut members connected to the pair of conductors; (e) means for securing the strut members within the opening with a non-conductive adhesive; means for providing a barrier means for preventing the ingress of adhesive into the interior recess of the reflector, the hollow sleeve member allowing the bottom length of the reflector to be attached to an existing socket; Reflective lamp unit designed to prevent light loss that can occur if the base of the reflector is long. 15. The reflective lamp unit according to claim 14, further comprising a lens element attached to the upper part of the reflector. 16. The reflective lamp unit of claim 14, wherein physical support of said tungsten-halogen lamp is provided entirely by said protruding conductor. 17. The tungsten filament is aligned with the central axis of the lamp unit and extends in the axial direction,
15. The reflector lamp unit of claim 14, wherein both ends are connected to a single pair of refractory metal conductors hermetically sealed in a squeeze-sealed region of the glass envelope. 18. The tungsten filament is aligned with the central axis of the lamp unit and extends in the axial direction,
Claim 1: Both ends are connected to a first pair of heat-resistant metal conductors, and the other end of the heat-resistant metal conductor is joined to a second pair of large-diameter conductors having larger thermal expansion characteristics.
4. The reflective lamp unit described in 4. 19. The reflector lamp unit of claim 14, wherein said opening for said strut member is provided in a non-conductive wafer sealed to a bottom end of said reflector. 20. The reflective lamp unit of claim 14, wherein said means for electrically connecting said projecting conductor further comprises a fuse element. 21. The reflective lamp unit according to claim 14, wherein said sleeve member further has a longitudinal groove on its outer surface for accommodating one of said protruding conductors.