The invention relates to an electric lamp comprising: a lamp envelope including a pressed glass reflector body, a light source within the lamp envelope which is energizeable for emitting light, a lamp base having lamp contacts electrically connected to said light source, one of said lamp contacts comprising a threaded shell, and a skin mechanically secured to said lamp envelope and carrying said lamp base.

Such a lamp is known from U.S. Patent 4,658, 178 in the form of a PAR lamp. The skin is made of plastic and has a first end with ramp-like extensions engaged in dimples in the reflector body to mechanically secure the skin to the envelope. The skin has a second end canying a screw-type lamp base in the form of an outer threaded shell secured on a shank portion of the plastic skirt and a center contact. The lead wires from the light source are welded to each of the contacts. Various plastics for the skin are disclosed for accommodating different temperatures of the lamp envelope.

It was discovered that with an all plastic skirt, the relatively high temperature of the rear of the PAR lamp envelope, in lamp wattages as low as about 100 W, changed the characteristic of certain plastics over time. For example, it was found that with an all plastic skirt of ULTEM 1000™ available from the General Electric Company, cracking and clarification of the plastic occurred with an envelope temperature at the skirt/envelope interface of about 210-300°C, reducing the integrity of the skirt.

The lamp designer in this instance could try to select another plastic with higher temperature resistance. However, such materials may have other less desirable characteristics, such as higher initial cost, constraints on the molding process, brittleness, lower elasticity, etc. Plastic skins are typically secured to the lamp envelope by mechanical means, such as with tabs or nubs engaging in respective dimples at the basal end of the lamp envelope, so as to avoid the use of cement and the consequent curing times. High temperature plastics generally have a higher glass fiber content, making them less elastic and

generally more brittle. Furthermore, pressed glass reflector bodies generally have large dimensional variations over the course of a production run due to mold wear, for example, on the order of 0.5 mm for a PAR 38 lamp. With skins of high temperature plastic, these tolerances make it difficult to obtain a proper fit with the lamp envelope because they are not sufficiently elastic to expand and snap onto the lamp envelope if undersized, leading to an unacceptable scrap rate in production. The more brittle nature of higher temperature plastics also leads to cracking due to differences in coefficients of thermal expansion between the plastic and reflector body during lamp use.

It is an object of the invention to provide an electric lamp with an improved skirted lamp base construction, and which is solder-free and weld-free.

According to the invention, a lamp of the type described in the opening paragraph is characterized in that: the skirt includes a metallic skin portion mechanically secured top the lamp envelope and a plastic skirt portion mechanically secured to the metallic skirt portion and carrying the threaded shell.

The metallic skirt portion according to the invention is sufficiently ductile to allow simple assembly to the lamp envelope by known techniques, such as peening. Additionally, the metal skirt portion was found to provide an advantageous temperature drop across its length, reducing the temperature experienced by the plastic portion on the order of 5-7.5% . This was a surprise, because metals generally have a high thermal conductivity and would not be expected to significantly reduce the temperature experienced by the plastic portion. This temperature drop allows for the use of a less heat-resistant plastic, which is generally of lower cost and which generally provides more desirable mechanical characteristics for attaching components of the lamp base, such as greater elasticity, than a more heat-resistant plastic.

According to a favorable embodiment, the metallic skirt portion includes parts integrally molded in the plastic skirt portion. This provides a low-cost method of securing the two skirt portions together, which is automatically obtained during the molding process of the plastic portion of the skirt. Favorably, the part of the metallic skirt portion which is molded in the plastic skirt portion includes a circumferential flanged rim. The flanged rim provides structural stiffness to the sleeve at the area of the joint while also providing additional surface area for contact with the plastic, thereby improving the overall integrity of the hybrid skirt.

It should be noted that U.S. Patent 2,262,629 shows a PAR lamp with a metal skirt carrying a base have a threaded shell over an insulator body. The insulator body, as used in the industry for close to 50 years, is not plastic but glass. Such an insulator is not useful as a skirt. According to another embodiment of the invention, the lamp base includes a lamp base contact electrically connected to a conductive lead from the light source. The lamp base contact has (i) a contact portion for contacting a corresponding contact in a socket and (ii) a rigid shank extending from the contact portion. The plastic skirt portion has a bore wall defining a clamping bore for receiving the shank, the bore being sized and the plastic portion surrounding the clamping bore having an elasticity selected such that (i) the electric lead is securely clamped between the shank and the bore wall when the shank is inserted into the clamping bore with the contact portion seated against the insulative portion and (ii) the lamp contact is secured in the clamping bore solely by friction between the shank and the bore wall, the shank and the bore wall being free of any snap-type engagements. The above features provide a simple, readily manu factorable lamp base construction in which a simple insertion of the contact's shank into the clamping bore (i) firmly secures the lamp contact in the lamp cap and (ii) provides a reliable electrical connection of the lead to the contact and mechanical connection of the lead to the lamp cap. The contact itself is simple - there are no bendable leaves, tabs, lips, flaps or fingers. Accordingly, no closing of these elements is required as with prior art lamp caps, known for example, from U.S. Patent 2,664,551 ; 2,736,873 and U.S. 2,732,532. No additional welding, soldering, peening, pinning, swaging or other metal forming of this contact is required either. The simple shape of the contact and the simple axial insertion motion of the contact into the bore implies a rather simple mechanization, which is extremely important for the very high speed manufacturing necessary for a commercially successful lamp production.

According to a favorable embodiment, the lead extends into the clamping bore with its free end extending in the direction of insertion of the shank into the clamping bore. This avoids the possibility of the lead being pushed out of the bore back towards the lamp envelope when the shank is inserted in the clamping bore. This also has the significant advantage that since the free end of the lead is extending into the bore in the direction of the envelope the lead does not extend to the exterior of the lamp cap. Thus, no trimming of the lead is necessary, further simplifying production.

The above-described orientation of the lead is carried out in one embodiment by a guide bore in the plastic skirt portion which axially extends adjacent the

clamping bore. The lead extends from the lamp envelope through the guide bore in the direction opposite the direction of insertion of the shank and then extends into the clamping bore, providing a simple threading path. Favorably, the guide bore includes tapered guide walls narrowing in the direction away from the lamp envelope for guiding the lead into and through the guide bore as the skirt is placed onto the lamp envelope to receive the lead. Thus, less criticality is required in aligning the skirt with the envelope to reliably thread the lead during high speed production.

To provide a neat, tamper-proof appearance it is desirable that the guide bore terminates adjacent the clamping bore so that the guide bore and the lead extending therefrom into the clamping bore are fully covered by the contact portion of the lamp cap contact. To further improve appearance and tamper resistance, in another embodiment the insulative portion includes a counter bore having a shape complimentary to the contact portion and into which the contact portion is recessed. Recessing the circumferential outer edge of the contact in this manner renders it very difficult for a user to remove the contact without tools.

Instead of the guide bore extending axially adjacent the clamping bore for guiding the lead to the exterior, the guide bore may communicate directly with the clamping bore and guide the lead directly into the clamping bore, for example, at right angles to its axis. This has the advantage that the clamping bore itself acts as a stop to limit the exposure of the lead, thereby automatically measuring the length of the lead to be clamped in the bore.

In yet another embodiment, suitable for lamps which use leads having a conductive core covered by an insulative sheath, the guide bore itself includes a stop which engages the sheath but not the core to control the length of the core inserted into the clamping bore. This feature also prevents the possibility of the lead from being pulled further into the bore during insertion of the shank.

The above-described guiding features are also applicable to the other lead clamped by the threaded shell.

These and other features of the invention will be described with reference to the following drawings and detailed description, which are illustrative of the inventive features and not limiting.

Figure 1 is a diagrammatic cross-section of a PAR lamp illustrating a first embodiment of a hybrid skirted lamp base according to the invention;

Figure 2 is a diagrammatic cross-section of the plastic poπion of the skin

illustrating a second embodiment with a variation of the threading path of the center lead wire from that shown in Figure 1 ; and

Figure 3 is a diagrammatic cross section of a third embodiment illustrating another threading path for the center lead-wire.

Figure 1 shows an end portion of the reflector body of a parabolic aluminized reflector (PAR) lamp including a lamp cap which embodies several features of the invention.

The lamp includes a lamp envelope 1 of pressed hard glass having a plurality of recesses 3. A conductive center lead wire 5 and a corresponding side wire 7 extend from respective ones of ferrules 9, 11 in the axial direction away from the lamp envelope 1. The ferrules 9, 11 hermetically seal the envelope 1 and provide mechanical support and electrical connection to the light source, in the Fig. in the form of an incandescent filament 8, in a well known manner. Alternatively, the light source could be a halogen burner or a high pressure gas discharge arc tube, such as a metal halide arc tube.

A lamp base 15 is secured to the envelope 1 and includes a skirt 17, 40 with a plastic portion 17 of synthetic resin material and a metallic portion 40. The plastic portion 17 carries the lamp base 15 including a center contact 19 and a threaded shell 30. The contact 19 has (i) a contact portion 21 for contacting a corresponding contact in a mating socket and (ii) a rigid shank 23 extending from the contact portion 21. The plastic portion 17 has a re-entrant portion 25 with a bore wall 27 defining a clamping bore 26 for receiving the shank 23. The bore wall 27 has a diameter selected relative to that of shank 23 and the synthetic resin material of the portion 17 has a modulus of elasticity selected so that the center lead 5 is securely clamped between the shank 23 and the bore wall 27 when the shank is inserted into the clamping bore 26 with the underside 22 of the contact portion 21 seated against the end surface 29 of the reentrant portion 25. The lamp contact 19 and lead wire 5 are secured in the clamping bore 26 solely by the press fit between the shank 23 and the bore wall 27 due to the elasticity of the synthetic resin material of the bore wall.

In the lamp cap of Figure 1, the shank 23 and the bore wall 27 are both circular cylindrical in shape. The shank 23 has a rounded/chamfered edge 24 as does bore wall 27 (at reference numeral 28) to guide the shank during insertion into the clamping bore. Alternatively, the shank/bore may have a slight taper, for example on the order of l °-2° towards the lamp envelope. The shank 23 as shown is solid, but may be tubular. The simplicity of these shapes allow these elements to be more cheaply manufactured than some

of the more complicated components present in the prior art, such as with the spring-fingers of the contact shown in U.S. Patent 2,336,529 or the quadrant flaps of U.S. Patent 2,664,551. Additionally, the insertion of the contact into the clamping bore in the present invention completes the assembly, whereas the tubular rivet of the and the flaps, tabs, lips or leaves of the patents referred to and other known patents require further mechanical deformation to clamp the wire after their contacts are first secured to their respective insulative bodies. Accordingly, it is readily seen that the disclosed arrangement according to the invention is a simple, elegant, yet effective solution which has previously remained unrecognized by those in the lamp arts. The threaded metallic contact 30 is in electrical contact with the side lead wire 7, which extends from ferrule 9 through bore 31 and then back towards the envelope 1 in the direction of insertion (indicated by Arrow A) of the threaded contact 30. The threaded shell 30 is circumferentially swaged or peened to the plastic skirt portion 17 at the axial location indicated by reference numeral 33 to mechanically secure it thereto and to provide electrical contact with side wire 7. It is noted that it is known from commercially available compact fluorescent lamps to fix the side lead-wire between the threaded metallic shell of the lamp cap and the plastic housing by swaging, peening, or otherwise deforming the threaded shell onto the plastic housing with the side lead wire therebetween.

The metallic skirt portion 40 includes a first circumferential end portion 41 for receiving the basal portion 2 of the lamp envelope. A second circumferential end portion 43 is integrally molded in a first end portion of the plastic skirt portion 17. The second end portion 43 of the metal skirt 40 includes a flanged rim 45 extending generally transverse to the lamp axis. The flanged rim 45 extends about the entire circumference of the metal skirt portion 40. The rim 45 also includes slot or holes distributed about its circumference through which the plastic material of skirt portion 17 extends. This ensures that the skirt portion 17 is rotationally locked to the skirt portion 40. The second end portion 41 is secured to the basal portion 2 by peening into recesses 3. No cement is used.

Various samples were made to test the feasibility of the hybrid lamp base according to the invention. In a first experiment, lamp bases with hybrid skirts according to Figure 1 were compared to all-plastic skirts. In both cases, the plastic was ULTEM 1000™. For the lamp cap according to Figure 1 , the metallic skirt was made of brass having a wall thickness of 0.4 to 0.5 mm. Both samples were placed in an oven at 250°C, which is the maximum fixture temperature for a high-hat fixture according to the IEC standards. After 48 hours, the all-plastic skirted bases completely melted and ended up as a puddle of plastic

while the hybrid skirted bases according to the invention remained intact and useable. This was completely surprising, since after 48 hours in the oven both the all-plastic and the hybrid skirted bases would be experiencing the same temperature regardless of the difference in the heat capacity and conductance between the metallic skirt portion of the hybrid bases and the corresponding plastic portion of the all-plastic bases. It is believed that the presence of the metallic skirt portion added structural integrity and prevented the plastic from deforming and flowing.

In additional tests, six bases were made and again placed in an oven at 250 °C for 90 hours. The six bases included three hybrid and three all-plastic bases with each of the plastics of Table I.

TABLE I

Brand/ Source Type Deflection Flexural Designation Temp. (C) Modulus ©264PSI (GPA)

Ryton/RT02 Philips 66 Poly-phenylene 260 1.72 Sulfide

Amodel ^® / Amoco Polyphath- 294 12.4 AF-4133X Polymers almide (33 % Glass Reinforced)

Wellamid™ Wellman, Inc. Nylon 66 240 6.85

As illustrated in Table II, after 90 hours each of the all-plastic skirts exhibited significant visible damage including marks and shape distortions. In contrast, the hybrid skirts of Ryton and Amodel showed no visible damage. The hybrid base of Wellamid showed minor distortion on the interior of the shell.

TABLE II

SHELL CRACKS DISTORTION

AP Wellamid Y Major (melted)

AP Amodel Y Major

AP Ryton Y Major

H Wellamid N Minor Interior

H Amodel N No

H Ryton N No

H = Hybrid; AP = All Plastic.

In yet another test, two complete 120 W, 120 V PAR lamps were burned base-up in high-hat fixtures at 100% , 110%, and 120% of rated voltage and stabilized for 2 hours at each voltage. One lamp had an all-plastic base of Wellamid Nylon 66 and one lamp had a hybrid base in which the plastic portion was of Amodel plastic. Temperature measurements were taken at the interface of the skirt with the reflector heel ("Temp 1 "), and the joint between the metal skirt portion and the plastic skirt portion (for the hybrid base) and the corresponding location for the all-plastic base ("Temp 2"). These temperatures are shown in Table III.

TABLE III

Hybrid All-Plastic

120V 132V 144V 120V 132V 144V (100%) (110%) (120%) (100%) (110%) (120%)

TEMP 1 164°C 175 187 133 142 151 TEMP 2 177 189 202 179 188 202

As shown in Table III, with the all-plastic skirts, the highest temperature experienced was 202°C, at the interface of the plastic with the glass reflector body. For the hybrid skirt, the highest temperature was the same, at the interface with the reflector body, but this temperature is experienced by the metal skirt portion. The highest temperature

experienced by the plastic was 187°C, about 7.5% less than with the all-plastic skirt. At rated voltage, the highest temperature of the plastic was still about 5% lower than for the all- plastic skirt. It should be noted that the difference in plastic between the two samples is not believed to effect the temperature measurements. Figure 2 illustrates a variation of the plastic portion for use with lamps having insulated conductive leads. Parts identical to those in Figure 1 bear the same reference numerals. The leads 5, 7 in this embodiment have an insulative sheath 5a, 7a about their conductive single-strand core 5b, 7b respectively. The skirt portion 37 has tapered guide walls 49 for guiding the lead 5a through the guide bore 50. The guide walls 49 also serve as a stop for limiting the length of the trimmed end portion 5c (stripped of its insulative sheath) which extends out of the guide bore 50 by engaging the end of the insulative sheath. However, since the free end portion 5c extends in the same direction as the direction of insertion of the shank into the clamping bore, the free end portion cannot be pushed out of the bore during insertion of the shank 23. Movement of the lead wire 5 is further limited by the interaction of the end of the sheath 5a with the tapered guide walls.

The skirt portion 37 also has a recess 53 which has a complementary shape to the outer circumferential edge 22b of contact 19. Recessing of this edge prevents tampering by the user to remove contact 19. The guide bore 50 and lead 5 are also covered by the contact portion 21 of contact 19, providing a neat, clean appearance. Figure 3 shows a construction similar to that in Figure 2 but in which the guide bore 61 communicates directly with the clamping bore 66, extending generally transversely to the direction of insertion of shank 23 (Fig. 1). The contact 19 is not shown, to better illustrate the position of end portion 5c after threading through the guide bore 61.

In the embodiments shown above, suitable materials for the center contact 19, the threaded shell 30 and the skirt portion 40 include brass and aluminum. It should be noted that in prior art bases which used a glass insulator, aluminum could not be used for the threaded shell because the molten glass destroyed the aluminum. Thus, the much lower temperature setting plastics in the skirt portion expands the choice of metals available to the lamp designer. The lead wires for the embodiments of Figures 2,3 had one (1) tinned copper strand with a PVC/nyion insulation sheath.