NL8902438A - ELECTRIC LAMP. - Google Patents

Description

N.V. Philips' Incandescent lamp factories in Eindhoven.

"Electric lamp."

The invention relates to an electric lamp provided with a light-transmitting lamp vessel having an axis and an end part on that axis, an electric element in the lamp vessel, a plastic lamp base with an axis, which carries electrical contacts and is fixed around that end part of the lamp vessel. which lamp cap has a sheath portion with an open end portion surrounding said end portion of the lamp vessel, and a base portion opposite the open end portion, said base portion carrying at least one of the contacts, current supply conductors extending from the electrical element to the contacts of the lamp cap, the lamp cap and lamp vessel have cooperating cams and grooves, which limit relative rotation and translation of the lamp cap.

Such a lamp is known from GB 1,240,346.

The lamp base of the known lamp is a Swan (bayonet) lamp base, with which a lamp holder makes electrical contact at two discrete places on the base part. In this known lamp, the lamp cap at the open end portion has axial slits to make the lamp cap at that end portion flexible so that the lamp cap when assembled with the lamp vessel can be widened at its open end portion to engage the cams and grooves to come.

A drawback of this known lamp is that the lamp cap of a finished lamp can be widened again as a result of its flexibility, and that the coupling between the lamp cap and the lamp vessel can then be lost. To overcome this drawback, the slits are closed, for example, with glue or sealant after assembly. A drawback of this is that the use of, for example, sealant, which must be cured, for attaching the lamp cap to the lamp vessel is not avoided.

Another Swan-type plastic lamp base is known from GB 2,152,746A. This lamp cap also has slits at the open end portion or, after placement on the end portion of a lamp vessel, is thermally deformed to form cams that engage grooves in the lamp vessel.

This GB 1,380,720 is an electric lamp with a plastic lamp base of the Swan type known, in which the lamp base is glued to the lamp vessel. The lamp has no means to withstand M, torsional forces applied to the coupling of the larap base to the lamp vessel. The known lamp has no essential advantages over a lamp with a lamp base attached with kit.

The object of the invention is to provide an electric lamp of the type described in the opening paragraph with a lamp cap of a construction which, inter alia, allows an easy assembly of the lamp cap and the lamp vessel and which is furthermore suitable to be formed as an Edison lamp cap, wherein after all, in a lamp holder an electrical contact is made at any location along the circumference of the lamp base, near its base part.

This object has been achieved with a lamp of the type described in the opening paragraph, because the lamp cap has an axial partial surface and a first and a second part to the side of that partial surface, which parts are rigidly connected to each other.

This construction has significant advantages with both Swan and Edison lamp bases, including rapid assembly, good coupling of lamp barrel and lamp cap, and the ability to give the power supply conductors a defined path through the lamp cap.

The parts of the lamp cap can be connected to one another by means which are integral therewith, for instance by mechanical means, such as for instance a snap connection. For example, co-acting cams on the first and second parts of the lamp cap can occur. An embodiment with protrusions and recesses is also very advantageous, wherein a protrusion is always clampingly received on a part of the lamp cap in a recess in another part of the lamp cap. In one embodiment, a recess has a narrowing through which a projection protrudes. Usually the application of such a narrowing results in the recess opening into the outer surface of the lamp cap.

The coupling of the parts of the lamp cap to each other, and therefore the coupling of the lamp cap to the lamp vessel, is particularly tight if a click connection occurs on the open end portion of the lamp cap. This is favorable for lamp bases of a relatively large diameter, for example 20 mm or more, where higher requirements are imposed on the minimum torsional force that the lamp cap must withstand without losing its coupling to the lamp vessel than with lamp bases of a smaller diameter.

A snap connection, for example a snap connection in the open end section, can be combined with other types of connecting means elsewhere on the lamp cap, for example protrusions and recesses co-operating therewith.

Doou! ^! d: ·· l üMivot 1 is divided, the current supply conductors can easily be led out from the lamp cap, namely along the axial part plane. The relatively weak current supply wires then no longer need to be passed through narrow openings in the lamp cap.

An important other consequence of the axial division of the lamp cap is that a very good coupling of the lamp cap with the lamp vessel is obtained, with a very good protection against rotation and translation of one with respect to the other. To be able to couple the lamp base and the lamp vessel, the elasticity of the lamp base does not require elasticity of the lamp base. The cooperating cams and grooves occurring on the lamp vessel and the lamp cap may therefore be high or deep. Namely, the parts of the lamp cap are diametrically moved towards each other during assembly, with the insertion of the lamp vessel.

In a favorable embodiment, the lamp vessel and the lamp cap have co-operating transverse grooves and cams for an axial coupling, whereby the lamp vessel at its end section is externally and the lamp cap at its open end section is internally unround to secure against relative rotation.

The projections and the grooves may be formed such that the end portion of the lamp vessel and the open end portion of the lamp cap have co-operating cross-sections which have the shape of a flattened ellipse, the long axis of which is transverse to the partial surface. Torsional forces exerted on the lamp cap by the lamp envelope then form a lesser load on the coupling of the parts of the lamp cap.

Inwardly protruding, for example tapered, protrusions, for example prismatic ribs, may occur in the end portion of the lamp cap. These can compensate for dimensional differences, so that a tolerance-free coupling between the lamp vessel and the lamp cap can be obtained despite tolerances.

In a favorable embodiment, the lamp vessel has a first pair of mirror-image grooves and a second opposite pair. It is advantageous if the grooves have a boundary which lies in a substantially axial plane of the lamp vessel. Due to this limitation, cams on the end portion of the lamp cap have a good grip on the lamp vessel, in order to prevent relative rotation. It is advantageous if said cams have a cooperating surface lying substantially in an axial plane of the lamp cap.

In a variant of this embodiment, the cams are each connected to the lamp cap via an elastic arm. The variant can be realized by surrounding each cam with a U-shaped slit in the lamp base. In this variant, a rattle-free coupling between the lamp base and the lamp vessel can be obtained, regardless of dimensional tolerances. The division of the lamp cap provides the advantage that the cams can be engaged with the grooves without having to spring out further than they possibly do in their end position.

A contact may be formed on the base portion of the lamp cap, for example with solder, around a current supply conductor. In a favorable embodiment, however, the lamp base has an axially oriented cam at the base part on the partial surface, through which a current supply conductor emerges, that current supply conductor is bent back around that cam and grips a metal tube, for instance of brass or bronze, clamping around it. cam and that power supply conductor to form an electrical contact.

This contact has the advantage that no welding or soldering operation is required, and furthermore that cold flow of the contact during use of the lamp, which occurs with soldered contacts, is prevented. There may be protruding tongues on the metal tube, which protrude into the base part of the lamp base. As a result, the tube is extra secured j - ft ft rotation relative to the lamp base.

The axially oriented cam on the base portion of the lamp cap may be recessed into the surface of the base portion so that the metal tube protrudes just beyond that surface. When the tube is closed on one side to be bus-shaped, a flat transverse contact surface is formed. Alternatively, the metal tube may extend relatively far from the base portion to form a pin-shaped contact which may or may not be closed at its free end. The lamp cap may have two similar contacts on the base portion, such as two pin-shaped contacts, for example, with a fluorescent lamp, or two contact surfaces, for example, with an incandescent lamp with Swan-d lamp cap.

In another embodiment, a contact at the base portion is formed by a metal disc, which includes a perpendicularly bent tongue split to form a piercing contact. Piercing contacts are frequently used in the art to make an electrical connection with insulated or non-insulated conductors. With insulated conductors, which can also be used with the lamp according to the invention, the piercing cuts through the insulation.

In the base part of the lamp cap, a gutter-shaped recess can be provided, in which a current supply conductor is laid during the assembly of the lamp. The depression may be intersected by a cavity to receive the split tongue of the contact. A contact arranged centrally on the base portion can therefore already be sufficiently fixed. However, the contact can have a flanged edge, which can be inserted into recesses in the lamp cap for further fixation.

With an Edison lamp cap or a Swan-s lamp cap, in which cases with conventional metal lamp caps the mantle part of the lamp cap electrically contacts a lamp holder anywhere along its circumference near the base part, the lamp cap of the lamp according to the invention in a favorable embodiment, for example, formed as follows. A current supply conductor exits from the lamp cap near the periphery of the base portion and is bent back along the jacket portion of the lamp cap. An axially sectioned U-shaped metal ring abuts the base portion and grips the shell portion of the lamp cap and around the power supply conductor. In a variant of this, the mantle part of the lamp base has a circumferential groove and the Pay ring is additionally secured by bending it into that groove.

In another embodiment, a metal ring is in the form of a circular U-shaped trough. The lamp cap may have a circumferential groove at the periphery of the base portion, out of which a power supply conductor emerges, which is bent back along the mantle portion. The metal ring engages in the circumferential groove and around the jacket portion.

In a further embodiment, the lamp cap has a ring for making a second electrical contact with a lamp holder, which ring is provided with a split tongue which, as a piercing contact, connects the ring to a current supply conductor. The ring may have a second tongue, which, like the piercing contact, is received in a cavity in the lamp base and the ring additionally fixes. However, the ring may be recessed into recesses in the mantle portion of the lamp cap. The ring can be in the form of a U-shaped circumferential gutter, have a cross-section in the diameter, or have another shape, for instance be conical, with or without a cylindrical outer edge.

With an Edison lamp base, the mantle part of the lamp base has an external screw thread, with a Swan lamp base, the mantle part has radial projections to work together mechanically with a lamp holder.

An advantage of a plastic lamp cap is that it is prevented that the lamp cap is welded firmly to a lamp holder at the end of the life of a lamp. That phenomenon can occur with a light bulb. If the filament breaks, a discharge arc can form in the lamp envelope. Due to the high current of that arc, a fuse blows which may be included in a current supply conductor. In this case, a discharge arc can arise in the lamp cap, which jumps to the metal mantle of the lamp cap and welds this mantle to the lamp holder.

It is also possible that a discharge arc in one current supply conductor within the lamp cap jumps to the other. The divided lamp cap of the lamp according to the invention makes it possible for the current supply conductors to each have their own enclosed space through the lamp cap and thereby prevent flashover of a discharge arc.

In conventional Edison lamp bases, where the second contact is caused by a current supply conductor being led out at the open end of the lamp cap and attached to the lamp cap, the distance from that attachment to the lamp barrel is much shorter than from the base contact to the lamp vessel. A piece of the first-mentioned current supply conductor must therefore be cut off, in order to prevent the free end of that conductor, which may have mains voltage, from extending past and touching the lamp vessel.

In the lamp according to the invention with an Edison or a Swan-s lamp base, the distances from the contacts to the lamp vessel are already little different. In a favorable embodiment, the path for the current supply conductor to the contact on the mantle part of the lamp cap is so long that the distances from the contacts to the lamp vessel are almost the same distance. The relevant current supply conductor then need not be shortened.

It is advantageous if a part of the lamp cap in the base portion has a transversely directed groove on the partial surface and the other part of the lamp cap has a transversely directed cam on the partial surface, which co-acts with the groove and encloses a current supply conductor in that groove. The power supply conductor then exits from the lamp cap at a defined location, which facilitates mechanized attachment to a contact of the lamp cap. This ridge and groove also prevent the bent portion of the conductor from being caught between the two parts of the lamp cap and not making a good connection with the contact of the lamp cap.

Electric lamps can also emit light, though little, through the end portion of the lamp vessel. In some applications, for example in darkroom lamps, it may be a drawback if light emerges along the axial part of the lamp cap, which comes from the end portion of the lamp vessel. In a special embodiment, a part of the lamp cap has a rebate, at least on the open end part, in which the other part is included. The lamp base is therefore light-tight.

The electric lamp according to the invention can for instance be an incandescent lamp, for example a halogen incandescent lamp, a low-pressure or a high-pressure discharge lamp. Namely, the nature of the electrical element is of no significance to the essence of the invention. The electrical element can be arranged in an inner envelope in the lamp vessel.

From the open end portion of the lamp cap, a scale-shaped extension thereof can extend to the side of the lamp vessel, which is, for example, curved paraboloidally or elliptically. The inner surface thereof can be mirrored to form a lamp / reflector unit.

With a Swan lamp base it is favorable if the radial projections that have to cooperate with a lamp holder are formed by metal pins that are anchored in the lamp base. The protrusions can also consist of the ends of one continuous pin. It may be recommended that the pin (s) within the lamp cap is (are) completely encased in plastic to avoid contact with power supply conductors.

A wide variety of plastics can be used for application in the lamp cap taking into account the temperature the lamp cap obtains during operation of an electric lamp of a particular type. As examples, thermoplastic plastics such as polyetherimide, polyether sulfone, polyether ether ketone, for example with a basic structure as shown in Figure 16, are mentioned polybutylene terephthalate, polypropylene oxide, polyphenylene sulfide, polyamideimide, polyimide.

Embodiments of the electric lamp according to the invention are shown in the drawing. In it is

Figure 1 shows an electric lamp in side view,

Figure 2 shows the view of the parts of the lamp cap of Figure 1 according to II not yet assembled,

Figure 3 shows a section according to III-III in Figure 2,

Figure 4 shows a section according to IV-IV in Figure 3,

Figure 5 shows the partial plane view of the lamp cap of Figure 1 with contacts in section,

Figure 6 shows a side view, partly broken away, of another embodiment of an electric lamp.

Figure 7 shows a further embodiment of a lamp base, as shown in Figure 5.

Figure 8 shows the view of the parts of the lamp cap according to VIII in Figure 7 after they have been brought into opposition.

Figure 9 is an exploded view of a further embodiment of the lamp according to the invention.

Figure 10 is a section through the lamp vessel of Figure 9 according to X-X.

Figure 11 shows a view of contacts suitable for the lamp of Figure 9.

Figure 12 shows a section according to XII-XII in Figure 11.

Figure 13 is an interior view of the parts of another embodiment of a plastic lamp base, shown as in Figures 5 and 7.

Figure 14 cross sections along XIV in Figure 13 opposed.

Figure 15 shows the parts of the same lamp base according to XV in Figure 13, after being placed in opposition.

Figure 16 shows the basic structure of a plastic, a linear aromatic polymer, used in the lamp cap.

The electric lamp of Figure 1 has a translucent lamp vessel 1 with a shaft 2 and an end portion 3 on that shaft. The lamp vessel 1 is blown, consists of glass and is closed in a vacuum-tight manner. An electric element 4, an incandescent body, is arranged in the lamp vessel 1. A plastic lamp base 5, for example of polyethersulfone, has a shaft 6, carries electrical contacts 7, 8 and is fixed around the end portion 3 of the lamp vessel 1. The lamp base 5 has a jacket portion 9 with an open end portion 11 and a base portion 12 opposite the open end portion 11. The base portion 12 carries a contact 8. Current supply conductors 13, 14 run from the electrical element 4 to the contacts 7, 8 of the lamp cap 5.

The lamp cap 5 and the lamp vessel 1 have co-operating cams 20 and grooves 10 that limit relative rotation and translation of the lamp cap.

The lamp base 5 has an axial partial surface 15 and a first 16 and a second part 17 on the side of that partial surface 15, which parts 16, 17 are rigidly connected to each other. In the lamp cap shown, the means by which the parts 16, 17 are rigidly connected to each other are integral with those parts. ,

Figure 2 shows the first part, 16 and the second part 17 of the lamp cap 5 put into opposition for assembly. The first part 16 has projections 18, the second part 17 recesses 19 (Figure 4) as integral means for coupling the parts together.

Figure 3 shows projections 20 on the parts 16 and 17 of the lamp cap 5 which engage in the grooves 10 of the lamp vessel 1,

Figure 4 shows the recesses 19 into which the projections 18 protrude. The recesses 19 have a narrowing 21 through which the protrusions protrude. In order to be able to realize these constrictions 21, the recesses 19 extend to the outer surface of the lamp cap.

Figure 4 also shows that the projections 20 in the lamp cap 5 (Figure 3) and the grooves 10 in the end portion 3 of the lamp vessel 1 (Figure 1} are formed such that the open end portion 11 of the lamp cap 5 has a cross-section which has the shape of a flattened ellipse whose long axis 22 is transverse to the dividing surface 15. The end portion 3 of the lamp vessel 1 has a co-operating cross section with a complementary shape, thereby securing the lamp cap 5 and the lamp vessel 1 against relative rotation. both parts 16, 17 of the lamp cap 5 already individually severely limit the relative rotation possibility of the lamp vessel 1. As a result, the coupling between the parts 16, 17 of the lamp cap 5 is only very small in the longitudinal direction of the projections 18 when the lamp vessel 1 exerts a torsional force on the lamp cap 5.

Figure 5 shows that the current supply conductors 13, 14 are led out along the dividing surface 15 of the lamp cap 5. When the lamp vessel is placed in the first part 16 of the lamp cap 5, the current supply conductors 13, 14 are simply placed over the base part 12 of the lamp cap 5 to protrude from the lamp cap 5 after the second part 17 has been fitted. The thin wires forming the current supply conductors 13, 14 do not need to be threaded through narrow openings.

The lamp cap 5 has (Fig. 2, 3, 5) on the partial surface 15 on the base part 12 an axially oriented cam 23, through which a current supply conductor 14 protrudes from the lamp cap 5, which is bent back around the cam 23. A metal tube 8, shown in axial cross-section in Figure 5, grips clamping around said cam 23 and around said power supply conductor 14. In Figure 5 it can be seen that the cam 23 is sunk into the base portion 12 of the lamp cap 5. The tube 8 is closed on one side in the figure to form a transverse contact surface. Protruding tongues 24 exist on the tube 8, which engage the base portion 12 and lock the tube 8 against relative rotation. In addition, the tube 8 forms an additional coupling of the parts 16, 17 of the lamp cap 5 at the extreme end of the base part 12 where there is little space for protrusions 18 and recesses 19 (Figure 4), which form the parts 16, 17 of the lamp cap keep the lamp cap 5 with the lamp vessel 1 already coupled thereto.

The other current supply conductor 13 exits along the dividing surface 15 of the lamp cap 5 near the periphery of the base portion 12 and is bent back along the sheath portion 9.

An O-shaped metal ring 7 in axial section abuts the base portion 12 and grips the cylindrical portion 9 and around the current supply conductor 13. In Figure 5, the jacket portion 9 has a circumferential groove 25 in which the ring 7 is bent. The ring 7 forms the side contact of the Edison lamp base 5 shown. The ring 7 can make electrical contact with a lamp holder at any place on its circumference.

The attachment of the lamp cap 5 to the lamp vessel 1 and the attachment of the current supply conductors 13, 14 to the contacts 7, 8 of the lamp cap 5, as well as the attachment of those contacts to the lamp cap, are entirely realized in the shown lamp by assembly. Thereby no use has been made of thermal processes, such as sealants, gluing, soldering, welding, and auxiliary materials such as sealant or glue.

In the embodiment shown (Figures 2, 3, 5), the axially oriented cam 23 on the sub-surface 15 has a cooperating transversely directed cam 26 and groove 27 in the second 17 and first part 16 of the lamp cap 5, respectively, which cam 26 and groove 27 enclose the power supply conductor 14 and cause said conductor to exit the lamp cap 5 at a defined location.

The lamp cap 5 near the periphery of the base portion 12 has a transversely directed protrusion 28 on the subplane 15 and a transversely directed recess 29 in the subplane 15, respectively on the second 17 and the first part 16 of the lamp cap, which connects the current supply conductor 13 make a defined place emerge from the lamp cap (Figure 2, 3, 5). In addition, this projection 28 and this recess 29 ensure that the spreader guide 13 within the lap foot 5 travels a pad that has a transverse portion, thereby increasing the length of the pad within the lap foot 5. This ensures that the length of the path of the two straw supply conductors 13, 14 between the end portion 3 of the lapping vessel and the contacts 7, 8 (Figure 5) is essentially the same. When using equally long spreader guides 13, 14 of the correct length, guide 13 need not be shortened.

The electric lamp of Figure 6, in which like parts have the same reference numerals as in the previous Figures, has a lamp cap 55, from the open end portion 11 of which an inner concave and mirrored body 40 extends integrally with the lamp cap 55 along the lamp vessel 1 . The first part 66 of the lamp cap 55 has a gutter-shaped space 41 in which the spreader guide 13 is accommodated. Otherwise, the first part 66 is identical to the first part 16 in Figures 1-5. The second part 67 completely closes the space 41, has a concave and mirrored part 40 and is otherwise identical to the second part 17 in Figures 1-5. The space 41 forms a closed path for the current supply conductor 13. As a result, no discharge arc can arise in the cavity of the lamp cap 55 between the current supply conductors 13, 14.

An advantage of the lamp cap of the lamp according to the invention is that the end part of a lamp vessel may have one specific shape and size, irrespective of the type of lamp cap that the lamp vessel must be wearing, for example a B22 lamp cap or an E27 lamp cap. When using conventional lamp bases of those types, the lamp barrel at the end portion must be sized differently when a 22 mm diameter bayonet lamp cap is mounted than when using a 27 mm diameter Edison lamp cap. In the production of lamps using conventional lamp bases, this requires a switchover on the machines on which the lamp envelope is formed at its end section, even if the lamps are of the same power and fire voltage. Plastic B22 and E27 lamp bases can be internally sized and shaped to fit one lamp vessel.

For example, instead of a blown lamp vessel, a tubular lamp vessel with a pinched seal or a two-part lamp vessel made of pressed glass can be used in the lamp according to the invention.

In Figures 7 and 8, parts corresponding to parts of Figures 1-5 have a reference numeral 70 higher than in Figures 1-5. In these Figures, cams 90 cooperating with tangential grooves in the end portion of a lamp vessel are formed by the wall of the recesses 89, into which a projection 88 is to be received, and by the casing of the extension of those projections 88. Figure 8 shows the clearly see the internal round shape of the open end section 81. The protrusions 88, 88 'and the recesses 89, 89' cooperate to interconnect the parts 86, 87 of the lamp cap 75. By the ring 77, shown in axial section, those parts 86, 87 are held tightly together near the base portion 82. Contact 78 also contributes to this.

The protrusions 88 'have a smaller diameter than the protrusions 88, which provide a strong coupling to the open-end portion 81. The protrusions 88 'therefore have a less important function, partly because a lateral displacement of the two parts 86, 87 along the part surface 85 is also already prevented by a rebate 100 and an edge 91 cooperating therewith.

However, the first part 86 of the lamp cap 75 mainly has a rebate 100, into which an edge 91 of the second part 87 falls to make the lamp cap light-tight.

The lamp base has tapered projections 90 'in the open-end portion 81, in the Figure, prismatic ribs that compensate for dimensional differences with a lamp vessel. They can be deformed or partly broken away by that lamp vessel. The axially oriented cam 93 has a cooperating transversely oriented cam 96 and groove 97 on the sub-section 85, the cam 96 being closer to the open-end portion 81 than cam 26 in Figure 5. Further away from the open-end portion 81, the groove 97 two protrusions 97 '. During the mounting of the lamp cap 75 on a lamp vessel, a current supply conductor is slid radially between these projections 97 'and is held by these projections in the groove 97 until the second part 87 is arranged.

The base portion 82 of the lamp cap has a circumferential groove 99, into which a metal ring 77 in the form of a circumferential U-shaped trough can be received and from which a current supply conductor 83 emerges, with which the ring makes an electrical connection.

The groove may be provided with prismatic ribs corresponding to ribs 90 'in the open-end portion 81.

In Figure 9, parts corresponding to parts of Figures 1-5 have a reference numeral 100 higher than in those Figures.

In Figure 9, the end portion 103 of the translucent lamp vessel 101, which includes, for example, an electrode pair as an electrical element, has grooves 110, 110 '(see also Figure 10). The plastic lamp base 105 has a first 116 and a second part 117 to the side of the axial part face 115, each of which is provided with projections 120 to cooperate with the grooves 110, 110 '. The parts 116, 117 of the lamp cap 105 are rigidly joined together by snap connections 118, 119, at the open end portion 111. Protrusions 118 'and recesses 119' contribute to the connection. The lamp base 105 carries contacts 107 and 108.

In Figure 10, shapers S1, S2 are shown, each of which has formed a pair of grooves 110, 110 'in the end portion 103 of the lamp vessel 101 (Figure 9). Each groove pair 110, 110 'has a groove 110 which is the mirror image of the other groove 110'. Moreover, the groove pair 110, 110 'made by shaper is mirrored in the Figure with the opposite other groove pair made by the other shaper S2.

The grooves each have a boundary 110a, 110'a located in a substantially axial plane of the lamp vessel 101. The grooves provide good grip to the uniform cams.

In Figure 11, a metal strip 201 is shown which carries a contact 208 corresponding to the contact 108 of Figure 9, a contact 207 corresponding to contact 107, which contacts are suitable as contact on the base portion and the jacket portion of a lamp base, respectively. They can be easily detached from each other and from the strip 201.

The conical annular contact 207 (compare also Figure 12) has a split tongue 210 (compare also 107 in Figure 9) as a piercing contact. When the ring 207 is released from the strip 201, the tongue 210 is bent through 90 °. The ring 207 has a cylindrical edge 212 which can be inserted into recesses in a lamp cap for fixation. A connecting strip 211 may also remain on the ring 207 as a split tongue or not.

Alternatively, the strip 211 may be separated as a split or not tongue together with contact 208, or completely removed from contacts 207, 208.

In Figures 11 and 12, contact 208 has a split tongue 209 as a piercing contact, which is identical to tongue 210. Contact 208 has a cylindrical flanged edge 213 (Figure 12) that can be recessed into recesses in a plastic lamp base .

In Figures 13-15, parts corresponding to parts of Figures 1-5 have a reference numeral 140 higher than in JK.

those Figures 1-5.

The first 156 and the second part 157 of the E27 lamp cap 145 of Figure 13 have a snap connection 158, 159 (see also Figure 14) on the open end portion 151, which gives a very strong connection of those parts to each other. In conjunction with the cams 160, they also provide a tight connection to a lamp vessel 101 (Figures 9 and 10). The cams have a substantially axially plane surface 160a (Figure 14) on which a groove in a lamp vessel with its axial limitation exerts pressure under a torsional force. That pressure is tangentially directed and loads the snap connection 158-159 tangentially, i.e. in the direction in which that connection is very strong.

The cams 160 are present on an elastic arm 160b, which is created by enclosing the cams each with a U-shaped slit 160c in the lamp cap 145. Due to that elastic arm 160b, the cam 160 adapts to the depth of the grooves 110, 110 '. The two parts 156, 157 of the lamp cap 145 with the cams 160 travel in the opposite direction when shaping the lamp cap on the lamp vessel in the same way as the shapers S1 and S2 after making the grooves 110, 110 '. This shows that the elastic arms 160b are not deformed until the cams are fully engaged with the grooves. Thus, the deformation of those arms 160b in the final position is the greatest deformation the arms have ever had, so that there is no prior plastic deformation.

The elastic arms 160b provide a rattle-free coupling of the lamp cap 145 to the lamp vessel.

The protrusions 158 'and the recesses 159' provide an additional coupling of the parts 156, 157, partly or largely to prevent displacement of those parts along the axial part surface 155.

Part 157 (Figure 13) is provided with conically shaped, flat projections 170 (see also Figure 15), which, when mounting the lamp cap 145 on a lamp vessel, catch its current supply conductors 153, 154 and guide them to trough-shaped recesses 171, 172 in the base portion 152 of the lamp base. An axially displaced transverse partition 170 'in portion 156 (Figure 13) is axially offset from the protrusions 170 when the power supply conductors 153, 154 are laterally confined when portions 156 and 157 are brought together. This confinement takes place well before those parts have reached their end position (see Figure 15). In a variant of the embodiment shown, the baffle 170 'jumps so far (170 "in Figure 15) that it takes the current supply conductor 153 (Figure 13) along a distance d transverse to the axis 146 and extends its weighing in the lamp cap 145. In this way it can be prevented that the current supply conductor 153 (compare 113 in Figure 9) extends beyond the relevant contact (107, Figure 9) and is visible on the outside of the lamp cap with the fully assembled lamp. respective cavity 173, 174 for receiving a split tongue 210, 209 on a contact 207 and 208, respectively (see Figures 11, 12). The cavity 173 'can receive an optional second tongue 211 on contact 207. That tongue 211 can provide an additional secure the contact 207 against rotation.

In Figure 15, there are recesses 175 in the axial cam 163, into which the contact (108, Figure 11) can be inserted, and recesses 165, into which the contact (107, Figure 11) can be inserted for fixation.

Claims (33)

1. Electric lamp provided with a translucent lamp vessel (1) with an axis (2) and an end portion (3) on that axis, an electric element (4) in the lamp vessel, a plastic lamp base ('5) with an axis (6) ), which carries electrical contacts (7, 8) and is secured around that end portion (3) of the lamp vessel (1), the lamp cap having a sheath portion (9) with an open end portion (11) that said end portion (3) of the lamp vessel (I), and a base portion (12), opposite the open end portion (II), which base portion (12) carries at least one (8) of the contacts, current supply conductors (13, 14) leading from the electrical element (4) the contacts (7, 8) of the lamp cap (5) run, the lamp cap (5) and the lamp vessel (1) having co-acting cams (20) and grooves (10), which have relative rotation and translation of the lamp cap (5) limited, characterized in that the lamp base (5) has an axial partial surface (15) and a first (16) and a second part (17) on the side of said partial surface (15), which d elements (16, 17) are rigidly connected to each other. Electric lamp according to claim 1, characterized in that the parts (16, 17) of the lamp base (5) have integral means (18, 19) connecting the parts thereto. Electric lamp according to claim 2, characterized in that the parts of the lamp cap are connected to each other by projections (18) and recesses (19), wherein projections (18) of a part (16) are clamped in a respective recess (19) in the other part (17). Electric lamp according to claim 3, characterized in that recesses (19) have a narrowing (21) through which a projection (18) protrudes. Electric lamp according to claim 2, characterized in that the parts (156, 157) of the lamp cap (145) are connected to each other by a snap connection (158, 159). Electric lamp according to claim 5, characterized in that the snap connection (158, 159) occurs at the open end portion (151) of the lamp base (145). Electric lamp according to claim 1 or 2, characterized in that the current supply conductors (13, 14) are led out along the dividing surface (15) of the lamp cap (5). Electric drawer according to claim 1, 2 or 7, characterized in that the cooperating cams (20) and grooves (10) are formed such that the end portion (3) of the lamp vessel (1) and the open end portion (11) of the lamp cap (5) have cooperating cross-sections which have the shape of a flattened ellipse, the long axis (22) of which is transverse to the dividing surface (15) of the lamp cap (5). jc Electric lamp according to claim 8, characterized in that in the open end portion (81) of the lamp base (75) protruding protruding projections (90 ') occur. Electric lamp according to claim 1, 2, 5 or 7, characterized in that the lamp vessel (101) in the end portion (103) has a first pair of mirror-image grooves (110, 110 ') and a second opposite pair of grooves (110, 110). 110 ') with which cams (120, 160) interact in the open end portion (111, 151) of the lamp cap (105, 145). Electric lamp according to claim 10, characterized in that the grooves (110, 110 ') have a boundary (110a, 110'a) lying substantially in an axial plane (102a-d) of the lamp vessel (101) . Electric lamp according to claim 11, characterized in that the projections (120, 160) lie a surface (co-operating substantially with an axial plane (146a) of the lamp cap (145) with the grooves (110, 110 '). 160a). Electric lamp according to claim 10 or 12, characterized in that the cams (160) are each connected to the lamp cap (145) via an elastic arm (160b). Electric lamp according to claim 13, characterized in that the cams (160) are each surrounded by a U-shaped slit (160c) in the lamp cap (145). Electric lamp according to claim 7, characterized in that the lamp cap (5) on the part face (15) on the bottom part (12) has an axially oriented cam (23) through which a current supply conductor (14) exits, which is bent back around said cam (23), and which grips a metal tube (8) around said cam (23) and said current supply conductor (14). Electric lamp according to claim 15, characterized in that the metal tube (8) has tongues (24) which engage in the base part (12) of the lamp base (5). Electric lamp according to claim 15, characterized in that on the axially oriented cam (23) on the partial surface (15) there is a cooperating transversely directed cam (26) and groove (27) enclosing the current supply conductor (14). Electric lamp according to claim 7, characterized in that a current supply conductor (13) exits the lamp cap (5) near the periphery of the base portion (12) and is bent back along the * κ jacket portion (9) of the lamp cap and that an axial section U-shaped metal ring (7) abuts the base portion (12) and grips the jacket portion (9) and around the current supply conductor (13). Electric lamp according to claim 18, characterized in that the sheath portion (9) of the lamp base (5) has a circumferential groove (25) in which the ring (7) is bent. Electric lamp according to claim 7, characterized in that the path of the current supply conductors (13, 14) between the lamp vessel (1) and the contacts (7, 8) on the lamp cap (5) is essentially the same length. Electric lamp according to claim 20, characterized in that the lamp cap (5) near the periphery of the base portion (12) has a transverse projection (28) on the part face (15) and a recess (29) co-operating therewith. enclose the power supply conductor (13). Electric lamp according to claim 21, characterized in that one part (157) of the lamp cap (145) has flat projections (170) and the other part (156) has a co-acting partition (170 "), which has a current supply conductor ( 153) extend by a distance (d) transverse to the axis (146) of the lamp cap. Electric lamp according to claim 7, characterized in that a current supply conductor (83) exits from the lamp cap (75) near the periphery of the base portion (82) and is bent over to the mantle portion (79) of the lamp cap and in that a metal ring (77) in the form of a U-shaped trough in a circumferential groove (99) in the base portion (82) from which the current supply conductor (83) exits and protrudes around the jacket portion (79). The electric lamp according to claim 7, characterized in that the lamp cap (145) has a contact (208) on the base part with a split tongue (209) inserted in the lamp cap and which keeps a current supply conductor (154) clamped. Electric lamp according to claim 24, characterized in that the lamp base (145) has a cavity (174) in which the split tongue (209) is received. Electric lamp according to claim 25, characterized in that the lamp base (145) has a trough-shaped recess (172) in which a current supply conductor (154) extends, which recess is section A through the cavity (174) in which the split tongue is included. Electric lamp according to claim 24, characterized in that the lamp base (145) has recesses (175) in an axial cam (163) at its base portion (152), in which a contact (208) around said cam (163) grabs, is carved. Electric lamp according to claim 7, characterized in that the lamp cap has an annular contact (207) which grips around the sheath portion (149) and has a split tongue (210) which protrudes into the lamp cap (145) and clamped a power supply conductor (153). Electric lamp according to claim 28, characterized in that the contact (207) has a second tongue (211) and that the tongues (210, 211) protrude into a respective cavity (173, 173 ') in the lamp cap. An electric lamp according to claim 28, characterized in that the lamp cap (145) has recesses (165) in its sheath portion (149) into which the annular contact (207) is recessed. Electric lamp according to claim 7, characterized in that a current supply conductor (13) within the lamp cap (55) has a space (41) closed from the other current supply conductor (14). Electric lamp according to claim 1, 2 or 7, characterized in that one part (86) of the lamp base (75) has a rebate (100) and the other part (87) has an edge (91) which is in said rebate (100) is included to make the lamp cap (75) light-proof at least at the open end portion (81). Electric lamp according to claim 1, 2 or 7, characterized in that an internally concave, mirrored body (40) extends from the open end (11) of the lamp base (55) to the side of the lamp vessel (11), integrally with the lamp base (55).