NL8702968A - ELECTRIC BULB AND BLOWED BALLOON FOR IT. - Google Patents

Description

. * PHfi 12356 1 N.V. Philips "Incandescent light factories in Eindhoven.

Electric light bulb and blown balloon for it.

The invention relates to an electric light bulb comprising: - a vacuum-sealed, blown glass lamp vessel provided with. an axis of symmetry, 5. a largest diameter transverse to the axis of symmetry,. a neck-shaped first wall section behind the largest diameter, which wall section at its free end carries a lamp base which has electrical contacts,. an internal concave second wall section, 10. an internal concave third wall section,. opposite the lamp cap, in front of the largest diameter, an internally concave fourth wall section, - a helically wound filament arranged about the axis of symmetry, substantially in a plane transverse to that axis, - means for keeping the filament positioned, - current supply conductors of run the filament to contacts on the lamp base.

The invention also relates to a blown glass balloon suitable for use in the lamp.

Such a lamp is known from US 2 110 590.

In the known lamp, the second wall section, together with a reflector arranged within the neck-shaped wall section, forms a half ellipse in axial section. The third wall portion is a branch of a parabola which is revolved about an axis parallel to the parabola axis, with the parabola axis between the branch of the parabola and the axis of revolution.

The two wall sections are mirrored, their foci located on a circle coincide and the filament is arranged in the plane through those foci.

The known lamp solves the problem that parabolic reflectors in the focal plane are too narrow if one wants to place the filament in a deep reflector to get a good Γ7 0 v '. Rv PHN 12356 2 bundling of the generated light , while the transverse dimensions of the lamp do not want to be exceeded by a conventional size.

Because the branches of the parabola are moved apart in an axial section in the known lamp, the lamp vessel is wider in the focal plane. However, the filament in the focal plane is in a narrow portion of the lamp vessel, far from the largest diameter of the lamp vessel. A drawback of the known lamp is therefore that only incandescent bodies that absorb a relatively low power can be mounted in the lamp vessel, in order to prevent overheating of the lamp vessel.

Electric lamps in power value of between 15 and 100 W, e.g. 15, 25, 40, 60, 75 and 100 W, intended for mains operation, are made in a large number of types. Thereby, not only the finish, the coating or the machining, of the wall of the lamp vessel differs, but also its shape and the size and shape of the internal parts of the lamp, such as the means for keeping the filament positioned.

The electric light bulbs for mains operation, which are in the mentioned power range, include: - lamps, such as those according to the quoted ÜS 2 110 590, with a mirrored curved wall part, opposite which wall part is a window, which e.g. is satin-finished (slightly scattering), e.g. as a result of an etching operation, and / or is colored; - lamps with a substantially spherical lamp balloon, which is transparent or frosted, or which is coated with a white or colored light-scattering layer; - lamps with a curved conical wall part nearby, and a curved wall part 30 opposite the neck-shaped wall part, wherein the conical wall part is provided with a white or colored light-scattering layer and the curved wall part is slightly scattering and optionally colored. These lamps emit light on all sides, but provide along the axis, in directions away from the neck-shaped wall part, a higher luminous intensity than in other directions, - lamps with a spherical wall part opposite the neck-shaped wall part, which is mirrored or, for example, of a white, light-scattering PHN 12356 3 coating is provided.

The production of this large number of lamp types is very complicated due to the variety of lamp vessel types, which require their own supply and discharge mechanisms and their own means of transport on and between the production machines, and furthermore require their own packaging. Switching production machines from one lamp type to another is therefore a very time-consuming task. Another complication of their manufacture is that the various types of lamps require their own means of holding the filament in position.

The object of the invention is now to provide an electric incandescent lamp with a blown glass lamp vessel shaped in such a way that said lamp vessel may have received a coating or processing of choice to realize a lamp of a variety of different types.

The invention also aims to provide a blown glass lamp balloon suitable for use in such an electric light bulb.

This object has been achieved with an electric incandescent lamp of the type described in the opening paragraph according to the invention in that - the second wall section in axial section is curved substantially according to a circular arc and extends predominantly in transverse direction between the neck-shaped wall section and the largest diameter, the center of curvature being in front of the largest diameter, on the other side of the axis of symmetry, - the third wall section in axial section is curved substantially according to a circular arc and extends predominantly in axial direction before the largest diameter, the center of curvature lies behind the largest diameter and on the other side of the axis of symmetry, which wall part near the largest diameter gradually merges into the second wall part, the filament is arranged near the largest diameter.

Since the second wall section extends predominantly in the transverse direction in axial section, the lamp vessel widens rapidly near the neck-shaped wall section. This is in sharp contrast to the lamp of the quoted US 2 110 590. As a result, even if the lamp has a standardized axial size, the incandescent body can be positioned near the largest diameter of the lamp vessel and yet deep in the lamp vessel, which is relatively close to the SV Λ / W .... v ν ’

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PHN 12356 4 neck-shaped wall section, is arranged.

This has great advantages. With a largest diameter of approx. 60 mm, which is also common for commercial lamps of low power (e.g. 25 W), filaments of relatively high power (e.g. 75 or 100 W) can be accommodated because of their location near the largest diameter. Before the largest diameter, the lamp still has a considerable axial dimension, so that in mirrored embodiments, the filament is surrounded by mirrored wall sections over a large spatial angle.

The invention is described in detail with reference to the drawings, in which embodiments of the lamp according to the invention are shown.

In the drawings:, Fig. 1 shows a first embodiment of a lamp in side view with the lamp vessel in axial section,

Fig. 2-5 shows a mirrored blown glass balloon in axial section suitable for use in a second embodiment of a lamp.

Fig. 6 a variant of the balloon of FIG. 2-5 in 20 axial section.

Fig. 7 another embodiment of the lamp, partly in side view, partly in axial section.

In FIG. 1, the electric incandescent lamp has a vacuum-tight, blown glass lamp vessel 1 that has an axis of symmetry 2, a largest diameter 3 transverse to the axis of symmetry and a neck-shaped first wall portion 4 behind the largest diameter 3. The neck-shaped wall section 4 carries a lamp base 5 at its free end, which has electrical contacts 6, 7.

The lamp vessel 1 further has an inner concave second wall portion 8, 30 ', an inner concave third wall portion 9, 9' and opposite the lamp base 5, in front of the largest diameter 3, an inner concave fourth wall portion 10.

A helically wound filament 11 is arranged about the axis of symmetry 2, substantially in a plane transverse to that axis. The lamp has means 12 for keeping the filament 11 positioned and current supply conductors 13 running from the filament 11 to contacts 6, 7 on the lamp cap 5.

PHN 12356 5

The second wall section 8, 8 'is curved in axial section substantially according to an arc of a circle and extends predominantly in transverse direction between the neck-shaped wall section 4 and the largest diameter 3. {The figure shows that the dimensions of the lamp vessel 5 from the neck-shaped wall portion 4 and going to the largest diaieter 3 increase more in transverse direction than in axial direction). The center of curvature 14 of the wall portion 8 is in front of the largest diameter 3 on the other side of the axis of symmetry 2. The largely transverse direction in which the wall portion 8 extends implies that the center of curvature 14 is relatively far from the largest diameter 3 is removed.

The third wall portion 9, 9 'is curved in axial section substantially according to a circular arc and extends predominantly in axial direction before the largest diameter 3. (The dimensions of the lamp vessel 1 increase from axial diameter 3 more strongly in axial direction than they decrease in transverse direction). The wall portion 9 has a center of curvature 15 which lies behind the largest diameter 3 on the other side of the axis of symmetry 2. The wall portion 9, 9 'gradually merges into the second wall portion 8, 8' near the largest diameter 3.

The filament 11 is arranged near the largest diameter 3.

In a favorable embodiment, the fourth wall section is curved in an area at a distance from the axis of symmetry, in axial section, substantially according to a circular arc, the center of curvature being near the axis of symmetry and in front of the filament. This embodiment has the advantage that the lamp can be designed as a top mirror lamp. The lamp then has a mirror coating on the wall sections in front of the filament. Such a lamp 30 can otherwise have a e.g. have white, partly reflective, partly translucent cover.

In FIG. 1, that embodiment is shown. The fourth wall section 10 has an annular zone 16, 16 'spaced from the axis of symmetry 2, in which the wall section is curved in an axial section substantially along an arc of a circle. The center of curvature 17 of the zone 16 lies near the axis of symmetry 2 and in front of the filament 11. In the region 18 in the direct vicinity of the axis 2 it can be f, f ^ l * V ^ ..

PHN 12356 6 fourth wall section 10 have a larger radius of curvature, or are ogive. In FIG. 1 is a mirror coating with e.g. aluminum, silver, copper / aluminum, gold, indicated with 19. Fig. shows that the glow body 11 is located in all directions at a relatively great distance from the wall of the lamp vessel 1.

A lamp vessel 1 of the same shape as in Fig. 1 may be completely transparent or almost completely frosted. Otherwise, said lamp vessel may have a light-diffusing coating, optionally containing white or colored pigment. In a special embodiment, the lamp vessel 1 has a white light-scattering coating on the wall sections 4, 8, 8 'and 9, 9' while the wall section 10 is satinized or has a non-pigmented or little pigmented coating. In that case, the lamp radiates forward, in directions which make a relatively small angle with the shaft 2, more light than when the entire lamp vessel is provided with the same coating. Laterally, the lamp has a lower luminance.

In all these embodiments, the same set 12 can be used to keep the same filament 11 positioned.

It is of particular importance that, even when the lamp according to the invention is designed as a reflector lamp, the same means, the same set, can be used to keep the same filament positioned.

The invention also relates to a blown glass balloon suitable for use in the electric incandescent lamp according to the invention. An important property of the balloon is that it is mechanically strong. The balloon is therefore suitable for evacuation for the manufacture of vacuum lamps or for the production of specular coatings.

In Figs. 2-5, identical parts have the same reference numerals as in FIG. 1.

In these Figures the lamp vessel 21 is provided with a mirror coating 29 on its inner surface on the wall sections 8, 8 'and 9,9', as well as on a part of the wall section 4.

In FIG. 2, the beam path of light emitted by the filament at point 11 towards wall portion 9 'is reflected and reflected by this wall portion. The wall portion 9 'thus forms a screen which prevents light from exiting at great angles with the shaft 2. The wall portion 9 'reflects the striking PHN 12356 7 light backwards to the wall portion 8, which casts the light in forward directions through the wall portion 10, which functions as a light window. It is noteworthy that, although wall portion 9 'forms a shield for the said light rays, the wall portion 9 does not form or hardly hinder the emergence of the rays reflected by wall portion 8.

Fig. 3 shows that beams thrown on wall section 9 'by the filament in point 1' are also reflected towards wall section 8 and are subsequently ejected through this section 8, without wall section 9 intercepting rays to any significant degree.

From fig. 4 it appears that the rays cast by the filament in point 11 onto the wall portion 8 'are reflected and can pass through the light window 10 without or practically without hindrance from the wall portion 9'.

Likewise, FIG. 5 that beams which are cast by the glow body from 11 'onto wall section 8' are also thrown out by experiencing this wall section without, or practically without hindrance, from wall section 9 '.

In view of the symmetry of the balloon 21, with a lamp from this balloon the beam of light rays falling directly on wall section 8 or on wall section 9 is similar.

Thus, the mirrored wall portion 9, 9 'has a multiple function: a) it prevents large-angle light loss with the axis 2, b) it interacts with the main reflector formed by the wall portion 8, 8', and c) it at least hardly impedes any rays reflected by said wall portion.

The one shown in Figs. 2-5 shown beam parts are amplified by light emitting directly without reflection. The mirrored wall sections 8, 8 'and 9, 9' surround the filament 11, 11 'in a finished lamp over a space angle of approx. 2.5 × sr, so that a considerable part of the generated light is bundled, even without that a reflector body is arranged in the neck-shaped wall part 4.

The filament can be arranged in various shapes, e.g. approximately as an open circle or along three sides of an isosceles trapezoid.

In an embodiment of the lamp according to the invention, the second wall section has a zone near the neck-shaped wall. v ·; i 'PHN 12356 8 part relief. The wall section can be roughened, matted or satined in that zone. Ripple may otherwise be superimposed on the wall portion in axial section. Its amplitude may decrease with increasing distance from the neck-shaped wall portion.

Such a relief can homogenize the light intensity in the light beam of the lamp in reflector design. A ripple superimposed on the second wall portion is very attractive because it can be passed to the balloon when the balloon is blown.

In Fig. 6, the second wall portion 48, 48 'of the balloon 41 is embossed in a zone near the neck-shaped wall portion 4. A ripple 49 with an amplitude that decreases with increasing distance from the neck-shaped wall portion 4 is superimposed on that wall portion.

A lamp made from the balloon shown in Figs. 2-5, which had a largest diameter of 60 mm and which consumed a power of 40 W at 15,225 V, had a filament arranged along four sides of an equilateral pentagon. The lamp produced a beam with a heart value of 550 cd and a beam width of 2x 15 °. A commercial reflector lamp of the same power and a largest diameter of 63 mm produces a beam with a center value of 450 20 cd with the same beam width. Within the said angle, the luminous flux of the lamp according to the invention was further 35% greater than that of the commercial lamp.

GB 2 097 997 discloses an electric light bulb which also has mirrored, co-operating wall parts. A strongly widened mirrored wall part near the neck of the lamp vessel is a paraboloid. Opposite is a mirrored, atmospheric wall section. These two wall parts are connected by a substantially transversely extending, annular wall part.

The known lamp unites the functions normally carried out together by a head mirror lamp and an external paraboloidal reflector. The spherical reflector casts light on the paraboloidal reflector, which must cast the light outward.

The known lamp has a number of drawbacks. Although the filament is arranged on the largest diameter of the lamp vessel, it is also surrounded by the much closer spherical wall part. As a result, the lamp can only contain filaments of a relatively low power.

PHN 12356 9

The spherical wall part does shed light on the paraboloid, but it also shields a considerable part of the paraboloid, mirror-like wall part, precisely because the spherical wall part must be relatively bulky from a thermal point of view. Finally, the known lamp vessel is mechanically relatively weak due to its shape.

In a special embodiment of the electric incandescent lamp according to the invention, in which the second wall part and the third wall part are mirrored, an annular screen is arranged inside the lamp vessel and coaxially therewith, which part is surrounded by the third wall part and partly by the fourth wall part .

Such a screen does not or hardly hinder the movement of the light reflected by a mirrored wall part. On the other hand, it is counteracted that light emitted by the filament directly, without reflection on a mirrored wall part, leaves the lamp vessel at a relatively large angle with the axis. As a result, the screen gives the lamp a higher visual comfort, while the luminous flux in the beam of rays that form a slight angle to the axis is hardly, if at all, smaller.

The annular screen can for instance be cylindrical. Otherwise, the screen may narrow towards the fourth wall portion. The screen may e.g. be spherically curved with the center of curvature coinciding with the geometric center of the filament. Otherwise, the screen may be aspherically curved, e.g. ellipsoidal. If such a narrowing screen is reflective, incident light can be reflected to the second mirrored wall portion and added through that portion to the bundled light.

The screen can be carried by the means that keep the filament positioned. Another possibility is that the screen is supported by springs which rest against the wall of the lamp vessel. A favorable embodiment is that in which springs co-act with a constriction in the neck-shaped, first wall section at the location where this merges into the second, mirrored wall section. Such a constriction in itself already has the advantage that the surface of the second mirrored wall section is relatively large because that wall section extends relatively far to the axis, and that the neck-shaped wall section is nevertheless relatively wide near the lamp base. The lamp 5 / l - t 'f.

PHN 12356 10 therefore meets safety requirements, which require that the lamp cap cannot be touched with a standardized test finger after it has been placed in a lamp holder.

Fig. 7 shows such a lamp. Parts of the Figure corresponding to parts of Figure 1 have a reference number 60 higher.

The lamp vessel 61 has a constriction 80 where the first neck-shaped wall section 64 merges into the second wall section 68, 68 '.

The second wall portion 68, 68 'and the third wall portion 69, 69' have a mirror coating 79.

An annular screen 81 is arranged inside the lamp vessel 61 and coaxially thereto, which is partly surrounded by the third mirrored wall section 69, 69 'and partly by the fourth wall section 70. The screen 81 is supported by spring wires 82, 83 which cooperate with the constriction 80. An advantage of the attachment of the screen 81 to the lamp vessel 61 is that the mounting of the screen can be done prior to the actual manufacturing process of the lamp. The positioning of the screen 81 is simple and accurate. The construction is also resistant to shocks. A third spring 20, not visible in the figure, is contained in the complete lamp for spring 83. The screen 81 intercepts the light rays a and b and all rays passing between them, which would otherwise leave the lamp vessel, ray a and nearby rays under a relatively large angle with the axis 62. Due to its spherical shape, the screen casts striking rays back to the second wall portion 68, 68 ', 25 which it adds to the beam bundle.

The screen can consist of a variety of metals, e.g. aluminum, chrome-nickel steel, molybdenum, etc.

8 7 C> f '

Claims (10)

1. Electric light bulb comprising: - a vacuum-sealed, blown glass lamp vessel provided with. an axis of symmetry,. a largest diameter transverse to the axis of symmetry, 5. a neck-shaped first wall section behind the largest diameter, which section part at its free end carries a lamp base which has electrical contacts,. an internally concave second wall section,. an internal concave third wall section, 10. opposite the lamp cap, for the largest diameter an internal concave fourth wall section, - a helically wound filament arranged about the axis of symmetry, substantially in a plane transverse to that axis, - means positioned about the filament 15. power supply conductors running from the filament to contacts on the lamp cap, characterized in that, - the second wall section is curved in axial section substantially in an arc of a circle and extends predominantly in transverse direction between the neck-shaped wall section and the largest diameter, with the center of centering in front of the largest diameter, on the other side of the axis of symmetry, - the third wall section in axial section is substantially curved in an arc of a circle and extends predominantly in axial direction before the largest diameter, wherein the center of curvature behind the largest diameter and on the other The side of the axis of symmetry lies, which wall section near the largest diameter gradually merges into the second wall section, the filament is arranged near the largest diameter. Electric filament lamp according to claim 1, characterized in that the fourth wall section is curved in an axial section substantially in a circular arc in a zone remote from the axis of symmetry, the center of curvature near the axis of symmetry and in front of the filament lies. 3. Electric light bulb according to claim 1, characterized in that the neck-shaped wall section has a constriction at the location where that wall section merges into the second wall section. Γ ~ / '- PHN 12356 12 Electric light bulb according to claim 1 or 3, characterized in that the second wall section and the third wall section are mirrored. 5. Electric light bulb according to claim 1 or 4, characterized in that the second wall section has relief in a zone near the neck-shaped wall section. 6. Electric light bulb according to claim 4 or 5, characterized in that an annular screen is arranged inside the lamp vessel and coaxially therewith, which part is surrounded by the third wall part, partly by the fourth wall part. Electric light bulb according to claim 6, characterized in that the screen narrows towards the fourth wall section. 8. Electric light bulb according to claim 6 or 7, characterized in that the annular screen is supported by springs which rest against the wall of the lamp vessel. Electric light bulb according to claim 8, characterized in that the springs co-act with a constriction in the neck-shaped wall section. 10. Blown glass balloon suitable for use in the electric light bulb according to any preceding claim. f '7 A n O r (- ƒ sj': J ^: · Γ: