SK7992000A3 - Gas discharge lamp, especially low pressure gas discharge lamp - Google Patents

Abstract

The lamp has a transparent bulb (17) containing a transparent tube (10) defining a gas discharge path with electrodes (14,21) at the ends. The tube is closed at one end (13), open at the other (12). One electrode is mounted in the tube at the closed end and the other is mounted outside the tube. The open end of the tube is arranged so that the plasma of the gas discharge path runs along the internal surface of the lamp bulb.

Description

Gas discharge lamp, in particular a low pressure gas discharge lamp

Technical field

The invention relates to a gas discharge lamp, in particular a low-pressure gas discharge lamp with a light-transmitting lamp bank and a light-transmitting tube arranged in the lamp bank, for determining the discharge path at the ends of which an electrode is provided, the light-transmitting tube being closed at one end and the other and wherein one of the two electrodes is provided in the light-transmitting tube in the region of the closed end and the other in the lamp bulb outside the light-transmitting tube.

BACKGROUND OF THE INVENTION

Conventional gas discharge lamps have a glass light-permeable tube that is coated with a luminophore and at its ends electrodes are disposed, which airtightly pass through the closed ends of the tube and are supplied with electric current. According to the traditional design of gas discharge lamps, the glass tube is assembled from one or more U-shaped sections of the glass tube or spiral-bent sections to guide the discharge according to the desired light output through a glass tube determined by a path of greater or lesser length. necessary space and at the same time the characteristics of the emitted light that approaches the bulbs. Although gas-discharge lamps of this kind are excellent and economically superior to energy consumption, consumers use these gas-discharge gas-discharge lamps with reservations only, as they are not very satisfactory from an aesthetic point of view.

In order to meet the aesthetic needs of consumers who would like to use a gas discharge lamp as an energy-saving lighting fixture but not want to give up the traditional light bulb they are accustomed to, they have already developed gas discharge lamps with a glass tube that it serves as a sheath for determining the discharge path, simply arranged in a frosted glass or plastic flask, so that the finished luminaire gives the impression of a typical bulb from the outside. In these lamps, for example, traditional flasks in the shape of a candle or in the form of a candle are fitted via gas-discharge lamps formed in a corresponding compact spherical manner and are connected to one another.

However, this process has the disadvantage that the light output is lowered by about 20% due to the flask mounted over the gas discharge lamp. In addition, the operation of the gas discharge lamp is noticeably limited in that the heat transfer from the discharge housing to the environment is reduced by the external lamp bank so that the temperature stability of the plasma on the discharge path is impaired.

DE 30 19 605 A1 already discloses a low-pressure lamp with an outer bulb and an inner tube having one end open and the other closed. Two electrodes are located in the region of the closed end of the inner tube, one electrode being arranged inside and the other outside of the tube, so that a discharge path extending from the electrode arranged inside the tube and subsequently through the inner space of the outer bank outside the inner tube to the other electrode.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a further gas discharge lamp which provides stable light operation at a particularly good light output.

A gas-discharge lamp, in particular a low-pressure lamp, fulfills this task

SUMMARY OF THE INVENTION A gas discharge lamp having a light-transmitting bulb and a light-transmitting tube arranged in a discharge path for determining a discharge path at the ends of which an electrode is provided, the light-transmitting tube being closed at one end and open at the other end and one of the two electrodes in the light-transmitting tube in the region of the closed end and the other in the lamp bulb outside the light-transmitting tube, according to the invention, the principle being that the open end of the light-transmitting tube is arranged such that the discharge plasma extends along the inner surface of the lamp bulb.

According to a further embodiment of the invention, the light-transmitting tube for determining the path of the discharge is closed only at one end so that the other end thereof is open and that a gas discharge electrode is assigned to the other open end of the light-transmitting tube outside the tube, in the lamp bulb, the open end of the light-transmitting tube. is arranged such that the discharge path plasma extends along the inner surface of the flask. In this way, the discharge path that exists both inside and outside the tube in the lamp bank can be realized. In particular, this discharge path design has the advantage that the discharge path is in direct thermal contact with the lamp bulb, so that the bulb acts as a nickname for the gas discharge tube, so that it is maintained at a constant temperature after operation.

A further essential advantage of the gas discharge lamp according to the invention is that the light forms not only the part of the discharge path which lies inside the light transmitting tube, but also the discharge path running outside the tube in the lamp bank. Thus, a luminous flux generated outside the tube is added to the luminous flux generated in the light-transmitting tube, which at least compensates for the light losses caused by the lamp bank.

According to the invention, it is possible, on the one hand, to produce high-performance gas discharge lamps with an output of up to 80 W in a compact design having a light output or a light yield comparable to a 400 W lamp. On the other hand, the plasma flow in the lamp bulb ensures uniform light emission, which produces essentially the same light impression corresponding to the bulb.

In another preferred embodiment of the invention, the two electrodes are placed side by side inside or outside of the light-transmitting tube in the lamp bulb and that the open end of the light-transmitting tube is spaced apart from the electrode of the outside of the tube. This arrangement of the electrodes with respect to the light-permeable tube enables, for a simple and cost-effective assembly, in particular an expedient arrangement of the individual elements of the luminaire according to the invention.

It is particularly advantageous here that the closed end of the light transmitting tube is arranged in the end region of the lamp bulb having an electrical connection, while the open end of the light-transmitting tube lies in another end region of the lamp bulb. The interior of the bank can thus be optimally used to extend the discharge path. At the same time, production is simplified, since the individual electrodes can be inserted and sealed into the lamp bulb at their closing with their corresponding current passages.

The low-power gas discharge lamp according to the invention can be produced in a simple manner by arranging a light-transmitting tube in the flask, for example in the form of a candle, whose length substantially corresponds to the free length of the interior of the flask. A discharge path of approximately twice the length of the light-transmitting tube is allowed. However, for gas discharge lamps with a higher light output, it is advantageous if the tube is helically twisted or meander-shaped between its ends. In this case, it is particularly advantageous if the light-transmitting tube is one-piece.

However, according to another embodiment of the invention, the light-transmitting tube may be composed of at least two sections. In this case, it is possible to realize the tubular sections lying close together so that the internal space of the lamp bulb is optimally used.

It is particularly expedient if the light-transmitting tube and, where appropriate, the lamp bulb are glass. Depending on the wavelength of the light produced by the gas discharge, the use of quartz glass may be advantageous.

However, for conventional gas discharge lamps to be produced in mass production, the normal glass used in

light technology, UV-proof. In this if it is expedient, when as light permeable tube, so and bank lamps They are inside coated phosphors which changes emerging UV radiation on visible light and p his using can a flat set spectrally

the properties of the emitted light of the gas discharge lamp according to the invention, in a manner corresponding to the purpose of use of the luminaire.

When the gas discharge lamp according to the invention is filled with an inert gas such as argon or mercury such that UV mercury emissions are used to produce light, although the luminophore coating of the flask is reduced, the luminous flux produced in the light-permeable tube coated with luminophore. At the same time, however, UV light itself is also generated in the bulb, since part of the discharge path extends outside the light-permeable tube in the lamp bulb. This UV light generated in the lamp bulb changes into visible light by means of the lamp luminophore coating. The luminous flux generated in this way is added to the luminous flux emanating from the light-transmitting tube, the reduction in the visible luminous flux on the luminescent coating of the lamp bulb being at least compensated.

In order to be able to better adapt the spectral characteristics of the gas discharge lamp according to the invention to the requirements of the current application, it can be provided that different luminophores are used for the coating of the light-transmitting tube and the discharge tube.

In order to obtain a color rendering factor of 93 or more, it is provided according to the invention that a 3 to 5 band luminophore is used for the coating of the light-transmitting tube or lamp bulb.

One expedient embodiment of the invention is characterized in that the lamp bulb is closed by a closing element in which the electrodes are stored and on which a light-transmitting tube is mounted, wherein the electrodes and the light-transmitting tube can be positioned independently of each other and sealed into the closing element.

It is furthermore advantageous if the lead wires to the electrodes are designed as a connector so that the tube of the lamp tube and the electrodes can be placed in one socket at the same time and can be connected to the electronic upstream switch.

A particularly uniform plasma distribution is achieved when the open end of the light-transmitting tube is arranged in the axis of symmetry of the lamp bulb.

In this case, it is expedient if the open end of the light-transmitting tube lies at a distance which is less than half the diameter of the light-transmitting tube relative to the inner surface of the lamp bulb or lies in a plane including the axis of symmetry of the lamp. the diameter of the light-transmitting tube.

It is further preferred that the open end of the light-transmitting tube is easily conical widened.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is explained in more detail below with reference to the figures in FIG. 1 is a schematic representation of a gas discharge lamp according to the invention having the external shape of a traditional incandescent lamp; FIG. 2 shows a candle-shaped gas lamp according to the invention, FIG. 3 shows a further gas discharge tube according to the invention with a straight tube in a flask; FIG. 4 shows a gas discharge lamp corresponding to FIG. 3 with a spiral tube in a flask; and FIG. 5 is a front view of the spiral tube of FIG. 4 from above.

In the various figures of the drawing, corresponding structural elements are denoted by the same reference numerals.

DETAILED DESCRIPTION OF THE INVENTION

As shown in FIG. the light-permeable is screwed by the luminophor 11.] while the other, the closed end region

1, tube, coiled

In FIG. the bottom includes a gas discharge lamp according to a particularly glass tube and its inner surface is 1 is an open drawn end 13, 13 is in a glass tube of the invention

10, which coated end 12.

closed. A first electrode 14 arranged in the form of a spiral, for example, and its lead wires 15 pass hermetically through the closure of the glass tube 10, e.g.

The glass tube 10 is arranged in the lamp bulb 17, which is also coated with a luminophore 11 'on its inner surface. The flask 17 has a spherical or pear-like shape known from bulb manufacture and is closed by a sealed glass plate 18 in which a pumping tube 19 is inserted. The glass plate 18 is guided on one side by the lead wires 15 of the first electrode 14 and on the other by the lead wires 20 electrodes 21 and are hermetically sealed. The sealing of the lead wires 15, 20 of the electrodes 14, 21 and the pump tube 19 can be carried out simultaneously with the sealing of the glass plate 18 with the lamp bulb 17.

After venting and subsequently filling the lamp bulb 17 with an inert gas, for example argon, and after introducing mercury, the tapping tube 19 is hermetically sealed.

A lamp tube 17 with a glass tube 10 arranged therein is mounted on a cap 22 in which an electronic upstream switch 23 is located. The cap 22 further has a connecting element 24, which can be formed, for example, in a manner not shown in more detail than a screw thread. by means of which the gas lamp according to the invention can be screwed to a traditional incandescent lamp socket.

In the manufacture of the gas discharge lamp according to the invention, after the manufacture of the flask 17 and the light-transmitting tube of suitable glass, the inner surface of the glass tube 10 and the flask 17 is first coated with a luminophore H, 11 '. The same or different luminophores can be used to coat the glass tube 10 and the lamp bulb 17. The type of glass used for the glass tubes 10 and the flask 17 is chosen in the same way as the luminophores for coating depending on the desired spectral characteristic of the light emitted by the finished lamp. For the gas discharge lamp according to the invention for domestic use, the usual types of glass are used in the manufacture. Of course, it is also possible to use silicon glass for special lamps intended to emit, for example, UV light. In addition, it is also possible to make the glass tube 10 for determining the discharge path in the silicon glass lamp bulb 17 and to coat only the inner surface of the bulb 17 with a phosphor 1ó. In addition, it is also possible to form a bulb bank of silicon glass.

After the light-permeable glass tube 10 and the lamp bulb 17 have been prepared in a corresponding manner and, in the preferred embodiment described above, are coated with a phosphor 11, 11, an electrode 14 is inserted into one end 13 of the glass tube 10. forming a crimped spot 16 through which the lead wires 15 of the first electrode 14 pass through hermetically, will melt.

Subsequently, the glass tube 10 is arranged on the glass plate 18, wherein the lead wires 15 of the first electrode 14 can be formed such that the glass pipe 10 is held by the lead wires 15. Once the second electrode 21, the pump tube 19 and the lamp bulb 17 are arranged on the glass of the plate 18, sealing the glass plate 18 with the lamp bulb 17 and sealing the pump tube 19 and the lead wires 15, 20 of the electrodes 14, 21 at the same time.

In this case, it is also possible first to seal the lead wires 15, 20 of the electrodes 14, 21 and the pump tube 19 into a glass plate.

18, which serves as a connecting element so that in a second working step the glass plate 18 is sealed together with the lamp bulb. This makes it possible to use the melting technique for highly developed machine production in simple collet elements.

The prepared flask 17 may then be vented to be subsequently filled with an inert gas, for example argon, so that the pressure of the inert gas in the lamp flask 17 is about 3 hPa (3 mbar). In addition, 3 to 10 mg of mercury is filled through a pump tube 19, which is then hermetically sealed.

Subsequently, the unit prepared from the lamp bulb 17 and the glass tube 10 is fastened to the socket 22, connecting the lead wires 15, 20 of the electrodes 14, 21 correspondingly to the electronic upstream switch 22.

In operation of the finished luminaire, a discharge path is formed between the two electrodes 14, 21, the length of which is determined by the effective length of the glass tube 12 of the glass tube 10 from the arranged outside of the glass first electrode 14 in the flask and the spacing of the open end of the second electrode 21. in the neighborhood 17 lamps. The light generated by the plasma path of the discharge tube in the glass tube 10 is converted to visible light by the luminophore 11 on the inner surface of the glass tube 10, while the light generated by the plasma in the lamp bulb 17 outside the glass tube 10 is converted to visible light by the luminophore 11 '. banks 17.

The luminous flux generated by the luminophor 11 in the glass tube 10 and the luminophor 11 'in the lamp bank 17 are added so that the deterioration of the luminous flux from the glass tube 10 through the flask 17, respectively the luminophor coating 11' is compensated or even overcompensated.

The gas discharge lamp according to the invention has not only a high luminous flux yield but also a stable luminous output, since the plasma of the discharge path is in direct contact with the discharge tube 17, by which the heat generated in the plasma is dissipated into the environment. The lamp bulb 17 thus allows the plasma to be cooled through the discharge path and acts as a cold location to provide a stable plasma temperature.

Fig. ₂₄ illustrates another gas discharge lamp according to the invention having a candle-shaped bulb 17. A substantially straight glass tube 10 'is provided in the lamp bulb 17', the open end 12 of which is drawn up at the tip of the bulb 17 '. The lamp bulb 17 'is closed at the end facing away from the tip by a glass plate 18 in which the pump tube 19 and the lead wires 15, 20 of the first and second electrodes 14 are sealed respectively.

21. The first electrode 14 is disposed in the glass tube 10 'in the region of its closed end 13.

The lamp bulb 17 is mounted in a cap 22, in which a corresponding upstream switch 23 is located. In addition, a cap element 24 'is provided on the cap 22, which serves in particular as a screw thread for screwing a gas-shaped gas lamp according to the invention into a traditional incandescent lamp socket.

The electrodes 14, 21, between which plasma discharge paths are generated during operation of the luminaire, are arranged side by side inside or outside the glass tube 10 '. The glass tube 10 'is formed in such a way that its open end 12 is as far away as possible from the second electrode 21 lying outside the glass tube so that the longest possible discharge path in the flask 17' can be realized outside the glass tube 10 thereby ensuring a high light output.

The production and operation of the gas invention corresponds to that described in FIG. First

candle-shaped lamps according to the operation of the gas-discharge lamp

Fig. 3 shows a lamp bulb 17 in which a direct light-transmitting tube 10 is inserted. The inner surface of the lamp bulb 17 is coated with a luminophore 11 '. whereas the glass tube 10 is coated on its inner and outer surface with luminophor 11. In particular, three, four or five-band luminophores are used, i.e. luminophores, which transmit UV light generated by discharge to visible light in three, four or five spectral regions.

The lamp bulb 17 is at its end shown in FIG. 3 as a bottom, closed by a glass plate 18 which serves as a glass connecting element through which the natural wires 15, 20 of the electrodes 14, 21 and the pump tube 19 are drawn and sealed in this element. The glass tube 10 is also immediately sealed into the glass plate 18 and surrounds the first electrode 14.

The open end 12 of the glass tube 10 lies with respect to the inner surface of the lamp bulb 17 at a small distance d. The distance d is expediently less than half the diameter of the tube. In addition, the glass tube 10 has at its open end 12 a small conical extension 12.

By means of the arrangement provided according to the invention, with the indispensable widening of the open end 12 of the glass tube 10, it is achieved that the plasma formed in the discharge and hence the discharge path is substantially uniformly distributed over the entire inner surface of the bulb 17, thereby producing a uniformly illuminating lamp.

The glass tube 10 is arranged concentrically with the symmetry axis A of the lamp bulb 17.

In the manufacture of the lamp according to the invention, the electrodes 14, 21 with their lead wires 15, 20, the pump tube 19 and the glass tube 10 with the glass plate 18 are first sealed. In a second technological operation the assembly thus prepared can then be inserted into the lamp bulb 17 was then hermetically sealed by sealing the glass plate 18 with the flask 17 and aligning the electrodes 14, 21 and the glass tube 10 in the lamp flask 17.

Fig. 4 shows another lamp according to the invention which differs from that shown in FIG. 3, only the spiral-shaped glass tube 10. The spiral-shaped glass tube 10 is again arranged such that the spiral axis coincides with the axis of symmetry of the lamp bulb 17.

The open end of the spiral glass tube 10 is, as best seen in FIG. 5, bent so that the throat surface 12 of the open end 12 of the spiral glass tube 10 lies in one plane 6 that includes the axis of symmetry A of the lamp bulb 17. The center point of the neck surface 12 is expediently aligned with the axis A of symmetry.

Although in this arrangement the open end 12 with the opening 12 'does not lie immediately opposite the inner surface of the lamp bulb 17, the arrangement of the open end 12 at a small distance d to the bulb 17 achieves that plasma is also substantially evenly distributed over the entire inner surface of the bulb.

17th

In order to assemble the lamp housing according to the invention on the socket 22 as easily as possible, the supply wires 15 are provided.

of the electrodes 14, 21 formed as a connector, which may for example have a rectangular cross-section. The electrical connection of the electrodes 14, with the upstream switch 23, and the mechanical connection of the discharge housing to the socket can be easily and reliably accomplished in this way.

Claims (21)

PATENT CLAIMS 1. Gas discharge lamp, in particular a low pressure gas discharge lamp, so - a light-transmitting lamp bulb (17, 17 ') and so - a light-permeable tube (10, 10 ') arranged in the lamp bulb (17, 17'), to determine the discharge path at the ends of which the electrode (14, 21) is provided, - the light-transmitting tube (10, 10 ') being closed at one end (13) and open at the other end (12), and - wherein one of the two electrodes (14) is provided in the light-transmitting tube (10, 10 ') in the region of the closed end (13) and the other electrode (21) in the lamp bulb (17, 17') outside the light-transmitting tube (10, 10 ') ), characterized in that the open end (12) of the light-transmitting tube (10, 10 ') is arranged such that the plasma of the discharge path extends along the inner surface of the lamp bulb (17, 17'). The lamp according to claim 1, characterized in that the two electrodes (14, 21) are placed side by side inside or outside the light-transmitting tube (10, 10 ') in the lamp bulb (17, 17') and that the open end ( 12) the light-transmitting tube (10, 10 ') is arranged at a distance from the electrode (21) provided outside the light-transmitting tube (10, 10'). The lamp according to claim 1 or 2, characterized in that the closed end (13) of the light-transmitting tube (10, 10 ') is arranged in the end region of the lamp bulb (17, 17') having an electrical connection while the open end (12) of the light-transmitting tube (10, 10 ') lies in the second end region of the lamp bulb (17, 17'). The lamp according to claims 1 to 3, characterized in that the light-permeable tube (10) is helically wound between its ends. 5. The lamp according to claim 1, wherein the light-transmitting tube is meander-shaped between its ends. The lamp according to one of the preceding claims, characterized in that the light-transmitting tube (10, 10 ') is one-piece. The lamp according to one of claims 1 to 5, characterized in that the light-transmitting tube is composed of at least two sections. The lamp according to one of the preceding claims, characterized in that the light-transmitting tube (10, 10 ') consists of glass. The lamp according to claim 8, characterized in that the light-transmitting tube (10, 10 ') consists of quartz glass. The lamp according to one of the preceding claims, characterized in that the lamp bulb (17, 17 ') consists of glass, in particular a type of glass, such as a light-transmitting tube (10, 10'). The lamp according to one of the preceding claims, characterized in that the light-permeable lamp bulb (17, 17 ') is coated on the inner surface with a luminophor (11'). The lamp according to one of the preceding claims, characterized in that the light-permeable tube (10, 10 ') is coated on the inner surface or on the outer surface with a luminophore (11). The lamp according to claim 11 and 12, characterized in that different luminophores (11, 11 ') are used for the coating of the light-transmitting tube (10, 10') and the lamp bulb (17, 17 '). The lamp according to one of claims 11, 12 or 13, characterized in that a 3 to 5 band luminophore is used for the coating of the light-transmitting tube (10, 10 ') or the flask (17, 17'). The lamp according to one of the preceding claims, characterized in that the lamp bulb (17, 17 ') is closed by a connecting element 18, in which the electrodes (21, 14) are received, in which the light-transmitting tube (10, 10) is mounted. '). The lamp according to claim 15, characterized in that the electrodes (21, 14) and the tube (10, 10 ') can have a position independent of each other and can be sealed into the connecting element (18). The lamp according to one of the preceding claims, characterized in that the lead wires (15, 20) to the electrodes (21, 14) are designed as connectors to provide the lamp bulb (17, 17 ') with the tube (10, 10'). and the electrodes (21, 14) are connected to an electronic upstream switch (23). The lamp according to one of the preceding claims, characterized in that the open end (12) of the light-permeable tube (10, 10 ') is arranged in the axis of symmetry (A) of the lamp bulb (17, 17'). The lamp according to one of the preceding claims, characterized in that the open end (12) of the light-transmitting tube (10, 10 ') lies opposite the inner surface of the lamp bulb (17, 17') with a distance (d) of less than half the diameter of the light-transmitting tube (10, 10 '). The lamp according to one of claims 1 to 18, characterized in that the open end (12) of the light-transmitting tube (10, 10 ') lies in a plane (E) containing the symmetry axis (A) of the lamp bulb (17, 17'). its inner surface has a distance (d) which is less than half the diameter of the light-transmitting tube (10, 10 '). The lamp according to one of the preceding claims, characterized in that the open end (12) of the light-permeable tube (10, 10 ') has a slightly conical shape.