JP2000509889A - Lighting units, low-pressure mercury discharge lamps, power supply units, and federated packaging - Google Patents

Abstract

(57) [Summary] A lighting unit according to the present invention includes a power supply unit (1) and a low-pressure mercury discharge lamp (2). The low-pressure mercury discharge lamp has a light-transmissive discharge vessel (3), on the inner surface of which a light-emitting layer (3) is provided, which contains mercury and one or more rare gases. The discharge space (4) containing the filler is hermetically sealed and surrounded. A first electrode (5a) and a second electrode (5b) are arranged in the discharge space, each of which comprises coiling of a metal wire coated with one or more metal oxides emitting electrons. Each electrode is electrically connected to each current supply conductor (6a, 6b) extending to the outside of the discharge vessel (3). This current supply conductor is electrically connected to a power supply unit outside the discharge vessel, said unit igniting a low-pressure mercury discharge lamp when switched on. During normal operation, at least a portion (5 ^* ) of the electrodes (5a, 5b) has an effective value at least 1.8 times the minimum electrode current Ip4 requiring thermoelectrons. Of the electrode current Iel. The lighting unit according to the invention has a long switching life.

Description

The present invention relates to a lighting unit comprising a power supply unit and a low-pressure mercury discharge lamp, wherein the low-pressure mercury discharge lamp comprises a light source. The container has a transparent discharge vessel, and a light emitting layer is provided on the inner surface of the vessel. The discharge space is hermetically sealed by the vessel. The discharge space contains one or more rare gases in addition to mercury. And a first and second electrode disposed in the discharge space, each of the electrodes including coiling of a metal wire coated with one or more metal oxides that emit electrons, and It is electrically connected to each of the outwardly extending current supply conductors, where it is electrically connected to a power supply unit, which is switched on and has a low temperature Igniting a low-pressure mercury discharge lamp condition relates the lighting unit. Illumination units having a low-pressure mercury discharge lamp, hereinafter referred to as "lamp", are widely used for normal illumination purposes. Since these lighting units have a higher luminous efficiency than the luminous efficiency of the incandescent lamp, considerable energy saving is possible. During normal operation of the lighting unit, discharge is maintained by the discharge current between the electrodes. The manner in which the lamp is lit depends on the type of lighting unit. In the case of a "hot start" type lighting unit, each of these electrodes has another current supply conductor. Before the ignition voltage is applied between the electrodes, the other electrodes reach the temperature required for normal operation by the auxiliary current flowing from the current supply conductor to the other current supply conductor. However, with this ignition method, a relatively long delay occurs between the operation of switching on the lighting unit and the actual lamp ignition, hereafter an ignition delay. This is a disadvantage. In addition, the necessary preparation for this makes such lighting units relatively expensive. In the case of a lighting unit of the "rapid start" type, these electrodes each have another current supply conductor, these electrodes being provided with an increased temperature by an auxiliary current. In this type of lighting unit, the ignition voltage is applied immediately after the switch is turned on. Here, a firing delay occurs, but the firing voltage is not high enough to fire the lamp and the electrodes are still cold. The lamp is not ignited until the electrodes are at a sufficiently high temperature. A lighting unit of the kind described in the preamble of the description, in which the lamp ignites in cold conditions, is described in U.S. Pat. No. 5,314,067. Also known as "cold start" or "instant start", in the case of such a lighting unit, the ignition voltage is shortly after switching on, ie less than 100 ms. With a delay, a voltage is applied between these electrodes at a level sufficient to actually ignite the lamp. These electrodes are at normal operating temperature only after ignition. No further current supply conductors for these electrodes are required for this type of lighting unit. These electrodes are heated exclusively by the discharge arc applied thereto, and in this case by the discharge current during normal operation. If the electrodes have a type and a current supply conductor, an auxiliary current can contribute to maintaining the normal operating temperature of the electrodes. Usually, the continuous operation life of the lamp of the above-mentioned lighting unit is long. The life of a lighting unit in which the lamp is ignited in cold conditions is actually limited by the switching life of the lamp, i.e. the number of times the lamp can be switched on. In practice, igniting the lamp with the electrodes still cold can result in relatively severe damage to these electrodes, which may cause them to deform after a relatively small number of switching operations. found. In order to suppress the frequency of switching, sometimes the lamp is continuously lit even when illumination is required only for a short period. This impairs the energy savings obtained compared to incandescent lamps. It is an object of the present invention to provide a lighting unit of the kind mentioned in the preamble of the description, which has a long switching life, despite the fact that the lamp is almost ignited immediately after switching on. According to the invention, a lighting unit of the kind described in the preamble of the description requires that, during normal operation, at least a part of each electrode requires thermionic electrons in order to achieve this purpose. Here, T is a period of one cycle of the current I. The temperature of the electrode is strictly high enough to cause a heat release if the electrode current has an effective value equal to Ip4. This temperature is approximately 950K. Tungsten electrodes have a resistance of four times the resistance at room temperature. In this case, it is assumed that the positions to which the arcs of these electrodes are applied have relatively high hot spot temperatures. Surprisingly, the lamps of the lighting unit according to the invention have a considerably longer switching life, despite a higher thermal load on the electrodes. What can be explained, on the other hand, is that the metal of the metal oxide used for electron emission plays an important role during the ignition of the lamp. This higher hot spot temperature is expected to reduce the emissive metal oxide, such as barium oxide, at a higher rate to the respective metal, such as barium, so that the metal can While the number of operations is small, It is. By increasing the effective value in this way, the life of the lamp is extremely shortened when the electrode is continuously lit by the action on the metal wire. In the embodiment of the lighting unit according to the invention, the electrode current Iel is the discharge current Id. In a preferred embodiment, each of these electrodes has another current supply conductor, during normal lighting the discharge current Id or from the # 1 electrode to the second electrode and the auxiliary current Ih It flows from the supply conductor to another current supply conductor. In this case, the electrode current Iel is the sum of the discharge current Id and the auxiliary current Ih. At the electrodes, relatively large losses are obtained in the emitter material. In a preferred embodiment of the lighting unit according to the invention, the supply unit is provided with a high-frequency circuit arrangement having first and second output terminals, provided with dielectric means and capacitance means, wherein the first output terminal is provided with dielectric means. And the second output terminal is connected to the current supply conductor of the second electrode, and the tungsten current supply conductors of these electrodes are connected together via the capacitance means. This is one of the embodiments characterized by connection. The dielectric means and the capacitance means together form a resonance circuit, by means of which the ignition voltage increases after the lighting unit is switched on. If a defect occurs in one of these electrodes, the circuit with the capacitive means is broken, so that no further ignition voltage can occur. Thus, when the lamp reaches its end of life, a dangerous state can be avoided. The value of the auxiliary current and the value of the discharge current can be easily adjusted by selecting the capacitance means and the dielectric means. In a preferred embodiment, the electron-emitting metal oxides comprising these electrodes include barium oxide, calcium oxide, and strontium oxide. The lamp and the power supply unit can be integrated into a single unit. Alternatively, the lamp can be detachably coupled to the power supply unit. Therefore, the present invention provides a power supply unit for electrically and mechanically coupling a low-pressure mercury discharge lamp to a supply unit, such that the low-pressure mercury discharge lamp and the power supply unit constitute a lighting unit according to the present invention. A low-pressure mercury discharge lamp comprising a first coupling member specially adapted to cooperate with a second coupling material. The present invention also provides a low-pressure mercury discharge lamp for electrically and mechanically coupling a low-pressure mercury discharge lamp to a supply unit such that the low-pressure mercury discharge lamp and the power supply unit are combined to form a lighting unit according to the present invention. It also relates to a supply unit comprising a second joint material specially adapted to cooperate with the first joint member of the lamp. The combination of the power supply unit and the low-pressure mercury discharge lamp should be selected so as to achieve the object of the present invention, since the first and second coupling members are particularly adapted to cooperate with each other. Is evident. Alternatively, the power supply unit and the low pressure mercury discharge lamp, which together form a suitable combination to achieve the objects of the present invention, can be packed together. Accordingly, the present invention is a combined packaging comprising a low-pressure mercury discharge lamp comprising a first coupling member and a power supply unit comprising a second coupling member, wherein the first and second coupling members are provided. Are cooperating with each other, in which the components electrically and mechanically couple the low-pressure mercury discharge lamp to the power supply unit, the low-pressure mercury discharge lamp and the power supply unit constituting a lighting unit according to the invention. Also, it is related to the packaging. This very fact that the low-pressure mercury discharge lamp and the power supply unit are packed together indicates that the lamp and the power supply unit form a lighting unit according to the invention. In this case, it is not necessary that the coupling members can exclusively cooperate with each other. The first and second coupling members may have respective means for electrically and mechanically coupling the low-pressure mercury discharge lamp to the power supply unit, for example. This mechanical connection can be, for example, a snap connection, a clamp connection or a screw connection. In an embodiment, the electrical coupling means comprises first and second coupling members each comprising a coil, which forms a transformer with the power supply unit in the coupled state of the low-pressure mercury discharge lamp. In another embodiment, the electrical coupling means is realized, for example in the form of contact pins that can be maintained by a clamping fit in the contact socket of the power supply unit. These means can at the same time be mechanical coupling means. These and other aspects of the lighting unit according to the invention will be described in more detail with reference to the drawings. 1 shows a first embodiment of a lighting unit according to the invention, FIG. 2 shows a detail II of FIG. 1, and FIG. 3 shows a lighting unit according to the invention. This shows a second embodiment. The lighting unit according to the present invention shown in FIG. 1 includes a power supply unit 1 and a low-pressure mercury discharge lamp 2. This lighting unit can serve as an alternative to an incandescent lamp. The low-pressure mercury discharge lamp 2 has a light-transmissive discharge vessel 3, which has a fluorescent layer 3 'on its inner surface. The discharge vessel 3 surrounds the discharge space 4 and is filled with mercury and argon and hermetically sealed. First and second electrodes 5 a and 5 b are arranged in discharge space 4. FIG. 2 shows the electrode 5a in more detail. The electrode 5b has the same structure as the electrode 5a. These electrodes 5a and 5b comprise a metal coil coated with one or several electron-emitting metal oxides. The electrodes are formed from triple coils of tungsten wire, in this case having a diameter del of 24 μm and coated with barium oxide, calcium oxide and strontium oxide. The minimum value of the electrode temperature required for heat release is 950K. When these electrodes are used, the current Ip4 required to obtain this temperature is 60 mA. These electrodes 5a and 5b are electrically connected to the respective current supply conductors 6a and 6b extending outside the discharge tube 3, where they are connected to the power supply unit 1. The electrodes 5a and 5b are also connected to other current supply conductors 6a 'and 6b' extending outside the discharge tube 3, respectively. The power supply unit 1 is housed in a housing 7 that supports the lamp 2 and the lamp cap 8. This power supply unit 1 is provided with first and second output terminals K1 and K2, and is provided with a high-frequency circuit array S having dielectric means L and capacitance means C. With this high frequency circuit arrangement S, an AC voltage is applied at 50 kHz. The first output terminal K1 of this circuit arrangement S 1 is connected to the current supply conductor of the first electrode 5a via dielectric means. The second output terminal K2 is connected to the current supply conductor 6b of the second electrode 5b. The other current supply conductors 6a 'and 6b' of these electrodes are connected together via a capacitance means C. The dielectric means L is formed by a coil having a self-inductance of 3.1 mH. The capacitance means C is formed by a capacitor having a capacitance of 4.7 nF. The power supply unit 1 is connected to the contacts 8a and 8b of the lamp cap 8. The combination of the electrode current Iel has an effective value of 135 mA and maintains the discharge. An effective value 1 that flows through the current supply conductors 6a ′ and 6b ′ and supplies more heat to the electrodes It flows through the ends 5a ^* of the electrodes 5a, 5b which extend between 6b and the position where the discharge arc is applied to the electrodes. In this embodiment, the currents Id and Ih are approximately 90 ° It is. It flows through the end 5a ^* of 5a, 5b. This value is greater than 1.8 times the minimum current Ip4 required for heat release. The value of Iel is 2.8 times Ip4 in this case. The power consumption of the lamp in this lighting unit is 10 W. The above-described lighting unit according to the present invention is described below as “Invention 1”. The present invention It differs from the lighting unit according to the invention in that it is less than 5 times. The power consumption of this lamp is 7W. In the case of another lighting unit according to the invention (Invention 2), the electrodes are triple wound tungsten wires with a diameter _del of 38 [mu] m further coated with a mixture of barium oxide, calcium oxide and strontium oxide. The discharge vessel contains a filler, mercury, and a mixture of neon and argon. Effective electrode current In other words, it is 0.74 in this case. Other lighting units not according to the invention (see (Invention 2). The lamp of the lighting unit according to Invention 2 and Reference 2 consumes approximately 16 W of power during normal operation. Six lighting units according to the first embodiment of the present invention according to the present invention and six lighting units according to the second embodiment of the present invention according to the present invention, and five lighting units according to the first embodiment not according to the present invention and not according to the present invention. The switches of the five lighting units of the embodiment of Reference 2 are periodically switched at 1 minute and 3 minutes, respectively, to determine the switching life. If these lamps are ignited in a cold state with a firing voltage of 750 Vrms, they will be ignited within 100 ms after switching on the lighting unit. This results in the following table: Ths shown here is the temperature of the hot region of the electrode, and Ns is the switching life. It is clear that the lighting units of the inventions 1 and 2 according to the invention have a much longer switching life than the lighting units of the references 1 and 2 not according to the invention. A second embodiment of the lighting unit according to the invention is shown in FIG. Here, constituent members corresponding to the constituent members in FIG. 1 are denoted by reference numerals that are larger by 10. In the embodiment shown, the low-pressure mercury discharge lamp 12 is provided with a first coupling member 19. The power supply unit was provided with a second coupling member 20. The power supply unit is housed in a housing 17 that supports the lamp cap 18 by contacts 18a and 18b. The first coupling member 19 and the second coupling member 20 are particularly adapted to each other and cooperate to achieve an electrical and mechanical coupling of the low-pressure mercury discharge lamp 12 to the power supply unit 11. The low-pressure mercury discharge lamp 12 and the power supply unit 11 are housed in a packaging 21. In the combined state, the low-pressure mercury discharge lamp 12 and the power supply unit together form an illumination unit according to the invention. In FIG. 3, the contact pins 19a and 19b, which can be held by a clamping fit in the contact sockets 20a, 20b of the power supply unit 11, are mechanically and electrically connected between the low-pressure mercury discharge lamp 12 and the power supply unit 11. Form means for joining. The other current supply electrodes of these electrodes are not connected in FIG. In improving this embodiment, another current supply conductor is connected together inside the first coupling member via an impedance such as, for example, a capacitance impedance. Instead, an auxiliary current also flows between the electrodes. In another embodiment, other current supply conductors are connected to contact pins that cooperate with contact bushes.

────────────────────────────────────────────────── ─── [Continuation of summary] Long switching life.

Claims (1)

[Claims] 1. It comprises a power supply unit (1; 11) and a low-pressure mercury discharge lamp (2; 12), wherein the low-pressure mercury discharge lamp (2; 12) has a light-transmitting discharge vessel (3; 13). A fluorescent layer (3 ′; 13 ′) is formed on the surface, the discharge space (4, 14) is hermetically sealed by this container, and one or more rare gases are added to the discharge space in addition to mercury. In addition, a first electrode (5a; 15a) and a second (5b; 15b) electrode are arranged in the discharge space, and each of these electrodes (5a, 5b; 15a, 15b) It includes a coil of metal wire coated with one or more metal oxides emitting electrons, and these electrodes are connected to respective current supply conductors (6a, 6b; 16a, 16a, 16b) and the power supply unit The lighting unit, which is electrically connected and ignites a low-pressure mercury discharge lamp in a low temperature state when the switch is turned on, has a configuration in which each of the electrodes (5a, 5b) is used during normal lighting. At least one end (5a ^* ) of at least one of the minimum electrode currents Ip4 requiring thermionic electrons. 2. The electrodes (5a, 5b) are electrically connected to other current supply conductors (6a, 6b) extending to the discharge vessel (3), respectively, and the discharge current Id is supplied to the first electrode during normal lighting. And an auxiliary current Ih flows from the current supply conductors (6a, 6b) of each electrode to the other current supply conductors (6a ', 6b'). The lighting unit as described. The lighting unit according to claim 2, wherein the lighting unit is an effective value. 4. The power supply unit (1) is provided with a high-frequency circuit arrangement (S) having a first output terminal (K1) and a second output terminal (K2), and a dielectric means (L) and a capacitance means (C). And the first output terminal (K1) is connected to the current supply conductor (6a) of the first electrode (5a) via the dielectric means (L), and the second output terminal (K2) is connected to the first output terminal (K2). It is connected to the current supply conductor (6b) of the second electrode (5b), and the other current supply conductors (6a ', 6b') of these electrodes are connected together via the capacitance means (C). The lighting unit according to claim 2 or 3, wherein 5. The lighting unit according to any one of claims 1 to 4, wherein one or more electron-emitting metal oxides of the electrode are barium oxide, calcium oxide, and strontium oxide. 6. The low-pressure mercury discharge lamp is connected to the power supply unit (11) so that the low-pressure mercury discharge lamp and the power supply unit (11) constitute a lighting unit according to any one of claims 1 to 5 in a combined state. Low pressure mercury having a first coupling member (19, 19a, 19b) specially adapted to cooperate with a second coupling member (20, 20a, 20b) of a power supply unit for electrical and mechanical coupling. Discharge lamp. 7. A system for electrically and mechanically coupling a low-pressure mercury discharge lamp to a power supply such that the low-pressure mercury discharge lamp and a power supply unit constitute a lighting unit according to any one of claims 1 to 5 in a coupled state. A power supply unit (11) having a second coupling member (20, 20a, 20b) specially adapted to cooperate with the first coupling member (19, 19a, 19b) of the low-pressure mercury discharge lamp (12). 8. A packaging (21) comprising a low-pressure mercury discharge lamp (12) comprising a first coupling member (19, 19a, 19b) and a second coupling member (20, 20a, 20b) is accommodated, the first and second coupling members cooperating with each other, in which the members connect the low-pressure mercury discharge lamp to the power supply unit electrically and mechanically. A combined packaging, wherein the low-pressure mercury discharge lamp and the power supply unit form a lighting unit according to any of the preceding claims.