EP2893551A1 - Lampe à décharge à empêchement diélectrique - Google Patents

Lampe à décharge à empêchement diélectrique

Info

Publication number
EP2893551A1
EP2893551A1 EP13776714.1A EP13776714A EP2893551A1 EP 2893551 A1 EP2893551 A1 EP 2893551A1 EP 13776714 A EP13776714 A EP 13776714A EP 2893551 A1 EP2893551 A1 EP 2893551A1
Authority
EP
European Patent Office
Prior art keywords
lamp
dbe
electrodes
discharge
electrode
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP13776714.1A
Other languages
German (de)
English (en)
Inventor
Michael Meisser
Rainer Kling
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Karlsruher Institut fuer Technologie KIT
Original Assignee
Karlsruher Institut fuer Technologie KIT
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Karlsruher Institut fuer Technologie KIT filed Critical Karlsruher Institut fuer Technologie KIT
Publication of EP2893551A1 publication Critical patent/EP2893551A1/fr
Withdrawn legal-status Critical Current

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Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J65/00Lamps without any electrode inside the vessel; Lamps with at least one main electrode outside the vessel
    • H01J65/04Lamps in which a gas filling is excited to luminesce by an external electromagnetic field or by external corpuscular radiation, e.g. for indicating plasma display panels
    • H01J65/042Lamps in which a gas filling is excited to luminesce by an external electromagnetic field or by external corpuscular radiation, e.g. for indicating plasma display panels by an external electromagnetic field
    • H01J65/046Lamps in which a gas filling is excited to luminesce by an external electromagnetic field or by external corpuscular radiation, e.g. for indicating plasma display panels by an external electromagnetic field the field being produced by using capacitive means around the vessel

Definitions

  • the invention relates to a lamp based on the principle of Dielectric Disabled Discharge (DBE), a so-called DBE lamp.
  • DBE lamp is used as a synonym or abbreviation for a lamp based on the principle of dielectrically impeded discharge.
  • DBE lamps are used as optical radiation sources in industry and technology, especially in the UV and VUV range. Such lamps may e.g. be used for water disinfection, the surface treatment in the semiconductor industry, and using phosphors as a long-lasting, homogeneous and "instant-on" light source in copy machines and for ambient lighting. Furthermore, DBE lamps can be used for exhaust gas purification in industrial and gastronomical plants.
  • mercury low-pressure lamps or high-pressure lamps have frequently been used in these fields of application, which represent an environmental problem due to their mercury content and their low efficiency with regard to the generation of VUV radiation.
  • these lamps are not like the DBE lamp in a short time on and off, but sometimes require minutes of "boot” until the radiation power has reached its target value.
  • DBE lamps immediately emit their maximum power, are mercury-free and produce VUV radiation with a wavelength of 10 nm to 200 nm with high efficiency.
  • a gas- or air-filled space between insulating coated electrodes can be ionized or enter a low-temperature plasma state when an AC voltage to the Electrodes in gas-filled space generates sufficient field strengths.
  • the electrodes are isolated by means of a dielectric with respect to the gas-filled space. By displacement currents an electrical discharge is caused despite isolation and it can be transmitted almost continuously electrical power in the plasma. Since the electrical discharge between the electrodes is impeded by the dielectric energy and time, one speaks of a "dielectrically impeded discharge", abbreviated DBE.
  • DBE lamps particularly tubular DBE lamps
  • the power density is to be understood here as the optical radiation power per surrounded by the outer lamp envelope gas volume.
  • a certain part of the gas space is used for the discharge. This part should be called discharge volume.
  • the efficiency of DBE lamps decreases sharply with increasing radiation output from a given discharge volume. Therefore, no DBE lamps are yet known that can replace mercury-containing low and medium pressure lamps with comparable power density. Discharges into DBE lamps can be generated in an energy-efficient manner only over impact widths in the range from 2 mm to 4 mm.
  • the striking distance is the distance between two dielectrically isolated electrodes of the DBE lamp, between which the electrical discharge takes place through the gas-filled space.
  • the gas pressure would have to be significantly reduced in order not to require an inadmissibly high operating voltage.
  • Maximum usable electrical voltages are limited by the available insulating materials and the performance of the power electronics with which, e.g. High voltage pulses are generated to operate the DBE lamp. Typically, the maximum usable voltage is limited to 5 kV.
  • the invention has for its object to provide a DBE lamp with increased power density.
  • a dielectrically impeded discharge lamp in one aspect, includes a housing that includes an interior space filled with a gas mixture suitable for generating radiation upon electrical discharge through the gas mixture.
  • the DBE lamp also has at least three electrodes electrically insulated from the gas mixture, at least two of the electrodes being in contact with different electrical potentials. At least two of the electrodes at different electrical potential are arranged as internal electrodes in the interior of the DBE lamp. The at least two electrodes at different potentials are electrodes from the quantity of at least three electrodes of the DBE lamp which are electrically insulated from the gas mixture.
  • the DBE lamp can be provided for generating radiation with high voltage pulses.
  • the interior of the DBE lamp is filled with gas which generates electromagnetic radiation in the UV range, in particular in the VUV range, when electrical potentials are applied to the electrodes when the electrical voltage passes through an area of the internal space between the electrodes discharges.
  • gas which generates electromagnetic radiation in the UV range, in particular in the VUV range, when electrical potentials are applied to the electrodes when the electrical voltage passes through an area of the internal space between the electrodes discharges.
  • a xenon can be used as a gas for generating optical radiation having a wavelength of about 172 nm.
  • the gas in the interior is thereby transferred into the plasma state, in particular into the low-temperature plasma state.
  • the electrodes are at different electrical potentials or can be applied to different electrical potentials.
  • the electrodes may be designed and provided to achieve radiation generation by pulsed operation.
  • the electrodes are not at each time at the potential associated with the respective electrode, but at least during the pulse.
  • the voltage pulses along a discharge path in the DBE lamp can be offset in time from one another, as a result of which the individual discharge paths are better, in particular dynamically, controllable.
  • at least two internal electrodes can be present at different electrical potential, so that between these two internal electrodes an electrically dielectrically handicapped discharge for radiation generation can take place.
  • At least one of the electrodes is formed electrically insulated from the interior by a dielectric.
  • a dielectric preferably be carried out by, a glass layer (quartz glass, Suprasil), ceramics or plastics (Teflon).
  • the electrodes may be e.g. be surrounded by a glass layer and / or be arranged separated by a glass layer from the interior.
  • the housing can be made of a dielectric as external insulation.
  • the dielectric can be coated with phosphorus, in particular if it is simultaneously used as a lamp vessel, in order to achieve a wavelength transformation of the emitted optical radiation.
  • a plurality of electrodes in particular a plurality of internal electrodes
  • multi-part discharge paths can be generated in the interior of the DBE lamp.
  • Multi-part discharge paths extend over a plurality of electrodes, which are at different and / or alternating electrical potentials. By such multi-part discharge paths, the volume of the interior can be used more efficiently.
  • an at least two-part discharge path can be provided in the DBE lamp, ie, for example, a discharge between the first Electrode and the second electrode and a discharge between the second electrode and the third electrode.
  • At least two of the electrodes are formed as internal electrodes, ie the part of the discharge path between the two internal electrodes lies completely in the interior of the DBE lamp. Internal electrodes are arranged completely in the interior. Only the electrical leads of the internal electrodes can be arranged at the edge of the interior, but the electrode parts used for the electrical discharge are enclosed on all sides by the gas mixture or only separated from the gas mixture via the insulation.
  • external electrodes are disposed either outside of the gas mixture filled interior space or at the periphery thereof (e.g., on the glass wall of the interior space). From external electrodes, discharge paths can be formed only in the direction of the interior of the DBE lamp. Since internal electrodes are disposed entirely inside, discharge paths to other electrodes in arbitrary directions can be formed from internal electrodes (except for the direction in which the electrical lead of the internal electrode leads out of the internal space).
  • At least one electrode of each discharge path is electrically insulated from the gas in the interior.
  • the discharge path can also be formed at least in three parts or with even more discharge sections. In other words, at least one discharge for generating radiation takes place along a discharge section, which is arranged between the two internal electrodes.
  • the internal electrodes are not surrounded by the gas only at their electrical leads. Otherwise, the internal electrodes are completely surrounded by the gas of the interior and preferably isolated from the gas.
  • the internal electrodes are arranged completely in the interior except for their or their supply end or ends.
  • the use of multi-part discharge paths inside the DBE lamp makes it possible to make good use of the volume of the interior, even if the maximum gap between the electrodes remains constant. This achieves good efficiency and high power density.
  • the electrodes can be arranged so that the entire volume of the interior, which is enclosed by the lamp body, is used for generating radiation.
  • the total volume of the DBE lamp can be increased by the use of multiple electrodes.
  • the usable volume for generating radiation can be increased.
  • At least one of the internal electrodes is substantially rod-shaped.
  • the electrodes can also be designed as a substantially rod-shaped internal electrodes.
  • the electrodes have the shape of an elongated cylinder whose cylinder diameter is formed substantially smaller than the cylinder height. Typical diameters of the rod-shaped internal electrodes are in the range of a few millimeters.
  • the internal electrodes may abut at one or both cylinder ends at an electrical potential. A significant part of the outer surface of the shell of the elongated cylinder is facing the interior.
  • the internal electrodes may e.g. be formed as a wire which is surrounded by a dielectric. Due to the rod-shaped design, the inner electrodes occupy little space in the interior and leave as much volume of the interior for generating radiation.
  • the electrodes are made of an electrically conductive material.
  • various metals are possible in the form of solid or hollow bars, wires, nets or strands, dielectric layers applied to the dielectric (e.g., bright gold) and the combination of both.
  • the electrodes can be enveloped in the gas space with a dielectric, coated with a dielectric on the inside of the lamp vessel, so the Housing, or be mounted on the outside of the lamp vessel. Not all electrodes must be dielectrically isolated from the gas space. It is advantageous in special cases, the dielectric only on one side to hinder the discharge by only one of the electrodes, between which the discharge takes place, is electrically isolated by a dielectric sheath from the gas space.
  • the electrodes are arranged in the DBE lamp such that at least one discharge path with a plurality of discharge sections is formed in the interior, wherein a single discharge section is formed between two electrodes which rest against electrically different potentials.
  • the discharge path can have at least three discharge sections.
  • the length of a discharge section can be limited by the maximum reachable distance.
  • discharge paths having three to ten discharge sections may be provided in the DBE lamp, i. an electrical discharge via four to eleven different electrodes.
  • the individual discharge sections can also be referred to as discharge layers.
  • the maximum number of discharge layers is limited by the electrodes in the gas space and their dielectric sheath, which reduce the optical system efficiency by radiation absorption and multiple reflection.
  • the discharge path may have an even number of discharge portions, and the electrodes may be arranged symmetrically in the DBE lamp.
  • the electrodes can be arranged with circular symmetry with respect to the central axis of the tube, that is to say the cylinder axis.
  • the DBE lamp can be adjusted by varying the number of electrodes per equipotential surface and varying the number of discharge sections to a predetermined pressure, a predetermined ignition voltage for discharge, a predetermined type and thickness of the dielectric and / or predetermined lamp dimensions.
  • the discharge path can also have an odd number of discharge sections and the electrodes can be arranged in an interdigital structure, in particular with respect to their electrical potential, in the interior of the DBE lamp, preferably also on the lamp outer bulb. Equally far away from a central axis of the DBE lamp electrodes lie on an alternating electrical potential, with unbalanced equipotential surfaces arise in the interior. Such an asymmetric arrangement may be useful for certain boundary conditions such as pressure, ignition voltage, type and thickness of the dielectric and / or lamp dimensions.
  • the electrodes can be arranged in the DBE lamp such that strike widths are formed substantially equally long over the individual discharge sections. This results in a uniform radiation power in the individual space regions of the interior and it is to be provided by the power electronics essentially two different potentials, preferably via a pulsed excitation of the enclosed gas in the lamp chamber.
  • the interior space is designed to be electrically insulated from an environment of the DBE lamp via an external insulation.
  • This isolation can e.g. be formed as a glass or a glass cylinder.
  • a glass cylinder is a dielectric and thus serves for electrical insulation of the interior. At the same time, glass is well-suited for the airtight enclosure of the gas and is permeable to the radiation generated in the interior.
  • the outer insulation may be formed as a boundary or housing of the DBE lamp.
  • the DBE lamp may have at least one outer electrode, which is arranged so that the outer electrode is electrically insulated from the interior by the outer insulation.
  • An outer electrode thus does not need its own insulation, but can use the outer insulation of the interior.
  • the outer electrode is outside the interior and / or at the edge of the interior arranged.
  • the outer electrode can rest against the outer insulation from the outside, ie on the side of the outer insulation opposite the inner space.
  • all external electrodes can be designed to be at the same electrical potential for generating radiation.
  • the outer electrodes are used as an electrically conductive fluid, such as a fluid.
  • the fluid may e.g. be grounded, so abut the electrical ground, and serve as the outer electrode of the DBE lamp, which is insertable into the fluid.
  • the radiation generated in the interior can be used to sterilize the fluid.
  • an inner electrode is arranged centrally on a central axis of the housing.
  • all internal electrodes of a group of internal electrodes are equidistant from a central axis of the housing.
  • the internal electrodes may be divided into several such groups. All groups can have the same number of internal electrodes.
  • One of the group of internal electrodes may e.g. Define equipotential surfaces in the interior of the DBE lamp, wherein the equipotential surfaces each pass through the individual groups of internal electrodes when the internal electrodes of a group are at the same potential.
  • the internal electrodes of a group can also be applied to alternating electrical potentials.
  • the electrodes are divided into pairs of electrodes and each electrode pair has its own ballast, or a separate output of a used for the operation of the entire lamp or lamp group ballast, for electrical potential generation. It can also ballasts for each discharge position or a discharge section may be provided. By individual ballasts, or separate outputs of a ballast used for the operation of the entire lamp or lamp group manufacturing inaccuracies such as different strike widths between the electrodes can be compensated by adjusting the electrical potentials. This optimizes the lamp operation. In this case, a ballast with inductively and / or galvanically decoupled or separate outputs can be used, which reduces the circuit complexity.
  • the housing and thus also the inner space are cylindrical and the inner electrodes are formed substantially parallel to the cylinder axis of the housing.
  • efficient use of the interior e.g. provided for a tubular DBE lamp.
  • a holder supports the internal electrodes with respect to the housing, e.g. the external insulation, of the interior.
  • the internal electrodes are made thin, e.g. rod-shaped. Thereby, from a certain length of the inner space, it may cause deformation, e.g. sagging, the internal electrodes come.
  • a corresponding holder prevents such a deformation of the internal electrodes and thus a distortion of the intended arrangement of the internal electrodes in the interior.
  • the holder may e.g. be formed as one or a plurality of glass rods, which support the internal electrodes. Glass serves as another dielectric and is almost transparent to the generated radiation.
  • At least one of the internal electrodes does not have its own dielectric insulation.
  • Such an uninsulated inner electrode may be formed, for example, as a mesh electrode.
  • one or more of the internal electrodes may also be formed uninsulated.
  • a plurality of internal electrodes are arranged as a subgroup with the same electrical potential in the DBE lamp. In this case, the subgroup of the internal electrodes can not only rest at the nominally identical potential, but can also be electrically connected to one another at exactly the same potential, that is to say electrically conductively.
  • FIG. 1A is a schematic cross-sectional view of a first known DBE lamp with two outer electrodes
  • Figure 1 B in a schematic cross-sectional view of a second known DBE lamp with external electrodes and a tubular central electrode;
  • Figure 2 is a schematic cross-sectional view of a first
  • Figure 3 is a schematic cross-sectional view of a second
  • Figure 4 is a schematic cross-sectional view of a third
  • Figure 5 is a schematic cross-sectional view of a fourth
  • Figure 6 is a schematic cross-sectional view of a fifth
  • FIG. 7 is a schematic cross-sectional view of a sixth
  • FIG. 1A schematically shows a cross-section through a first known DBE tubular lamp 1.
  • the DBE lamp 1 is formed as an elongate tube bounded by a cylindrical outer insulation 20 of glass. Inside the outer insulation 20, an inner space 10 is arranged, which is filled with a suitable gas for a dielectrically impeded discharge.
  • the outer insulation 20 encloses the gas in the interior 10, is permeable to optical radiation generated in the interior 10 and serves as a dielectric insulation of two electrodes 50 and 50 ", which are formed as external electrodes and are aligned parallel to the cylinder axis of the tubular DBE lamp 1
  • the cylinder axis of the DBE lamp 1 is in cross-section in FIG. 1A the center of the circle, that is to say the center of the circular cross section through the interior 10.
  • the two outer electrodes 50 and 50 ' are at different potentials.
  • discharges can form in the gas-filled interior 10 due to the displacement current penetrating the outer insulation 20, these discharges converting the gas into the plasma state, which generates optical radiation in the interior 10 .
  • the outer electrodes 50 and 50 ' are spaced apart from one another by the distance between the tube diameter of the DBE lamp 1 by a distance d.
  • FIG. 1B shows schematically a cross-section through a second known tubular DBE lamp 1 '.
  • the DBE lamp 1 ' is similar to that in FIG. 1A shown DBE lamp 1 as elongated tube with the cylindrical outer insulation 20 and the interior 10 is formed.
  • the DBE lamp 1 has four outer electrodes 50 which are at a negative electrical potential.
  • a central electrode 50 is arranged, which is likewise of tubular design, has a smaller diameter than the outer insulation 20 and which shares the same cylinder axis with the outer insulation 20.
  • the central electrode 99 includes a dead space 99, in FIG no radiation is generated.
  • the central electrode 50 ' is connected to a positive electrical potential, so that an electrical discharge can take place between the central electrode 50 "and the outer electrodes 50 via the inner space 10 and the outer insulation 20.
  • the discharge takes place over a distance d between the cylinder jacket of the central electrode 50 "and the cylinder jacket of the outer insulation 20.
  • FIG. 2 shows a first exemplary embodiment of a DBE lamp 2 according to the invention with a four-part discharge path 32.
  • the DBE lamp 2 is tubular and, in FIG shown to the central axis of the tube.
  • the gas-filled interior 10 is surrounded by the outer insulation 20.
  • the outer insulation 20 is formed as a glass tube, which acts as a dielectric and electrical insulation and is transparent to radiation generated in the interior 10.
  • a plurality of outer electrodes 60 and 60 'are arranged in an outer region of the DBE lamp 2 and by the outer insulation 20 with respect to the inner space 10 are electrically insulated.
  • the DBE lamp 2 shown in FIG. 2 has two external electrodes 60, which rest against a negative electrical potential or ground. Furthermore, the DBE Lamp 2 two outer electrodes 60 ', which bear against an electrically positive potential.
  • the two "cold" outer electrodes 60 and the two “hot” outer electrodes 60 ' are uniformly spaced from each other over the outer circumference of the outer insulation 20 and are disposed at an alternating potential.
  • two outer electrodes 60, 60 'with different potentials are arranged at 90 ° from each other, while two outer electrodes 60, 60' are arranged at the same potential around each other.
  • the angle data are based on the cross section shown and with respect to the center axis of the DBE lamp. 2
  • the insulations 63 may e.g. be formed of glass or a quartz, e.g. as thin glass tubes.
  • the insulations 63 serve as a dielectric for the dielectrically impeded discharge of the DBE lamp 2.
  • the discharges extend along discharge paths 32, 32 ', which are not arranged centrally symmetrical to the central axis of the lamp vessel. That is, the discharge paths 32, 32 'do not entirely follow rays that intersect the central axis of the lamp vessel.
  • the internal electrodes 62, 62 'and external electrodes 60, 60' there are three-part and four-part discharge paths through the interior 10, of which, for example, in each case a three-part discharge path 32 'and a four-part Discharge path 32 are shown.
  • the discharge path 32 ' leads from a first cold outer electrode 60 along a first discharge section 32a to a first hot inner electrode 62'.
  • the first discharge section 32a takes place over a distance d2 between these two electrodes.
  • the distance d2 corresponds to the distance between the outer diameter of the outer insulation 20 to the nearest inner electrode 62 '.
  • the distance d1 corresponds to the distance between the inner electrodes 62 ', 62 to each other and the side of the square, in which the inner electrodes 62, 62' are arranged in the cross section shown.
  • the first discharge section 32a and the third discharge section 32z are approximately the same length. With cold or hot electrode, an electrode is referred to as a negative or positive electrical potential.
  • the internal electrodes 62, 62 'and external electrodes 60, 60' are made e.g. the four-part discharge path 32 through the inner space 10, of which a discharge path 32a-d is shown by way of example in FIG.
  • the discharge paths 32c and 32d are formed.
  • discharge path 32c runs in the same way as discharge path 32b between two internal electrodes 62 and 62 ', while discharge path 32d extends between an internal electrode 62' and an external electrode 60.
  • Three and four-part discharge path 32 'and 32 may occur simultaneously.
  • the distances between the discharge sections d2 should be approximately as large as d1 formed when the DBE lamp 2 is operated with only one electric ballast.
  • the distances can be made different sizes, if multiple ballasts are used.
  • Electronic ballasts are used to generate the electrical potential to which both the inner and the outer electrodes abut. When using each of their own electrical ballast for each pair of electrodes can be compensated by individually tuning the different potentials an irregularity in the design of the DBE lamp.
  • FIGS. 1B and 2 it can be seen that the volume of the interior 10 in the case of the DBE lamp 2 shown in FIG. 2 can be better utilized for generating radiation than in the case of the DBE lamp 1 'shown in FIG. 1B a take, the internal electrodes 62, 62 * so slim training less volume than the center electrode 50 "of the DBE lamp 1 '.
  • the multi-part discharge path 32 is better able to penetrate more gas-filled inner volume of the inner space 10 than in the discharge in Furthermore, the slender inner electrodes 62, 62 'cause a much smaller shielding of radiation arising in the inner space 10 than in the known DBE lamp 1', while the large central electrode 50 "provides a large non-transparent shielding the radiation that reduces the radiation yield.
  • Discharge path 32 has three discharge sections or discharge layers, for which an outer piston diameter of about three times the distance d2 is advantageous.
  • the internal electrodes 62, 62 ' may be at other voltage potentials than the external electrodes 60, 60' to allow different strike widths.
  • the DBE lamp 2 is particularly suitable for generating VUV radiation.
  • FIG. 3 shows a DBE lamp 3, which is constructed similarly to the DBE lamp 2 shown in FIG. In contrast to the DBE lamp 2, all four outer electrodes 60 of the DBE lamp 3 are designed and intended to be connected to the same electrical potential, eg to ground. Therefore, the external electrodes 60 can also be replaced with a conductive fluid such as water to be purified.
  • the outer electrodes 60 can be designed in addition to the strip design, inter alia, as a mesh electrode, as a transparent electrode (ITO coating) or as a structured vapor-deposited metal.
  • the DBE lamp 3 has five internal electrodes 62 ', 62, of which four hot internal electrodes 62' are arranged in cross section in a square.
  • a central inner electrode 62 is formed as a cold electrode.
  • the first discharge portion 33a extends from a first cold outer electrode 60 to a first hot inner electrode 62 '
  • the second discharge portion 33b from the first hot inner electrode 62' to the central cold inner electrode 62
  • the third discharge portion 33c from the central cold inner electrode 62 to one second hot inner electrode 62 'and the fourth discharge portion 33d from the second hot inner electrode 62' to a second cold outer electrode 60.
  • the discharge beats at the first and fourth discharge portions 33a, 33d are made a distance d2 between the outer electrode 60 and an outer inner electrode 62 ' the second and third discharge portions 33b, 33c are separated by a distance d1 between an outer inner electrode 62 'and the central inner electrode 62.
  • FIG. 4 shows a cross section through a tubular DBE lamp 4, which is constructed in a similar way to the DBE lamp 3 shown in FIG. However, the DBE lamp 4 has four further internal electrodes 62 '. Overall, the DBE lamp 4 in the interior space 10 has a (hot) central inner electrode 62 ", therefore four (cold) inner electrodes 62 arranged at the corners of a small square, four (hot) inner electrodes 62 'arranged around the corners of a large square. and four (cold) outer electrodes 60.
  • the small square and the large square are arranged rotated by 45 ° in the cross-sectional view
  • the eight outer electrodes 60 are arranged in two outer squares, the one opposite the large square of the four outer inner electrodes 62 '. is arranged twisted by + 22.5 ° and the other is arranged by -22.5 ° with respect to the large square of the four outer internal electrodes 62 '.
  • FIG. 5 shows a cross-section through a tubular DBE lamp 5, which is constructed in a similar way to the DBE lamp 3 shown in FIG.
  • the central inner electrode 62 " which is designated 62 in FIG. 3 is marked at lamp 5 by a diameter that is greater than the diameter of the sixteen (hot) inner electrodes 62 'arranged in a circle around the central lamp center.
  • the inner diameter of the lamp outer vessel that is to say the outer insulation 20, is larger than the diameter of the circle in the illustrated cross section, on which the inner electrodes 62 'are advantageously arranged equidistant from one another
  • the diameter of the central inner electrode 62 " is smaller in cross section than the diameter of the circle on which the internal electrodes 62 'are arranged.
  • the inner electrodes 62 ' preferably have the same distance d2 from both the inner electrode 62 "and the outer electrodes 60 (distance d1) which are arranged on the outside of the lamp outer bulb (ie the outer insulation 20.)
  • one inner electrode 62' and one outer electrode 60 are included at the center of each beam on a beam through the central center of the lamp Such a beam is shown in Figure 4 along the discharge path 32.
  • the discharge follows a discharge path 32 of up to four sections 32a-32d.
  • Discharge portion 32a extends between an outer electrode 60 and an inner electrode 62 ', whereas discharge portion 32b extends from this inner electrode 62' to central inner electrode 62 ". Symmetrically, the discharge may proceed following the other discharge portions 32c and 32d.
  • the central inner electrode 62 '' may be at the same potential as the outer electrodes 60, for which the distance d1 is advantageously equal to the distance d2 It is possible to apply different potentials to the further inner or outer electrodes and to use these different potentials Design of the discharge processes are used.
  • the advantage of the embodiment of the lamp 5 shown in FIG. 5 lies in the lamp 1 'shown in FIG. Y in the better utilization of the gas volume due to the greater number of discharge layers.
  • the central inner electrode 62 may consist of an aluminum layer which reflects the optical VUV radiation well, and in contrast to a further increase in the discharge layer number, the non-use of a dead space 99 inside the central inner electrode 62" is accepted.
  • the lamp volume determined by the lamp outer diameter is used more effectively for generating optical radiation.
  • FIG. 6 shows a cross section through a tubular DBE lamp 6, which is constructed in a similar way to the DBE lamp 5 shown in FIG.
  • both the internal electrodes 62 and 62 'with each other and the external electrodes 60 and 60' have different, advantageously alternating, potentials.
  • Another difference from the embodiment shown in FIG. 5 lies in the arrangement of the internal electrodes 62 and 62 'into subgroups of the same potential. By this group arrangement, it can be ensured that discharges, which follow rays which have a right angle to the rays through the central lamp center, can form at different distances from the central lamp center.
  • Such a beam is shown in Figure 7 as a discharge section 36 formed between a subset of internal electrodes 62 and a subset of internal electrodes 62 '.
  • a subgroup of internal electrodes each consists of three internal electrodes 62 and 62 ', which are in contact with the same potential.
  • the subgroups are arranged with alternating polarity around the central inner electrode 62 "in the DBE lamp 7.
  • a discharge path 32 'following the discharge sections 32a, 36 and 32d may also be established.
  • the formation of the discharge section 36 is particularly advantageous since the optical radiation generated here is hardly shadowed by other internal electrodes or external electrodes and is therefore only slightly weakened.
  • the inner diameter of the central inner electrode 62 "can be further reduced with the same outer diameter of the lamp, thereby making the lamp volume enclosed by the lamp outer diameter even more efficient for generating optical VUV radiation.
  • the DBE lamp could also have further internal electrodes arranged in the interior, eg in a square.
  • a central inner electrode can be provided which is surrounded by inner electrodes arranged in ever larger squares.
  • the squares of successive internal electrodes of the individual discharge layers can be arranged offset from each other by 45 °.
  • the internal electrodes could also be arranged in a different geometric shape, wherein from the central axis of the DBE lamp equidistant and remote internal electrodes are arranged in cross section, preferably symmetrically with respect to the central axis of the DBE lamp.
  • the same distance from the central axis of the inner electrodes can be divided into groups of the same potential. In the case of the DBE lamp 4 shown in FIG. 4, this results in a discharge path 32 which runs along up to six individual discharge paths 32a to 32f, thus having six parts and having six discharge layers.
  • the distance across the respective distances d1, d2 and d3 should be the same size, if the DBE lamp is operated only with a single electric ballast.
  • the arrangement of the inner and outer electrodes shown results in equipotential surfaces in the interior along the same distance from the central axis of the DBE lamp inner electrodes.
  • the equipotential surfaces lie essentially on a cylinder jacket around the tube center axis of the DBE lamp through the same distance from the central axis of the tube inner electrodes.
  • strike ranges for the electrical discharge at a given pressure, given ignition voltage, given glass thickness of the insulations and the lamp bulb diameter can be adjusted by a variation of the number of internal electrodes per equipotential surface, as well as by a variation of the number of Discharge documents.
  • an arrangement of the electrodes in an interdigital structure is advantageous.
  • the electrode polarity of the inner and outer electrodes, which are equidistant from the central axis of the DBE lamp alternates (see FIG. This results in unbalanced equipotential surfaces in the DBE lamp, which may be useful under certain boundary conditions.
  • the discharge paths between the inner and outer electrodes, which are equidistant from the central axis of the DBE lamp lie on beams which form a right angle to a beam through the central lamp center.
  • the electrical potentials at the electrodes shown in the DBE lamps 2, 3, 4, 5, 6 and 7 are in each case selected for a possible embodiment.
  • the potentials can not only be interchanged with each other, but also be applied differently to the electrodes. It is also possible to use not only hot and cold electrodes, but also to apply graded electrical potentials between the two extremes to the electrodes, wherein emergence of the discharge paths can be selectively controlled or influenced.
  • either holders may be provided for supporting the internal electrodes, or a plurality of DBE lamps may be arranged in series, their tube center axes coinciding.
  • FIGS. 2 to 7 only one discharge path 32 and 33 are shown by way of example. In fact, in the DBE lamps 2 to 7, discharges also take place via further discharge paths which are analogous to the respective discharge path 32 shown or 33 are arranged between the electrodes.
  • At least one discharge section discharge path is arranged between two internal electrodes.

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  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Engineering & Computer Science (AREA)
  • Plasma & Fusion (AREA)
  • Vessels And Coating Films For Discharge Lamps (AREA)

Abstract

L'invention concerne une lampe à décharge à empêchement diélectrique (2; 3; 4; 5; 6; 7) comprenant un boîtier (20) qui entoure un espace intérieur (10) rempli d'un mélange gazeux adapté pour générer un rayonnement lors d'une décharge électrique à travers le mélange gazeux, et au moins trois électrodes (60, 60', 62, 62') électriquement isolantes vis-à-vis du mélange gazeux. Deux au moins des électrodes (60, 60', 62, 62') sont à des potentiels électriques différents et deux au moins des électrodes sont disposées sous la forme d'électrodes intérieures (62, 62') ayant un potentiel électrique différent dans l'espace intérieur (10) de la lampe à décharge à empêchement diélectrique (2; 3; 4; 5; 6; 7).
EP13776714.1A 2012-09-07 2013-09-06 Lampe à décharge à empêchement diélectrique Withdrawn EP2893551A1 (fr)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
DE201210017779 DE102012017779A1 (de) 2012-09-07 2012-09-07 Dielektrisch behinderte Entladungs-Lampe
PCT/EP2013/002687 WO2014037118A1 (fr) 2012-09-07 2013-09-06 Lampe à décharge à empêchement diélectrique

Publications (1)

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EP2893551A1 true EP2893551A1 (fr) 2015-07-15

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EP13776714.1A Withdrawn EP2893551A1 (fr) 2012-09-07 2013-09-06 Lampe à décharge à empêchement diélectrique

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EP (1) EP2893551A1 (fr)
DE (1) DE102012017779A1 (fr)
WO (1) WO2014037118A1 (fr)

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CN105101603B (zh) * 2015-08-04 2018-06-08 昆山禾信质谱技术有限公司 一种介质阻挡放电等离子体射流装置

Family Cites Families (12)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CH676168A5 (fr) * 1988-10-10 1990-12-14 Asea Brown Boveri
EP0482230B1 (fr) * 1990-10-22 1995-06-21 Heraeus Noblelight GmbH Dispositif de rayonnement à haute puissance
US6888041B1 (en) * 1997-02-12 2005-05-03 Quark Systems Co., Ltd. Decomposition apparatus of organic compound, decomposition method thereof, excimer UV lamp and excimer emission apparatus
CA2224699A1 (fr) * 1997-12-12 1999-06-12 Resonance Ltd. Electrode creuse pour lampe sans electrode
KR100438831B1 (ko) * 2001-11-22 2004-07-05 삼성전자주식회사 플라즈마 평판 램프
JP3996450B2 (ja) * 2002-06-14 2007-10-24 Necライティング株式会社 出力光色可変の平面型希ガス放電灯とこれを用いた照明器具および点灯方法
DE10336088A1 (de) * 2003-08-06 2005-03-03 Patent-Treuhand-Gesellschaft für elektrische Glühlampen mbH UV-Strahler mit rohrförmigem Entladungsgefäß
US7446477B2 (en) * 2004-07-06 2008-11-04 General Electric Company Dielectric barrier discharge lamp with electrodes in hexagonal arrangement
US7683343B2 (en) * 2005-01-28 2010-03-23 Koninklijke Philips Electronics N.V. Treatment system comprising a dielectric barrier discharge lamp
US7495396B2 (en) * 2005-12-14 2009-02-24 General Electric Company Dielectric barrier discharge lamp
KR100740511B1 (ko) * 2006-01-07 2007-07-19 주식회사 광운디스플레이기술 다중전극 이중관 형광 램프
WO2012050916A2 (fr) * 2010-09-29 2012-04-19 Ultraviolet Sciences, Inc. Source de lumière excimère

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
See references of WO2014037118A1 *

Also Published As

Publication number Publication date
DE102012017779A1 (de) 2014-03-13
WO2014037118A1 (fr) 2014-03-13

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