KR101246412B1 - Lighting apparatus - Google Patents

Abstract

In the high-pressure discharge lamp in which the discharge tube is provided inside the exterior, and the inner diameter of the exterior and the outer diameter of the discharge tube are almost the same, and at least a part of the exterior and the discharge tube are in contact with each other, it is possible to suppress the roughness unevenness caused by the surface temperature unevenness. will be.

The high-pressure discharge lamp 10 is composed of a discharge tube 11 and an appearance 20, and is turned on by applying an alternating voltage from the power supply unit 1 to the pair of electrodes 16 of the high-pressure discharge lamp 10. At the time of lighting, the high pressure discharge lamp 10 is cooled by circulating the cooling water W in the cooling water flow path 65. The power supply unit 1 drives the inverter with a drive signal of the normal lighting frequency f1 to light the lamp 10. Before the illuminance unevenness occurs, the frequency unevenness of the frequency f2 lower than that of the unevenness unevenness can be eliminated. The lamp 10 is turned on by switching to the drive signal. Thereby, the density distribution nonuniformity of the cation which arises at the time of normal lighting can be eliminated, and unevenness distribution can be suppressed.

Description

Lighting device {LIGHTING APPARATUS}

The present invention relates to a light-emitting device of a high-pressure discharge lamp having both ends sealed and a pair of electrodes opposed to each other, and at least a metal-sealed discharge tube, and an appearance provided outside the discharge tube.

For example, in hardening processing of resin, such as an adhesive agent, and exposure processing, such as a printed board, a high pressure discharge lamp (ultraviolet irradiation lamp) is used as an ultraviolet light source, for example.

Since this high-pressure discharge lamp (ultraviolet ray irradiation lamp) becomes a high temperature at the time of lamp lighting, it cools as described in patent document 1. As shown in FIG.

Patent Literature 1 describes a technique in which a water-cooled jacket having a double-pipe structure is provided outside the discharge tube (hereinafter referred to as the light-emitting tube in Patent Literature 1) to allow cooling air to flow between the light-emitting tube and the water-cooled jacket inner tube.

The light source shown in FIG. 1 of patent document 1 is shown in FIG. As shown in the figure, the ultraviolet irradiation lamp 101, the water cooling jacket 102, and the end caps 103a and 103b of both ends of the water cooling jacket are provided. The ultraviolet irradiation lamp 101 seals a pair of electrodes on both ends of a straight tube-shaped quartz glass light emitting tube 106, and seals rare gas, mercury, and a metal halide inside.

The water-cooled jacket 102 is made of a transparent material such as a cylindrical quartz glass, and has a double pipe structure consisting of an inner tube 121 and an outer tube 122, and through connecting tubes 123a and 123b provided on both ends of the outer periphery. Cooling water 104 circulates in the jacket from the outside to cool the light emitting tube 106 near the air layer and to absorb heat radiated from the lamp 101.

The air vent 131 is provided in one end cap 103a of the water cooling jacket 102, and the exhaust port 132 is provided in the other end cap 103b. Then, the cooling wind 105 enters the inside of the water cooling jacket 102 from the air vent 131 from the outside and flows through the space between the light emitting tube 106 and the inner tube 121 of the water cooling jacket 102 from the outside. Heat is removed from the light emitting tube surface to cool the light emitting tube 106.

From the numerical example described in Paragraph No. [0011] of Patent Document 1, the one described in Patent Document 1 is, for example, the outer diameter of the light emitting tube 106 is 24 mm, the water-cooled jacket inner tube 121 is 26 mm, and the gap between them is 1 mm. (= 1000 µm) can be read.

10B is a cross-sectional view of the light emitting tube 106 and the inner tube 121 described in Patent Document 1 taken in a plane perpendicular to the tube axis direction.

In the cooling described in Patent Document 1, since the high-pressure discharge lamp (ultraviolet irradiation lamp) is not sufficiently cooled, a technique described in Patent Document 2 has recently been developed.

Patent Document 2 uses a high-pressure discharge lamp as a double tube structure to close the gap between the discharge tube and the external appearance located outside thereof to increase the cooling effect to the discharge tube by the cooling water flowing in the outer periphery of the external appearance.

The cross-sectional structure of the light irradiation apparatus shown in patent document 2 is shown in FIG. 11, and the cross-sectional structure of the discharge tube and external appearance of the light irradiation apparatus shown in FIG. FIG. 12B is a cross-sectional view taken along the line B-B in FIG. 12A.

This light irradiation apparatus is equipped with the high pressure discharge lamp 10 as a light source. The high-pressure discharge lamp 10 is comprised by the discharge tube 11 which is the rod shape as a whole, and the exterior 20 which consists of quartz glass, for example, in which this discharge tube 11 was arrange | positioned inside.

In the discharge tube 11, a pair of rod-shaped electrodes 16 each made of, for example, tungsten are disposed to face each other inside a straight tube inner tube 12 made of, for example, quartz glass, which is sealed at both ends, Each electrode 16 projects axially outward from the outer end of the seal portion 13 through a metal foil 1 made of, for example, molybdenum, which is hermetically embedded in a rod-shaped seal portion 13 formed in the inner tube 12. It is electrically connected to the external lead 18 which is extended.

In the gap between the discharge tube 11 and the appearance 20 of the high-pressure discharge lamp 10, an air layer or a gas layer made of a suitable gas is formed.

This light irradiation apparatus is provided so that it may extend along the tube axis of the said high pressure discharge lamp 10, and forms the cooling water flow path 65 through which the cooling water W flows between the outer peripheral surface of the high pressure discharge lamp 10. FIG. A cylindrical cooling jacket 60 and an inner space disposed at both ends of the high pressure discharge lamp 10 and the cooling jacket 60 are connected to the cooling water flow path 65 between the high pressure discharge lamp 10 and the cooling jacket 60. It has a cooling mechanism comprised by the cooling water supply flow path formation member 61 and the cooling water discharge flow path formation member 62 which communicate.

Moreover, in the back side of the high-pressure discharge lamp 10 with respect to the light irradiation direction (down direction in FIG. 11), for example, the groove-shaped reflector 70 which has the parabolic reflecting surface 71 in the cross section is Stretch along the high pressure discharge lamp 10 in a state in which the first focus coincides with the center of the high pressure discharge lamp 10 (a straight line connecting the center of the pair of electrodes 16 in the high pressure discharge lamp 10). And the light emitted from the high-pressure discharge lamp 10 is directly or reflected by the reflector 70 to become parallel light and the work stage 76 through the mask M held on the mask stage 75. It is irradiated to the workpiece | work 77, such as a liquid crystal panel and a semiconductor element, where the photosensitive agent, such as a resist, was apply | coated on the image.

In the light irradiation apparatus, the cooling water W is supplied by an appropriate cooling water supply means (pump) not shown in the case of lighting the high-pressure mercury lamp 10.

The cooling water W supplied is formed inside the cooling water flow path 65 formed between the high-pressure discharge lamp 10 and the cooling jacket 60, and the wall surface of the high-pressure discharge lamp 10, specifically, the outer circumferential surface of the exterior 20. It flows along the axial direction, and cools the whole high pressure discharge lamp 10, and is discharged | emitted through the cooling water discharge flow path formation member 62. FIG.

In the discharge tubes of these high-pressure discharge lamps, cations such as Fe, Tl, Sn, Zn, and In are sealed together with Hg or Hg, and they are excited during lamp lighting to emit light.

[Patent Document 1] Japanese Unexamined Patent Publication No. 06-267512

[Patent Document 2] Japanese Unexamined Patent Publication No. 2008-146962

If the average gap between the discharge tube and the external appearance of the cooling water flows to the outer circumferential surface, that is, the difference between the external diameter of the discharge tube and the internal diameter of the external appearance is small, for example, the average gap is 100 μm or less, the illuminance distribution in the longitudinal direction of the discharge tube is uneven. (So-called unevenness of illumination) This did not occur when it was described in patent document 1.

As a result of earnestly examining by the present inventors, it turned out that this was due to making the clearance smaller than the thing of patent document 1.

Specifically, since the member constituting the discharge tube and the external appearance is a glass member, the outer surface thereof is nonuniform as if it becomes a wave shape. For this reason, the gap between the discharge tube and the external appearance is subject to variation of, for example, ± 100 µm, and when the average gap is, for example, 100 µm or less, the gap is 100% or more.

In other words, the discharge tube and the external part are in contact with each other, and in other places, for example, a gap of 200 μm or less exists. When the coolant flows to the outer peripheral surface of the external appearance, the discharge tube is efficiently cooled because the parts to be contacted have good thermal conductivity, whereas the parts having a gap of 200 μm are not cooled as efficiently because they are less thermally conductive than the parts to be contacted. Also in the longitudinal direction of the discharge tube, a portion that is efficiently cooled and a portion that is not cooled are formed.

Inside the discharge tube, cations such as Fe and Tl are sealed together with Hg or Hg. Since these cations have a high density at a low temperature part in the thermal equilibrium state and a low density at a high temperature part, in the case of the high-pressure discharge lamp described in Patent Document 2, at a part that is efficiently cooled in the longitudinal direction thereof. The density of the cation is high and the density is low in the uncooled part. In this way, it is considered that the density distribution of the cations in the longitudinal direction in the discharge tube is uneven, and the illuminance distribution becomes uneven (roughness unevenness).

In addition, in the case of Patent Document 1, since the average gap is 1000 µm, the outer tube shape of the discharge tube and the outer appearance becomes wavy, so even if the gap is subjected to a variation of, for example, ± 100 µm, the variation of the gap is only about 10%. Do not. For this reason, in the high pressure discharge lamp of patent document 1, cooling distribution in the longitudinal direction hardly generate | occur | produced, and it is thought that illumination intensity distribution did not become uneven (illuminance nonuniformity).

This invention is made | formed in view of the said situation, The objective of this invention is equipped with a discharge tube and the external appearance provided in the outer side, the inner diameter of an external appearance and the outer diameter of a discharge tube are substantially the same, and an external appearance and at least one part of a discharge tube contact, The high-pressure discharge lamp which exists is providing the lighting apparatus and lighting method which suppressed illumination intensity nonuniformity.

In this invention, the said subject is solved as follows.

(1) Both ends are sealed, and a pair of electrodes are opposed to each other, and at least a whole is formed in a rod-shaped discharge tube formed by encapsulating a metal, and an outer diameter of the discharge tube is provided. The outer diameter of the lamp is almost the same, and the outer tube and the discharge tube are in contact with each other, and the average value of the difference between the inner diameter of the tube and the outer tube of the discharge tube is, for example, about 100 μm, and extends along the tube axis of the high-pressure discharge lamp. And a flow path forming member that forms a flow path through which the coolant flows between the exterior of the high pressure discharge lamp, and a feeder that is electrically connected to the pair of electrodes to feed the high pressure discharge lamp. In the apparatus, the power supply unit is configured as follows.

That is, a signal generation generates a first signal having a normal lighting frequency f1 for lighting the high-pressure discharge lamp and a second signal having a frequency f2 lower than the normal lighting frequency f1 for solving the unevenness unevenness of the high-pressure discharge lamp. Means, switching means for selectively outputting the first signal or the second signal, and an inverter driven by the first signal or the second signal to supply an alternating voltage of frequency f1 or frequency f2 to the high-pressure discharge lamp. It consists of a circuit. Then, the high-pressure discharge lamp is turned on at the normal lighting frequency f1, and the lamp 10 is turned on by switching to a frequency f2 having a lower frequency than that at which the illuminance unevenness can be eliminated before the illuminance unevenness occurs.

(2) In the above (1), a timer means is provided in the switching means, and the timer means supplies the alternating voltage at a frequency f1 to the discharge lamp after the first predetermined time to supply the high pressure discharge lamp. The frequency of the AC voltage is lowered from f1 to f2, and the AC voltage of the frequency f2 is supplied to the high-pressure discharge lamp for the second predetermined time.

(3) In (1) and (2), the relationship between the normal lighting frequency f1 [Hz] and the frequency f2 [Hz] is set to f2 ≦ 0.3 f1.

(4) In above (1) (2) (3), containing mercury, the metal filled in the discharge vessel, the mercury density encapsulating the normal lighting frequency f1 [Hz], the discharge tube [mg / cm ^3] in the Is Hg, and when the distance [m] between electrodes is AL, it is set as f1 <(Hg / 30) ^-0.33x250 / AL.

In the present invention, the following effects can be obtained.

(1) generate a first signal having a normal lighting frequency f1 and a second signal having a frequency f2 lower than f1 for eliminating unevenness of illuminance, and switching the first signal and the second signal to Since it is made to light, the density distribution nonuniformity of the cation which generate | occur | produces at the time of normal lighting can be eliminated, and it can suppress that illumination intensity distribution becomes nonuniform (illuminance nonuniformity).

In other words, by switching to a frequency f2 lower than the frequency f1, cation is attracted to one electrode side, thereby suppressing roughness unevenness, which can eliminate the density distribution unevenness of cations generated when the light is turned on at the normal lighting frequency f1. can do.

(2) By using a timer means to switch the frequency of the alternating voltage supplied to the high-pressure discharge lamp, it is possible to suppress the unevenness (illuminance unevenness) of the illuminance distribution by means of a relatively simple constitution so that practically it does not interfere. Can be.

(3) The illumination unevenness can be effectively eliminated by setting the relationship between the normal lighting frequency f1 [Hz] and the frequency f2 [Hz] to f2 ≦ 0.3 f1.

(4) When the normal lighting frequency f1 [Hz] is Hg and the mercury density [mg / cm ³ ] enclosed in the discharge tube is set to Hg, and the inter-electrode distance [m] is set to AL, f1 <(Hg / 30) ^-0.33 By setting it as x250 / AL, acoustic resonance can be suppressed and color nonuniformity by the gas distribution and generation | occurrence | production of the dense standing wave of an ion can be suppressed.

First, the light irradiation apparatus made into object of this invention is demonstrated.

The light irradiation apparatus of this invention is equipped with the high pressure discharge lamp similarly to the said FIG. 11, The flow path formation member which partitions the flow path through which the coolant which cools a lamp flows along the external wall surface at the time of lamp lighting is provided. It's an installed configuration.

1 is a cross-sectional view illustrating an outline of a configuration of a light irradiation apparatus according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view along the line A-A in FIG. 1.

This light irradiation apparatus is provided with the high pressure discharge lamp 10 as a light source, and is installed so that it may extend along the tube axis of the high pressure discharge lamp 10 in the state which the high pressure discharge lamp 10 inserted in the inside, and is a high pressure discharge. It has the cylindrical cooling jacket 60 which is a flow path formation member which forms the cooling water flow path 65 through which the cooling water W flows between the outer peripheral surface of the lamp 10. As shown in FIG.

At both ends of the high-pressure discharge lamp 10 and the cooling jacket 60, an internal space is formed in the cooling water supply flow path forming member 61 in communication with the high-pressure discharge lamp 10 and the cooling water flow path 65 between the cooling jacket 60. And the cooling water discharge flow path forming member 62 are configured to constitute a cooling mechanism. ·

The cooling water supply flow path forming member 61 and the cooling water discharge flow path forming member 62 are generally L-shaped tubular, and the high-pressure discharge lamp 10 and the cooling jacket 60 have, for example, a tube axis in a horizontal direction. It is connected in an extended posture.

The outer peripheral surface of the cooling jacket 60 is held and fixed by, for example, a ring (not shown) by the blocking portion 63 on the inner side in the axial direction, and the blocking portion 64 on the outer side in the axial direction. ), The outer circumferential surface of the high-pressure discharge lamp 10 is held and fixed through, for example, a ring (not shown).

The cooling jacket 60 is comprised by the material which transmits the ultraviolet-ray radiated | emitted from the dead discharge lamp 10, for example, quartz glass.

On the back side of the high-pressure discharge lamp 10 with respect to the light irradiation direction (downward in FIGS. 1 and 2), for example, a groove-shaped reflector 70 having a parabolic reflecting surface 71 in cross section, Along the high-pressure discharge lamp 10 in a state where the first focus coincides with the center of the high-pressure discharge lamp 10 (a straight line connecting the center of the pair of electrodes 16 in the high-pressure discharge lamp 10). It is arranged to extend.

The light emitted from the high-pressure discharge lamp 10 is directly or directly reflected by the reflector 70 to be parallel light and placed on the work stage 76 through the mask M held on the mask stage 75. For example, it irradiates to the workpiece | work 77, such as a liquid crystal panel and a semiconductor element, to which photosensitive agents, such as a resist, were apply | coated.

Thus, the reflective surface 71 is formed of a multilayer film formed by alternately depositing other reflective layers such as titanium dioxide and silica, for example.

The feeder 1 is electrically connected to the pair of electrodes 16 of the high-pressure discharge lamp 10 via an external lead 18, and an alternating voltage is applied between the pair of electrodes from the feeder 1. , The high-pressure discharge lamp 10 lights up.

At the time of lighting of the high-pressure mercury lamp 10, the cooling water W is supplied by appropriate cooling water supply means (pump) not shown. Thus, cooling of the high pressure discharge lamp 10 is achieved by circulating the cooling water W at a flow rate of, for example, 5 L (liter) / min.

The cooling water W supplied is formed inside the cooling water flow path 65 formed between the high-pressure discharge lamp 10 and the cooling jacket 60, and the wall surface of the high-pressure discharge lamp 10, specifically, the outer circumferential surface of the exterior 20. Flows along.

Next, the high pressure discharge lamp 10 will be described.

In the high-pressure discharge lamp 10, the inner diameter of the outer tube 20 and the outer diameter of the discharge tube 11 are almost the same, the outer tube 20 and the discharge tube 11 are in contact with each other, and the average gap between the outer tube and the discharge tube is 100 μm. It is a double pipe structure comprised below.

In addition, the average clearance here means measuring the inner diameter L4 of the outer appearance 20 and the outer diameter L5 of the discharge tube 11 in multiple places before assembling the outer appearance 20 and the discharge tube 11, and the difference Is an average value obtained by halving, and refers to an average value of the gap in the radial direction between the electrodes measured at a plurality of locations in the effective light emitting region.

For example, the inner diameter L4 of the external appearance 20 is calculated | required as follows.

The outer diameter L1 of the exterior 20 before assembling the exterior 20 and the discharge tube 11 is measured, and the thickness L2 of the thick portion and the thickness L3 of the thin portion of the inner thickness of the exterior 20 are measured. It measures and calculates the inner diameter L4 of the external appearance 20 by L4 = L1-L2-L3.

In addition, the outer diameter L5 of the discharge tube 11 is the outer diameter of the discharge tube 11 measured before assembling the external appearance 20 and the discharge tube 11.

3 is a cross-sectional view showing an outline of the configuration of the high-pressure discharge lamp according to the embodiment of the present invention.

As shown in FIG. 11, this high-pressure discharge lamp 10 is a pair of each made of tungsten, for example, inside a straight inner tube 12 made of, for example, quartz glass sealed at both ends. The rod-shaped electrodes 16 are disposed to face each other, and the electrodes 16 are sealed through a metal foil 1 made of, for example, molybdenum, which is hermetically embedded in a rod-shaped seal portion 13 formed in the inner tube 12. The discharge tube 11 which is the rod-shaped whole, electrically connected to the outer lead 18 which protrudes and extends outward from the outer end of 13, and this discharge tube 11 are arrange | positioned inside, for example It is comprised by the exterior 20 which consists of quartz glass. Both ends of the discharge tube 11 and the external appearance 20 are being fixed by the adhesive agent 24 via the base 25. As shown in FIG.

The seal part 13 in the discharge tube 11 is formed by the shrink seal method which pressure-reduces the inside, for example by making both ends in the pipe body which is a constituent material of the inner pipe 12 melted, The diameter is smaller than the center portion (part corresponding to the light emitting region) of the discharge tube 11.

The high-pressure discharge lamp 10 is a high-pressure mercury lamp or a metal halide lamp. In the discharge tube 11, for example, 1 mg / mm ³ or more of mercury is sealed and a rare gas such as argon gas is sealed in an appropriate amount. It is. In addition, halogen compounds such as iron (Fe), thallium (Tl), tin (Sn), zinc (Zn), and indium (In) may be encapsulated with mercury (Hg), and further, mercury (Hg) is contained. Some do not. And it emits the light containing the ultraviolet-ray whose wavelength is 350-450 nm, for example.

The power supply part 1 is electrically connected to the pair of electrodes of the high-pressure discharge lamp 10 as shown in FIG. 1.

4 is a configuration diagram showing details of a power supply unit according to the first embodiment of the present invention.

The power supply part 1 is connected to the boosting rectifier circuit 2 to which the DC voltage is supplied, and the full bridge type which is connected to the output side of the booster rectifier circuit 2, and changes a DC voltage into an AC voltage, and supplies it to the discharge lamp 10. FIG. Coil LL1, starter coil LL2, and starter circuit 4 connected in series to the high voltage discharge lamp 10 between the inverter circuit 3, the full bridge type inverter circuit 3, and the high voltage discharge lamp 10. And a controller 5 for controlling the driving of the switching element (for example, IGBT) of the full bridge inverter circuit 3.

The booster rectifier circuit 2 is a rectifier circuit connected to the AC power supply 2a and constituted by the boost transformer T1, the rectifier diode D1, and the smoothing capacitor C1, and converts the AC voltage into a DC voltage. The DC voltage boosted by the boost chopper circuit constituted by the subsequent coil LL3, the switching element S1, the diode D1, and the capacitor C2 is supplied to the full bridge inverter circuit 3.

The control circuit 2b is connected to the switching elements S1 such as the IGBT and the FET of the promotion chopper circuit, and the desired voltage can be supplied by changing the switching frequency and the ON and OFF periods of the switching element S1. .

The full bridge inverter circuit 3 is comprised by switching elements Q1-Q4, such as IGBT and FET connected in bridge shape. ON and OFF of the switching element of the full bridge inverter circuit 3 are driven by the driver circuit mentioned later.

In the operation of the full bridge inverter circuit 3, the switching elements Q1 and Q4 and the switching elements Q2 and Q3 are alternately turned ON and OFF. When the switching elements Q2 and Q3 are turned on, the boost rectification circuit 2 → the switching element Q3 → the coil LL1 → the starter coil LL2 → the discharge lamp 10 → the switching element Q2 → the boost rectification circuit ( Current flows in 2).

On the other hand, when the switching elements Q1 and Q4 are turned on, the boost rectification circuit 2 → the switching element Q1 → the discharge lamp 10 → the starter coil LL2 → the coil LL1 → the switching element Q4 → the boost rectification. An alternating rectangular wave current is supplied to the discharge lamp 10 through the path of the circuit 2.

The control part 5 is comprised by the multivibrator, LC oscillation circuit, etc., The fundamental frequency oscillation circuit 5a which transmits the signal A which is a basic oscillation waveform, and the low frequency oscillation circuit which transmits the signal B which is lower than the signal A ( 5c) and a timer circuit 5b for transmitting a timer signal T for switching ON-OFF at a predetermined time. The signals A, T, and B output by the basic frequency oscillation circuit 5a, the timer circuit 5b, and the low frequency oscillation circuit 5c are combined in the driver circuit 5d.

Each signal A, B, T is combined, and the synthesis | combination of the signal for controlling the full bridge type inverter circuit 3 is demonstrated using FIGS.

5 is a detailed view of the driver circuit.

The signal A having the frequency f1 output by the oscillation circuit 5a is input to one input terminal of the logic circuit L1 (AND circuit), and the output of the timer circuit 5b is output to the other input terminal of the logic circuit L1. Signal T is input. As shown in FIG. 7 described later, the output signal T of the timer circuit 5b is, for example, at the time of falling of the signal A, from the high level (H level) to the low level (L level) or the low level (L level). To a high level (H level), the state changes from H to L level every first predetermined period of signal A, and the state changes from L to H level every second predetermined period of signal A. FIG.

The logic circuit L1 outputs a signal A when the output of the timer circuit 5b is at the H level.

The output signal T of the timer circuit 5b is input to the logic circuit L2 (inverting circuit), inverted, and input to one input terminal of the logic circuit L3 (AND circuit). The output of the low frequency oscillation circuit 5c (signal B having the frequency f2 (f2 <f1)) is input to the other input terminal of the logic circuit L3. The logic circuit L3 outputs the signal B when the output signal T of the timer circuit 5b is at the L level.

The outputs of the logic circuits L1 and L2 are input to an input terminal of the logic circuit L4 (OR circuit), and the logic circuit L4 outputs a signal A when the output of the timer circuit 5b is at the H level, and the timer circuit 5b. When the output of L is at the L level, the signal B is output. That is, the switching circuit SL is constituted by the timer circuit 5b and the logic circuits L1, L2, L3, and L4, and the switching circuit SL is the signal A in accordance with the output signal T of the timer circuit 5b. Or outputs the signal B selectively.

The output signal C1 of the logic circuit L4 is input to the delay circuit DD1, and the delay circuit DD1 outputs a signal C2 delayed by the signal C1. Signals C1 and C2 are input to an input terminal of a logic circuit L5 (AND circuit), and the logic circuit L5 outputs a signal X which is the AND signal. This signal X becomes the drive signal of the switching elements Q1 and Q4 of the full bridge inverter circuit 3.

The signals C1 and C2 are inverted by the logic circuits L6 and L7 (inverting circuits) and input to the input terminal of the logic circuit L8 (AND circuit), and the logic circuit L8 outputs the signal Y which is the AND signal. This signal Y becomes a drive signal of switching elements Q2 and Q3 of the full bridge inverter circuit 3.

FIG. 6 is a flowchart showing the operation of the control unit, FIG. 7 is a timing chart of the control unit, and the operation will be described with reference to FIGS. 5, 6 and 7.

First, in step S1, the signal A which is a basic oscillation waveform is created from the fundamental frequency oscillation circuit 5a.

Next, in step S2, the lighting waveform and the timer waveform of the frequencies f1 and f2 are generated based on the basic oscillation waveform. That is, based on the signal A output from the oscillation circuit 5a, in the low frequency oscillation circuit 5c, a signal B which is lower than the signal A is created, and the timer circuit 5b uses the signal A for a predetermined time. The timer signal T for switching ON-OFF is created.

In step 3, the signal A (frequency f1), the signal B (frequency f2), and the signal T are combined, and the drive signals X and Y of the switching elements Q1-Q4 comprised from the IGBT etc. of a full bridge inverter circuit are created. do.

In step 4, based on the X and Y waveforms, the switching elements Q1 to Q4 are turned on and off and the AC is turned on.

That is, in the period in which the signal T is at the H level, the signals X and Y of the normal lighting frequency f1 are output to light the high-pressure discharge lamp at the normal lighting frequency f1.

Next, a predetermined time after the start of lighting at the normal lighting frequency f1 before the high voltage discharge lamp causes uneven illuminance, the signal T is set to the L level, and the high pressure discharge lamp is turned on at a frequency f2 lower than the normal lighting frequency f1.

At this time, since the low frequency is input to the cation of the discharge tube of the high-pressure discharge lamp, the time attracted to the cathode becomes long, and the cation in the plasma is disturbed. Due to the stirring effect, the distribution of cations becomes uniform, the variation in density distribution of the cations can be resolved more than when the normal lighting frequency f1 is input, and the roughness variation can be suppressed.

In the circuit of Fig. 5, a delayed circuit DD1 is provided to generate a delayed signal C2, and a logical product of the signal C1 and the signal C2 (or its inverted signal) is performed to turn on the signal X and the signal Y. In the interim period, a rest period in which both signals are turned OFF is provided. This is to form a dead time in order to solve the problem of destruction when the switching elements Q1 to Q4 are turned on at the same time.

In the present embodiment, the signal A having the normal lighting frequency f1 and the signal B having the frequency f2 lower than f1 are generated, and the timer circuit 5b switches the signals A and the signal B every predetermined time, and lights up normally. The high-voltage discharge lamp is turned on by driving the switching elements Q1 to Q4 of the full-bridge inverter circuit 3 by the signal of the frequency f1 and the signal of the frequency f2 having a lower frequency than that capable of eliminating the uneven illuminance. Since the density distribution nonuniformity of the cation which generate | occur | produces at the time of normal lighting is solved, it can suppress that a roughness distribution becomes uneven (roughness nonuniformity).

That is, every predetermined time, by switching to the frequency f2 lower than the normal lighting frequency f1, the cation is attracted to one electrode side and the density distribution unevenness of the cation which arises when it is lighting at the normal lighting frequency f1 can be eliminated, Thereby, roughness nonuniformity can be suppressed.

In addition, since the time at which the high-pressure discharge lamp generates the uneven illuminance is known in advance, the signal T of the timer circuit 5b described above switches the signal AB at a predetermined time before the uneven illuminance occurs in the high-pressure discharge lamp. The timing is set.

Moreover, as shown in the experimental result mentioned later, low frequency f2 is 5 Hz or more, and when it is 30% or less of normal lighting frequency f1, it is effective in suppressing roughness nonuniformity, suppressing electrode deformation.

Moreover, it is preferable to set it as before the nonuniform distribution of cation generate | occur | produces as a timing which inserts the low frequency f2 into the normal lighting frequency f1. For this reason, it is preferable to insert the low frequency f2 within 10 minutes after starting lighting at the normal lighting frequency f1.

The period in which the low frequency f2 is inserted is 1 cycle to 10 cycles (one cycle is the ON-OFF period of the signal of the frequency f2), and the period of lighting at the normal lighting frequency f1 is in the range of 0.1 to 6 seconds as time. It is desirable to.

In addition, it is thought that the period for turning on the low frequency f2 and the period for turning on the low frequency f2 are determined by the specifications of the lamp, the lighting conditions, the area where the external appearance and the light emitting tube abut, the number of the abutting portions, and the like.

Here, in the lamp which turns on AC lighting, it is conventionally known that illumination intensity nonuniformity generate | occur | produces by acoustic resonance (for example, 15th line etc. of the upper left column of 2nd page of Unexamined-Japanese-Patent No. 63-285899) Reference).

Acoustic resonance occurs under the condition that the following expression (1) is satisfied. In addition, fa shown by following formula (1) is an acoustic resonance frequency, m is a constant, V is sound speed (m / s), and AL is the distance between electrodes (unit: m).

fa = mv / (2AL)... (One)

Under conditions satisfying this formula (1), it is known that dense standing waves of gas molecules and ionizing ions are generated in the axial direction of the lamp (referred to as "acoustic resonance"), whereby color irregularities are generated.

In general, the sound velocity v in Formula (1) can be represented by specific heat ratio γ, density p (unit: kg / m ³ ), and pressure ρ (unit: N / m ² ) (see the following equation (2)). )

v = (y p / p) ^0.5 . (2)

Substituting (2) into (1), the following equation (3) is obtained.

fa = m (γp / ρ) ^0.5 / (2AL)... (3)

This acoustic resonance frequency fa depends on the vapor pressure, gas density, temperature, and the like of the encapsulated product.

In actual lamps, these values are not constant, and have a distribution largely dependent on lamp size (inner diameter, distance between electrodes, their ratio), lighting condition (input), and cooling condition (internal surface temperature, etc.) of the discharge tube. Therefore, it is necessary to obtain it experimentally strictly.

An object of the present invention is to suppress illuminance unevenness, and since this illuminance unevenness is also caused by acoustic resonance as described above, it is preferable to suppress acoustic resonance as well.

Therefore, the range where the normal lighting frequency f1 in this application does not satisfy said acoustic resonance frequency fa was experimentally calculated | required.

As a result, it turned out that the following conditions (4) are approximated. In addition, Hg shown in the condition (4) is a sealed mercury density (unit: mg / cm <^3> ), and AL is distance between electrodes (unit: m) similarly to the above.

f1 <(Hg / 30) ^-0.33 x 250 / AL... (4)

In the lighting device of FIG. 4, the switching between the signal A and the signal B is performed using the switching circuit SL including the timer circuit 5b and the logic circuits L1 to L4 for switching at a predetermined time. The means for switching the signal and the signal B is not limited to the timer circuit, and the description means may be used below.

FIG. 8: is a block diagram of the power supply part which concerns on 2nd Embodiment of this invention, and another structural example is demonstrated by the same figure. FIG.

The lighting device shown in Fig. 8 is provided with a plurality of illuminometers PS1, PS2, PS3, ... along the longitudinal direction of the high-pressure discharge lamp, and a comparison circuit 5e for comparing the measurement results by the illuminometer with each other; When the difference between the outputs is a predetermined value or more, a feedback control circuit 5f for switching the signal A and the signal B is provided.

That is, instead of the timer circuit 5b of FIG. 4, the comparison circuit 5e and the feedback control circuit 5f are provided, and the signal is fed by the feedback control circuit 5f based on the comparison result of the comparison circuit 5e. A and signal B are switching.

In FIG. 8, only the circuit which produces | generates the signal T which operates the driver circuit 4d differs, and the other structure is basically the same as that shown in FIG. 4, and only the difference with FIG. 4 is demonstrated below.

When the lamp is turned on, a plurality of illuminometers PS1, PS2, PS3, ... are provided so as to be located in the radial direction between the electrodes of the high-pressure discharge lamp 10 (hereinafter, three illuminometers PS1, PS2, PS3 are provided). It is explained as).

The plurality of illuminometers PS1, PS2, and PS3 measure the illuminance in the longitudinal direction of the high-pressure discharge lamp 10, and transmit the measurement result to the comparison circuit 5e. In the comparison circuit 5e, the measurement results by the illuminometers PS1, PS2, and PS3 are compared, and when a deviation of a certain value or more occurs in the measurement results, a switching signal D is sent to the feedback control circuit 5f. Ship.

The feedback control circuit 5f sends a signal for switching the lighting frequency to the driver circuit 5d when the illuminance distribution in the longitudinal direction of the high-pressure discharge lamp 10 deviates from the predetermined range. That is, the feedback control circuit 5f sets the signal E to L level, and the driver circuit 5d indicates that the drive signal X of the switching elements Q1 to Q4 of the full bridge inverter circuit is set when the signal E becomes L level. , The frequency of Y is switched from the normal lighting frequency f1 to f2.

As a result, when the deviation of the measurement result of the illuminometer is eliminated, the comparison circuit 5e stops sending the switching signal D, and the feedback control circuit 5f sets the signal E to H level. When this signal E becomes H level, the driver circuit 5d returns the frequencies of the drive signals X and Y of the switching elements Q1 to Q4 of the full bridge inverter circuit to the normal lighting frequency f1.

The predetermined range referred to here is a range in which uniformity of allowable illuminance distribution is maintained by the irradiated object irradiated with ultraviolet rays from the high-pressure discharge lamp 10, and the uniformity of the allowable illuminance distribution can be maintained, for example A roughness distribution of ± 10%.

The internal structure of the driver circuit is basically the same as that shown in FIG. 5, and the operation thereof is as shown in FIG. 7, and the signal E is input to the terminal to which the signal T is input in FIG. 5.

The difference between the first embodiment and the present embodiment is that the timing at which the switching from the normal lighting frequency f1 to f2 is every predetermined time in the first embodiment, while in the present embodiment is a deviation from the predetermined illuminance distribution. Other actions and effects are common.

In order to confirm the effect of this invention, the following experiment was done.

(1) Experimental Example 1

The structure of the light irradiation apparatus used for an experiment is shown to FIG. 9 (a). It has the same structure as the light irradiation apparatus shown in the said FIG. 1, The specification is as follows.

Discharge tube (light emitting tube): inner diameter 5.4 mm outer diameter 9 mm

Appearance: Inner diameter 9.15mm Outer diameter 12mm

Interelectrode distance: 500 mm

· Inclusion

Mercury density 5mg / cm ³

Flow rate of coolant flowing between the water cooling jacket and the exterior: 20 L / min

The lighting condition of the high-pressure discharge lamp used in the experiment is to input the signal of the frequency f1 and f2 as the input of the normal lighting frequency f1 for 1 second, and then input the low frequency f2 for one cycle (one cycle at ON-OFF of the frequency f1). Entered alternately. In other words, the normal lighting frequency f1 is 1 second → the low frequency f2 is 1 cycle → the normal lighting frequency f1 is 1 second →... (Hereafter the same).

The lighting frequency is as follows.

Normal lighting frequency f1: 100, 500, 800, 1000 Hz

Low frequency f2: 3, 5, 10, 30, 50, 100, 150, 200, 300, 500 Hz

A plurality of illuminometers are arranged outside the radial direction between the electrodes of the high-pressure discharge lamp used for the experiment through the cooling jacket. These several illuminometers are arrange | positioned along the longitudinal direction of a high pressure discharge lamp, and measure the illuminance distribution in the longitudinal direction.

This illuminometer was arranged at intervals of 10 mm from the position 5 cm away from the tip of the electrode in the axial direction toward the longitudinal direction of the high-pressure discharge lamp.

Then, the illuminometer measures the illuminance up to 5 cm of the electrode facing each 1 cm in the axial direction from the position of 5 cm from the electrode tip. As shown in Fig. 9B, the average value is obtained from the illuminance measured from each illuminometer. It calculated | required and observed the difference (that is, roughness nonuniformity) of the average value and each roughness.

The results of the observation are summarized in Table 1. In Table 1, when there is a deviation of at least 15% or more from the average value, it is set as X, when the deviation is between 10% and 15% at maximum, and when it is deviation between at most 5% and 10%, it is set as 5 and at most 5 When deviation was less than%, it was set as (circle).

As shown in Table 1, when the low frequency f2 is 30% or less of the normal lighting frequency f1, the effect of suppressing the unevenness in illuminance can be obtained.

However, when the low frequency f2 was 3 Hz, electrode deformation occurred. This is considered to be a deformation of the electrode which unilaterally collided with electrons because the period in which the current flowed from one electrode to the other electrode, that is, the DC lighting period was long. For this reason, as a preferable range of low frequency f2, it becomes 5 <= f2 <= 0.3f1.

In addition, in Table 1, although the normal lighting frequency f1 is all (triangle | delta) in 1000 Hz, it shows that illuminance unevenness may be suppressed in the range where the normal lighting frequency f1 is 800 Hz or less. This corresponds to f1 <(Hg / 30) ^-0.33 x 250 / AL in the formula (4), in which the range of f1: 80 Hz or less is a condition for suppressing acoustic resonance, as described above. It turns out that the roughness nonuniformity by was able to be suppressed.

(2) Experimental Example 2

The light emission length (interelectrode distance) of the lamp was changed to 1000 mm, and the experiment was performed under the same conditions as in Experimental Example 1. The lamp specifications are as follows.

Discharge tube (light emitting tube): inner diameter 5.4 mm outer diameter 9 mm

Appearance: Inner diameter 9.15mm Outer diameter 12mm

Emission length (distance between electrodes): 1000 mm

· Inclusion

Mercury density 5mg / cm ³

Flow rate of cooling water flowing between the water cooling jacket and the exterior: 25 L / min

The results are shown in Table 2.

In this case, it can be seen that suppression of the unevenness of illuminance due to acoustic resonance functions between the frequencies f1 between 400 Hz and 500 Hz.

(3) Experimental Example 3

The inclusions of the lamp were changed, and the same experiment was conducted under the same conditions as in Experiment 1 using a metal halide lamp. The lamp specifications are as follows.

Discharge tube (light emitting tube): inner diameter 4.6mm outer diameter 10.3mm

Appearance: inner diameter 10.45mm outer diameter 13mm

Emission length (distance between electrodes): 500 mm

· Inclusion

Mercury Density ： 2.5mg / cm ³

Iron Iodide ： 0.45mg / cm ³

Thallium Iodide: 0.06mg / cm ³

Flow rate of coolant flowing between the water cooling jacket and the exterior: 20 L / min

The results are shown in Table 3.

In this case, it can be seen that the suppression of the uneven illuminance due to acoustic resonance is functioning between the frequency f1 between 1000 Hz and 1200 Hz. That is, compared with the addition amount of metal other than mercury, when the addition amount of mercury is large (about 5 times or more than other metals), f1 <(Hg / 30) ^-0.33 x 250 / AL of the above formula (4) can be applied. I can see.

Moreover, it was confirmed from the experiment result of said (2)-(3) that the formula of 5 <= f2 <= 0.3f1 which is a preferable range of the low frequency f2 obtained by the experiment example 1 is applicable also to other lamp | ramp.

BRIEF DESCRIPTION OF THE DRAWINGS It is sectional drawing which shows the outline of the structure of the light irradiation apparatus which concerns on embodiment of this invention.

FIG. 2 is a cross-sectional view taken along the line A-A in FIG. 1.

3 is a cross-sectional view showing an outline of the configuration of the high-pressure discharge lamp according to the embodiment of the present invention.

4 is a configuration diagram showing details of a power supply unit according to the first embodiment of the present invention.

FIG. 5 is a detailed view of a driver circuit of the control unit shown in FIG. 4.

6 is a flowchart showing the operation of the control unit.

7 is a timing chart for explaining the operation of the controller.

8 is a configuration diagram of a power supply unit according to the second embodiment of the present invention.

9 is a diagram showing the configuration, the measurement position and the illuminance of the light irradiation apparatus used in the experiment.

10 is a diagram illustrating a configuration of a light source according to the related art.

It is a figure which shows the structure of the conventional light irradiation apparatus.

It is a figure which shows the discharge tube and external appearance of the light irradiation apparatus shown in FIG.

<Code description>

1: Feeding part 2: Boosting rectifier circuit

2a: ac power 2b: control circuit

3: full bridge inverter circuit 4: starter circuit

5: control unit 5a: basic frequency oscillator circuit

5c: low frequency oscillation circuit 5b: timer circuit

5d: driver circuit 5e: comparison circuit

5f: feedback control circuit 10: high pressure discharge lamp

11: discharge tube 12: inner tube

13: seal part 16: electrode

17 metal foil 18 external lead

20: appearance 60: cooling jacket

61: cooling water supply flow path forming member

62: cooling water discharge flow path forming member

63, 64: blocking portion 65: cooling water flow path

70: reflector 75: mask stage

76: work stage 77: work

T1: step-up transformer D1: diode

C1: smoothing capacitor C2: condenser

LL1: Coil LL3: Coil

S1: switching element SL: switching circuit

DD1: delay circuit PS1, PS2, PS3: illuminometer

W: Coolant M: Mask

Q1 to Q4: Switching elements L1 to L8: Logic circuit

Claims (4)

Both ends are sealed, and a pair of electrodes are opposed to each other, and at least a whole discharge tube formed of a metal is sealed, and the discharge tube is provided outside the discharge tube, and the discharge tube and the average gap are close to 100 μm or less. A high-pressure discharge lamp having an appearance made of arranged glass, A flow path forming member which is provided to extend along the tube axis of the high pressure discharge lamp and forms a flow path through which the coolant flows between the appearance of the high pressure discharge lamp; A lighting device comprising a feeding part electrically connected to the pair of electrodes and feeding the high-pressure discharge lamp, The feed section, Signal generating means for generating a first signal having a normal lighting frequency f1 for turning on the high-pressure discharge lamp and a second signal having a frequency f2 lower than the normal lighting frequency f1 for canceling the uneven illuminance of the high-pressure discharge lamp; and, Switching means for selectively outputting the first signal or the second signal; And an inverter circuit which is driven by the first signal or the second signal and supplies an alternating voltage of frequency f1 or frequency f2 to the high-pressure discharge lamp. The method according to claim 1, The switching means has a timer means, and by the timer means, the frequency of the alternating voltage supplied to the high-pressure discharge lamp after the first predetermined time after the start of supplying the alternating voltage of frequency f1 to the discharge lamp is determined from f1 to f2. And the AC voltage of the frequency f2 is supplied to the high-pressure discharge lamp for a second predetermined time. The method according to claim 1 or 2, A relationship between the normal lighting frequency f1 [Hz] and the frequency f2 [Hz] is f2 ≦ 0.3 f1. The method according to claim 1 or 2, Mercury is contained in the metal encapsulated in the discharge tube, The normal lighting frequency f1 [Hz] is when the mercury density [mg / cm ³ ] enclosed in the discharge tube is Hg, and the inter-electrode distance [m] is AL, f1 <(Hg / 30) ^-0.33 x 250 It is / AL, The lighting device characterized by the above-mentioned.

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