JP2010277707A - Lamp device for illumination - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize improvement of lamp life through restraint of deterioration of illuminance even in case a bright spot of an arc column of a high-pressure discharge lamp generated in lapse of time moves. <P>SOLUTION: Light emitted from the high-pressure discharge lamp 11 starting with generation of high-voltage startup pulse is made reflected at a first focus F1 through a reflector 17, and, with a second focus F2 converging the light reflected from the reflector 17 as a converging face, the converged light is guided from an irradiation face on a converging face of optical fiber 26. The high-pressure discharge lamp 11 is enabled to adjust positional relations with the reflector 17 by adjusting a horizontal direction with screws h1, h2, a vertical direction with screws v1, v2, and an axis direction with an adjustment lever 191, respectively. With this, the bright spot of the arc column of the high-pressure discharge lamp 11 can be adjusted to an optimal position of the first focus F1. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention uses a high-pressure discharge lamp that requires a high-voltage start-up pulse at start-up as a light source, makes light from the discharge lamp enter from the incident end of the photoconductive element, and obtains spot illumination from the output end of the photoconductive element The present invention relates to a lamp device.

  Conventionally, an illumination lamp device used as spot illumination has a glass rod connected to an incident end portion to which a cap portion is attached, and discharges light from an incident end portion of an optical fiber that protrudes a part of the glass rod from the cap portion. Incident light is obtained so that spot illumination can be obtained from the exit end of the optical fiber. (For example, Patent Document 1)

JP 2002-75046 A

  The technique of Patent Document 1 described above realizes an illumination light source device using a plastic optical fiber that can easily increase the amount of incident light while preventing melting at the incident end.

  However, a high-pressure discharge lamp is generally used as the light source supplied to this type of optical fiber. The high-pressure discharge lamp is different from the manufacturing time due to the movement of the bright spot of the arc column due to the change with time after the manufacturing. For this reason, in addition to the problem that the luminous flux from the high-pressure discharge lamp to the incident end of the optical fiber is reduced, the illumination intensity is reduced. There was a problem that the temperature at the incident end rose and the optical fiber melted.

  An object of the present invention is to provide an illumination lamp device capable of suppressing the decrease in illuminance and improving the life even when the bright spot of the arc column of the high-pressure discharge lamp generated with the passage of time moves. It is in.

  In order to solve the above-described problems, an illumination lamp device according to the present invention reflects light emitted from a high-pressure discharge lamp that is started by generating a high-voltage start pulse through a reflector as a first focus, In the illumination lamp device, wherein the second focal point for condensing the light reflected from the reflector is a condensing surface, and the condensed light is irradiated from the exit surface to the condensing surface of the photoconductive element. The discharge lamp is characterized in that the positional relationship between the bright spot of the arc column of the high-pressure discharge lamp and the reflector can be adjusted.

  According to the present invention, even when a bright spot (bright column) moves due to a change with time after manufacture, the change in illuminance can be suppressed and the life of the lamp can be improved.

It is a disassembled perspective view for demonstrating one Embodiment regarding the lamp device for illumination of this invention. It is sectional drawing along the Ia-Ib line | wire of FIG. It is sectional drawing of the principal part of FIG. It is a partially cutaway perspective view of the principal part of FIG. It is the IIa-IIb sectional view taken on the line of FIG. It is a circuit block diagram for demonstrating an example of the lighting circuit used for the lamp device for illumination of this invention. It is explanatory drawing for demonstrating the arc column shape which changes with a time-dependent change. FIG. 4 is a sectional view showing only the main part corresponding to FIG. 3 for explaining the operation of the present invention. It is sectional drawing of the state rotated 90 degree | times centering on the O-axis of FIG. 8 for demonstrating operation | movement of this invention.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.

  1 to 5 are diagrams illustrating an embodiment of the illumination lamp device according to the present invention. FIG. 1 is an exploded perspective view of a main part, FIG. 2 is a cross-sectional view taken along line Ia-Ib of FIG. 3 is a cross-sectional view of the main part of FIG. 2, FIG. 4 is a partially cutaway perspective view of the main part of FIG. 1, and FIG. 5 is a cross-sectional view taken along the line IIa-IIb of FIG.

  The illumination lamp device 100 shown in FIGS. 1 and 2 is a spot illumination device, and this illumination lamp device 100 spot-irradiates illumination light to an irradiation target through a light guide 200 externally connected to the housing 12, for example. Is.

  In the illumination lamp device 100, for example, at least a metal halide and a rare gas are sealed in a discharge vessel that requires a high-voltage start pulse at the start, and the high-pressure discharge lamp 11 is supplied from a high-pressure discharge lamp 11 and an external AC power supply. And a lighting circuit interposed on the power supply path up to the above, and these are housed in the housing 12 to constitute a main part.

  The interior of the housing 12 is partitioned into two upper and lower chambers by a partition wall. A space defined on the upper side of the housing 12 is configured as a lamp chamber 13, and a space defined on the lower side is configured as a circuit chamber 14.

  In addition, a work opening 15 that opens the lamp chamber 13 to the outside is opened at the top of the housing 12, and a lid 16 that opens and closes the work opening 15 is fitted in and removed from the work opening 15. Fits freely. For example, as shown in FIG. 1, the work opening 15 opens a predetermined region from the upper surface of the housing 12 to the left and right side surfaces, and a step 151 is formed around the edge of the work opening 15. It is installed. The lid 16 closes the work opening 15 by fitting the inner surface of the lid 16 to the step portion 151.

  A high pressure discharge lamp 11 is accommodated in the lamp chamber 13. The high-pressure discharge lamp 11 is previously modularized integrally with the reflector 17 and the socket 18 outside the lamp chamber 13 to constitute a light source module 150. The high pressure discharge lamp 11 is housed in the lamp chamber 13 through the work opening 15 in the state of the light source module 150, and is held in the lamp chamber 13 through the light source holder 20.

  The reflector 17 is configured by, for example, an elliptical reflector having a reflective concave surface 171 that forms a partial shape of a rotating ellipse. A bulb insertion hole 173 is opened in the base 172 of the reflector 17, and the distal end side of the high-pressure discharge lamp 11 is inserted into the bulb insertion hole 173. Further, a socket 18 can be fitted to the base 172 of the reflector 17, and by this fitting, the socket 18 is electrically connected to the high-pressure discharge lamp 11, and the high-pressure discharge lamp 11 is connected to the reflector 17. Hold.

  At this time, the light emitting portion 112 of the high-pressure discharge lamp 11 faces the inside of the reflective concave surface 171 and is positioned at the first focal point F1 of the reflective concave surface 171 as shown in FIG. Thereby, the reflector 17 reflects the light emitted from the light emitting unit 112 of the high-pressure discharge lamp 11 by the reflecting concave surface 171 and condenses it at the second focal point F2.

  As shown in FIG. 5, the base portion 172 is formed with adjustment screws h1 and h2 for entering and exiting the valve insertion hole 173 in the horizontal direction and adjustment screws v1 and v2 for entering and exiting the valve insertion hole 173 in the vertical direction. The When the screws h1 and h2 are put in and out, the sealing portion 111 of one electrode of the high-pressure discharge lamp 11 is moved in the horizontal direction, and the first focus F1 can be moved in the horizontal direction by this movement. In addition, when the screws v1 and v2 are inserted and removed, the sealing portion 111 of one electrode of the high-pressure discharge lamp 11 is moved in the vertical direction, and the first focus F1 can be moved in the vertical direction. The relationship between the insertion and removal of the screws h1 and h2 is such that when one is inserted, the other is removed. This also applies to the screws v1 and v2.

  The sealing part 111 of the high-pressure discharge lamp 11 is attached with a base 19 having a screw s1 formed on the outer periphery, and the screw s1 and a screw s2 formed in a part of the bulb insertion hole 173 are screwed together. 19 and the reflector 17 are combined. The screws s 1 and s 2 can move in the axial direction of the high-pressure discharge lamp 11 by rotating an adjustment lever 191 attached to the outer peripheral surface of the base 19.

  The light source holding unit 20 includes, for example, a spacer 21 fixed on the front end side in the lamp chamber 13 and a support unit 23 slidably attached to a chassis 22 in the lamp chamber 13.

  The spacer 21 positions the light source module 150 coaxially with the light guide insertion hole 24 opened at the front end surface of the housing 12, prevents light leakage, and prevents scattering of glass dust due to breakage of the discharge lamp 11. Is for. A stepped portion 211 that can be fitted to the distal end portion of the reflector 17 is provided around the base end portion of the spacer 21. Further, on the inner peripheral side of the step portion 211, a light shielding surface 212 for shielding stray light emitted without being properly collected by the reflector 17 is recessed, and further, at the bottom of the light shielding surface 212, A light guide hole 213 communicating with the light guide insertion hole 24 is opened.

  When the reflector 17 is properly fitted to the step portion 211, the spacer 21 aligns the optical axis O with the optical axis of the light guide insertion hole 24 and the light guide 200 inserted into the light guide insertion hole 24. The reflector 17 is positioned at a position where the second focal point F2 coincides with the condensing surface 264.

  The support portion 23 is, for example, configured with a cylindrical holder 231 that supports the light source module 150 and a piston 232 that is slidably accommodated in the chassis 22 and is disposed coaxially with the light guide insertion hole 24. A spring 25 is interposed between the holder 231 and the chassis 22, and the holder 231 is urged toward the spacer 21 by the spring 25. The holder 231 is advanced to a position where the light source module 150 can be held (clamped) with the spacer 21.

  As shown in FIG. 3, an incident side of a light guide 200 for irradiating the light emitted from the high-pressure discharge lamp 11 to the outside is inserted into the light guide insertion hole 24. The light guide 200 includes an optical fiber 26 that is a kind of photoconductive element and a base portion 27. The optical fiber 26 includes a glass core 261, a plastic core 262 optically connected to the glass core 261, and a clad 263 disposed integrally on the outer peripheral surface of the glass core 261 and the plastic core 262.

  The base 27 holds the portion of the clad 263 that straddles the glass core 261 and the plastic core 262 in such a shape that the condensing surface 264 of the glass core 261 is exposed. For example, a magnet attracting means is attached to the periphery of the glass core 261 of the base portion 27.

  In addition, for example, a magnet attracting means is attached to the casing 12 that is in the vicinity of the through hole formed concentrically with the light guide hole 213 of the spacer 21 and faces the magnet. This magnet and the magnet on the base portion 27 side are in an adsorbing relationship.

  In addition, any one of the magnet attached to the base part 27 and the magnet disposed to face the magnet may be a magnetic body. Further, a convex portion is formed on a part of the outer peripheral surface of the base portion 27, and a concave portion that can be engaged with the convex portion of the base portion 27 is formed on the inner peripheral surface of the light guide insertion hole 24. When the concave portion of the light guide insertion hole 24 is engaged, the condensing surface 264 of the optical fiber 26 is formed so as to be positioned at the second focal point F2, so that the workability of attaching the optical fiber 26 can be improved.

  Therefore, after the base portion 27 of the light guide 200 is inserted into the light guide insertion hole 24, the light condensing surface 264 of the light guide 200 is reliably condensed at the second focal point F2 by the mutual attractive force of the magnets. Thereby, the light emitted from the light emitting unit 112 of the high-pressure discharge lamp 11 is reliably and efficiently incident on the light guide 200.

  Further, a lighting circuit 141 is accommodated in the circuit chamber 14. As shown in FIG. 6, the lighting circuit 141 is supplied with power from the external power source 61 and generates an igniter circuit 62 that generates a high-voltage start pulse when the high-pressure discharge lamp 11 is started. And a ballast circuit 63 for maintaining a stable lighting state (after lighting). The lighting circuit 141 is connected to the external power supply 61 via the interlock switch 64 and is connected to the high-pressure discharge lamp 11 via a connector 66 interposed on the power supply path 65.

  The interlock switch 64 is a normally open push type switch having a push button 641 at the top. The interlock switch 64 is fixed on the partition wall 131 at a position where the push button 641 faces the work opening 15 in the vicinity of the side wall 121 of the housing 12. The interlock switch 64 is turned on when the push button 641 is pressed, and electrically connects the external power supply 61 side and the lighting circuit 141 side. On the other hand, the interlock switch 64 is turned off when the push button 641 is released and cuts off the electrical connection between the external power supply 61 side and the lighting circuit 141 side.

  The connector 66 is disposed in the lamp chamber 13. The connector 66 includes a fixed-side connector portion 661 fixed in the lamp chamber 13 and a movable-side connector portion 662 that can be fitted into and removed from the fixed-side connector portion 661. The fixed connector portion 661 is electrically connected to the lighting circuit 141 side. The movable connector portion 662 is electrically connected to the high-pressure discharge lamp 11 side via the socket 18. The high-pressure discharge lamp 11 is electrically connected to the lighting circuit 141 by fitting the movable connector portion 662 to the fixed connector portion 661.

  Thereby, when the cover body 16 is removed and the work opening 15 is opened, the push button 641 is not pressed, and the interlock switch 64 is maintained in the off state. Therefore, even when the user performs replacement work of the high-pressure discharge lamp 11 or the like, the electrical connection between the external power supply 61 side and the lighting circuit 141 side is cut off.

  In this way, the condensing surface of the light guide can be reliably held at the second focal point F2 by the attractive force between the magnets, and the light generated by the high-pressure discharge lamp is supplied to the incident end of the optical fiber. be able to.

  Hereinafter, an adjustment example of a defect that also causes the movement of the bright spot of the arc column that has changed due to a change with time of the above-described lighting lamp device will be described with reference to FIGS. 7 is an explanatory diagram for explaining the arc column shape that changes with time, FIG. 8 is a cross-sectional view showing only the main part corresponding to FIG. 3, and FIG. 9 is centered on the O-axis of FIG. It is sectional drawing which showed the state rotated 90 degree | times right.

  First, FIG. 7A shows arc columns generated in the electrodes 721 and 722 when the electrodes 721 and 722 opposed to each other in the discharge vessel 71 are energized under the initial state of the high-pressure discharge lamp 11. The arc column shape 74 in lighting in the initial state is a long and thin linear shape with an intermediate portion swelled between the electrode 721 and the electrode 722. As a result, the first focal point F <b> 1 that is reflected by the reflector 17 and serves as a base point of the second focal point F <b> 2 that is also a condensing surface of the optical fiber is located at the center of the intermediate portion of the arc column shape 74.

  Since the high-pressure discharge lamp 11 uses a halogen cycle, the sublimated tungsten adheres again to the tip of the electrode, and as shown in FIG. 7B, a protrusion 75 is formed in the middle of the tip of one of the electrodes 722, for example. Is done. This protrusion 75 becomes the starting point of the arc column, and the arc is formed at the center of the electrode, and the arc column is slightly deviated from the first focal point F1. As a result, the light flux at the second focal point F2 collected through the reflector is reduced, and the light irradiated from the optical fiber is also darkened.

  Further, as shown in FIG. 7C, in addition to the protrusion 75 formed on the electrode 722, the first focal point F1 in the arc column shape when the protrusion 76 due to the adhesion of tungsten is also formed on the electrode 721 side. The position will be almost out of the arc column. The decrease in the luminous flux at the second focal point F2 becomes remarkable, and the irradiation light from the optical fiber becomes darker and is not practically used as the high-pressure discharge lamp 11, and needs to be replaced.

  Therefore, the arc columns in FIGS. 7B and 7C are shown in the case where the bright spot of the arc column is shifted from the first focal point F1 in the vertical direction with the high pressure discharge lamp 11 attached. The horizontal direction adjusting screws v1 and v2 shown in FIG. 8 are adjusted, and the high-pressure discharge lamp 11 is moved in the direction of the arrow H or L in the drawing so that the bright spot of the arc column comes to the position of the first focal point F1. .

  The arc column in FIGS. 7B and 7C is shown in FIG. 9 when the bright spot of the arc is shifted in the horizontal direction from the first focus F1 with the high-pressure discharge lamp 11 mounted. The vertical adjustment screws h1 and h2 are adjusted, and the high-pressure discharge lamp 11 is moved in the direction of the arrow L or R in the drawing so that the bright spot of the arc column comes to the position of the first focal point F1.

  In addition, when the bright spot of the arc column is in any of the axial directions of the electrodes 721 and 722, by rotating the adjustment lever 191, the high-pressure discharge lamp 11 is moved in the direction of entering and exiting the bulb insertion hole 173, Adjustment is made so that the bright spot of the arc column comes to the position of the first focus F1.

  As described above, when the bright spot of the arc column shifts from the position of the first focal point F1 with the time-dependent change of the high pressure discharge lamp, the three-dimensional adjustment of the light emitting portion of the high pressure discharge lamp 11 is enabled. It is possible to move to the original position of the first focus F1. For this reason, even when the luminescent spot of the arc column deviates from the first focal point F1, the adjustment to the optimum position is possible, which contributes to the improvement of the life of the high-pressure discharge lamp.

  Further, when the positions of the first focal point F1 and the second focal point F2 are shifted and the light of the high-pressure discharge lamp is irradiated to other than the core of the optical fiber, the arc column bright spot of the high-pressure discharge lamp is adjusted to dissolve the optical fiber. Can also be prevented.

  The present invention is not limited to the above-described embodiment. For example, the photoconductive element is exemplified by an optical fiber, but may be a lens. In addition, the positional relationship between the high pressure discharge lamp and the reflector whose arc column bright spot has moved over time is adjusted by manual adjustment of the horizontal, vertical and axial directions of the high pressure discharge lamp with respect to the reflector. It is also possible to automatically adjust the horizontal, vertical, and axial directions so that the illuminance change of the emitted light from the point or photoconductive element is detected and the illuminance of the emitted light is optimized.

DESCRIPTION OF SYMBOLS 100 High pressure discharge lamp apparatus 150 Light source module 200 Light guide 11 High pressure discharge lamp 111 Sealing part 112 Light emission part 12 Case 17 Reflector 171 Reflection concave surface 172 Base 173 Valve insertion hole 18 Socket F1 First focus F2 Second focus 19 Base 191 Adjustment Lever 20 Light source holding part 21 Spacer 213 Light guide hole 22 Chassis 23 Support part 231 Holder 24 Light guide insertion hole 26 Optical fiber 261 Glass core 262 Plastic core 263 Cladding 264 Condensing surface 27 Base part v1, v2, h1, h2, s1, s2 Screw 71 Discharge vessel 721, 722 Electrode 74 Arc column shape 75, 76 Projection

Claims (5)

The light emitted from the high-pressure discharge lamp that is started by generating a high-voltage start pulse is reflected through the reflector as the first focal point, and the second focal point that condenses the light reflected from the reflector is the condensing surface. In the illumination lamp device that irradiates the condensed light from the exit surface to the condensing surface of the photoconductive element,
The high pressure discharge lamp is an illumination lamp device characterized in that a positional relationship between a bright spot of an arc column of the high pressure discharge lamp and the reflector can be adjusted.   2. The illumination lamp device according to claim 1, wherein the high-pressure discharge lamp has at least a metal halide and a rare gas sealed in a discharge vessel that requires a high-voltage start pulse at the time of start-up.   3. The illumination lamp device according to claim 1, wherein the high-pressure discharge lamp can be adjusted in three-dimensional directions with respect to the reflector.   The adjustment of the high pressure discharge lamp is performed by changing a reflection direction of the reflector that reflects light emitted from the high pressure discharge lamp based on a change in an arc column shape of the high pressure discharge lamp. Item 2. An illumination lamp device according to Item 1.   The illumination lamp device according to claim 1, wherein the photoconductive element is an optical fiber or a lens.

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