JP5460161B2 - Irradiation apparatus or discharge lamp holding method thereof - Google Patents

Description

  The present invention relates to holding a discharge lamp, and more particularly to simplification of installation work.

Conventionally, a short arc mercury lamp has been attached as follows. In the case of the vertical holding type, the base provided at the end of the lamp is fixed to the mounting portion of the machine. Thereafter, in order to match the focal position of the mirror, the lamp is moved together with the mounting portion to perform positioning in the x, y, and z directions.
Patent Document 1 discloses a mechanism for easily performing such positioning.

JP 2004-185999 A

  However, even in the method disclosed in Patent Document 1, the positioning in the x, y, and z directions is necessary every time the lamp is replaced.

  An object of the present invention is to solve the above problems and provide an irradiation apparatus or a discharge lamp holding method that does not require positioning in the x, y, and z directions each time a lamp is replaced.

(1) An irradiation system according to the present invention is an irradiation system including a discharge lamp having a tapered solid taper-shaped base, and an irradiation device having a holding mechanism for holding the discharge lamp when the discharge lamp is inserted. The holding mechanism is a hollow member whose inner wall has a shape matching the tapered solid taper shape of the base, and a holding member for holding the hollow member, the hollow member being in a direction perpendicular to the axial direction of the discharge lamp. Has a holding member that can move in the axial direction without moving, and the base is provided with a positioning portion that positions the discharge lamp in the axial direction with respect to the irradiation device. And urging means for urging the hollow member toward the discharge lamp.
Therefore, when the discharge lamp is inserted into the hollow member, the tapered solid taper shape of the base matches the hollow member. As a result, positioning in the direction orthogonal to the axial direction of the discharge lamp is performed. The holding member holds the hollow member so as to be movable in the axial direction without moving in the direction orthogonal to the axial direction. Therefore, when the discharge lamp is further inserted against the biasing means from this state, the positioning in the orthogonal direction is performed by the positioning portion while the positioning in the orthogonal direction is performed. That is, even if there is a slight deviation in the size of the tapered solid taper shape, it can be absorbed by the movement of the hollow member, so that the axial direction and the direction perpendicular to the axial direction can be positioned with respect to the base. It becomes.

  (2) The irradiation device according to the present invention is an irradiation device having a holding mechanism for holding a discharge lamp having a tapered solid taper-shaped base when the discharge lamp is inserted, wherein the holding mechanism has an inner wall formed by the base. A hollow member having a shape that matches the tapered solid taper shape, and a holding member that holds the hollow member, the axial direction without moving the hollow member in a direction perpendicular to the axial direction of the discharge lamp And a holding member that is movably held.

  Therefore, when the discharge lamp is inserted into the hollow member, the tapered solid taper shape of the base matches the hollow member. As a result, positioning in the direction orthogonal to the axial direction of the discharge lamp is performed. The holding member holds the hollow member so as to be movable in the axial direction without moving in the direction orthogonal to the axial direction. When the discharge lamp is further inserted, positioning in the axial direction is performed by the positioning portion while positioning in the orthogonal direction is performed. That is, even if there is a slight deviation in the size of the tapered solid taper shape, it can be absorbed by the movement of the hollow member, so that the axial direction and the direction perpendicular to the axial direction can be positioned with respect to the base. It becomes.

  (3) A discharge lamp according to the present invention is a discharge lamp having a tapered solid taper-shaped base inserted into an irradiation device, and the base is positioned in the axial direction of the discharge lamp with respect to the irradiation device. A positioning part is provided.

  Therefore, when the discharge lamp is inserted into the irradiation device, the tapered solid taper shape of the base matches the hollow member. As a result, positioning in the direction orthogonal to the axial direction of the discharge lamp is performed. Further, since the holding member holds the hollow member so as to be movable in the axial direction without moving in the direction orthogonal to the axial direction, the positioning portion remains positioned in the orthogonal direction. Thus, the positioning in the axial direction is performed. That is, even if there is a slight deviation in the size of the tapered solid taper shape, it can be absorbed by the movement of the hollow member, so that the axial direction and the direction perpendicular to the axial direction can be positioned with respect to the base. It becomes.

  (4) The discharge lamp holding method according to the present invention is such that the discharge lamp base has a tapered solid taper shape, and when the discharge lamp base is inserted by the holding mechanism of the irradiation device, the discharge in the irradiation device that holds the discharge lamp base In the lamp holding method, as the holding mechanism, a hollow member whose inner wall has a shape that matches the tapered solid taper shape of the base is a holding member located on the outer side, and the hollow member is in the axial direction of the discharge lamp. The hollow member is urged toward the discharge lamp side without being moved in a direction orthogonal to the axial direction, and the tapered solid tapered base is inserted into the holding mechanism. If the hollow member is further inserted in a state of being aligned with the inner wall of the hollow member, the hollow member moves in the axial direction to position the discharge lamp in the axial direction. Part is to enable axial positioning in contact with the holding mechanism.

  Therefore, when the discharge lamp is inserted into the hollow member, the tapered solid taper shape of the base matches the hollow member. As a result, positioning in the direction orthogonal to the axial direction of the discharge lamp is performed. The holding member holds the hollow member so as to be movable in the axial direction without moving in the direction orthogonal to the axial direction. When the discharge lamp is further inserted, positioning in the axial direction is performed by the positioning portion while positioning in the orthogonal direction is performed. That is, even if there is a slight deviation in the size of the tapered solid taper shape, it can be absorbed by the movement of the hollow member, so that the axial direction and the direction perpendicular to the axial direction can be positioned with respect to the base. It becomes.

It is an external view of the irradiation system 1 concerning this invention. FIG. 3 is a diagram showing a base shape in the discharge lamp 10. It is a figure which shows the holding mechanism of the irradiation apparatus. It is a figure explaining holding | maintenance of the irradiation system. It is a figure explaining holding | maintenance of the irradiation system. It is a figure explaining holding | maintenance of the irradiation system.

DESCRIPTION OF SYMBOLS 1 Irradiation system 10 Discharge lamp 11 Base 12 Tapered part 13 Flange 15 Tip part 17 Groove 20 Holding mechanism 21 Outer cylinder 22 Inner cylinder
22a Inner wall 22b Taper hole 23 Upper lid 27 Electrode extraction part 31 Spring 32 Lower lid 32a Ball plunger 33 Through hole 34 Support part 35 Extrusion part 36 Bar 37 Handle

In FIG. 1, the external view of the irradiation system 1 by one Embodiment of this invention is shown. The irradiation system 1 includes a discharge lamp 10 and a holding mechanism 20.
The configuration of the discharge lamp 10 will be described with reference to FIG. The base 11 of the discharge lamp 10 has a metal taper portion 12, a tip portion 15, and a flange 13. The taper portion 12 has a tapered solid taper shape that decreases in diameter toward the tip. A groove 17 that engages with a ball plunger described later is formed in the distal end portion 15.

  In the discharge lamp 10, the base 11 is fixed to the lamp housing so that the axial center connecting the cathode and anode of the lamp and the axial center of the tapered solid taper shape of the base 11 coincide. Further, the axial publication is positioned so that the tip of the cathode is at a predetermined position at the position where the flange 13 is in contact with the upper lid of the holding mechanism 20. Therefore, if the base 11 is held at a predetermined position, positioning in an axial direction (z direction) with respect to an elliptical mirror (not shown) to which the holding mechanism 20 is fixed and a plane (xy plane) perpendicular thereto is possible. It becomes.

  The holding mechanism 20 will be described with reference to FIG. The holding mechanism 20 holds the base 11 of the discharge lamp 10 shown in FIG. At that time, the inner cylinder 22 which is a double structure is slid in the direction of the arrow α so as to be able to absorb the dimensional deviation in the tapered portion 12 of the discharge lamp 10. Details will be described below.

  As shown in FIG. 3, the holding mechanism 20 has an outer cylinder 21 in which an inner cylinder 22 is built. The inner wall 22 a of the inner cylinder 22 is configured with the same taper angle so as to be fitted to the tapered portion 12 of the discharge lamp 10. In the present embodiment, the taper angle θ is 2.8 degrees, but the present invention is not limited to this.

  The outer cylinder 21 has a substantially cylindrical shape, and a flange surface for attaching to the irradiation device is formed in part. As the shape of the inner cylinder 22, the outer wall in contact with the outer cylinder 21 is a cylindrical shape, and the inner wall has a tapered solid taper shape whose diameter decreases toward the tip.

  The inner cylinder 22 is held by the outer cylinder 21 so as to be movable in parallel with the arrow α direction while being covered with the upper lid 23 and the lower lid 32. A spring 31 is provided as a biasing means between the lower lid 32 and the inner cylinder 22 and biases the inner cylinder 22 toward the upper lid 23. The upper lid 23 is screwed to the outer cylinder 21 by screws 23b and the lower lid 32 is screwed by screws 33b (see FIGS. 3A and 3C).

  A part of the outer cylinder 21 is provided with a notch 21a. An electrode take-out portion 27 screwed to the inner cylinder 22 protrudes from the notch 21a.

  A through hole 33 is provided in the center of the lower lid 32. The lower lid 32 is provided with four ball plungers that engage with the grooves 17 provided at the tip 15 of the base 11. A support portion 34 is fixed to the lower lid 32, and a bar 36 is supported on the support portion 34. An extruding portion 35 is fixed to the bar 36, and when the handle 37 is moved in the direction of arrow β, the tip portion 15 of the base 11 inserted into the through hole 33 by the extruding portion 35 is moved to the direction of arrow α. It can be pushed out in the opposite direction.

  The usage method of the irradiation system 1 is demonstrated using FIGS. FIG. 4A shows a state in which the base 11 is located above the tapered hole 22b. From this state, as shown in FIG. 4B, when the base 11 is inserted into the tapered hole 22b, the side surface of the tip portion 15 comes into contact with the ball plunger 32a, and insertion in the direction of the arrow α temporarily stops. . In this state, the tapered portion 12 and the inner wall 22a of the inner cylinder 22 are not yet fitted.

  When the operator inserts the discharge lamp 10 in the direction of the arrow α against the pressing force of the ball plunger 32a, the tapered portion 12 and the inner wall 22a of the inner cylinder 22 are fitted as shown in FIG. 5A. Thereby, the base 11 is positioned with respect to the holding mechanism 20 in a plane (xy plane) perpendicular to the axial direction (z direction). In this state, since the flange 13 and the upper lid 23 are positioned in a state where a gap t is formed, positioning in the axial direction (z direction) is not performed.

  When the operator further inserts the discharge lamp 10 in the direction of the arrow α, the inner cylinder 22 slides in the direction of the arrow α with the tapered portion 12 and the inner wall 22a of the inner cylinder 22 fitted as shown in FIG. 5B. . Therefore, the flange 13 and the upper lid 23 come into contact with each other while being positioned on a plane (xy plane) perpendicular to the axial direction (z direction). Thereby, the positioning of the base 11 in the axial direction (z direction) is also completed. Further, the groove 17 of the base 11 is fitted with the ball plunger 32a. The ball plunger 32a maintains this state. This prevents the base 11 from moving in the direction opposite to the arrow α direction.

  As already described, the base 11 is fixed to the lamp housing so that the flange 13 is in contact with the upper lid 23 and positioned in the axial direction (z direction) as a lamp. Further, the base 11 is fixed to the lamp housing so that the axial center connecting the cathode and the anode of the lamp and the axial center of the tapered solid taper shape of the base 11 coincide. Therefore, when the base 11 is positioned in the xyz direction with respect to the holding mechanism 20, positioning in the x, y, and z directions is completed for the entire discharge lamp 20.

  To remove the discharge lamp 10 from the holding mechanism 20, the handle 37 is moved in the direction of arrow β as shown in FIG. As a result, the tip portion 15 of the base 11 inserted into the through-hole 33 is pushed out by the push-out portion 35 in the direction opposite to the arrow α direction.

  In the present embodiment, the inner cylinder 22 slides only in parallel with the axial direction (z direction). Therefore, even if the diameter of the taper portion 12 of the base 11 is slightly deviated, the taper 12 does not interfere when positioning in the z direction as long as it can be absorbed by sliding.

  In addition, the inner cylinder 22 that is in surface contact with the tapered portion 12 of the base 11 is made of metal, and the electrode take-out portion 27 is fixed to the inner cylinder 22 and is exposed to the outside of the outer cylinder 21. Electrical contact can also be made automatically.

  In the present embodiment, the inner cylinder 22 and the outer cylinder 21 are cylindrical and are configured to be slidable in the axial direction. However, one part of the inner cylinder 22 and the outer cylinder 21 is concave, and the other is convex at a position opposite to this. You may comprise by shape.

  In the present embodiment, the inner cylinder 22 that fits into the tapered shape of the base 11 is made of metal. However, not all of the inner tube 22 may be made of metal, but part of the inner tube 22 may be made of metal.

  In the present embodiment, a conical shape is adopted as the tapered solid taper shape. This may be a polygonal pyramid shape as long as the axial direction of the lamp is a tapered solid taper shape in which the cross-sectional area decreases toward the tip. Moreover, the shape which deleted a part of cone on the plane may be sufficient.

  In this embodiment, an ultra-high pressure mercury lamp is used as the discharge lamp. However, the present invention can be applied to other short arc type discharge lamps such as a xenon lamp instead of the mercury lamp.

Also, any discharge lamp that requires positioning in the x, y, and z directions to use an elliptical mirror is applicable.

Claims (3)

A discharge lamp having a tapered solid taper-shaped base,
When the discharge lamp is inserted, an irradiation device having a holding mechanism for holding the discharge lamp,
An irradiation system comprising:
The holding mechanism is
A hollow member whose inner wall has a shape that matches the tapered solid taper shape of the base;
A holding member for holding the hollow member, the holding member holding the hollow member movably in the axial direction without moving in the direction orthogonal to the axial direction of the discharge lamp;
Have
The base is provided with a positioning portion for positioning the discharge lamp in the axial direction with respect to the irradiation device,
E Bei biasing means for biasing said hollow member to the discharge lamp side,
The tapered solid taper-shaped base is inserted into the inner wall, and in a state where the tapered solid taper matches the inner wall of the hollow member, the tapered solid tapered shape of the base is arranged so that the positioning portion is not in contact with the holding mechanism, The tapered shape of the inner wall of the hollow member is related. From this state, when the base is further inserted into the holding member, the hollow member moves in the axial direction, and the axial positioning of the discharge lamp is performed. A positioning part configured to perform axial positioning by contacting with the holding mechanism;
Irradiation system characterized by When a discharge lamp having a tapered solid taper-shaped base is inserted, an irradiation device having a holding mechanism for holding the discharge lamp,
The base is provided with a positioning portion for positioning the discharge lamp in the axial direction with respect to the irradiation device,
The holding mechanism is
A hollow member whose inner wall has a shape that matches the tapered solid taper shape of the base;
A holding member for holding the hollow member, the holding member holding the hollow member movably in the axial direction without moving in the direction orthogonal to the axial direction of the discharge lamp;
Have,
When the tapered solid taper-shaped base is inserted into the inner wall and is aligned with the inner wall of the hollow member, the tapered solid tapered shape of the base and the hollow so that the positioning portion is not in contact with the holding mechanism. The taper shape of the inner wall of the member is related, and from this state, when the base is further inserted into the holding member, the hollow member moves in the axial direction, thereby positioning the discharge lamp in the axial direction. The positioning part to be configured to be in contact with the holding mechanism and capable of axial positioning;
Irradiation device characterized by. The discharge lamp base has a tapered solid taper shape, and when the discharge lamp base is inserted by a holding mechanism of the irradiation device, a discharge lamp holding method in the irradiation device for holding the discharge lamp,
As the holding mechanism, a hollow member whose inner wall has a shape that matches the tapered solid taper shape of the base is a holding member located on the outer side, and the hollow member is moved in a direction perpendicular to the axial direction of the discharge lamp. Without holding the movably in the axial direction, the hollow member is biased to the discharge lamp side,
Mouthpiece of the tapered solid tapered shape is inserted into the inner wall, in a state consistent with the inner wall of the hollow member, the positioning portion is a non-contact state with the holding mechanism, the non-contact state that written, it is further inserted If that, against the urging force, the hollow member to move in the axial direction, the positioning unit to position the axial direction of the discharge lamp, the positioning in the axial direction in contact with the holding mechanism That
A discharge lamp holding method characterized by the above.

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