JP3806579B2 - Endoscope light source device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an endoscope light source device for supplying illumination light to an endoscope.
[0002]
[Prior art]
Conventionally, an endoscope light source device is used to supply illumination light to an endoscope inserted into a body cavity. The xenon lamp of the endoscope light source device needs to be replaced with a new light source lamp after being used for several hundred hours, for example. Therefore, an ordinary endoscope light source device has a structure in which a light source lamp can be taken out from a lamp house and replaced with a new xenon lamp.
[0003]
A xenon lamp generally emits a large amount of light and generates a large amount of heat. Therefore, conductive heat sinks are respectively attached to the anode and cathode portions of the xenon lamp so that this heat is effectively dissipated. In order to supply lighting power to the xenon lamp, the xenon lamp is detachably connected to an electrode member connected to the power circuit for lighting the xenon lamp via each heat sink. Therefore, when replacing the xenon lamp, first remove the old xenon lamp attached to the heat sink, attach the new xenon lamp to the heat sink, and then install the lamp unit consisting of the xenon lamp and heat sink in the lamp house. It is necessary to electrically connect each heat sink to the electrode member. In other words, a fixing fastening structure and an electrical contact structure are respectively provided in the heat sink and the lamp house, and mechanical and electrical connection work through such a structure is required for replacement of the xenon lamp. . A specific conventional example of such an endoscope light source device will be described below.
[0004]
10 and 11 schematically show an example of a conventional structure of an endoscope light source device. The endoscope light source device includes a lamp unit 104 in which a conductive anode-side heat sink 102 and a cathode-side heat sink 103 are attached to a xenon lamp 101. A rod-shaped fastening member 107 is inserted into each of the heat sinks 102 and 103. A cylindrical knob portion 105 is formed on one end side of the fastening member 107 so as to be positioned on one end side of each of the heat sinks 102 and 103. On the other side of the fastening member 107, a male screw portion 106 is formed on the other end side of each of the heat sinks 102 and 103. The fastening member 107 is made of an arbitrary material, but is preferably made of a conductive member in order to further enhance the electrical connection between the heat sinks 102 and 103 and an electrode block 109 described later.
[0005]
In the lamp house (housing), a pair of conductive electrode blocks 109 that can be connected in contact with the heat sinks 102 and 103 mounted therein are disposed. On the contact surface of the electrode block 109 that contacts the heat sinks 102, 103, a female screw portion 108 that engages with the male screw portion 106 of the fastening member 107 and a projection 110 are provided. Further, a hole 111 into which the protrusion 110 of the electrode block 109 is inserted and connected is provided on the surface of each of the heat sinks 102 and 103 that contacts the contact surface of the electrode block 109.
[0006]
Therefore, in such a configuration, after the lamp unit 104 is inserted into the lamp house, the knob portion 105 of the fastening member 107 is rotated so that the male screw portion 106 of the fastening member 107 is replaced with the female screw portion 108 of the electrode block 109. Then, the heat sinks 102 and 103 are pressed against the contact surface of the electrode block 109, and the lamp unit 104 is positioned and fixed in the insertion direction, and is electrically connected. At this time, the protrusion 110 of the electrode block 109 is inserted and connected to the hole 111 of the lamp unit 104, whereby positioning in a direction other than the insertion direction of the lamp unit 104 is also performed.
[0007]
Japanese Patent Publication No. 7-70850 discloses another structure of an endoscope light source device. An endoscope light source device disclosed in this publication includes a xenon lamp, conductive anode-side heat sink and cathode-side heat sink that hold the xenon lamp, and an electrically insulating support substrate that fixedly supports both heat sinks. The lamp unit comprised by is provided. The anode side heat sink is provided with a female (or male) electrode connector, and the cathode side heat sink is provided with a male (or female) electrode connector. In addition, an electrically insulating fixed substrate is disposed in the lamp house, and this fixed substrate is provided with an electrode connector for male-female connection with an electrode connector on the heat sink side.
[0008]
In such a configuration, when the lamp unit is pushed into the lamp house at a predetermined position, the electrode connector on the heat sink side and the electrode connector on the fixed substrate side are joined to each other, and power connection to the lamp unit is made, The lamp unit is fixed.
[0009]
[Problems to be solved by the invention]
By the way, in the conventional structure shown in FIGS. 10 and 11, since the lamp unit and the electrode block are both electrically connected and fixed at the same time by inserting the lamp unit into the lamp house, The insertion direction of the lamp unit into the house is limited to one direction. However, since this conventional structure is not provided with means for preventing the lamp unit from being inserted in the wrong direction, the lamp unit is inverted upside down with respect to its normal insertion direction, and the front and back are inverted. There is a possibility of being inserted into the lamp house in a state or in a state where the top and bottom and front and rear are reversed. In such a case, if the heat sink of the lamp unit and the electrode block in the lamp house are in contact with each other or at a short distance, power may be supplied to the lamp unit when the lamp is turned on. There may be a situation in which positive and negative voltages are applied to the lamp, or electric discharge occurs due to poor contact at the electrical contact portion. The endoscope light source device disclosed in Japanese Patent Publication No. 7-70850 also has the same problem. In addition, forcibly inserting the lamp unit into the lamp house may damage the connector-shaped electrical contact portion.
[0010]
The present invention has been made paying attention to the above circumstances, and an object of the present invention is to provide an endoscope light source device capable of preventing the lamp unit from being inserted in the wrong direction with respect to the lamp house. It is in.
[0011]
[Means for Solving the Problems]
An endoscope light source device according to an embodiment of the present invention includes an illumination lamp including an anode portion and a cathode portion, a conductive anode heat sink that holds the anode portion and has a heat dissipation function, and holds the cathode portion. A lamp unit having a conductive cathode-side heat sink having a heat dissipation mechanism, a lamp house having an insertion port through which the lamp unit can be detachably accommodated and the lamp unit is inserted and removed, the anode-side heat sink, and the At least one insertion direction restricting portion formed integrally with at least one heat sink of the cathode side heat sink and separated from the other heat sink, and engaged with the insertion direction restricting portion provided in the lamp house A concave engaging portion, An anode-side guide groove and a cathode-side guide groove that extend in the insertion direction of the lamp unit in the lamp house and receive the bottom of the anode-side heat sink and the bottom of the cathode-side heat sink, respectively. Comprising The width dimension perpendicular to the insertion direction of one of the heat sinks of the anode side heat sink and the cathode side heat sink is smaller than the width dimension perpendicular to the insertion direction of the other heat sink, and the bottom of one heat sink having a small width dimension. The width dimension perpendicular to the insertion direction of the one guide groove receiving is smaller than the width dimension of the other heat sink having the larger width dimension, The insertion direction restricting portion is disposed on the near side in the insertion direction in the heat sink, and interferes with the engaging portion when the lamp unit is erroneously inserted into the lamp house on the near side and the far side. The insertion of the lamp unit is stopped, and the lamp unit is inserted into the lamp house. Accidentally reversed around the axis with the width direction perpendicular to the insertion direction as the central axis When inserted, the lamp unit interferes with the lamp house and stops the insertion of the lamp unit, and when the lamp unit is inserted into the lamp house in a normal insertion direction, it engages with the engaging portion. It is characterized by that.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0015]
1 to 8 show a first embodiment of the present invention. FIG. 1 shows a lamp mounting portion of an endoscope light source device 1 according to this embodiment. As shown in the drawing, an optical base 3 formed of an insulating member is attached on the chassis 2 of the light source device 1. In addition, a lamp house (housing) 4 is erected on the optical base 3, and a lamp unit 6 c is detachably mounted in the lamp house 4 in a predetermined mounting state. The lamp unit 6c includes a cylindrical xenon lamp 5 as a light source lamp, and an anode-side heat sink 6a and a cathode-side heat sink 6b that hold the xenon lamp 5 and have a heat dissipation function. The anode-side heat sink 6a and the cathode-side heat sink 6b are respectively attached to the anode and cathode electrodes of the xenon lamp 5.
[0016]
The rear end of the chassis 2 is connected to the lower end of a rear panel (not shown), and the top cover 10 is connected to the upper end of the rear panel. An opening is formed on one side surface of the top cover 10, and this opening is opened and closed by a lamp replacement door 21 (see FIG. 4).
[0017]
The light emitted from the xenon lamp 5 is emitted from the cathode side end face of the lamp unit 6c through the opening of the lamp house 4 facing the cathode side end face, and is arranged along the optical axis O and a condensing lens 7 (not shown). The light is condensed on the end face of the light guide 9 of the endoscope located in front of the diaphragm. The light guide 9 is detachably attached to the light guide connector receiver (or scope receiver) 8.
[0018]
As shown in FIGS. 2 and 3, rod-like fastening members 13 are inserted into the heat sinks 6a and 6b of the lamp unit 6c. A cylindrical knob portion 11 is formed on one end side of the fastening member 13 so as to be positioned on one end side of each of the heat sinks 6a and 6b. Further, a male screw portion 12 is formed on the other side of the fastening member 13 so as to be located on the other end side of each of the heat sinks 6a and 6b. The fastening member 13 is formed of an arbitrary material, but is preferably formed of a conductive member in order to further enhance the electrical connection between the heat sinks 6a and 6b and an electrode block 15 described later.
[0019]
Further, in the lamp house 4, a pair of conductive electrode blocks 15 that can be connected in contact with the heat sinks 6a and 6b mounted therein are disposed. On the contact surface of the electrode block 15 that contacts the heat sinks 6a and 6b, a female screw portion 14 that is screwed with the male screw portion 12 of the fastening member 13 and a protrusion 16 are provided. In addition, a hole 17 into which the protrusion 16 of the electrode block 15 is inserted and connected is provided on the surface of each of the heat sinks 6a and 6b that contacts the contact surface of the electrode block 15.
[0020]
In addition, at least one of the heat sinks 6a and 6b is provided with a protruding insertion direction restricting portion (convex portion) 18 on the upper side of the surface opposite to the surface in contact with the contact surface of the electrode block 15. Yes. Further, the lamp house 4 is provided with an engaging portion (concave portion) 19 that engages with the insertion direction restricting portion 18 at the upper end portion of the lamp unit insertion opening. The engaging portion 19 is formed by, for example, partially cutting off the upper surface of the lamp house 4 so as to escape the protrusion of the insertion direction restricting portion 18. The engaging portion 19, together with the insertion direction regulating portion 18, defines an insertion direction defining means that regulates the normal insertion direction of the lamp unit 6 c with respect to the lamp house 4 (prevents insertion of the lamp unit 6 c in the wrong direction). It is composed.
[0021]
FIG. 4 shows a lamp replacement door 21 that opens and closes the opening of the top cover 10. As illustrated, a switch pushing member 22 that moves in conjunction with opening and closing of the lamp replacement door 21 is provided on the back surface (inner surface) of the lamp replacement door 21 facing the inside of the lamp house 4. As shown in FIG. 5, an interlock switch 23 that operates in conjunction with opening and closing of the lamp replacement door 21 is disposed inside the lamp house 4 while being held by the bracket 24. The interlock switch 23 is turned on and off by a switch pushing member 22 that moves in conjunction with opening and closing of the lamp replacement door 21. Specifically, when the lamp replacement door 21 is opened as shown in FIG. 6A, the interlock switch 23 is turned OFF, and the lamp replacement door 21 is closed as shown in FIG. 6B. Then, the interlock switch 23 is turned on.
[0022]
In order to reliably turn on / off the interlock switch 23, generally, high processing accuracy and position accuracy are required for each component such as the switch pushing member 22 and the bracket 24 of the interlock switch 23. However, in this embodiment, the switch push-in member 22 is moved along with the ON / OFF of the interlock switch 23 so that the interlock switch 23 can be reliably turned ON / OFF without requiring such high accuracy. A guide port 25 for guiding is provided in the bracket 24.
[0023]
7 and 8 show the cathode-side heat sink 6b viewed from the lamp 5 side. As illustrated, the cathode-side heat sink 6b is provided with a cylindrical magnetic body 26. The magnetic body 26 adjusts the deviation due to the geomagnetism of the bright spot position that occurs when the xenon lamp 5 is lit, so that a stable light amount can be obtained. One side of the magnetic body 26 is covered in five directions by a holding member 27 formed by bending a metal plate into a box shape. In this case, the holding member 27 is fixed to the cathode-side heat sink 6b so that the other end of the magnetic body 26 is fitted into a groove portion 28 provided in the cathode-side heat sink 6b. The holding member 27 is not limited to a metal plate, and may be any shape or material as long as it can cover one side of the magnetic body 26 and be fixed to the heat sink 6b.
[0024]
Next, the operation | movement at the time of lamp replacement | exchange of the light source device 1 for endoscopes of the said structure is demonstrated.
[0025]
First, as shown in FIG. 3A, the lamp unit 6 c is inserted into the lamp house 4 in the normal direction, and the knob portion 11 of the fastening member 13 is rotated so that the male screw portion 12 of the fastening member 13 is rotated. Is screwed onto the female threaded portion 14 of the electrode block 15, the heat sinks 6a and 6b are pressed against the contact surface of the electrode block 15, and the lamp unit 6c is positioned and fixed in the insertion direction, and electrical connection is established. Made. This state is shown in FIG. At this time, the protrusion 16 of the electrode block 15 is inserted and connected to the hole 17 of the lamp unit 6c, whereby positioning in a direction other than the insertion direction of the lamp unit 6c is also performed. Further, in this state, the protruding insertion direction restricting portion 18 provided on at least one of the heat sinks 6a and 6b is satisfactorily engaged with the engaging portion of the lamp house 4, and the lamp unit 6c is positioned in the normal mounting state. Is done.
[0026]
On the other hand, if the lamp unit 6c is inserted in the wrong direction, the insertion direction restricting portion 18 interferes with the lamp house 4 or the optical base 3 immediately after the insertion starts, and the lamp unit 6c cannot be further inserted. . Therefore, it does not collide with a portion where the fastening structure or the contact structure is not suitable. That is, it is possible to prevent deformation and damage of the fastening structure and contact structure due to erroneous insertion, and a discharge phenomenon due to contact failure of the contact portion.
[0027]
As described above, the endoscope light source device 1 according to the present embodiment has the insertion direction defining means for defining the normal insertion direction of the lamp unit 6 c with respect to the lamp house 4. In addition, this insertion direction defining means is extremely simple in that a projection-like insertion direction restricting portion 18 is provided on at least one of the heat sinks 6 a and 6 b and the insertion direction restricting portion 18 is engaged with the engaging portion 19 of the lamp house 4. This is realized by a simple configuration. Therefore, when the xenon lamp 5 is replaced, it is possible to prevent the lamp unit 6c from being inserted in the wrong direction with a very simple structure. Therefore, it is possible to prevent the fastening structure and the contact structure from being deformed or damaged due to erroneous insertion, the discharge phenomenon due to the contact failure of the contact portion, and the like.
[0028]
In this embodiment, since the guide port 25 that guides the movement of the switch pushing member 22 when the interlock switch 23 is turned ON / OFF is provided in the bracket 24, the required machining accuracy and position accuracy are greatly increased. It can be reduced.
[0029]
Note that the heat sinks 6a and 6b used for cooling the xenon lamp 5 are generally processed by extrusion molding of aluminum because they require characteristics of high heat dissipation and high conductivity. Correspondingly, the insertion direction restricting portion (protrusion portion) 18 of the heat sinks 6a and 6b according to the present embodiment is also perpendicular to the insertion direction of the lamp unit 6c without using a secondary cutting process. It can be formed by extruding in any direction. Therefore, workability is very good. Further, the insertion direction restricting portion 18 is not limited to being integrally formed as a part of the heat sinks 6a and 6b as described above, but may be formed by attaching protruding separate parts to the heat sinks 6a and 6b. Further, the shape and size of the insertion direction restricting portion 18 can be variously changed. In short, when the lamp unit 6c is inserted in the normal direction, the insertion direction restricting portion 18 and the engaging portion 19 are satisfactorily engaged, and when the lamp unit 6c is inserted in the wrong direction, it is inserted. The shape and size of the insertion direction restricting portion 18 are set such that the direction restricting portion 18 does not engage with the engaging portion 19 and interferes with an arbitrary portion of the lamp house 4 so that the lamp unit 6c cannot be inserted. Set it. Further, the insertion direction restricting portion 18 may be provided in the lower part of the surface of the heat sinks 6 a and 6 b opposite to the surface that is in contact with the contact surface of the electrode block 15. In this case, the engaging portion 19 is provided on the optical base 3.
[0030]
FIG. 9 shows a second embodiment of the present invention. As shown in the drawing, the lamp unit 31c of the endoscope light source device according to the present embodiment includes a cylindrical xenon lamp 5 as a light source lamp, and anode sides attached to respective anode and cathode electrodes of the xenon lamp 5. The heat sink 31a and the cathode side heat sink 31b are configured. Further, the optical base 3 in the lamp house has an anode side guide groove 32a and a cathode side guide groove (concave portion) 32b that can receive the bottom portions (convex portions) of the anode side heat sink 31a and the cathode side heat sink 31b only in a certain direction. Is provided. Specifically, the anode-side heat sink 31a and the cathode-side heat sink 31b have different widths (for example, a width in a direction perpendicular to the insertion direction of the lamp unit 31c) and guide grooves 32a that receive these heat sinks 31a and 31b. 32b are also different from each other, and only the guide groove 32a (32b) and the heat sink 31a (31b) having the same width dimension can be engaged with each other. That is, the heat sinks 31a and 31b and the guide grooves 32a and 32b form insertion direction defining means for defining the normal insertion direction of the lamp unit 31c with respect to the lamp house by making the width dimensions thereof different. The width dimensions of the guide grooves 32a and 32b are set slightly larger than the width dimensions of the corresponding heat sinks 31a and 31b.
[0031]
In such a configuration, the anode-side heat sink 31a and the cathode-side heat sink 31b are fitted into the anode-side guide groove 32a and the cathode-side guide groove 32b only when the lamp unit 31c is inserted into the lamp house in the normal direction. The mechanical and electrical connection of the lamp unit 31c is normally performed.
[0032]
Therefore, according to the present embodiment, it is possible to obtain the same function and effect as in the first embodiment, and it is only necessary to match the heat sinks 31a and 31b with the guide grooves 32a and 32b as the mounting portions. The effect that it is easy to make an operator visually recognize is acquired. Also in the present embodiment, the difference in the width (thickness) of the heat sinks 31a and 31b can be determined by extruding the lamp unit 6c in a direction perpendicular to the insertion direction without using a secondary cutting process. Since it can be formed by molding, workability is very good.
[0033]
In addition, according to the technical content demonstrated above, the various structures as shown below are obtained.
[0034]
1. An illumination lamp that generates illumination light;
A lamp unit that holds the lamp and includes a heat sink having a heat dissipation function;
A lamp house having an insertion port in which the lamp unit is housed and can be taken in and out;
In an endoscope light source device comprising:
The heat sink and the lamp house are provided with a convex portion and a concave portion that can be inserted into a mounted state only when mounted in a normal insertion direction.
An endoscope light source device characterized by the above.
[0035]
2. An xenon lamp for illumination having an electrode part of an anode and a cathode and generating illumination light;
Holding the anode side electrode part of the xenon lamp, a conductive anode side heat sink having a heat dissipation function;
A lamp unit configured to hold a cathode side electrode portion of the xenon lamp and include a conductive cathode side heat sink having a heat dissipation function;
A lamp house having an insertion port in which the lamp unit is housed and can be taken in and out;
In an endoscope light source device comprising:
Providing at least one of the anode-side heat sink and the cathode-side heat sink has a protrusion that protrudes in a direction perpendicular to the lamp house unit insertion direction,
A surface of the lamp house that faces the protrusion of the heat sink is disposed close to the heat sink, and a relief portion that does not interfere with the protrusion when the lamp unit is mounted is provided.
An endoscope light source device characterized by the above.
[0036]
3. An xenon lamp for illumination having an electrode part of an anode and a cathode and generating illumination light;
Holding the anode side electrode part of the xenon lamp, a conductive anode side heat sink having a heat dissipation function;
A lamp unit configured to hold a cathode side electrode portion of the xenon lamp and include a conductive cathode side heat sink having a heat dissipation function;
A lamp house having an insertion port in which the lamp unit is housed and can be taken in and out;
In an endoscope light source device comprising:
The anode-side and cathode-side heat sinks have different widths in the direction perpendicular to the insertion direction,
In the lamp unit insertion port of the lamp house, receiving the lower surfaces of the anode side and cathode side heat sinks, providing a groove portion having a width wider than the width of each heat sink, and the width of the groove portion with respect to the narrow heat sink, Narrower than the width of the narrow heat sink,
An endoscope light source device characterized by the above.
[0037]
4). The light source device for an endoscope according to item 1 or 2, wherein the protrusion is provided on the front upper surface of the heat sink and the recess is provided on the lamp house.
[0038]
5). The light source device for an endoscope according to item 4, wherein the protrusion is a front lower surface of the heat sink.
[0039]
6). A lamp house having an insertion slot into which the lamp unit can be inserted;
In an endoscope light source device comprising:
At least one of the anode side heat sink and the cathode side heat sink is provided with a protrusion on the front upper surface with respect to the lamp house unit insertion direction,
The front surface of the lamp house facing the upper surface of the heat sink is brought close to the heat sink, and a relief portion that does not interfere with the protrusion when the lamp unit is mounted is provided.
An endoscope light source device characterized by the above.
[0040]
7). An xenon lamp for illumination having an electrode part of an anode and a cathode and generating illumination light;
Holding the anode side electrode part of the xenon lamp, a conductive anode side heat sink having a heat dissipation function;
A lamp unit configured to hold a cathode side electrode portion of the xenon lamp and include a conductive cathode side heat sink having a heat dissipation function;
A lamp house having an insertion port into which the lamp unit can be inserted;
In an endoscope light source device comprising:
The anode side and cathode side heat sinks have different widths in the direction perpendicular to the insertion direction,
In the lamp unit insertion port of the lamp house, receiving the lower surfaces of the anode side and cathode side heat sinks, providing a groove portion having a width wider than the width of each heat sink, and the width of the groove portion with respect to the narrow heat sink, Narrower than the width of the narrow heat sink,
An endoscope light source device characterized by the above.
[0041]
【The invention's effect】
As described above, according to the endoscope light source device of the present invention, it is possible to prevent the lamp unit from being inserted in the wrong direction with respect to the lamp house.
[Brief description of the drawings]
FIG. 1 is a side view showing a partial cross section of a main part of an endoscope light source device according to a first embodiment of the present invention.
2 is a perspective view of a lamp unit that constitutes the endoscope light source device of FIG. 1. FIG.
3A is a front sectional view showing a process of inserting the lamp unit of FIG. 2 into the lamp house, and FIG. 3B is a front sectional view showing a state where the lamp unit of FIG. 2 is completely installed in the lamp house. FIG.
4 is a perspective view of a lamp replacement door of the endoscope light source device of FIG. 1 as viewed from the inside of a lamp house. FIG.
FIG. 5 is a perspective view of an interlock switch that operates in conjunction with opening and closing of the lamp replacement door.
6A is a top view of the interlock switch of FIG. 5 in the OFF state, and FIG. 6B is a top view of the interlock switch of FIG. 5 in the ON state.
FIG. 7 is a side view of the cathode-side heat sink as viewed from the lamp side.
8 is a perspective view of a main part of the cathode-side heat sink in FIG. 7;
FIG. 9 is a side view showing a main part of an endoscope light source device according to a second embodiment of the present invention.
FIG. 10 is a perspective view of a conventional lamp unit mounting portion.
11 is a front view of the lamp unit of FIG.
[Explanation of symbols]
1. Light source device for endoscope
4 ... Lamphouse
5 ... Xenon lamp (lighting lamp)
6a, 6b, 31a, 31b ... heat sink
6c, 31c ... Lamp unit
18 ... Insertion direction restricting portion (insertion direction defining means)
19 ... engaging part (insertion direction defining means)
32a, 32b ... guide groove (insertion direction defining means)

Claims (1)

Lamp having an anode portion and a cathode portion, a conductive anode side heat sink that holds the anode portion and has a heat dissipation function, and a conductive cathode side heat sink that holds the cathode portion and has a heat dissipation mechanism Unit,
A lamp house capable of detachably storing the lamp unit and having an insertion port through which the lamp unit is inserted and removed;
At least one insertion direction restricting portion having a convex shape formed integrally with at least one heat sink of the anode side heat sink and the cathode side heat sink and separated from the other heat sink;
A concave engaging portion that is provided in the lamp house and engages with the insertion direction restricting portion;
An anode-side guide groove and a cathode-side guide groove that extend in the insertion direction of the lamp unit in the lamp house and receive the bottom of the anode-side heat sink and the bottom of the cathode-side heat sink, respectively.
Comprising
The width dimension perpendicular to the insertion direction of one of the heat sinks of the anode side heat sink and the cathode side heat sink is smaller than the width dimension perpendicular to the insertion direction of the other heat sink, and the bottom of one heat sink having a small width dimension. The width dimension perpendicular to the insertion direction of the one guide groove receiving is smaller than the width dimension of the other heat sink having the larger width dimension,
The insertion direction restricting portion is disposed on the near side in the insertion direction in the heat sink, and interferes with the engaging portion when the lamp unit is erroneously inserted into the lamp house on the near side and the far side. When the insertion of the lamp unit is stopped and the lamp unit is mistakenly inserted into the lamp house by being inverted in the direction around the axis with the width direction perpendicular to the insertion direction as the central axis, the lamp unit interferes with the lamp house. The insertion of the lamp unit is stopped, and when the lamp unit is inserted into the lamp house in a normal insertion direction, the engagement unit is engaged.
An endoscope light source device characterized by the above.

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