JPH0446254Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Technical Field of the Invention] The present invention relates to a light source device for an endoscope that cools the light guide entrance end of an endoscope mounted thereon by blowing air thereto.

[Technical background of the invention and its problems]

Generally, a light source device for an endoscope uses a high-intensity lamp as its light source lamp, and is configured to collect the light on the incident end surface of the light guide of the endoscope. Therefore, the incident end face portion is strongly heated. By the way, since the light guide uses an optical fiber bundle that is relatively susceptible to thermal damage, the incident end face portion thereof is easily damaged thermally (end face burnt) due to heating.

Therefore, conventionally, a method is known in which a nozzle directed toward the incident end face of the light guide is provided and air is blown onto the incident end face from this nozzle to cool the light guide (Japanese Patent Application Laid-open No. 81323/1983).

However, even when the connector of the endoscope is removed from the socket of the light source device, air is still blown out from the nozzle, so the discharge sound leaks outside, and the operating noise and vibration of the air pump continue. Therefore, these noises cause anxiety, especially for patients. In addition, unnecessarily continuing the air supply operation results in a loss of energy and shortens the life of the air supply pump.

[Purpose of invention]

This invention was made with attention to the above circumstances,
The purpose of this is to prevent air from being unnecessarily discharged from the light guide cooling nozzle when the endoscope connector is unplugged, so that no discharge noise or vibrations occur, and to save energy. An object of the present invention is to provide a light source device for an endoscope that can extend the life of an air pump.

[Summary of the idea]

The present invention uses a detection means that detects the removal state when the endoscope connector is removed from the socket to control the operation of the air supply pump that supplies air to the light guide cooling nozzle when the endoscope connector is removed. This is a light source device for an endoscope that is stopped.

Further, the socket includes a cap member that covers a distal end portion of the light guide tube including the incident end of the light guide when the endoscope connector is attached.
A cover glass is provided on the tip end of the cap member, and a nozzle is provided between the cover glass and the light guide entrance end, and is installed toward the light guide entrance end to blow cooling air to the light guide entrance end. It is structured as follows.

[Example of idea]

An embodiment of the present invention will be described below with reference to FIGS. 1 and 2.

Reference numeral 1 in FIG. 1 is a panel of a light source device, to which a socket member 2 is attached. A connector 3 of an endoscope is detachably attached to this socket member 2. Further, a light guide tube 4 in which a light guide made of an optical fiber bundle is inserted and an air supply tube 5 are protruded from the connector 3. The socket member 2 is formed with an insertion hole 6 that passes through the light guide tube 4, and an insertion hole 7 into which the air receiving tube 5 is inserted. An air pipe 8 is introduced into the insertion hole 7, and the air receiving pipe 5 is connected to the air pipe 8 when the connector 3 is attached to the socket member 2.

On the other hand, at the rear of the socket member 2, a mounting member 9 for incorporating a detection means, which will be described later, is connected in a tightly joined state. Further, the mounting member 9 is fixedly attached to the mounting plate 10. A guide hole 11 communicating with the insertion hole 6 is provided through the mounting member 9 and the mounting plate 10 . Then, the socket member 2
When connector 3 is attached to
As shown in FIG. 1, the insertion hole 6 and the guide hole 11
The tip portion thereof penetrates through the mounting plate 10. In this way, the mounting plate 10
The distal end portion of the light guide tube 4 passing through is covered by a cap member 12, which will be described later. The cap member 12 is attached to the mounting plate 10. In addition, the cap member 12
A transparent cover glass 13 is airtightly attached to the front end face of the light guide tube 4 so as to face the entrance end face (not shown) of the light guide at the front end of the light guide tube 4 . The light from the light source lamp 14 is received through the cover glass 13.

Further, a nozzle 15 is formed on the upper wall of the cap member 12 and opens toward the incident end surface. An air supply tube 16 is connected to this nozzle 15, and this air supply tube 16 is connected to the air supply pump 1.
7 is connected. Then, the air supply pump 1
7, pressurized air is sent to the nozzle 15 through the air supply tube 16, and is blown from the nozzle 15 onto the incident end face as cooling air. In addition, cap member 1
A discharge hole 18 is formed in the lower wall of the cap member 2, through which air blown into the cap member 12 is discharged to the outside.

On the other hand, as shown in FIG. 1, the mounting member 9 incorporates a detection means for detecting that the connector 3 is removed from the socket member 2. That is, an actuator hole 19 is opened in the wall of the mounting member 9, and an operating portion 21 of an actuator 20 made of an elastic material is inserted into the actuator hole 19 and projects into the guide hole 11. The base end of this actuator 20 is attached and fixed to the socket member 2 side. Further, the tip side of the actuator 20 protrudes outward from the mounting member 9, and a light shielding plate 22 is provided at this tip end. When the connector 3 is attached to the socket member 2, the operating portion 21 of the actuator 20 is pushed up by the light guide tube 4 inserted across the insertion hole 6 and the guide hole 11, and the actuator 20 Move from the position shown by the solid line to the position shown by the dotted line in the figure. On the other hand, the light shielding plate 22 shields the photointerrupter 23 from light when the connector 3 is not attached, and separates from the photointerrupter 23 when the connector 3 is attached to optically couple the photointerrupter 23.

FIG. 2 shows a circuit of the air pump control means, and according to this circuit, the CPU 24 connects the data bus line 25 and the control bus line 2.
6 to the ROM 27, RAM 28, and parallel port interface (PPI) 29. This PPI 29 is connected to the photointerrupter 23 mentioned above. On the other hand, the air pump 17 is connected to a power source 31 via the contacts of a relay 30. Further, this relay 30 is connected to a driving power source via the collector and emitter of a switching transistor 32. Further, the base of the switching transistor 32 is connected to the output terminal of the PPI 29 via an inverter 33.

Next, the operation of the above configuration will be explained. First, the connector 3 of the endoscope is attached to the socket member 2 as shown by the two-dot chain line in FIG. The air pump 17 operates to perform an air supply operation. That is, since the light guide tube 4 is inserted across the insertion hole 6 and the guide hole 11 of the socket member 2, the actuator 20 is pushed up, and its light shielding plate 22 is retracted from the photo interrupter 23, thereby blocking the photo interconnector 23 from light. combine. Then, the signal at this time is transmitted via PPI29.
The CPU 24 receives the signal and determines that the connector 3 is attached, and further, the CPU 24 closes the switching transistor 32 through the PPI 29 to close the contact of the relay 30, thereby shutting down the air supply pump 1.
7.

Thus, pressurized air is sent to the nozzle 15 through the air feeding tube 16 by the air feeding operation of the air feeding pump 17, and the air is blown from the nozzle 15 toward the light guide entrance end at the tip of the light guide tube 4. . As a result, the vicinity of the incident end is air-cooled, and end face burnout is prevented. Further, this blown air is sequentially discharged from the inside of the cap member 12 to the outside through the discharge hole 18. Note that since the tip of the light guide tube 4 is covered with the cap member 12 while being blown, there is no entrainment of dust, etc., and the dust is prevented from adhering to the incident end surface.

On the other hand, when the connector 3 is pulled out, the actuator 20 automatically returns to the position shown by the solid line in FIG. 1, and the photointerrupter 28 is shielded from light.
Then, this signal is received by the CPU 24 via the PPI 29, and it is determined that the connector 3 has been removed.
Therefore, the CPU 24 opens the switching transistor 32 through the PPI 29 to open the contacts of the relay 30 and stop the operation of the air pump 17.
That is, when the connector 3 is removed, the air supply operation of the air supply pump 17 is automatically stopped, and the blowing from the nozzle 15 is also stopped.

In this way, when the connector 3 is removed, air is not discharged unnecessarily, so that discharge noise, vibration, etc. are not generated. Furthermore, since the operation of the air pump 17 is also stopped, there is no operating noise, and electricity costs are saved, and the life of the air pump is also extended.

Although the above embodiment uses a computer for control, the signal from the photointerrupter 28 may be directly sent to the switching transistor 32 as shown in FIG. Further, the present invention may be arranged so that the nozzle 15 faces the incident end of the light guide without using the cap member 12.

[Effect of idea]

As explained above, according to the present invention, when the connector of the endoscope is removed from the socket, the air supply operation of the air supply pump is automatically stopped, and it is possible to avoid unnecessarily continuing to discharge air from the nozzle. , the discharge sound, signal, etc. are eliminated, and the patient's anxiety can be alleviated. Furthermore, it saves energy,
Moreover, the life of the pump itself can be extended.

Further, a cap member is provided to cover the tip portion of the light guide tube, and a cap member is provided between the cover glass provided on the tip surface portion of the cap member and the incident end of the light guide, and is installed toward the incident end of the light guide. By providing a nozzle that
This prevents cooling air from being squirted outward from the socket opening, thereby enhancing the above-mentioned effects.

[Brief explanation of drawings]

FIG. 1 is a side sectional view of a socket portion in one embodiment of the present invention, FIG. 2 is an electric circuit of this embodiment, and FIG. 3 is an electric circuit of another embodiment. 2...Socket member, 3...Connector, 4...
Light guide tube, 15... Nozzle, 17... Air pump, 20... Actuator, 22... Light shielding plate, 23,... Photo interrupter, 24...
CPU.

Claims (1)

[Scope of utility model registration request] A socket for attaching the endoscope connector formed by the incident end of the light guide, and a socket that covers the tip of the light guide tube including the incident end of the light guide when the endoscope connector is attached to this socket. A cap member, a cover glass provided on the tip end surface of the cap member, and a cap member installed between the cover glass and the light guide input end toward the input end of the light guide to supply cooling air to the input end. a blowing nozzle; an air supply pump that supplies cooling air to the nozzle; a detection means for detecting the removal state of the endoscope connector from the socket; A light source device for an endoscope, comprising: an air supply pump control means for stopping an air supply operation of an air pump.