JPH0222925B2 - - Google Patents

Description

[Detailed description of the invention] 〔Technical field〕 The present invention relates to an endoscope light source device.

[Prior art]

In conventional endoscope devices, when the endoscope connector is removed from the light source socket of the light source device, the light source light, especially the illumination light, leaks to the outside through the light source socket, and this leaked light enters the eye. It is very bright and can cause eye damage. For this reason, it has been considered to operate a light source shutter to prevent the collimation light from leaking to the outside when the endoscope connector is pulled out. However, since the light source shutter is irradiated with the collimation light at this time, the light source shutter is heated and the temperature of the light source socket increases accordingly.

〔the purpose〕

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide an endoscope light source device that prevents light from leaking outside when an endoscope connector is removed and removed, and that reduces temperature rise in the light source socket and its surroundings. .

〔overview〕

According to the present invention, there are provided a means for detecting removal and removal of an endoscope connector, and a light shielding means that operates in response to detection of removal and removal by the detection means and prevents leakage of collimation light to the outside via the light source socket. , and a control circuit that dims the collimation light of the light source in response to the detection of removal and removal by the detection means.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

According to FIG. 1, an endoscope connector 11 is inserted into a light source socket 12 of a light source device. A micro switch 14 is located close to the light source socket 12.
will be provided. This micro switch 14 is activated by contacting the endoscope light guide section 15.
It becomes OFF, and turns ON when the light guide section 15 approaches and separates, that is, when the endoscope connector 11 is removed and removed, and functions as a means for detecting the removal and removal of the endoscope connector. One of the connection terminals of this microswitch 14 is connected to one end of a power supply 17 via a relay solenoid 16, and the other connection terminal is connected to the other end of the power supply 17. A common terminal of relay switches 16a and 16b is connected to one end of a power supply 17, and a normally open contact of relay switch 16a is connected to one end of a solenoid 19 that drives a light source shutter 18. The other end of the solenoid 19 is connected to the other end of the power source 17.
A normally closed contact of the relay switch 16b is directly connected to one end of the collimation light source 20, and a normally open contact is connected to one end of the collation light source 20 through a resistor 21. The other end of the collation light source 20 is connected to the other end of the power source 17.

According to the light source device described above, when the endoscope connector 11 is connected to the light source socket 12, the micro switch 14 is turned off, so the relay solenoid 16 is deenergized. Therefore, the illumination light source 20
The output of the power supply 17 is directly supplied to the collation light source 20.
emits light at the rated light intensity. At this time, since the shutter solenoid 19 is also deenergized, the light source shutter 18 is open, and the collimation light from the light source 20 enters the incident end of the light guide section 15. In this state, when the endoscope connector 11 is removed from the light source socket 12, the micro switch 14 detects this removal and turns on. As a result, the relay solenoid 16 is energized and the relay switches 16a, 16
b is switched, the shutter solenoid 19 is energized, the shutter 18 closes the light source optical path, and the illumination light source 2
0 is supplied with a reduced power supply output by a resistor 21. As a result, the illumination light is transmitted to the light source socket 12.
Since the illumination light source 20 is dimmed by reducing the input, the light source shutter 18 will not be heated strongly, and the temperature around the light source socket 12 will become abnormal. It never rises to the top.

FIG. 2 shows a socket portion 30 of the light source device. This socket portion 30 is provided with a guide hole 33 into which a light guide portion 32 of an endoscope connector 31 is inserted. An actuator hole 34 is formed in communication with the guide hole 33, and an actuator 35 made of an elastic body is disposed in this actuator hole. The protruding and recessing portion 35a of the actuator 35 protrudes and retracts into the guide hole 33. A light shielding plate 36 is provided at the tip of the actuator 35, and the photo interrupter 37 is shielded from light by this light shielding plate 36. When the endoscope connector 31 is connected to the light source socket section 30, the actuator 35 is pushed out by the light guide section 32 and remains at the position indicated by the dotted line.
At this time, the light shielding plate 36 of the actuator 35 is separated from the photo interrupter 37, and the light emitting element and the light receiving element of the photo interrupter 35 are optically coupled. On the other hand, when the endoscope connector 31 is pulled out, the light shielding plate 36 releases the optical coupling of the photo interrupter 37.

The photo interrupter 37 is used in the embodiment of FIG. In this embodiment, the collimation light source is controlled by a microcomputer. According to this embodiment, the CPU 41 connects the ROM 44 and the RAM via the data bus 42 and control bus 43.
45. Parallel port interface (PPI) 4
6, parallel interval timer (PIT) 47,
Counter (CTC) 48 and programmable keyboard display controller (PKDC) 49
is connected. PKDC 49 is connected to display panel 50. PPI 46 is connected to photo interrupter 37 and shutter control circuit 51. PIT47
are the collation light control circuit 52 and the zero cross detection circuit 5
Connected to 3. This zero cross detection circuit 53 detects the zero cross of the AC power supply 54. When the zero-cross detection signal is supplied to the PIT 47, it is determined from the zero-cross interval whether the AC power source 54 is in the range of 50 Hz to 60 Hz. Light intensity data tables corresponding to 50Hz and 60Hz are stored in the RAM 45, and the illumination light source 5 is
5 is controlled. This will be explained with reference to the flowcharts of FIGS. 4 and 5.

When the power supply 54 is turned on, the power supply 5
It is determined whether 4 is 50Hz or 60Hz. If it is 50Hz
“1” is stored in a predetermined address of RAM45,
If it is 60Hz, "0" is stored. Then RAM
For example, "5" is set in the soft counter 45. Thereafter, it is determined from the state of the photo interrupter 37 via the PPI 46 whether an endoscope (scope) has been inserted. If the scope is inserted, it is determined whether the set light amount is "0" or not.
It is assumed that the set amount of light can be set in four stages: 3, 2, 1, and 0, corresponding to strong, medium, weak, and stop, respectively. If the set light amount is "medium", that is, "2", power is supplied to the light source 55 so that the light amount is "medium". In this case, when setting the light intensity, the data for light intensity "2" from the light intensity data table in RAM45 is
The conduction angle of the thyristor 56 is determined based on the light amount data "2" in this area, and the conduction angle signal of the photocoupler 5
7, the thyristor 56 is controlled, and the collation light source 55 is turned on at a medium intensity.

If the light intensity is set to “low”,
The soft counter in RAM 45 is decremented by "1". At this time, since the soft counter is "4", the light source 55 is controlled by the "medium" light amount. This is because when the light is turned on at a low level, the lighting condition becomes unstable, so the light intensity is first turned on at a medium level and then changed to a low level. This lighting at a "medium" light intensity is performed for the value set in the soft counter, that is, for the count of "5". This 5 count indicates the number of times the flow in Figure 5 is repeated, and if one cycle of the flow is 100 milliseconds, it is 500.
Equivalent to milliseconds. Each time this cycle progresses, the soft counter is decremented by "1", and when the soft counter reaches "0", the light amount is made "weak".

If the endoscope connector is pulled out while the light source 55 is turned on with a "medium" or "strong" light intensity, the photo interrupter 37 detects this. CPU4
1 recognizes removal via PPI46 and RAM4
The light amount data "weak", that is, data "1" is extracted from 5, and the light source 55 is made to have a weak light amount via the PIT 47. At this time, the shutter solenoid 59 is operated via the photocoupler 58 of the shutter control circuit 51 to close the shutter and prevent leakage of the collimation light to the outside.

〔Effect of the invention〕

As explained above, according to the present invention, when the endoscope connector is removed from the light source socket, this is detected, and the collimation light from the collation light source is prevented from leaking to the outside, and the collation light is dimmed. The influence of the leaked light on the human body and the rise in temperature of the parts surrounding the light source socket due to the collimation light are suppressed.

[Brief explanation of drawings]

FIG. 1 is a schematic configuration diagram of an endoscope light source device according to one embodiment of the present invention, FIG. 2 is a sectional view of a light source socket used in an endoscope light source device according to another embodiment, and FIG. 3 is a circuit diagram of an endoscope light source device using the photo interrupter of FIG. 2, and FIGS. 4 and 5 are flowcharts illustrating the operation of the endoscope light source device of FIG. 3. 11... Endoscope connector, 12... Light source socket,
14... Micro switch, 15... Light guide section, 16... Relay solenoid, 17... Power supply, 18
...Light source shutter, 19...Solenoid, 20...Verification light source, 30...Light source socket section, 31...Endoscope connector, 35...Actuator, 37...Photo interrupter, 51...Shutter control circuit, 52...Verification light control circuit, 53...Zero cross detection circuit.

Claims (1)

[Scope of Claims] 1. A light source socket to which an endoscope connector is connected; a light source that generates collimation light to be introduced into the endoscope via the endoscope connector; means for detecting removal and removal of the mirror connector; light shielding means that operates in response to removal detection by the detection means and blocks the collimation light between the light source and the light source socket; An endoscope light source device comprising: a control circuit that reduces the illumination light of the light source in response to detection of the light source. 2. The endoscope light source device according to claim 1, wherein the control circuit includes means for reducing a lighting current to the light source. 3. The endoscope light source device according to claim 1, wherein the control circuit includes means for changing the optical path of the light source.