JPS58182885A - Laser irradiation device - Google Patents

Abstract

PURPOSE:To simultaneously or selectively irradiate two types of working laser lights of different wavelengths from two light guide by simply operating a reflecting mirror. CONSTITUTION:When a reflection mirror 9 is set to position A' in case the first and second working laser light sources 1, 2 are in oscillated state, the first laser light 5 and the second laser light 6 reflected on a reflecting mirror 8 are superposed, when shutters 3, 4 are opened, and led to the first light guide 11. When the shutter 4 is closed while the shutter 3 remains open, only the first laser light 5 is irradiated from the first light guide 11. When the mirror 9 is disposed at the position A, the lights 5, 6 are superposed via a dichromatic mirror 7 when the shutters 3, 4 are opened, and reflected via reflecting mirrors 9, 10 and led into the second light guide 12.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a laser irradiation device, and more particularly to a laser irradiation device that includes two light guide paths and can arbitrarily irradiate two types of working laser beams with different wavelengths.

Conventionally, several laser irradiation devices have been proposed that can irradiate two types of working laser beams with different wavelengths simultaneously or selectively. When the irradiated part is a living body, it is known that the interaction between the living body and the laser light varies greatly depending on the wavelength of the irradiated laser light. Therefore, it has been reported that these laser irradiation devices can utilize the characteristics of laser surgery to proceed with surgery more effectively by appropriately using the working laser beam, compared to the case where only a single laser beam is irradiated. ing.

For example, Japanese Patent Publication No. 56-1.30145 discloses a device equipped with two types of working lasers, a CO□ laser and YA and G lasers, and also equipped with two laser light guide paths. . In this device, one light guide is a manipulator light guide and the other light guide is a fiber light guide. Here, the fiber light guide is used under an endoscope.

In this way, there is no other device that has two light guide paths and can use different light guide paths depending on the field of application, and it is useful.

However, in the above device, although CO2 laser light and YAG laser light can be irradiated simultaneously or selectively from the manipulator light guide path, YAG laser light can be irradiated from the fiber light guide path.
It was possible to irradiate only the AG laser beam alone.

As described above, in laser surgery, it is known that appropriately using a plurality of laser beams can produce greater effects than irradiating them alone.

Therefore, in order to maximize the advantages of laser surgery in each field of application, it is desirable for a device equipped with two light guide paths to be able to irradiate each laser beam freely from each light guide path.

The present invention has been made in view of the above-mentioned circumstances, and its objects are as follows. That is, in a laser irradiation device equipped with two types of laser light sources that generate work laser beams with different wavelengths and two light guide paths for transmitting the laser beams, the laser beam is transmitted from each light guide path. An object of the present invention is to provide a laser irradiation device that can irradiate simultaneously or selectively.

The invention will now be described in detail with reference to the accompanying drawings.

FIG. 1 is an explanatory diagram showing one embodiment of the present invention.

As shown in the figure, a first working laser light source 1 and a first working laser light #j2 are provided inside the maggot pufferfish 13, and generate a first loser light 5 and a second laser light 6, respectively. do.

Here, for example, a CO2 laser is used as the first working laser light source, and a YAG laser is used as the second working laser light source.

In the figure, 3 and 4 indicate /yasota, and by opening and closing each, the emission of the first and second laser beams 5 and 6 is controlled. When the heat exchangers 3 and 4 are in a closed state, the laser beam 5.6 is incident on the heat exchangers 3' and 4'.

On the other hand, a dichroic mirror 7 and a reflecting mirror 9 are placed on the optical path of the first loser light 5.

In fact, a reflection mirror 8 is positioned on the optical path of the second laser beam 6.

Here, the dichroic mirror 7 is adjusted to be transparent to the first laser beam 5 and reflective to the second laser beam 6.

Therefore, the second laser beam 6 reflected by the reflection mirror 8 is
It is adjusted coaxially with the first loser light 5 by a dichroic mirror 7.

Further, the reflection mirror 9 is equipped with a slide mechanism (t' shown in the figure), and the mirror is moved in parallel between position A and position A'. Position A indicates that the mirror is on the optical path of the loser light 5, and position A' indicates that it is outside the optical path. By operating the reflecting mirror 9, the optical path of the light beam incident on the mirror is switched between the 14th light guide channel and the 2nd light guide channel.

That is, when the reflecting mirror 9 is at the position AK, the optical path of the light beam incident on the mirror is switched, and after being reflected by the reflecting mirror 10, it is introduced into the second light guide path 12. When the reflecting mirror 9 is at position A', the light flux is introduced into the first light guide path 11.

As is clear, a manipulator light guide is used for the first light guide 11 and a fiber light guide is used for the second light guide 12. Manipulator light guides are desirable for surgical use because they can focus the illuminating laser light into a tiny spot. However, the fiber light guide is used under endoscopy.

In the apparatus having the above configuration, when the reflecting mirror 9 is set at position A', that is, in the first light guide channel, the apparatus operates as follows.

When the first and second working laser light sources 1.2 are in the oscillation state, when the shutter 3.4 is opened, the first and second laser lights 5.6 are emitted. Therefore, as mentioned above, the rule
The laser light 5 and the second laser light 6 reflected by the reflection mirror 8 are superimposed and introduced into the first light guide path 11 . That is, the first laser beam and the second laser beam can be irradiated simultaneously from the first light guide path 11.

If you open Tsuyatsuta 3 and close only 7 Yasota 4,
Only the first loser light 5 is emitted from the first light guide path 11 .

Similarly, when the glosser 4 is opened and only the laser beam 3 is closed, only the second laser beam 6 is irradiated from the first light guide path 11.

Next, the state where the reflection mirror 9 is at position A, that is, the second
The operation of the light guide channel will be explained.

When both the vines 3 and 4 are open, the first
And the second laser beam 5.6 is superimposed by the dichroic mirror 7, and then reflected by the reflecting mirror 9 and the reflecting mirror 10.
The light is reflected and directed into the second light guide path 2.

That is, from the second light guide path 12, the first loser light 5 and the second
Laser light 6 is irradiated at the same time.

Now, let's release Tsuyatsuta 3'! When only the light source 4 is closed, only the loser light 5 is irradiated from the second light guide path 12.

11. When only the laser beam 3 is closed, only the second laser beam 6 is irradiated from the second light guide path I2.

FIG. 2 is an explanatory diagram showing another embodiment of the present invention. In this embodiment, a visible guide light source 14 is provided, and the visualization of the first and second laser beams 5, 6 is defined as will be described later.

A visible laser such as a He-Ne laser is used as the guide light source 14, and generates guide light 15.

16 shown in the figure is a dichroic mirror, and 17
indicates a reflective mirror. Dichro ink mirror 16
is transparent to the first loser light 5, and is transparent to the guide light 15.
It is adjusted to have reflective properties.

The bent dichroic mirror 7 is adjusted to have transparency not only for the first loser light 5 but also for the guide light 15.

7- It should be noted that the other configurations are the same as those of the first embodiment, so the explanation here will be omitted.

In this embodiment, when the light sources 1, 2.14 are in the oscillation state and the glossers 3, 4 are opened, all the laser beams 5, 6.15 are emitted.

Here, the guide light 151'' reflected by the reflecting mirror 17
i. Loser light 5 transmitted through the dichroic mirror 16
superimposed on This superimposed light beam is then directed toward the dichroic mirror 7 and transmitted through the mirror.

On the other hand, the second laser beam 6 reflected by the reflection mirror 8 is superimposed on the first loser beam 5 and the guide beam 15 that have passed through the dichroic mirror 7. The three light beams 5, 6.15 superimposed by the mirror 7 are directed to the reflecting mirror 9.

Therefore, when the reflecting mirror 9 is at the position A', the first and second laser beams are emitted from the first light guide path 11 simultaneously and visually guided. Here, if only the shiner 3 is kept open and the shiner 4 is closed, the first light guide path 1
1, the first laser beam is irradiated in a visible 8-guided manner. On the other hand, if only the shiner 4 is kept open and the shiner 3 is closed, the second laser beam 6 is visually guided and irradiated from the first light guide path 11.

Similarly, by setting the reflecting mirror 9 at position A and controlling the opening/closing of the mirrors 3 and 4, simultaneous irradiation and selective irradiation of the first and second laser beams can be obtained from the second light guide path 12. can. Needless to say, these laser irradiations are performed under visual guidance.

In this embodiment, in front of the dichroic ink mirror 7 (
Here, "front" means the side of the laser light source and indicates the position of the laser beam pathfinder. ), the first loser light 5 and the guide light 15 are superimposed, but there is no need to be limited to this. That is, it may be placed anywhere as long as it is in front of the reflecting mirror 9, and may be superimposed with the second laser beam 6. If the above conditions are met, visible guidance can be achieved for the laser light irradiated from either of the two light guide paths.

As described above in detail, the present invention enables simultaneous irradiation and selective irradiation of two types of working laser beams having different wavelengths for two light guide pots.

Moreover, switching between the first light guide channel and the second light guide channel can be conveniently performed by a simple operation using a single reflecting mirror.

Therefore, according to the present invention, a surgery that maximizes the advantages of laser surgery can be expected in each field.

Further, in the device shown in the second embodiment of the present invention, the light beams irradiated from the tilted portions of the first and second light guide paths are also visually guided, which is very convenient.

In the above-described embodiment, the reflecting mirror 9 is moved in parallel by a sliding mechanism, but the present invention is not limited to this. For example, the rotation of a reflecting mirror may be used. 1. In the embodiment, the laser beams 3 and 4 are used to control the emission of the first and second laser beams 5 and 6, but this can be easily replaced by oscillation control on the laser light sources 1 and 2. Furthermore, in the embodiment described above, the first light guide path 11 may be replaced with a fiber light guide path 7.

[Brief explanation of the drawing]

FIG. 1 is an explanatory diagram showing one embodiment of the present invention, and FIG. 2 shows another embodiment. The symbols given in the figure are: 1. First working laser light source, 2. Second working laser light source, 3.4 7 Yatsuta, 5... Second laser beam, 6. Second laser light, 7.16. Dichroic mirror, 8,9
, 10.17... Reflection mirror, 11 First light guide path, 1
2. Second light guide path, 14... Visible guide light source, 15...
・Guide light, indicates. Patent applicant Japan Infrared Industry Co., Ltd. Representative Norihiro Suenaga

Claims (2)

[Claims] (1) A first working laser light source that generates a second laser beam, a second working laser light source that generates a second laser beam, and first and second light guide paths that transmit the laser beam. In the laser irradiation device, means for controlling emission of the first and second laser beams independently of each other;
means for superimposing the laser beams on the same optical path, and means for switching the optical path in two directions, and the light beam whose optical path has been switched by the means for switching the optical path in two directions is directed to a first light guide path and a second light guide path. A laser irradiation device characterized in that it is introduced into a tilted optical path. (2) The apparatus according to item 1, further comprising a visible guide light source that generates a visible guide light, and a portion of the guide light and the first and second laser beams at a position in front of the reflecting mirror. A laser irradiation device characterized by comprising means for superimposing both on the same optical path.