JPH06127B2 - Optical fiber cable - Google Patents

Description

TECHNICAL FIELD The present invention relates to a laser irradiation device such as a laser beam machine or a laser knife.

Conventional technology Infrared laser light such as CO ₂ laser is suitable for evaporation and incision of living tissue, and a laser irradiation device using this is put into practical use. Heretofore, since an appropriate optical fiber that transmits this wavelength has not been developed, the infrared laser light is guided to a surgical site by a mirror-joint type light guide path composed of a plurality of mirrors. FIG. 4 shows an example of a laser irradiation device using a mirror joint type light guide path 37.
A description will be given based on the figure. Reference numeral 38 denotes a main body having a power source (not shown) and the like, and the laser light emitted from the oscillation tube 39 is sent to the handpiece 40 via several mirrors 36. He / Ne laser light as a visible light guide light is focused on the laser light focus from an oscillator (not shown) in the main body 38 via several mirrors 36. However, the mirror-joint type light guide 37 has a problem of poor operability. For example, an optical fiber cable for guiding the laser light by an optical fiber made of a halide such as KRS-5 has been put into practical use. Came. The optical fiber cable has good operability,
It has a small diameter and can sufficiently handle surgery in the pores. Further, the CO ₂ laser light is an invisible light having a wavelength of 10.6 μ, and requires visible light guide light such as He / Ne laser that clearly indicates the irradiation position to the operator. The mirror joint type light guide 37
Allows the CO ₂ laser light and the He / Ne laser light for the guide light to be docked in the middle and allows the guide light to pass through the center of the CO ₂ laser light. Also, in the optical fiber cable, since the passing wavelength of the optical fiber such as KRS-5 is 1.5μ to 25μ, He ・ N
e Visible light (wavelength 0.68μ) such as laser cannot be passed, and quartz fiber for guide light is also used. Figure 2,
FIG. 3 shows an example of a laser irradiation device using the optical fiber cable 21, which will be described with reference to the drawing. Two
Reference numeral 2 is a main body having a power source (not shown) and the like, and the laser light emitted from the oscillation tube 23 passes through the infrared optical fiber 4 such as KRS-5 in the optical fiber cable 21, and the handpiece 24 Is irradiated from. Reference numeral 25 is an operation panel for controlling the irradiation amount of laser light and the like.
Is a support rod for holding the optical fiber cable 21. Further, He / Ne laser light as visible light guide light passes from an oscillator (not shown) in the main body 22 and a quartz fiber 27 to a quartz fiber 28 in the optical fiber cable 21, and from the handpiece 24 to the laser. Focus on the focus of light. The optical fiber cable 21 will be described with reference to FIG. 29 is the main body 2
It is an incident-side condenser lens attached to the second side, which collects CO ₂ laser light and makes it enter the end face of the optical fiber 4 in the optical fiber cable 21. 30 is Windu. The optical fiber 4 and the quartz fiber 28, one end of which is fixedly held by the input connector 31, the other end thereof is fixed and held by a holder 34, and the holder 34 is attached to a screw (not shown) in the handpiece 24. Fixed. Reference numeral 33 is a condenser lens fixedly held in the handpiece 24. A curvature limiting cable 35 is fixed to the input connector 31 at one end and to the handpiece 24 at the other end by a screw (not shown).

Problems to be Solved by the Invention At present, there are laser irradiation devices using a mirror-joint type light guide path on the market, and it is priced to additionally purchase a laser irradiation device using an optical fiber cable with good operability. However, there is a problem in securing the installation location, etc., and it cannot be easily implemented. Therefore, the mirror joint type has a problem in that it cannot sufficiently cope with the operation in the pores and is difficult for the operator to handle due to operability.

Means for Solving the Problems The present invention relates to an optical fiber for guiding power laser light for surgery, a guide light fiber for clearly indicating the laser light emitted from the optical fiber, and an incidence of the optical fiber and the guide light fiber. Side branching means for branching the surgical power laser light and the guide light incident coaxially thereto to the optical fiber and the guide light fiber entrance, and the branched surgical power laser. An optical fiber cable comprising: an optical unit that collects light and makes it enter the optical fiber.

Action The CO ₂ laser light and the guide light are distributed by the distribution mirror and the condenser lens provided in the optical fiber cable, and the CO ₂ laser light and the guide light are irradiated to the optical fiber and the guide light quartz fiber, respectively. Moreover, it is a structure that can be easily attached to and detached from the mirror joint type light guide path.

Embodiment An embodiment of the present invention will be described with reference to FIG. On the CO ₂ laser emission side of the light guide 2 that holds several mirrors 1 fixed,
The connector 3 containing the optical fiber 4 is fixed by the screw 19. The connector 3 has a distribution mirror 5 inside.
The distribution mirror 5 has one end fixed by a fixing pin 6 and the other end to which a turning pin 8 is attached, and the turning pin 8 slides in a slit groove 7 provided in the connector 3, Can be moved. A guide light mirror 9 is fixedly held at a position corresponding to the distribution mirror 5, and a guide light quartz fiber 10 is fixed at a position corresponding to the guide light mirror 9 with an adhesive or the like. 1
1 is a condenser lens fixed to the lens holder 12,
It is fixed in the connector 3 by screws. The optical fiber 4 is fitted and fixed in a protective tube 13 made of, for example, metal, and is fixed in the connector 3 at a focal position of the condenser lens 11 with a screw. 14 is a fixture,
The connector 3 and the curvature limiting tube 15 are fixed.

The emitted CO ₂ laser light 16 passes through the light guide path 2 through several mirrors 1, passes through the distribution mirror 5, is focused on the condenser lens 11, and passes through the optical fiber 4. It is emitted from a handpiece (not shown).
The He / Ne laser light 17 emitted as the guide light for visible light passes through the light guide path 2 through the several mirrors 1, is reflected by the distribution mirror 5, and passes through the guide light mirror 9. Then, the quartz fiber 10 for guide light is irradiated, and is focused and irradiated from the handpiece (not shown) to the focal position of the CO ₂ laser light.

That is, the distribution mirror 5 is connected to the optical fiber cable 1
Since it is provided in the connector 3 of 8, the CO ₂ laser light 16 can be obtained by simply connecting the connect 3 to the light guide path 2.
At the same time, the guide light 17 can be emitted.

After the optical fiber cable 18 and the light guide path 2 are connected, only the guide light 17 is irradiated and the distribution mirror 5 is rotated, whereby the guide light (He / Ne laser light) is emitted.
The red light of 17 passes through the optical fiber 4 with a slight output though the passing wavelengths are different. Of course, if the optical axis is deviated, even a small irradiation amount cannot be obtained, and the optical axis can be checked by adjusting the position of the condenser lens 11. Further, there is a device that uses not only a CO ₂ laser but also a YAG laser. Against this, it is possible to use a combination of CO ₂ and YAG by injecting into the quartz fiber 10 for guide light. If it is changed to quartz fiber or the like, the distribution mirror 5 is operated and it is also used exclusively for YAG.

EFFECTS OF THE INVENTION The present invention uses an optical fiber cable having a distribution mirror and a condenser lens, so that it can be easily connected to a mirror-joint type light guide path, is easy for the operator to handle, and is sufficiently compatible with surgery in pores. It is possible. Further, with the optical fiber cable of the present invention, it is possible to connect to the laser irradiation device for the mirror-joint type light guide path currently owned without purchasing a new laser irradiation device, which is inexpensive and space-saving, and has good operability. The effect is great.

[Brief description of drawings]

FIG. 1 (a) is a cross-sectional view of an optical fiber cable in one embodiment of the present invention, FIG. 1 (b) is a perspective view of a connector portion, and FIG.
FIG. 4 is an external view of a conventional laser irradiation device, FIG. 3 is a cross-sectional view of a conventional optical fiber cable, and FIG. 4 is an external view of a conventional laser beam irradiation device for a mirror joint type light guide path. 4 ... Optical fiber, 5 ... Distribution mirror, 11 ... Condensing lens, 10 ... Quartz fiber for guide light.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (56) Reference JP-A-52-61387 (JP, A) JP-A-54-36086 (JP, A) JP-A-58-185145 (JP, A) JP-A-58- 185146 (JP, A)

Claims (3)

[Claims] 1. An optical fiber for guiding surgical power laser light, a guide light fiber for clearly indicating the laser light emitted from the optical fiber, and an optical fiber and an incident side of the guide light fiber,
A branching means for branching the surgical power laser light and the guide light incident coaxially with the power laser light and guiding the branched power power laser light to the optical fiber and the entrance port of the guide light fiber. A fiber cable comprising: an optical means that emits light to enter the optical fiber. 2. The optical fiber cable according to claim 1, wherein the branching means is provided on the optical axis of the laser beam. 3. The optical fiber cable according to claim 1, wherein the branching means is rotatable.