KR100314093B1 - Laser handpiece - Google Patents

Abstract

PURPOSE: Provided is a laser handpiece, which changes a trace of laser beam conveniently in a narrow space by using a laser fiber as the first method for changing a beam trace. CONSTITUTION: A laser fiber irradiates laser beam generated from a laser beam output unit. A lens for collimating makes a laser beam irradiated by the laser fiber into a parallel ray. A trace of a laser beam outputted through the lens for collimating is changed by a prism and a trace of a laser beam outputted through the prism is finally altered by a reflecting mirror. A focusing lens focuses a laser beam reflected by the reflecting mirror and irradiates to a target. The laser fiber, the lens for collimating, the prism, the reflecting mirror and the focusing lens are kept in a main body. The lens for collimating and the prism are used as the first method for changing a beam trace. The reflecting mirror is the second method for changing a beam trace.

Description

Laser handpiece

The present invention relates to a laser handpiece, and more particularly, to a laser handpiece for irradiating a laser beam output from a laser output device to a predetermined position.

In general, the laser handpiece is to perform a predetermined task by the user irradiating the laser beam output from the laser beam output device to a specific object accurately, in particular, the medical laser handpiece by irradiating the laser beam to the affected part It is used to perform procedures such as cutting and coagulation of the affected part.

On the other hand, laser beams having wavelengths of 1.06 μm and 1.32 μm are typically used for surgery on tissues other than hard objects such as bones or teeth, such as gums or flesh, and are inserted into the laser handpiece during surgery. As the fiber, a silica laser fiber is usually used. In this case, the laser fiber is built up to the end of the laser handpiece so that the laser beam generated at one end of the laser fiber is directly irradiated to the affected part.

However, a laser beam having a wavelength of 2.94 μm is typically used for a procedure in a hard place such as a tooth or a bone. In this case, a sapphire laser fiber is typically used as a laser fiber in the laser handpiece. This is because a conventional silica laser fiber has a very large loss for a laser beam having a wavelength of 2 μm or more, so that the laser beam cannot be properly delivered.

1 shows a conventional laser handpiece used to treat a tooth or bone.

The conventional laser handpiece shown in FIG. 1 includes a sapphire laser fiber 12 and a laser fiber 12 that irradiate a laser beam output from a laser beam output device (not shown) in the handpiece main body 10. The collimating lens 14 for converting the laser beam irradiated from the laser beam into parallel light, and the reflector 16 and the laser beam reflected from the reflector 16 for changing the path of the laser beam output through the collimating lens 14 A focus lens 18 is provided for focusing the beam and irradiating it to one place.

In the conventional laser handpiece described above, since the sapphire laser fiber 12 is less flexible and difficult to bend, the reflector 16 is used to change the path of the laser beam irradiated from the laser fiber 12. The reason for changing the path of the laser beam is to allow the user to easily work.

However, the conventional laser handpiece illustrated in FIG. 1 has a problem that the user is very inconvenient to use because the portion of the handpiece body 10 is held in a straight line.

On the other hand, the angle of the user's hand in the laser handpiece to ease the work is 120 degrees to 140 degrees, and in order to design the handpiece with this structure, the path of the laser beam is used by using two or more reflectors. It should be changed more than two times, but changing the path of the laser beam using the reflector is because the laser beam hits the reflector at an angle, so the size of the reflector becomes large and the angle of the part holding the reflector is difficult to adjust and the size of the handpiece body There is a problem that the user is difficult to work holding in hand.

The technical problem to be achieved by the present invention is to provide a laser handpiece that can be easily changed in the form of a convenient shape for the user to be able to easily change the path of the laser beam in a small space.

1 is a view showing a conventional laser handpiece.

2 is a view showing a laser handpiece according to a first embodiment of the present invention.

3 is a view showing a laser handpiece according to a second embodiment of the present invention.

4 (a) and 4 (b) are top views and enlarged cross-sectional views of the light irradiation tip shown in FIG. 3.

5 (a) to 5 (c) are views showing various examples of the light irradiation tip shown in FIG.

6 (a) and 6 (b) are diagrams showing examples of light irradiation tips having additional injection holes.

7 is a view showing a laser handpiece according to a third embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

20 ... handpiece body, 22 ... laser fiber,

24 collimating lens, 26 prism,

28 ... reflectors, 30 ... focus lenses.

In order to achieve the above technical problem, a laser handpiece using a prism according to the present invention includes: a laser fiber for irradiating a laser beam output from a laser beam output device; A first beam path changing unit for changing a path of a laser beam output from the laser fiber; A second beam path changing unit for finally changing a path of a laser beam output through the first beam path changing unit; A focus lens for focusing the laser beam output through the second beam path changing unit and irradiating it to one place; And a handpiece body for storing the laser fiber, the first beam path changing part, the second beam path changing part and the focus lens.

Preferably, the first beam path changing unit includes a collimating lens for making the laser beam irradiated from the laser fiber into parallel light and one or more prisms for changing the path of the laser beam output through the collimating lens. Do.

The second beam path changing unit may include a reflector configured to finally change a path of an incident laser beam and output a laser beam to the focus lens.

In addition, the prism of the first beam path changing unit is preferably a dove prism having two refractive surfaces and two parallel reflective surfaces.

In addition, the handpiece body is preferably formed at an angle of 90 degrees or more so that the user is convenient to use.

In addition, the air supply pipe and water supply pipe for supplying air and water introduced from the outside for washing and cooling the irradiation unit irradiated with a laser beam; And an injection unit for injecting the air and water supplied through the air supply pipe and the water supply pipe to the irradiation unit, and an energy transfer unit for transferring energy of the laser beam focused by the focus lens to the irradiation unit. It is preferable to further include a light irradiation tip.

In addition, the energy transfer unit is preferably an optical fiber.

The light irradiation tip may further include a connection part connected to the handpiece main body and a protection part for preventing the energy transfer part from being damaged by physical force.

In addition, the end of the energy transfer portion is preferably formed at the same position as the end of the protective portion.

Moreover, it is preferable that the end of the said energy transfer part enters rather than the end of the said protection part, and is formed.

In addition, it is preferable that the end of the energy transfer portion protrudes from the end of the protective portion.

In addition, it is preferable that the end of the protection unit is further provided with one or more injection holes for injecting the air and the water in addition to the irradiation unit.

The first beam path changing unit may be configured to bend the laser fiber for irradiating the laser beam output from the laser beam output device at a predetermined angle to change the second beam path from the end of the laser fiber to which the laser beam is output. The second beam path changing unit may include a concave reflector for changing the path of the laser beam output from the laser fiber and transferring the laser beam to the focus lens.

Hereinafter, a laser handpiece according to embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 shows a laser handpiece according to a first embodiment of the present invention. The laser handpiece shown in FIG. 2 includes a laser fiber 22 for irradiating a laser beam output from a laser beam output device (not shown) and a laser beam irradiated from the laser fiber 22 into parallel light. For changing the path of the laser beam output through the prism 26 and the prism 26 for changing the path of the laser beam output through the collimating lens 24 and the collimation lens 24. Focusing lens 30, laser fiber 22, collimating lens 24, prism 26, reflecting mirror (28) for focusing and irradiating the laser beam reflected by the reflecting mirror 28 to one place 28 and a handpiece main body 20 for storing the focus lens 30. Here, the collimating lens 24 and the prism 26 are the first beam path changing means, and the reflector 28 is the second beam path changing means.

The prism 26 has two parallel reflecting surfaces and two refracting surfaces, and as shown in FIG. 2, the path of the laser beam differs depending on the angles α and β of the reflecting surfaces and the refracting surfaces. Preferably, the dove prism is refracted.

In the laser handpiece according to the first embodiment of the present invention configured as described above, the laser beam output from the laser beam output device (not shown) is irradiated through the laser fiber 22 and irradiated from the laser fiber 22. The laser beam is converted into parallel light by the collimating lens 24 and then incident on the prism 26 to change the path of the laser beam by a predetermined angle. Here, the prism 26 is a prism having two refractive surfaces and two reflective surfaces, so that the path of the laser beam is changed in three planes. Thus, the effect of changing the path of the laser beam using three reflectors can be obtained. .

The laser beam whose path is changed by the prism 26 is focused by the focus lens 30 after the path is finally changed by the reflector 28.

As described above, in the first embodiment of the present invention, since the path of the laser beam is changed by using the prism 26, the handpiece main body 20 may be formed even when the handpiece main body 20 is formed at 90 degrees or more, which is convenient for the user. 20) does not increase in size.

3 is a view showing a laser handpiece according to a second embodiment of the present invention. The laser handpiece according to the second embodiment of the present invention shown in FIG. 3 is introduced from the outside for cleaning and cooling of an irradiation unit (not shown) to which the laser beam is irradiated, compared to the laser handpiece shown in FIG. 2. An air supply pipe and a water supply pipe 32 for supplying air and water, an injection unit 42 and a focus lens for injecting air and water supplied through the air supply pipe and the water supply pipe 32 to an irradiation unit (not shown); It further comprises a light irradiation tip 44 having an optical fiber 40, which is an energy transfer unit for transmitting the energy of the laser beam focused by 30) to the irradiation unit. On the other hand, reference numeral 36 is a connection portion that is connected to the handpiece body 20, reference numeral 38 is a protective part for preventing the optical fiber 40 from being damaged by physical force, and reference numeral 34 is the focus lens 30 When the laser beam focused by the beam is incident on the optical fiber 40, the laser beam is a blocking portion so as not to be disturbed by air and water supplied from the air supply pipe and the water supply pipe 32. Here, the air supply pipe and the water supply pipe 32 are shown as one, but are actually composed of two supply pipes, an air supply pipe to which air is supplied and a water supply pipe to which water is supplied.

4 (a) and 4 (b) are top views and enlarged cross-sectional views of the light irradiation tip 44 shown in FIG. 3.

The laser handpiece according to the second embodiment of the present invention shown in FIG. 3 includes an air and water supply pipe 32 and a light irradiation tip 44 so that the laser beam can be easily irradiated to a predetermined position of the irradiation part. It can wash and cool the irradiation section and can withstand physical shocks caused by hard materials such as teeth.

5 (a) to 5 (c) are diagrams showing various examples of the light irradiation tip 44 shown in FIG.

The light irradiation tip shown in FIG. 5 (a) has an end portion and a protection portion of the optical fiber 40 to accurately match the direction of the laser beam output from the optical fiber 40 and the air and water injected from the injection portion 42. 38) is formed at the same position. The light irradiation tip shown in FIG. 5 (b) is formed so that the end of the optical fiber 40 enters the end of the protection part 38 in order to protect the optical fiber 40 in particular. And, the light irradiation tip shown in Figure 5 (c), the end of the optical fiber 40 so that the laser beam output from the optical fiber 40 is less affected by the air and water injected from the injection section 42 (protection portion ( It is formed to protrude from the end of 38).

6 (a) and 6 (b) show an example of a light irradiation tip having an additional injection hole, and the light irradiation tip shown in FIG. 6 (a) is the end of the protective part 38. FIG. The circular injection hole 46 is further formed in the portion to smoothly flow the air and water, thereby effectively injecting the air and water into the irradiation part, and the light irradiation tip shown in FIG. 6 (b) is a protective part 38. Semi-circular injection hole 48 is further formed at the end of the air and water to facilitate the flow of the air and water to effectively spray to the irradiation part.

7 is a view showing a laser handpiece according to a third embodiment of the present invention. The laser handpiece according to the third embodiment of the present invention shown in FIG. 7 includes a laser fiber 52 for irradiating by changing the direction of the laser beam output from the laser beam output device, and an output from the laser fiber 52. A concave reflector 54 for finally changing the path of the laser beam to be used, and a focal lens 56 and a laser fiber 52 for condensing and irradiating the laser beam reflected by the concave reflector 54 to one place. The handpiece main body 50 for storing the reflector 54 and the focus lens 56 is provided.

In the third embodiment of the present invention, instead of the collimating lens 24 and the prism 26 in the laser handpiece according to the first embodiment shown in Fig. 2, the laser fiber 22 is further extended to a predetermined angle. The curved laser fiber 52 is used, and the concave reflector 54 is used instead of the reflecting mirror 28. That is, the path of the laser beam output from the laser beam output device is directly changed by using the laser fiber 52 and then output to the focus lens 56 through the concave reflector 54. Therefore, the path of the laser beam can be easily changed in a small space.

Meanwhile, the laser handpiece according to the third embodiment of the present invention shown in FIG. 7 may further include an air supply pipe, a water supply pipe, a light irradiation tip, and the like, as in the second embodiment shown in FIG. In this case, various types of light irradiation tips shown in FIGS. 5 and 6 may be used.

As described above, the laser handpiece according to the present invention can facilitate the alignment of the optical axis by using a prism as the first beam path changing means, and the laser in a small space by using the laser fiber as the first beam path changing means. Since the path of the beam can be easily changed, the laser handpiece can be manufactured in a form convenient for the user to work with. In addition, the use of the present invention has the advantage that the light of different wavelengths, such as the aiming wavelength is irradiated at a point without chromatic aberration to the aiming site, the present invention is a medical laser including dental, skin cosmetic surgery, as well as other industrial processing machines It is also applicable to lasers.

Claims (19)

A laser fiber for irradiating a laser beam output from the laser beam output device; A first beam path changing unit having a collimating lens for converting the laser beam output from the laser fiber into parallel light and at least one prism for changing a path of the laser beam output through the collimating lens; A second beam path changing unit for finally changing a path of a laser beam output through the first beam path changing unit; A focus lens for focusing the laser beam output through the second beam path changing unit and irradiating it to one place; And And a handpiece body for storing the laser fiber, the first beam path changer, the second beam path changer, and the focus lens. The laser handpiece of claim 1, wherein the second beam path changing unit includes a reflector configured to finally change a path of an incident laser beam and output a laser beam to the focus lens. The laser handpiece of claim 1, wherein the prism of the first beam path changing unit is a dove prism having two refractive surfaces and two parallel reflective surfaces. The laser handpiece of claim 1, wherein the body of the handpiece is formed at an angle of 90 degrees or more to facilitate a user's use. According to claim 1, Air supply pipe and water supply pipe for supplying air and water from the outside for cleaning and cooling the irradiated portion irradiated laser beam; And Light having an injection unit for injecting the air and the water supplied through the air supply pipe and the water supply pipe to the irradiation unit and an energy transfer unit for transferring the energy of the laser beam focused by the focus lens to the irradiation unit. Laser handpiece further comprises a probe tip. The laser handpiece of claim 5, wherein the energy transfer unit is an optical fiber. The laser handpiece of claim 5, wherein the light irradiation tip further comprises a connection part connected to the handpiece body and a protection part for preventing the energy transfer part from being damaged by physical force. 8. The laser handpiece according to claim 7, wherein the end of the energy transfer part is formed at the same position as the end of the protection part. 8. The laser handpiece according to claim 7, wherein an end portion of the energy transfer portion is formed to enter an end portion of the protection portion. 8. The laser handpiece according to claim 7, wherein an end portion of the energy transfer portion protrudes from an end portion of the protection portion. 8. The laser handpiece according to claim 7, wherein at least one injection hole for injecting the air and the water is further provided at the end of the protection part. A laser fiber for irradiating a laser beam output from the laser beam output device; A concave reflector for finally changing a path of a laser beam output from the laser fiber; A focus lens for focusing and irradiating a laser beam output through the concave reflector; And A handpiece body for storing the laser fiber, the concave reflector, and the focus lens, Bending the laser fiber for irradiating the laser beam output from the laser beam output device at a predetermined angle to form an end of the laser fiber at which the laser beam is output, located near the concave reflector, so that the laser outputs from the laser fiber And a beam is irradiated to the concave reflector. 13. The apparatus of claim 12, further comprising: an air supply pipe and a water supply pipe for supplying air and water introduced from the outside for washing and cooling the irradiated portion to which the laser beam is irradiated; And Light having an injection unit for injecting the air and the water supplied through the air supply pipe and the water supply pipe to the irradiation unit and an energy transfer unit for transferring the energy of the laser beam focused by the focus lens to the irradiation unit. Laser handpiece further comprises a probe tip. The laser handpiece of claim 13, wherein the energy transfer unit is an optical fiber. The laser handpiece of claim 13, wherein the light irradiation tip further comprises a connection part connected to the handpiece body and a protection part for preventing the energy transfer part from being damaged by physical force. The laser handpiece according to claim 15, wherein the end of the energy transfer part is formed at the same position as the end of the protection part. 16. The laser handpiece according to claim 15, wherein an end of said energy transfer portion is formed inward of an end of said protection portion. 16. The laser handpiece according to claim 15, wherein an end of said energy transfer part is formed to protrude from an end of said protection part. 16. The laser handpiece according to claim 15, wherein at least one spray hole for injecting the air and the water is further provided at the end of the protective part.