KR101127789B1 - Fastening Structure for Medical LASER Handpiece - Google Patents

Abstract

The present invention relates to an optical fiber fixing structure of a medical laser handpiece, wherein the hollow portion (110a) is formed in the longitudinal direction and in communication with the hollow portion (110a), the first mounting hole (112) is formed and the first mounting A handpiece body 110 having a second mounting hole 113 stepped radially outwardly from the hole 112 at a rear end thereof; An incision 123 is formed at the tip to be inserted into the first mounting hole 112 of the handpiece body 110 to communicate with the hollow part 110a and to bite and fix the optical fiber f1. The fiber fixture 120 which is in communication with the fiber through-hole 121 is formed; A first fiber passing hole 131 is formed, and a third mounting hole 132 is opened to the fiber fixture 120 so that the fiber fixture 120 can be extrapolated coaxially. The outer circumferential surface 132a of the fastener holder 130 is fastened to the second mounting hole 113, and the fastener holder 130 is fastened to the second mounting hole 113 with respect to the fiber fastener 120. It is characterized in that the incision 123 to bite the optical fiber (f1) by applying a force to push forward, thereby stably holding and fixing the optical fiber even when capturing the molten fat generated during the racer procedure. There is an advantage to this.

Medical laser, handpiece, optical fiber, fixed structure, cushion, assembly angle, fat

Description

Fastening Structure for Medical LASER Handpiece

The present invention relates to an optical fiber fixing structure of a medical laser handpiece, and in particular, an optical fiber of a medical laser handpiece that is suitable to stably hold and fix the optical fiber even when the molten fat generated during the racer procedure is cushioned. The fiber fixing structure.

A general medical laser system includes a laser oscillation device having a laser oscillation unit for oscillating a laser, and a handpiece, which is a part of a hand held by an operator to adjust the direction of the laser oscillated by the laser oscillation device. The laser oscillated at is guided by the laser beam transmitter and delivered to the handpiece.

In addition, among the medical lasers, dermatological procedures used for skin removal, fat removal, etc. In the case of medical lasers, the laser oscillated by the laser oscillator is guided by the optical fiber and transferred to the handpiece. It occurs and is accompanied by pain, and the process of cooling the skin to be treated is necessary to cool the high temperature heat and to alleviate the pain caused by the procedure.

In addition, a configuration may be provided for suctioning the melted fat or water by the laser generated during the procedure.

1 is a cross-sectional view of an optical fiber fixing structure of a medical laser handpiece according to the prior art.

As shown in FIG. 1, the medical laser handpiece 10 according to the related art includes a handpiece body 11 having a hollow portion 11a formed in a longitudinal direction so as to house an optical fiber f1. The silicon guide 12 is inserted into the hollow portion of the distal end of the handpiece body 11 and has a fiber through hole 12a for inserting the optical fiber f1 therein to hold the optical fiber, and the silicon guide ( 12) and an optical fiber f1 is provided in the longitudinal direction in the coaxial direction so as to be configured as a cannula 13 for guiding the optical fiber to the subcutaneous fat.

However, the medical laser handpiece 10 according to the prior art as described above has the following problems.

The subcutaneous fat may be melted during the laser treatment process. The melted subcutaneous fat may rise up to the fiber passage hole 12a of the silicon guide 12 by the cannula 13 during the cushioning process.

The molten fat raised to the fiber passage hole (12a) is very slippery lubricating action, there was a problem that the silicon guide 12 does not properly hold the optical fiber (f1).

As described above, when the silicon guide 12 does not properly hold the optical fiber f1 and slides in the hollow part 11a, the optical fiber has difficulty in the procedure because of the flow or play.

The present invention was created to solve the problems of the prior art as described above, the object of the optical fiber fixing structure of the medical laser handpiece according to the present invention,

First, even if the molten fat generated during the racer treatment is cushioned, the optical fiber can be stably held and fixed,

Secondly, the incision is formed at the tip of the fiber fixture and the fiber holder is pushed forward while the fastener holder is fastened to the handpiece body and the assembly angle of the first mounting hole of the handpiece body and the tip of the fiber fixture The fiber can be held by directly biting it to make the fiber more stably fixed,

Third, by pressing the fixture holder to the handpiece body and compressing the sealing member made of silicon, the gap between the optical fiber and the second fiber passing hole of the sealing member is minimized so that the airtightness can be perfectly realized at the time of suction. An optical fiber fixing structure of a medical laser handpiece is provided.

In the optical fiber fixing structure of the medical laser handpiece of the present invention for achieving the above object, the hollow portion is formed in the longitudinal direction so that the optical fiber can be embedded, the first mounting hole is formed in communication with the hollow portion A handpiece body having a second mounting hole formed at a rear end thereof in a radially outward step from the first mounting hole; Is inserted into the first mounting hole of the handpiece body, the incision is formed in the incision in order to bite and fix the optical fiber communicating with the hollow portion and passing through the inside, the optical fiber is passed through the communication to the incision A fiber fixture having a fiber through-hole formed therein; A first fiber through hole is formed through which optical fibers can pass in the longitudinal direction, and the fiber fixture can be extrapolated coaxially. A third mounting hole opened toward the fiber fixing part, and an outer circumferential surface of the third mounting hole is fastened to the second mounting hole, and includes a fastener holder fixed to the handpiece body, 2 in the process of fastening to the mounting hole by applying a forwarding force (pushing forec) to the side of the front end of the handpiece body with respect to the fiber fastener inserted in the third mounting hole so that the incision portion bites the optical fiber It features.

The optical fiber fixing structure of the medical laser handpiece of the present invention having the configuration as described above has the following effects.

First, there is an effect that can hold and fix the optical fiber stably even when capturing the molten fat generated during the racer procedure.

Secondly, the incision is formed at the tip of the fiber fixture and the fiber holder is pushed forward while the fastener holder is fastened to the handpiece body and the assembly angle of the first mounting hole of the handpiece body and the tip of the fiber fixture Since the fiber can be directly held by holding the fiber, the fiber can be fixed more stably.

Third, by pressing the fastener holder to the handpiece body by pressing the sealing member of the silicon material, the gap between the optical fiber and the second fiber passing hole of the sealing member can be minimized, thereby effectively implementing airtightness at the time of suction.

The following will be described in detail with reference to the accompanying drawings a preferred embodiment of the optical fiber fixing structure of the medical laser handpiece of the present invention.

Figure 2 is a perspective view of the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention, Figure 3 is a cross-sectional view of Figure 2, Figure 4 according to an embodiment of the present invention Main part back perspective view of the optical fiber fixing structure of the medical laser handpiece is shown, Figure 5 is an enlarged cross-sectional view of the main portion of the handpiece body 110 in the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention. 6 is a cross-sectional view of the fiber fixture 120 in the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention, and FIG. 7 is a front view of FIG. 8 is a cross-sectional view of the fixture holder 130 in the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention, Figure 9 The cross-sectional view of the sealing member 140 in the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention is shown.

As shown, the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention, the hollow portion (110a) is formed in the longitudinal direction therein so that the optical fiber (f1) can be nested, The first mounting hole 112 is formed in communication with the hollow portion 110a, and the first step is formed radially outwardly from the first mounting hole 112 to have an inner diameter larger than the first mounting hole 112 2 mounting holes 113 are inserted into the handpiece body 110 formed at the rear end and the first mounting hole 112 of the handpiece body 110, and communicate with the hollow part 110a and the inside thereof. In order to bite and fix the optical fiber f1 passing therethrough, an incision 123 is formed at the distal end, and the fiber passage hole 121 through which the optical fiber f1 passes through the incision 123 is communicated with the incision 123. The formed fiber fixture 120 and the optical fiber f1 can be passed in the longitudinal direction. The first fiber through hole 131 is formed, and the inner peripheral surface is opened toward the fiber fixture 120 having a cylindrical shape so as to coaxially extrapolate the fiber fixture 120 inserted into the first mounting hole 112. A third mounting hole 132 formed therein, and a fixture holder having an outer circumferential surface 132a of the third mounting hole 132 fastened to the second mounting hole 113 to be fixed to the handpiece body 110. Characterized in that it comprises a 130.

At this time, the medical laser handpiece according to an embodiment of the present invention, the fiber fixture (inserted in the third mounting hole 132 in the process of fastening the fixture holder 130 to the second mounting hole 113 ( It is characterized in that the incision 123 to hold the optical fiber (f1) by applying a forwarding force (pushing forec) which is the side with the front end of the handpiece body 110 with respect to 120.

The optical fiber f1 is inserted into the fiber insertion hole 124 and the cannula 140 to guide the laser oscillated by the laser generator.

The fastener holder 130 is fastened to the third mounting hole 132 by way of fastening, for example, may be fastened by a screw fastening method as shown.

In the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention, the first mounting hole 112 is a hole body 112a having an inner circumferential surface and an optical fiber in the hole body 112a. (f1) is characterized in that it consists of a hole tip 112b inclined downward so as to narrow toward the center passing.

The outer circumferential surface of the fiber fixing member 120 is formed to correspond to the shape of the first mounting hole 112, and the body portion 120a has a cylindrical shape to correspond to the shape of the hole body 112a. The tip 120a is inclined downward toward the center through which the optical fiber passes from the body 120a to correspond to the shape of the hole body 112a, and the tip 120b is the cutout 123. It is characterized in that it is symmetrically divided around.

In the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention, when the fixing holder 130 is coupled to the second mounting hole 113 while pushing the fiber fixing member 120 to the front end The inclination angle θ1 of the tip tip 120b is inclined downward of the hole tip 112b so that the tip 120b may be retracted inward to allow the cutout 123 to bite and hold the optical fiber f1. It is characterized by being smaller than the angle θ2.

In the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention, between the cutout 123 and the optical fiber hollow hole 121 to hold the center position where the optical fiber f1 passes A first center through hole 122 is formed, and the cutout 123 and the fiber through hollow hole 121 communicate with each other by the first center through hole 122, and the hollow part 110a. And a second center through hole 110b is formed between the first and second mounting holes 112 to hold a center position through which the optical fiber f1 passes, and the hollow is formed by the second center through hole 110b. The unit 110a and the first mounting hole 112 are in communication with each other.

In the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention, the handpiece body 110, the suction tube 115 for capturing the subcutaneous fat melted by laser treatment is the hollow portion ( It is formed in communication with the branch 110a, the fiber through the hollow hole 121, the second fiber through hole 141 in the longitudinal direction communicates with the cutout 123 and the first fiber through hole 131. It is formed to, and characterized in that the seal ring member 140 is further included to prevent the molten fat or water that is the suction target during the suction (suction). The suction pipe 116 may be connected to the suction pipe 115.

In the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention, the sealing member 140 is made of an elastic material, for example, silicon, the bottom surface 132b of the third mounting hole 132 ) And a compression protrusion 133 which protrudes toward the fiber fixing part 120 and has a third fiber passing hole 133a formed therein to communicate with the second fiber passing hole 141. The pressing force 133 pushes forward against the sealing member 140 on the fiber through hollow hole 121 in the process of fastening the fixture holder 130 to the second mounting hole 113 (push forec). By compressing the sealing member 140 in the radial and longitudinal directions to minimize the gap between the optical fiber f1 and the second optical fiber through hole 141 to increase the sealing efficiency. do.

In the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention, the cannula is coupled to the front end of the handpiece body 110 and the optical fiber f1 is provided coaxially in the longitudinal direction. cannular) 150 is further characterized in that it is configured to include.

Meanwhile, in the optical fiber fixing structure of the medical laser handpiece according to the present invention, the silicon guide 12 described in the related art may be provided at the tip of the handpiece body 110.

The following describes the operation of the optical fiber fixing structure of the medical laser handpiece of the present invention having the configuration as described above.

10 is a view illustrating a fastening operation of the fiber fixture 120 and the fixture holder 130 in the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention (more specifically, the cutout of the fiber fixture 120). An operation diagram in which 123 bites and holds the optical fiber f1 is shown.

When the cushion is not necessary, an embodiment of the present invention can be implemented without using the sealing member 140.

As shown in (a) of FIG. 10, the fiber holder 120 is inserted into the first mounting hole 112, and then the fixture holder 130 is coupled to the second mounting hole 113 (for example, forcing). ) Or by screwing in.

At this time, since the inclination angle θ1 (for example, 57 degrees) of the tip tip 120b is smaller than the inclination angle θ2 (for example, 60 degrees) of the hole tip 112b, the tip tip 120b maintains a slight gap with respect to the hole tip 112b. The cutout 123 maintains a normal state.

As shown in (b) of FIG. 10, when the fixture holder 130 is coupled to the second mounting hole 113 (for example, by forcing or screwing, etc.), the fiber fixture 120 may be mounted in the third manner. Since the bottom surface 132b of the third mounting hole 132 pushes the fiber fixture 120 forward because it is interpolated in the hole 132, the fiber fixture 120 is pressed forward and receives a tip tip 120b. ) Is in close contact with the hole tip 112b.

As the tip tip 120b is in close contact with the hole tip 112b as described above, the cutout portion 123 is pulled into the center of the optical fiber f1 and the bite of the optical fiber f1 is firmly fixed.

FIG. 11 is a view illustrating a fastening operation of the fiber fastener 120, the sealing member 140, and the fastener holder 130 in the optical fiber fixing structure of the medical laser handpiece according to the embodiment of the present invention.

When a cushion is required, the sealing member 140 is used to implement an embodiment of the present invention.

As shown in (a) of FIG. 11, the fixture holder 120 is inserted into the first mounting hole 112 and the sealing member 140 is inserted into the fiber through-hole hole 121. The 130 is prepared to be coupled to the second mounting hole 113.

As shown in FIG. 11B, when the fixture holder 130 is coupled to the second mounting hole 113, the pressing protrusion 133 compresses the sealing member while pushing the sealing member forward.

When the pressing protrusion 133 compresses the sealing member 140 by applying a push forec to the fiber passing hollow hole 121 against the sealing member 140 in the inner tongue, the sealing member 140 is pressed. Is compressed in the longitudinal direction and the radial direction orthogonal to the longitudinal direction, and as a result, the diameter of the second optical fiber through hole 141 is reduced so that the gap between the optical fiber f1 and the second optical fiber through hole 141 is reduced. This is minimized and the optical fiber f1 completely blocks the second optical fiber through hole 141, so that melted fat, water, and the like flow back through the second optical fiber through hole 141 at the time of cushioning. do.

The above embodiments of the present invention are merely one embodiment of the technical idea of the present invention, and of course, other modifications can be made within the technical idea of the present invention by those skilled in the art.

1 is a cross-sectional view of an optical fiber fixing structure of a medical laser handpiece according to the prior art.

Figure 2 is a perspective view of the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention.

3 is a cross-sectional view of FIG. 2.

4 is a perspective view of the main part of the optical fiber fixing structure of the medical laser handpiece according to the embodiment of the present invention.

5 is an enlarged cross-sectional view of the main portion of the handpiece body 110 in the optical fiber fixing structure of the medical laser handpiece according to the embodiment of the present invention.

6 is a cross-sectional view of the fiber fixing tool 120 in the optical fiber fixing structure of the medical laser handpiece according to the embodiment of the present invention.

7 is a front view of FIG. 6.

8 is a cross-sectional view of the fixture holder 130 in the optical fiber fixing structure of the medical laser handpiece according to the embodiment of the present invention.

9 is a cross-sectional view of the sealing member 140 in the optical fiber fixing structure of the medical laser handpiece according to the embodiment of the present invention.

10 is a view illustrating a fastening operation of the fiber fixture 120 and the fixture holder 130 in the optical fiber fixing structure of the medical laser handpiece according to an embodiment of the present invention (more specifically, the cutting of the fiber fixture 120). The unit 123 bites and holds the optical fiber f1.

FIG. 11 is a view illustrating a fastening operation of the fiber fixture 120, the sealing member 140, and the fixture holder 130 in the optical fiber fixing structure of the medical laser handpiece according to the embodiment of the present invention.

          Explanation of symbols on the main parts of the drawings

110; Handpiece body

110a; Hollow part

110b; 2nd Center Passing Hall

112; 1st mounting hole

112a; Holbody

112b; Hole tip

113; 2nd mounting hole

115; Cushion Hall

116; Suction pipe

120; Fiber fixture

120a; Body

120b; Tip Tip

121; Fiber Pass Hollow Hall

122; 1st Center Passing Hall

123; Incision

130; Fixture holder

131; 1st fiber pass hole

132; 3rd mounting hole

132b; Bottom surface of the third mounting hole

132a; Outer peripheral surface of the third mounting hole

133a; 3rd fiber pass hole

133; Crimp stone

140; Sealing member

141; 2nd fiber pass hole

150; Cannula

f; Fiber optic

Claims (7)

The hollow part 110a is formed in the longitudinal direction so that the optical fiber f1 can be embedded therein, and the first mounting hole 112 is formed in communication with the hollow part 110a. A handpiece body 110 having a second mounting hole 113 formed at a rear end thereof in a radially outward step at 112; The cutout portion 123 is inserted into the first mounting hole 112 of the handpiece body 110, and the cutout portion 123 is attached to the tip to bite and fix the optical fiber f1 that communicates with and passes through the hollow portion 110a. A fiber fixing tool (120) formed with a cut and having a fiber through-hole (121) communicating with the cutout (123) and through which an optical fiber (f1) passes; A first fiber through hole 131 through which the optical fiber f1 can be passed in the longitudinal direction is formed, and the fiber fixture 120 can be extrapolated coaxially. A third mounting hole 132 opened toward the fiber fixing part 120 is formed, and an outer circumferential surface 132a of the third mounting hole 132 is fastened to the second mounting hole 113 so that the handpiece body It is configured to include a fixture holder 130 fixed to 110, The front of the front end of the handpiece body 110 with respect to the fiber fastener 120 inserted into the third mounting hole 132 in the process of fastening the fastener holder 130 to the second mounting hole 113 By acting a pushing force (pushing forec) to the incision 123 to bite the optical fiber (f1), The first mounting hole 112 includes a hole body 112a having an inner circumferential surface and a hole tip 112b inclined downward so as to narrow toward the center through which the optical fiber f1 passes from the hole body 112a. The outer circumferential surface of the fiber fixing device 120 is cylindrical to correspond to the shape of the hole body 112a, and the body part 120a to correspond to the shape of the hole body 112a. It consists of a tip tip 120b inclined downward toward the center through which the optical fiber passes, the tip tip 120b is symmetrically divided about the incision 123, When the fixture holder 130 is coupled to the second mounting hole 113 and pushes the fiber fixture 120 forward, the tip portion 120b is retracted inward and the cutout 123 is optical fiber f1. ), The downward inclination angle θ1 of the tip tip 120b is formed to be smaller than the downward inclination angle θ2 of the hole tip 112b. A first center through hole 122 is formed between the cutout 123 and the fiber through hollow hole 121 to hold a central position through which the optical fiber f1 passes, and the first center through hole ( 122, the cutout 123 and the fiber passing hollow hole 121 are in communication with each other, and a center position where the optical fiber f1 passes between the hollow part 110a and the first mounting hole 112. A second center through hole (110b) is formed to hold the, and the hollow portion 110a and the first mounting hole 112 is in communication with each other by the second center through hole (110b). Optical fiber fixing structure of the medical laser handpiece. delete delete delete The method according to claim 1, The handpiece body 110, the junction tube 115 for cushioning the subcutaneous fat melted by the laser procedure is formed in communication with the hollow portion (110a), It is built in the fiber through-holes 121, the second fiber through hole 141 is formed to communicate with the cutout 123 and the first fiber through hole 131 in the longitudinal direction, the suction (suction) The optical fiber fixing structure of the medical laser handpiece, characterized in that further comprises a sealing member 140 for preventing penetration of molten fat or water that is the suction target. The method according to claim 5, The sealing member 140 is made of an elastic material, A third fiber through hole 133a protruding from the bottom surface 132b of the third mounting hole 132 toward the fiber fixing part 120 and communicating with the second fiber through hole 141 is formed therein. Compression protrusion 133 is configured to further include, In the process of fastening the fixture holder 130 to the second mounting hole 113, the pressing protrusion 133 pushes forward with respect to the sealing member 140 on the fiber through hollow hole 121 in the inner snow. By operating the forec to compress the sealing member 140 medical laser handpiece, characterized in that to minimize the gap between the optical fiber f1 and the second optical fiber through hole 141 to increase the sealing efficiency Optical fiber fixing structure. The method of claim 6, The medical laser handpiece, characterized in that it further comprises a cannula (150) coupled to the front end of the handpiece body 110 and the optical fiber (f1) is provided coaxially in the longitudinal direction therein (150) Fiber optic fixing structure.

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