KR101281531B1 - Medical laser delivery device - Google Patents

Abstract

PURPOSE: A medical laser transfer device is provided to form a 360-degree revolution by preventing a cable to be twisted or disconnected in the rotation. CONSTITUTION: A refraction arm (10) connects multiple induction pipes. The refraction arm is installed between laser output sides of a laser generating apparatus. A plate body (40) is fixed to the laser output side of the laser generating apparatus. The plate body has one or more conductive patterns. A first signal transmitting apparatus (50) rotates according to the refraction arm.

Description

Medical laser delivery device {MEDICAL LASER DELIVERY DEVICE}

The present invention relates to a medical laser delivery device having a form of refractive cancer, and more particularly, to a medical laser delivery device so that the rotation can be made smoothly without interference from the cable.

Recently, the use of laser during dermatological and surgical procedures is a general trend. In medical treatment, laser treatment is performed in various ways such as incision of skin tissue, hemostasis, pain relief, tattoo removal, and skin dermabrasion.

As such, the laser used in the medical procedure is a high power laser and is oscillated in the laser generator. Since the high power laser oscillated by the laser generator is difficult to be transmitted directly to the patient, a laser delivery device capable of delivering the high power laser generated by the laser generator to the patient is needed.

The laser delivery device may use an optical fiber or may be in the form of a refractive arm. Among them, the laser delivery device in the form of a refractive arm connects several guide tubes (tubes) to rotate, and a reflection mirror is installed at each connection part to guide the laser generated by the laser generator along the guide tube. The handpiece attached to the tip of the laser delivery device irradiates the patient with the laser induced by the laser delivery device.

The laser delivery device is equipped with a guide beam generator for generating a guide beam for guiding a patient's procedure, and the handpiece adjusts the size of the laser and outputs the adjusted signal to the outside. The sensor mounted in the guide beam generator and the handpiece operates by receiving power from the laser transmitting device, and the sensor signal output from the sensor is transmitted to the laser transmitting device. That is, the cable drawn from the laser generator is connected to the sensor of the guide beam generator and the handpiece to transmit power and sensor signals. Typically the cable is routed along the length of the laser delivery device.

However, since the cable is wired along the length of the laser delivery device, the laser delivery device is restricted from rotating, and if the laser delivery device is forcibly rotated, the cable may be twisted or disconnected, causing the system to break down or incorrect signal transmission. There is a problem that a medical accident occurs.

An object of the present invention is to provide a medical laser delivery device that the rotation can be made smoothly without interference from the cable.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the particular embodiments that are described. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, There will be.

The present invention for achieving the above object comprises a plurality of induction pipes forming a node connected to each other rotatably, the refractive arm is installed to rotate between the laser output side of the handpiece and the laser generating device; A plate body having one or more conductive patterns constituting concentric circles and fixed to a laser output side of the laser generator; A first signal positioned on one surface of the plate facing the refractive arm and electrically connected to the first cable drawn from the handpiece, the first signal being in contact with the conductive pattern of the plate and rotating along the refractive arm Delivery means; And second signal transmitting means positioned on the other surface of the plate facing the laser generator and electrically connected to a second cable drawn from the laser generator, and in contact with the conductive pattern of the plate.

Specifically, the first signal transmission means may be in the form of a pin.

The first signal transmitting means may be inserted into the groove of the housing having the groove to be elastically inserted to maintain a contact with the conductive pattern of the plate.

The portion of the plate except the conductive pattern may be made of an insulating material.

The plate body, the first signal transmission means and the second signal transmission means may be provided at each part to which the guide tubes of the refractive arm are connected in a set.

According to the present invention, the twist and disconnection of the cable does not occur during rotation does not cause a system failure or medical accident, 360-degree rotation can be made smoothly. In addition, the wiring of the cable can be simplified and visually neat. In addition, since the optical fiber has a shape of a refractive arm rather than a shape, breakage can be minimized and loss of laser energy can be minimized.

1 is a view showing a state in which the medical laser delivery device of the present invention is mounted on a laser generating device.
FIG. 2 is an enlarged view of a portion A of FIG. 1.
3 is a cross-sectional view of FIG. 2.
FIG. 4 is a view illustrating the cover after removing the cover from FIG.
5 is an exploded view of FIG. 2 separately.
6 is a plan view showing a plate body having a conductive pattern in the present invention.
7 is a view showing the first and second signal transmission means connected to the conductive pattern of the plate body in the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like elements in the figures are denoted by the same reference numerals wherever possible. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

As shown in the figure, the medical laser delivery device of the present invention includes a refractive arm 10 provided between the laser generator 1 and the handpiece 3. The refractive arm 10 has a shape in which a plurality of guide tubes 11 forming a node are rotatably connected to each other, and is installed to be rotated on the laser output side 1a of the laser generating apparatus 1 and has a handpiece at the tip. Mount (3) to rotate.

A reflection mirror is installed at the joint formed by the connection portion of the induction pipes 11, and the joint arm 10 receives the laser oscillated by the laser generator 1 through the induction pipes 11 and the reflection mirror. Guided to (3), the handpiece 3 irradiates the patient with a laser induced from the joint cancer (10).

The mounting means 20 is provided in the laser output side 1a of the laser generator 1. The joint arm 10 is rotated 360 degrees from the laser generator 1 by being coupled to the mounting means 20 to be rotated. Mounting means 20 is mounted so as to protrude from the laser output side (1a) to engage the joint arm 10 to be rotated.

The mounting means 20 includes a first fixing member 21, a second fixing member 23, and a third fixing member 25. The first to third fixing members 21, 23 and 25 have a through hole therein. The through hole of the third fixing member 25 is formed in the same shape as the tip of the joint arm 10 to fit the tip of the joint arm 10.

The first fixing member 21 is detachably fixed to the laser output side 1a of the laser generating apparatus 1 by a screw coupling method or the like, and the second fixing member 23 is coupled to the first fixing member 21. It is fixed. The third fixing member 25 is supported by the second fixing member 23 and fits through the through holes of the second and third fixing members 23 and 25, and the bolt 27 is attached to the second and third fixing members 23 and 25. By fixing the third fixing members 23 and 25, the mounting means 20 is firmly fixed to the laser output side 1a of the laser generator 1. The mounting means 20 supports the joint arm 10 to be rotatably coupled to the laser output side 1a.

The support 30 is installed on the outer circumference of the third fixing member 25. The support 30 is attached to the outer circumference of the third fixing member 25 by inserting a hole formed in the center into the third fixing member 25. The support 30 is fixed to the third fixing member 25 by bolting in the horizontal axis direction to the annular projection 31 protruding below the hole.

The plate body 40 is installed on the support 30. The plate 40 is fixed to the support 30 by driving a bolt 41 to the support 30. The plate body 40 has one or more conductive patterns 43.

The conductive patterns 43 are arranged in the plate body 40 in a concentric shape in a ring shape having a different size. The conductive pattern 43 may be formed to be exposed to both the front and rear surfaces of the plate body 40, and only a part of the conductive pattern 43 may be exposed to the rear surface of the plate body 40. The conductive pattern 43 may be formed of a conductive metal such as aluminum or copper. The portion of the plate body 40 except for the conductive pattern 43 is made of an insulating material.

The first signal transmitting means 50 is positioned on the surface of the plate body 40 facing the refractive arm 10. The first signal transmitting means 50 is electrically connected to the guide beam generator (not shown) mounted on the refractive arm 10 and the first cable 51 drawn from the handpiece 3.

The first signal transmitting means 50 and the first cable 51 have the same number as the number of the conductive patterns 43. The first signal transmission means 50 and the first cable 51 may be electrically connected to each other via a connector 53 in the form of a printed circuit board (PCB), and the first cable 51 is bound by one cable. And may be wired along the length of the refractive arm 10.

The first signal transmitting means 50 continues to be in contact with the conductive pattern 43 of the plate body 40. The first signal transmitting means 50 may be formed in the form of a pin made of a conductive metal material.

The first signal transmitting means 50 in the form of a pin has a groove 61 and is elastically retracted with the help of an elastic body 63 such as a spring in the groove 61 of the housing 60 installed in the lower portion of the connector 53. It is inserted so as to maintain the state in contact with the conductive pattern 43 of the plate body 40. At this time, the housing 60 and the elastic body 63 is made of a conductive metal material.

The first signal transmitting means 50 rotates as the refractive arm 10 rotates and moves along the track formed by the conductive pattern 43. The support 30 may be enclosed with a cover 71 covering the connector 53, the connector 53 is firmly fixed to the inner wall surface of the cover 71, and the first cable 51 fixes the cover 71. It penetrates and is connected to the connector 53. Here, the cover 71 protects the plate body 43 and the connector 53 from the outside.

When the refraction arm 10 rotates in a clockwise or counterclockwise direction, the first cable 51 pulls the connector 53 in the rotational direction thereof, whereby the cover 71 rotates on the support 30 so that the first signal is transmitted. The means 50 can move along the track formed by the conductive pattern 43.

The second signal transmitting means 81 is located on the rear surface of the plate body 40 facing the laser generator 1. The second signal transmitting means 81 is electrically connected to the second cable 83 which is drawn out from the laser generator 1. The second cable 83 has the same number as the conductive pattern 43 and can be bound to one cable and drawn out from the laser generator 1.

The second signal transmitting means 81 contacts the conductive pattern 43 exposed on the back surface of the plate 40 to electrically connect the first cable 51 and the second cable 83. The first and second cables 51 and 83 are electrically connected by the first and second signal transmitting means 50 and 81 in contact with the conductive pattern 43 therebetween.

Even if the articulation arm 10 rotates 360 degrees, the first and second cables 51 and 83 are disconnected because the first signal transmission means 50 remains in contact with the conductive pattern 43. I never do that.

The support 30 forms an annular groove 37 below the plate 40 to provide a place where the second signal transmission means 81 can be connected to the conductive pattern 43. The second signal transmitting means 81 may be a connector in the form of a printed circuit board (PCB) fixed to the conductive pattern 43 and may be connected to the second cable 83 (see FIG. 3). In addition, the second signal transmitting means 81 may be the second cable 83 itself. The second cable 83 may be welded and fixed to the conductive pattern 43 to form the second signal transmitting means 81 (see FIG. 7).

As described above, even if the refractive arm 10 rotates 360 degrees from the laser generator 1, the first and second cables 51 and 83 are not twisted or disconnected. As a result, a system failure or a medical accident that has occurred due to twisting or disconnection of the cable does not occur, and the 360 ° rotation of the refractive arm 10 may be smoothly performed.

In addition, the wiring of the cable can be simplified and visually neat, and since the optical fiber has a shape of a refractive arm rather than a shape, damage can be minimized and laser energy can be minimized.

The guide beam generator and the handpiece 3 are provided with the first and second cables 51 electrically connected by the first and second signal transmitting means 50 and 81 in contact with the conductive pattern 43 therebetween. 83 may be operated by receiving the power of the laser generator 1, the sensor signal generated in the handpiece 3 may be transmitted to the laser generator (1).

The number of conductive patterns 43 may be increased or decreased depending on the structure of the device and the handpiece 3 mounted on the refractive arm 10, and the first and second signal transmitting means 50, 81 and The number of second cables 51 and 83 may also increase or decrease according to the number of conductive patterns 43.

The plate body 40, the first signal transmission means 50 and the second signal transmission means 81 may be installed at each part to which the induction pipes 11 of the refractive arm 10 are connected in a set. Then, the first cable 51 will be wired along the refractive arm 10 in a disconnected form at each connection site, and the conductive pattern 43 and the first signal transmission means 50 of the plate body 40 installed at each connection site. ) And the disconnected portion by the second signal transmission means 81 will be electrically connected. As a result, even if the induction pipes 11 of the refractive arm 10 rotate 360 degrees with each other, the first cable 51 is not twisted or disconnected, so that a system failure or a medical accident can be largely prevented, and the first cable 51 can be prevented. Wiring is simplified so that it can be seen visually and neatly.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined by the appended claims. It will be possible. Here, the essential technical scope of the present invention is shown in the claims, and all differences within the equivalent range will be construed as being included in the present invention.

1: laser generator 1a: laser output side
3: handpiece 10: refractive arm
11: guide tube 20: mounting means
21: first fixing member 23: second fixing member
25: third fixing member 27: bolt
30: support 31: annular protrusion
37: annular groove 40: plate body
41: bolt 43: conductive pattern
50: first signal transmitting means 51: first cable
53: connector 60: housing
63: elastomer 71: cover
81: second signal transmitting means 83: second cable

Claims (5)

A plurality of induction pipes forming a node to be rotatably connected to each other, the refractive arm being rotatably installed between the handpiece and the laser output side of the laser generator;
A plate body having one or more conductive patterns constituting concentric circles and fixed to a laser output side of the laser generator;
A first signal positioned on one surface of the plate facing the refractive arm and electrically connected to the first cable drawn from the handpiece, the first signal being in contact with the conductive pattern of the plate and rotating along the refractive arm Delivery means; And
A second signal transmitting means positioned on the other surface of the plate facing the laser generator and electrically connected to a second cable drawn from the laser generator, the second signal transmitting means contacting the conductive pattern of the plate; Device.
The method of claim 1,
The first signal transmitting means is in the form of a pin, medical laser delivery device.
The method of claim 2,
The first signal transmitting means is inserted into the groove of the housing having a groove elastically inserted into the medical laser delivery device to maintain a state of contact with the conductive pattern of the plate.
The method of claim 1,
A portion of the plate except the conductive pattern is made of an insulating material, medical laser delivery device.
The method of claim 1,
The plate body, the first signal transmission means and the second signal transmission means is made in a set, the medical laser delivery device is installed in each portion where the induction tubes of the refractive arm are connected.

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