KR101707659B1 - Irradiating Device for Medical Purpose controlling Temperature of High-Power Density Laser Diode and Touching Tip - Google Patents

Abstract

The present invention relates to a medical irradiation apparatus for controlling the temperature of a laser diode and a contact tip. More specifically, the present invention relates to a medical irradiator for controlling the temperature of a laser diode and a contact tip, And controlling the temperature of the contact tip to control the temperature of the contact tip, and a laser diode capable of comfortably receiving a dermatologic related procedure without feeling any inconvenience such as pain caused by the temperature rise of the contact tip will be.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a high-power laser diode,

The present invention relates to a medical irradiation apparatus for controlling the temperature of a high power laser diode and a contact tip. More specifically, the present invention relates to a medical irradiation apparatus for controlling the temperature of a laser irradiation site A high-power laser diode which can control the temperature of the contact tip corresponding to the temperature of the contact tip, and can receive a dermatologically related treatment without any feeling of inconvenience such as pain caused by the temperature rise of the contact tip, .

A laser is a device that generates optical electromagnetic waves using the inductive radiation properties of atoms and substances in excited states, and the light generated in this device is called a laser light. A laser having a wavelength ranging from a sub-millimeter wave to a light region outside the vacuum is referred to as a laser, and a laser having a longer wavelength than a millimeter wave is classified as a major.

The expansion of the majors, invented in 1954, led to the American physicist C.H. Towns and A.L. The shawl specifically suggested the possibility of lasers, and in 1960 T.H. Meiman succeeded in the laser oscillation for the first time. Since then, with the continuous laser invention, a wide variety of lasers using a large number of atoms and materials have been realized.

Different types of laser devices have different media, each has advantages and disadvantages, and has inherent characteristics. According to this characteristic, it is appropriately applied to various kinds of fertilizers. For medical use, it is applied to surgical operation or skin diseases .

Hair removal lasers commonly utilize pigment selectivity, where the laser beam passes through the skin and is converted from hair follicles into heat. Most of the laser uses the infrared region, and the principle is to burn the melanin pigment of the hair follicle. However, when the skin is dark, the efficiency is lowered. Nd YAG lasers or diode lasers have the advantage of being relatively less affected by such skin colors.

Hair is largely divided into thin and delicate hair (Vellus Hair) covering most of the body (except soles and palms) and terminal hair which grows thick hair, eyebrows, eyelashes, beard, armpit, etc. and most hairdressing Purpose Hair removal is targeted to Our Lady.

The cycle of hair is divided into three stages: Anagen, Catagen, and Telogen. Among them hair targeted by hair removal laser, hair removal, etc. is hair in 'Anagen'.

Laser hair removal usually requires 3 to 4 times to 8 to 10 occasions to complete hair removal. This is because there is a certain amount of hair that does not react with the laser. Considering the period of hair growth, the treatment is performed once every 4 to 6 weeks, and it is necessary to equip the hair removal device with high output, the heat sensation felt by the recipient, and the chilling to keep the pain minimized .

Currently, most of the products used in the clinics and clinics that are operating the skin cosmetic surgery are products that are supplied from abroad. Although they are excellent in performance and efficiency, they are difficult to change in reality from the viewpoint of economic efficiency considering market. Because of the high supply price of these surgical instruments, the operation cost in the clinic is becoming high price.

The products manufactured in the domestic market have a problem in that the operator can not satisfy the requirements required in the actual market because he or she feels a hot feeling or pain due to the inability to provide the output required for the hair removal or sufficient cooling.

A related related art is Korean Patent Registration No. 10-0855319 (registered on Aug. 25, 2008, entitled "Medical Skin Quenching Device"). The above-mentioned prior art can quickly and effectively cool the treatment area of the skin by rapidly cooling the treatment area of the skin using a tip with a lowered temperature by using the Peltier effect during skin treatment such as botox treatment and the like, Provided is a medical skin quenching device which can perform a procedure related to skin treatment more efficiently with ease.

The medical skin quenching device provided in the prior art includes a tip that contacts the treatment area of the skin, a Peltier element that keeps the tip in a low temperature state while contacting the tip using the low temperature part, and a power supply Device, and a housing for housing these.

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the above-mentioned problems, and it is an object of the present invention to provide a high-power 808nm diode laser wavelength that is safer than a conventional hair removal laser wavelength, It is an object of the present invention to provide a medical laser apparatus which can reduce the pain of a patient by applying a cooling system, and control the temperature of the laser diode and the contact tip, which are free from problems for long-

In order to accomplish the above object, the medical irradiator for controlling the temperature of the laser diode and the contact tip according to the present invention is characterized in that the conventional medical irradiator has insufficient cooling ability, In order to solve the problem of feeling pain and heat, a cooling module can be installed to sufficiently cool the contact tip, and thus a laser with a high output (480 W) can be used.

Therefore, the medical irradiator for controlling the temperature of the laser diode and the contact tip according to the present invention includes a contact tip 30 which contacts the treatment area of the skin, a contact tip 30 which is in contact with the contact tip 30, A laser diode 60 for irradiating a medical laser through the contact tip 30 and a plurality of Peltier elements 32 (34, 36, 38) , 34, 36, 38), and a power supply for supplying power to the laser diode (60).

The medical irradiator includes a cooler (50) for cooling the distilled water, and the cold distilled water supplied from the cooler (50) first cools the Peltier element of the Peltier elements, and the Peltier element And the distilled water flowing out of the Peltier element cooling the laser diode and cooling the remaining Peltier element.

Wherein the part of the Peltier elements is one or two Peltier elements of the Peltier elements,

Characterized in that the contact tip (30) is made of aluminum,

The laser irradiated from the laser diode 60 is an 808 nm diode laser.

The medical irradiator according to the present invention is a medical device for hair removal using an 808 nm diode laser. In the system for controlling the temperature of the laser diode and the contact tip, distilled water having a lowered water temperature passing through the cooler 50 is supplied to the Peltier element P1 (32) The temperature difference between the temperature of the laser diode 60 and the temperature of the distilled water discharged through the outlet 42 is lowered so that the condensation of the laser diode 60 is prevented It is possible to prevent electrical damage, to stably store the laser diode 60, and to lower the cooling efficiency due to a change in the external temperature depending on the use area of the laser irradiation device.

Ultimately, the medical irradiator according to the present invention is capable of performing the treatment regardless of the skin type or season by applying the 808 nm diode laser on the assumption that the temperature of the contact tip is maintained at a temperature at which the subject does not feel inconvenience, The safety of the procedure is improved, the temperature and pain of the patient are low, and there is no scar or procedure sign after the surgery.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic perspective view of a medical laser for controlling the temperature of a laser diode and a contact tip according to the present invention; FIG.
2 is a perspective view of a laser irradiation module for performing temperature control in a medical irradiation device for controlling the temperature of a laser diode and a contact tip according to the present invention.
FIG. 3 is a view showing the laser irradiation module for temperature control in the medical irradiation device for controlling the temperature of the laser diode and the contact tip according to the present invention, and the internal configuration of the laser irradiation module.
4 is a cross-sectional view of a laser irradiation module for performing temperature control in a medical light irradiator for controlling the temperature of the laser diode and the contact tip according to the present invention.
FIG. 5 is a configuration diagram of a temperature control module for a laser irradiation module that performs temperature control in a medical illuminator that controls temperatures of a laser diode and a contact tip according to the present invention.
6 and 7 are block diagrams of a temperature control module for a laser irradiation module that performs temperature control in a medical light irradiator for controlling the temperature of the laser diode and the contact tip according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic perspective view of a medical laser for controlling the temperature of a laser diode and a contact tip according to the present invention; FIG.

Referring to FIG. 1, a laser diode according to the present invention and a contact tip 30 for controlling the temperature of a contact tip are disposed inside a handpiece 10 of a medical irradiator, And a laser irradiation module 20 for controlling the temperature of the laser beam.

2 is a perspective view of a laser irradiation module for performing temperature control in a medical irradiation device for controlling the temperature of a laser diode and a contact tip according to the present invention. FIG. 3 is a view showing the laser irradiation module for temperature control in the medical irradiation device for controlling the temperature of the laser diode and the contact tip according to the present invention, and the internal configuration of the laser irradiation module.

2 and 3, the laser irradiation module 20 for controlling the temperature of the laser diode according to the present invention and the medical irradiator for controlling the temperature of the contact tip irradiates the laser to the outside of the rare- And four Peltier elements P1, P2, P3, and P4 (32, 3, 36, and 38) are vertically and horizontally disposed around the contact tip 30, respectively, .

The inlet 40 into which the cooling water for lowering the temperature of the Peltier element P1 according to the present invention installed inside the laser irradiation module 20 according to the present invention and the Peltier element P1 32 with the increased temperature are cooled And an outlet 42 through which the cooling water is discharged is provided at an upper middle portion of the laser irradiation module 20. [

Inside the laser irradiation module 20 of the present invention, there is provided a hose or the like through which the cooling water moves, and the Peltier element P1 (32) is installed so as to directly contact the hose or the like through which the cooling water flows. Further, it is preferable that a hose or the like through which the cooling water flows is arranged so as to face as wide as possible.

The present invention is characterized in that the distilled water having passed through the cooler 50 of the present invention and having a lowered water temperature passes the Peltier element P1 first, and then the cooling water lowers the temperature of the laser diode 60. [

If the distilled water having a low temperature passed through the cooler 50 serves to cool the laser diode 60 for the first time, an excessive temperature difference between the temperature of the cooling water and the temperature of the laser diode 60 whose temperature has risen due to the power- There is a high possibility that a condensation phenomenon occurs around the laser diode 60. If condensation occurs in the laser diode 60, it is highly likely that the device will fail.

Therefore, after the distilled water having passed through the cooler 50 and having a lowered water temperature is first introduced through the inlet 40 so as to cool the Peltier element P1 32, the Peltier element P1 32 is cooled through the outlet 42 The temperature of the discharged distilled water becomes higher than that of the distilled water flowing through the inlet 40. If the distilled water is supplied to cool the laser diode 60, the temperature difference between the temperature of the laser diode 60 and the temperature of the distilled water discharged through the outlet 42 becomes low, There is an effect that it can be prevented that it occurs.

The laser irradiation module 20 including the contact tip 30 of the present invention is made of aluminum. Accordingly, the weight of the laser irradiation module 20 is lowered, and the weight of the wearer's wrist is reduced, thereby minimizing the burden on the wrist during the operation of the hair removal for a long time and maintaining the heat transfer efficiency of the cooling.

4 is a cross-sectional view of a laser irradiation module that performs temperature control in a medical irradiation device for controlling the temperature of a laser diode and a contact tip according to the present invention.

4, a laser diode 60 is provided inside the laser irradiation module 20 of the present invention. Light rays emitted from the laser diode 60 are transmitted through the contact tip 30 to the patient's skin .

In general, an optical filter for condensing the laser beam emitted from the laser diode 60 is installed at the front of the laser diode 60 of the present invention. This is a conventional technique and is omitted from the drawing.

The Peltier element P3 (36) of the present invention is installed in the vicinity of the bottom surface of the laser irradiation module (20).

FIG. 5 is a configuration diagram of a temperature control module for a laser irradiation module that performs temperature control in a medical illuminator that controls temperatures of a laser diode and a contact tip according to the present invention. 6 to 7 are block diagrams of a temperature control module for a laser irradiation module that performs temperature control in a medical light irradiator for controlling the temperature of the laser diode and the contact tip according to the present invention.

5 to 7, it can be seen that four Peltier elements P1, P2, P3, P4 (32, 34, 36, 38) are installed on the basis of the contact tip 30 of the present invention. Peltier elements P1 and P3 32 and 36 are provided above and below the contact tip 30 and Peltier elements P2 and P4 34 and 38 are provided on the left and right sides of the contact tip 30.

The distilled water whose temperature has been slightly lowered in the cooler 50 of the present invention passes through the Peltier element P1 32 and then the distilled water whose temperature has slightly increased flows into the laser diode 60 to lower the temperature of the laser diode 60 do. Thereafter, the distilled water passes through the Peltier elements P2, P3, and P4 (34, 36, and 38) in order to cool the respective elements, and the distilled water with the increased temperature flows into the cooler 50 again.

The lifetime of the laser irradiation module 20 of the present invention is prolonged and four Peltier elements P1, P2, P3, P4 (32, 34 , 36, 38), so that the temperature of the contact tip (30), which is in contact with the patient's skin, is controlled, so that the patient can be treated without any inconvenience.

The cooling module of the Peltier element and the laser diode 60 according to the present invention is configured such that P1 (32) -> laser diode L / D 60 -> P2 34 -> P3 36 -> P4 38 - The temperature of the laser diode 60 is controlled to be in the range of 10 to 30 degrees while the distilled water circulates through the circulation of the cooler 50 to the P1 (32), and the temperature of the contact tip 30 Peltier elements P1, P2, P3, and P4 (32, 34, 36, 38) that lower the temperature are also simultaneously used.

The cooling module according to the present invention can extend the service life of the Peltier element itself by sufficiently cooling each of the Peltier elements P1, P2, P3 and P4 (32, 34, 36, 38) ). ≪ / RTI >

In addition, in the conventional popularized dermatologic irradiation device, although the contact tip 30 is made of copper, there is a problem that the weight of the physician's wrist is increased due to the weight of the contact tip. However, the contact tip 30 according to the present invention has the same skin cooling effect by replacing the material with aluminum and attaching four Peltier elements. However, since the contact tip 30 has a reduced weight and reduces weight applied to the wrist of the practitioner, .

The cooler 50 of the present invention can regulate the temperature level at which the distilled water is cooled and the distilled water originally discharged from the cooler 50 is not one Peltier element unlike the above described configuration, The cooling module may be changed so as to change the tube through which the distilled water flows to cool the element, cool the two Peltier elements, and allow the outgoing distilled water to be taken to cool the laser diode 60.

This corresponds to a deformation to make an optimum environment in which condensation does not occur in the laser diode 60 in consideration of the capacity of the Peltier element, the total number of the Peltier elements, the capacity of the laser diode 60, and the like.

Despite the variations of this cooling module, there is no change in achieving the object of preventing condensation on the laser diode, which is the ultimate goal of the present invention.

7, according to another cooling module of the Peltier element and the laser diode 60 according to the present invention, P1 (32) -> P2 (34) -> laser diode L / D 60 -> P3 ) -> P4 (38) -> cooler (50) -> P1 (32) to circulate the distilled water. In this case, the temperature is higher than the case of FIG. 6 before the distilled water is introduced for cooling the laser diode L / D 60.

According to the medical irradiator for controlling the temperature of the laser diode and the contact tip according to the present invention, the distilled water having passed through the cooler 50 and having a lowered water temperature cools the laser diode 60 so as to cool the Peltier element P1 (32) The temperature difference between the temperature of the laser diode 60 and the temperature of the distilled water discharged through the outlet port 42 is lowered, so that the condensation phenomenon of the laser diode 60 can be prevented.

While the preferred embodiments of the present invention have been described above using specific terms, such description is for illustrative purposes only and that various changes and modifications can be made without departing from the spirit and scope of the following claims. It is one thing. Such modified embodiments are not to be understood individually from the spirit and scope of the present invention, but are to be regarded as falling within the scope of the appended claims.

10: handpiece 20: laser irradiation module
30: Contact tip
32, 34, 36, 38: Peltier element
40, 44: inlet port 42, 46: outlet port
50: cooler 60: laser diode

Claims (5)

A contact tip in contact with the treatment site of the skin;
A plurality of Peltier elements for keeping the contact tip in a low temperature state while the low temperature part is in contact with the contact tip;
A laser diode for irradiating a medical laser through the contact tip;
And a cooler for providing cooling water for cooling the Peltier elements and the laser diode,
Characterized in that cooling water exiting from the cooler cools the Peltier elements of some of the Peltier elements, cooling the Peltier elements of the part and cooling the outgoing cooling water to cool the laser diode. For example.
The method according to claim 1,
Wherein the Peltier elements comprise a first Peltier element and a second Peltier element disposed at mutually spaced locations,
A first cooling water whose one end is connected to an outlet of the cooler and a part of which is in contact with the first Peltier element;
A second cooling water whose one end is connected to the other end of the first cooling water and whose part is in contact with the laser diode;
And a third cooling water pipe having one end connected to the second cooling water and partially connected to the second Peltier element and the other end connected to the inlet of the cooler,
The cooling water is cooled in the cooler and sequentially passes through the outlet of the cooler to the first cooling water, the second cooling water, and the third cooling water, and returns to the cooler through the inlet of the cooler A high-power laser diode and a medical irradiator for controlling the temperature of the contact tip.
The method according to claim 1,
Wherein the Peltier elements comprise a first Peltier element, a second Peltier element, and a third Peltier element provided at mutually spaced locations,
A first cooling water whose one end is connected to an outlet port of the cooler and a part of which is in contact with the first Peltier element and the second Peltier element;
A second cooling water whose one end is connected to the other end of the first cooling water and whose part is in contact with the laser diode;
And a third cooling water pipe having one end connected to the other end of the second cooling water and a part of which is in contact with the third Peltier element and the other end connected to the inlet of the cooler,
The cooling water is cooled in the cooler and sequentially passes through the outlet of the cooler to the first cooling water, the second cooling water, and the third cooling water, and returns to the cooler through the inlet of the cooler A high-power laser diode and a medical irradiator for controlling the temperature of the contact tip.
The method of claim 3,
The Peltier elements further comprise a fourth Peltier element provided at a position spaced apart from the first Peltier element, the second Peltier element, and the third Peltier element,
And the third cooling water is also in contact with the fourth Peltier element. The medical irradiator for controlling the temperature of the high power laser diode and the contact tip.
The method according to claim 1,
Characterized in that the high power laser diode and the contact tip temperature are controlled by cooling the part of the Peltier element and cooling the remaining Peltier elements after the outgoing cooling water cools the laser diode.

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