KR20240060187A - Chiropractic hybrid treatment device including body-attachable multi-wavelength low-level light energy treatment device and multi-depth subcutaneous tissue simultaneous/cross-permeation ultrasonic wave treatment device - Google Patents

Abstract

A complex surgical device is disclosed. According to one aspect of the present invention, an ultrasonic treatment device capable of performing procedures using ultrasound, a low-output optical energy treatment device that can be used simultaneously or in parallel with an ultrasonic treatment device, and capable of performing procedures using low-output light energy, and a low-output light energy treatment device And a charging device that can be charged by mounting the ultrasonic treatment device, wherein the low-output optical energy treatment device includes a housing having a plurality of light transmission holes formed through penetrating the lower surface, and an agent disposed inside the housing to supply electrical energy. 1 battery, a first circuit board disposed below the first battery and electrically connected to the first battery, and a first circuit board mounted below the first circuit board to generate low-output optical energy in different wavelength bands and disposed corresponding to the light transmission hole. irradiates low-output light energy to the outside and improves the effect of the complex treatment that occurs as low-output light energy of different wavelengths is irradiated together, so that the first area and the first area are divided based on the lower surface of the housing according to the wavelength of the low-output light energy. It includes a plurality of light energy elements arranged separately in a second area around the area, and the low-output light energy irradiated from the light energy elements is absorbed into the electron transport system of the mitochondrial biological membrane within the subcutaneous cells, generating ATP to strengthen the cell's immunity. and increase healing ability, generate ROS to activate cell repair and healing, generate NO to increase blood circulation and reduce inflammation, improve the transport of oxygen and immune cells in tissues, and placed in the first area. The low-output light energy irradiated from the light energy device has a relatively small scattering coefficient and low light absorption rate for melanin compared to the low-output light energy irradiated from the light energy device disposed in the second area, so it is used in the musculoskeletal system located at a depth of 15 mm or more from the skin surface. The amount of light can penetrate up to the trigger point, and the low-output light energy irradiated from the light energy element placed in the second area is relatively high compared to the low-output light energy irradiated from the light energy element placed in the first area. It has a high scattering coefficient and a high light absorption rate for melanin, so the penetration depth is shorter than the low-output light energy irradiated from the light energy element disposed in the first area, but a complex treatment device is provided that can penetrate the amount of light to a depth of 5 mm or more from the skin surface. .

Description

Chiropractic complex treatment device including a body attachable multi-wavelength low-output optical energy treatment device and a multi-depth tissue layer simultaneous/cross-penetrating ultrasound treatment device MULTI-DEPTH SUBCUTANEOUS TISSUE SIMULTANEOUS/CROSS-PERMEATION ULTRASONIC WAVE TREATMENT DEVICE}

The present invention relates to a chiropractic complex treatment device including a body attachable multi-wavelength low-output optical energy treatment device and a multi-depth tissue layer simultaneous/cross-penetrating ultrasound treatment device.

Photobiomodulation (PBM) technology is a treatment technology that irradiates and penetrates light energy such as lasers or LEDs into the human body to achieve effects such as cell regeneration, blood flow improvement, and nerve stimulation. It is used as a rehabilitation treatment technology for the prevention, treatment, and management of musculoskeletal degenerative diseases such as discs, or musculoskeletal pain diseases such as carpal tunnel syndrome, epicondylitis, knee joint pain, and neck syndrome.

Photobiological modulation technology, as a more fundamental treatment mechanism, exerts tissue reconstruction and regeneration effects by generating ATP cells and activating active oxygen and nitric oxide, so it can be used for degenerative and chronic pain diseases, etc., and is a non-invasive treatment method. Since there is no time limit and no side effects have been found, the potential for use in the field of hospital medical devices as well as personal medical devices is very high.

Republic of Korea Patent Publication No. 10-2021-0149125 (published on December 8, 2021)

The present invention provides a complex surgical device including a low-output light energy surgical device and an ultrasonic surgical device that can effectively perform pain treatment for musculoskeletal rehabilitation.

According to one aspect of the present invention, an ultrasonic treatment device capable of performing procedures using ultrasound, a low-output optical energy treatment device that can be used simultaneously or in parallel with an ultrasonic treatment device, and capable of performing procedures using low-output light energy, and a low-output light energy treatment device And a charging device that can be charged by mounting the ultrasonic treatment device, wherein the low-output optical energy treatment device includes a housing having a plurality of light transmission holes formed through penetrating the lower surface, and an agent disposed inside the housing to supply electrical energy. 1 battery, a first circuit board disposed below the first battery and electrically connected to the first battery, and a first circuit board mounted below the first circuit board to generate low-output optical energy in different wavelength bands and disposed corresponding to the light transmission hole. irradiates low-output light energy to the outside and improves the effect of the complex treatment that occurs as low-output light energy of different wavelengths is irradiated together, so that the first area and the first area are divided based on the lower surface of the housing according to the wavelength of the low-output light energy. It includes a plurality of light energy elements arranged separately in a second area around the area, and the low-output light energy irradiated from the light energy elements is absorbed into the electron transport system of the mitochondrial biological membrane within the subcutaneous cells, generating ATP to strengthen the cell's immunity. and increase healing ability, generate ROS to activate cell repair and healing, generate NO to increase blood circulation and reduce inflammation, improve the transport of oxygen and immune cells in tissues, and placed in the first area. The low-output light energy irradiated from the light energy device has a relatively small scattering coefficient and low light absorption rate for melanin compared to the low-output light energy irradiated from the light energy device disposed in the second region, so it is used in the musculoskeletal system located at a depth of 15 mm or more from the skin surface. The amount of light can penetrate up to the trigger point, and the low-output light energy irradiated from the light energy element placed in the second area is relatively high compared to the low-output light energy irradiated from the light energy element placed in the first area. It has a high scattering coefficient and a high light absorption rate for melanin, so the penetration depth is shorter than the low-output light energy irradiated from the light energy element disposed in the first area, but a complex treatment device is provided that can penetrate the amount of light to a depth of 5 mm or more from the skin surface. .

The plurality of light energy elements may include a first element disposed in the second area, and a second element disposed in the first area to irradiate low-output light energy in a relatively high wavelength range compared to the first element.

The plurality of light energy elements include a first element disposed in a second area, and a second element disposed in the first area to irradiate low-output light energy in a relatively high wavelength range compared to the first element, and the first element is , low-output light energy in the 630 to 680 nm wavelength range is irradiated for at least one of pain relief, lymph node stimulation, and edema relief, and the second element is 780 nm to 680 nm for at least one of improving blood flow, strengthening blood flow, and activating cells. It can irradiate low-output light energy in the 990nm wavelength range.

The plurality of light energy elements include a first element disposed in a second area, and a second element disposed in the first area to irradiate low-output light energy in a relatively high wavelength range compared to the first element, and the first element is , provided in plural pieces, arranged at a distance from each other along the outer circumference of the first area with the second element as the reference, and low-output light in a relatively low wavelength range compared to the second element around the skin area where low-output light energy is irradiated by the second element. Energy can be investigated.

The low-output optical energy treatment device is disposed on the lower side of the first circuit board, is in contact with the housing, and has a pass-through hole disposed corresponding to the light transmission hole. As it comes into contact with the photo-energy element inserted into the pass-through hole, the energy generated from the photo-energy element is generated. It may further include a heat sink that transfers heat to the lower surface of the housing.

The low-output optical energy treatment device is mounted on the lower part of the first circuit board, spaced apart from the optical energy element, and is placed corresponding to the light transmission hole, irradiates infrared rays to the outside and receives infrared rays reflected from the skin to detect whether or not the skin is approaching. Additional sensors may be included.

The low-output optical energy treatment device may further include a vibration motor that is electrically connected to the first circuit board and installed to contact the housing to generate and transmit vibration energy to the lower surface of the housing.

The ultrasonic treatment device includes a handpiece, a second battery disposed inside the lower portion of the handpiece to supply electrical energy, a second circuit board electrically connected to the second battery, and a second circuit board electrically connected to the handpiece. An ultrasonic unit that is coupled to one upper side of the unit and converts the electrical energy supplied from the second battery into vibration energy to generate ultrasonic waves, and generates ultrasonic waves of different frequency bands so that the ultrasonic waves can penetrate into the subcutaneous tissue at different depths, enabling single or cross irradiation. may include.

The charging station device includes a main body case having a plurality of insertion holes formed through the upper surface to enable insertion of a low-output optical energy treatment device or an ultrasonic treatment device, and a power port disposed on the side of the main body case and electrically connected to an external power source. , a third circuit board disposed inside the main case, electrically connected to the power port, and equipped with a charging pin that transmits electrical energy for charging at the top, a low-output optical energy formed inside the upper part of the main case and inserted into the insertion hole. It is formed to correspond to the shape of the insertion part of the treatment device or ultrasonic treatment device, opens upward through the insertion hole, and is placed on the upper side of the third circuit board so that the low-output light energy treatment device and the ultrasonic treatment device can be charged while inserted and mounted. It may include a plurality of charging cases with charging pins penetrating through the bottom.

The low-output optical energy treatment device is provided in plural and is attached to or worn on multiple body parts, enabling procedures using low-output light energy to be performed simultaneously on multiple body parts, and the ultrasonic treatment device is capable of performing low-output light energy treatment on one body part. While a procedure using the device is being performed, a procedure using ultrasound can also be performed on other body parts.

The low-output light energy treatment device is provided in plural numbers and is attached to or worn on multiple body parts, enabling procedures using low-output light energy to be performed simultaneously on multiple body parts. The ultrasonic treatment device uses low-output light energy in one body part. So that the procedure using and the procedure using ultrasound can be performed sequentially, the procedure using ultrasound can be performed before or after the procedure using a low-output optical energy treatment device.

According to the present invention, a complex surgical device including a low-output light energy surgical device and an ultrasonic surgical device capable of effectively performing pain treatment for musculoskeletal rehabilitation can be provided.

Figure 1 is a perspective view showing a low-output light energy surgical device included in a complex surgical device according to an embodiment of the present invention.
Figure 2 is a view showing the bottom of the housing of a low-output light energy surgical device included in a complex surgical device according to an embodiment of the present invention.
Figure 3 is a cross-sectional view taken along (a) line AA' and (b) line BB' of Figure 2.
Figure 4 is a perspective view showing an ultrasonic surgical device included in a complex surgical device according to an embodiment of the present invention.
Figure 5 is a cross-sectional view taken along line CC' of Figure 4.
Figure 6 is a perspective view showing a complex surgical device according to an embodiment of the present invention.
FIG. 7 is a cross-sectional view taken along (a) line DD' and (b) line EE' of FIG. 6.
Figure 8 is a graph showing light absorption rates for oxyhemoglobin, melanin, and water according to the wavelength of low-output light energy.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all transformations, equivalents, and substitutes included in the spirit and technical scope of the present invention. In describing the present invention, if it is determined that a detailed description of related known technologies may obscure the gist of the present invention, the detailed description will be omitted.

Terms such as first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

The terms used in this application are only used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Hereinafter, refer to the accompanying drawings for a chiropractic complex treatment device (100) including a body attachable multi-wavelength low-output optical energy treatment device (200) and a multi-depth tissue layer simultaneous/cross-penetrating ultrasound treatment device (300) according to the present invention. This will be described in detail, and when describing with reference to the accompanying drawings, identical or corresponding components will be assigned the same drawing numbers and overlapping descriptions thereof will be omitted.

Figure 6 is a perspective view showing a complex surgical device 100 according to an embodiment of the present invention.

According to this embodiment, as shown in FIG. 6, an ultrasonic treatment device 300 capable of performing a procedure using ultrasonic waves can be used simultaneously or in parallel with the ultrasonic treatment device 300, and is capable of performing a procedure using low-output light energy. A complex surgical treatment device 100 is provided, including a low-output light energy treatment device 200 and a charging device 400 capable of charging the low-output light energy treatment device 200 and the ultrasound treatment device 300 by placing them thereon.

According to this embodiment, a complex surgical device 100 that can effectively perform pain treatment for musculoskeletal rehabilitation by using low-output light energy and ultrasound in combination can be provided.

Hereinafter, each configuration of the complex surgical device 100 according to this embodiment will be described with reference to FIGS. 1 to 7.

FIG. 1 is a perspective view showing the low-output light energy treatment device 200 included in the complex surgery device 100 according to this embodiment, and FIG. 2 is a view showing the bottom of the housing 210 of the low-output light energy treatment device 200. , and FIG. 3 is a cross-sectional view taken along (a) line A-A' and (b) line B-B' of FIG. 2.

The complex surgical device 100 may include a low-output light energy surgical device 200 capable of performing procedures using low-output light energy.

The low-output light energy used in the low-output light energy treatment device 200 is a laser or LED with an output of about 500 mW or less, and low-output light energy therapy has been shown to be effective in relieving or treating pain through various clinical studies and experiments. It is known.

In particular, low-output light energy in the 600 to 1000 nm wavelength range affects cell activation and blood circulation, producing ATP, NO, and ROS, thereby promoting protein production and dilating blood vessels, alleviating pain and improving blood flow through biochemical mechanisms. , it exerts effects such as dilating blood vessels, stimulating lymph nodes, activating cells, etc.

As shown in FIGS. 1 to 3, the low-output light energy treatment device 200 includes a housing 210 having a plurality of light transmission holes 211 formed through penetrating the lower surface, and disposed inside the housing 210. a first battery 220 that supplies electrical energy, a first circuit board 230 disposed below the first battery 220 and electrically connected to the first battery 220, and a first circuit board 230 ) is mounted on the lower part of the cell to generate low-output light energy of different wavelengths, and is placed correspondingly to the light transmission hole 211 to irradiate low-output light energy to the outside, and a complex procedure that occurs as low-output light energy of different wavelength bands is irradiated together. A plurality of devices are arranged separately in the first area (A1) and the second area (A2) around the first area (A1) based on the lower surface of the housing 210 according to the wavelength range of the low-output light energy to improve the effect. It includes a light energy element 240, and the low-output light energy irradiated from the light energy element 240 is absorbed into the electron transport system of the mitochondrial biological membrane within the subcutaneous cells, generates ATP, increases the cell's immunity and healing power, and ROS generates activating cell repair and healing, produces NO to increase blood circulation, reduce inflammation, improves the transport of oxygen and immune cells in tissues, and a light energy element placed in the first area (A1) The low-output light energy irradiated from 240) has a relatively small scattering coefficient and low light absorption rate for melanin compared to the low-output light energy irradiated from the light energy element 240 disposed in the second area (A2), and is 15 mm from the skin surface. The amount of light is capable of penetrating up to the trigger point, which is a musculoskeletal pain point located at a depth of above, and the low-output light energy irradiated from the light energy element 240 disposed in the second area (A2) is directed to the first area (A1). The low-output light energy irradiated from the light energy element 240 arranged in the first area (A1) has a relatively large scattering coefficient and high light absorption rate for melanin compared to the low-output light energy irradiated from the arranged light energy element 240. Although the penetration depth is shorter, light can penetrate to a depth of 5 mm or more from the skin surface.

Using such a low-output surgical device, users can easily perform low-output light energy procedures on painful areas, and in particular, improved complex surgical effects can be achieved through simultaneous irradiation of low-output light energy in different wavelength bands.

Hereinafter, each configuration of the low-output light energy surgical device 200 included in the complex surgical device 100 according to this embodiment will be described with reference to FIGS. 1 to 3.

The housing 210 may be provided with a plurality of light transmitting holes 211 formed through the lower surface.

The housing 210 is formed in a plate shape and can be used by placing it on a painful body part such as the wrist like a kind of patch, or can be easily worn on the body by combining it with a separate band.

The light transmission hole 211 formed through the lower surface of the housing 210 can be used as a passage for low-output light energy to be irradiated to the outside.

Accordingly, the light transmission hole 211 may be formed to correspond to the shape of the irradiation end of the light energy element 240 to which low-output light energy is irradiated.

The first battery 220 may be disposed inside the housing 210 to supply electrical energy.

The first battery 220 may be provided to be rechargeable, and accordingly, the first charging terminal 213 for charging the first battery 220 is installed in the housing 210 to electrically connect the first battery 220. It can be connected to .

Additionally, a first charging indicator 215 may be installed on the side of the housing 210 to check the charging state of the first battery 220. Specifically, the first charging indicator 215 includes a plurality of light emitting elements. Including, the number of lights on the light emitting elements may vary depending on the state of charge of the first battery 220.

The first circuit board 230 may be disposed below the first battery 220 and electrically connected to the first battery 220 .

The first circuit board 230 is electrically connected to the first battery 220 and is electrically connected to various components such as the light energy element 240, thereby transmitting and controlling electrical energy to the corresponding components. there is.

The first circuit board 230 may be specifically a printed circuit board (PCB).

The plurality of optical energy elements 240 are mounted on the lower part of the first circuit board 230 to generate low-output optical energy in different wavelength bands and are disposed corresponding to the light transmission hole 211 to irradiate the low-output optical energy to the outside. You can.

The low-output light energy irradiated from the light energy device 240 is absorbed into the electron transport system of the mitochondrial biological membrane within subcutaneous cells, generates ATP (adenosine triphosphate), increases the immunity and healing power of cells, and reduces ROS (reactive It can generate oxygen species (active oxygen species) to activate cell repair and healing, and generate NO (nitric oxide) to increase blood circulation, reduce inflammation, and improve the transport of oxygen and immune cells to tissues. there is.

Here, the optical energy device may be a laser device or a device including an LED device.

Specifically, the plurality of light energy elements 240 include low-output light energy in the 630 to 680 nm wavelength range for at least one of pain relief, lymph node stimulation, and edema relief, and at least one of blood flow improvement, blood flow enhancement, and cell activation. It is possible to generate low-output light energy in different wavelength bands, including low-output light energy in the 780 to 990 nm wavelength range.

When low-output light energy in different wavelength bands as described above is simultaneously irradiated, the treatment effect caused by the low-output light energy in each wavelength band is generated simultaneously, resulting in a combined treatment effect.

The plurality of light energy elements 240 may generate low-output light energy in an output range of 100 mW or less. In this case, the output of the low-output light energy may be specifically 3 to 50 mW, and more specifically, 20 mW.

The plurality of optical energy elements 240 are located in the first area A1 and the second area A2 around the first area A1 based on the lower surface of the housing 210 according to the wavelength range of the low-output optical energy to be irradiated. Can be placed separately.

In this way, by organically arranging the plurality of light energy elements 240 in accordance with the treatment effect according to the wavelength of low-output light energy, the complex treatment effect that occurs as the low-output light energy of the different wavelengths described above is irradiated together is improved. You can do it.

Figure 8 is a graph showing light absorption rates for oxyhemoglobin, melanin, and water according to the wavelength of low-output light energy.

Looking at the low-output light energy radiated from the light energy device 240 disposed in the first area (A1) and the second area (A2) with reference to FIG. 8, the light energy device 240 disposed in the first area (A1) ), the low-output light energy irradiated from the light energy element 240 disposed in the second area (A2) has a relatively small scattering coefficient and a high light absorption rate for melanin, compared to the low-output light energy radiated from the light energy element 240 disposed in the second area (A2). The amount of light can penetrate from the surface to the trigger point, which is a musculoskeletal pain point located at a depth of 15 mm or more, and the low-output light energy irradiated from the light energy element 240 disposed in the second area (A2) is transmitted to the first area (A2). Compared to the low-output light energy irradiated from the light energy element 240 arranged in A1), the scattering coefficient is relatively high and the light absorption rate for melanin is high, so the light energy irradiated from the light energy element 240 arranged in the first area (A1) is high. The penetration depth is shorter than that of low-output light energy, but the amount of light can penetrate to a depth of 5 mm or more from the skin surface.

Specifically, the plurality of light energy elements 240 include a first element 241 disposed in the second area A2, and a relatively high wavelength range compared to the first element 241 disposed in the first area A1. It may include a second element 242 that irradiates low-output light energy.

That is, the second element 242, which irradiates low-output light energy in a relatively high wavelength range compared to the first element 241, is disposed in the first area A1, and the second element 242 is disposed in the first area A1. ) The first element 241 is disposed in the peripheral second area A2 and can irradiate low-output light energy in a relatively low wavelength range compared to the second element 242.

The first element 241 irradiates low-output light energy in the 630 to 680 nm wavelength range for at least one of pain relief, lymph node stimulation, and edema relief, and the second element 242 improves blood flow, strengthens blood flow, and Low-output light energy in the 780 to 990 nm wavelength range may be irradiated for at least one of cell activation.

Accordingly, when simultaneous irradiation is performed by the first element 241 and the second element 242, the second element 242 irradiates low-output light energy in the 780 to 990 nm wavelength range to improve blood flow, strengthen blood flow, and activate cells. While performing a procedure for at least one of the following, the first element 241 emits low-output light energy in the 630 to 680 nm wavelength range for at least one of pain relief, lymph node stimulation, and edema relief around the second element 242. By examining , it is possible to perform a cooperative procedure with the content of the procedure performed by the second element 242.

More specifically, the first element 241 may irradiate low-output light energy with a wavelength of 650 nm, and the second element 242 may irradiate low-output light energy with a wavelength of 830 nm.

The second element 242 irradiates low-output light energy from the skin surface to a deeper location compared to the first element 241, and the first element 241 emits low-output light energy in a lower wavelength range compared to the second element 242. It is possible to generate and irradiate a wider skin area compared to the second element 242.

Low-output light energy can penetrate deeper when the wavelength is higher, and can penetrate into a wider area when the wavelength is lower.

Therefore, the second element 242 irradiates low-output light energy in a relatively high wavelength range compared to the first element 241, and penetrates the low-output light energy narrowly and deeply from the skin surface like acupuncture, thereby improving blood flow, strengthening blood flow, and activating cells. At least one of the following can be performed, and in addition, the first element 241 irradiates low-output light energy in a relatively low wavelength range compared to the second element 242 around the second element 242 to massage a wide area of skin as if massaging. By penetrating into the area, at least one of pain relief, lymph node stimulation, and edema relief can be performed around the skin area where the procedure is performed by the second element 242.

The first elements 241 are provided in plural numbers and are spaced apart from each other along the outer circumference of the first area A1 with the second element 242 as the reference, so that low-output light energy is irradiated by the second element 242. Low-output light energy in a relatively low wavelength range compared to the second element 242 may be irradiated to the surroundings of the skin area.

That is, the plurality of first elements 241 are arranged to be spaced apart from each other along the outer circumference of the first area A1 with respect to the second element 242, and the skin is irradiated with low-output light energy by the second element 242. By using a cover case 460 around the area to irradiate low-output light energy in a relatively low wavelength range compared to the second element 242, at least one of improving blood flow, strengthening blood flow, and activating cells is achieved by the second element 242. It is possible to perform at least one of pain relief, lymph node stimulation, and swelling relief around the skin area where the procedure is performed.

Specifically, the plurality of first elements 241 may be arranged radially around the second element 242 and may be arranged to be spaced apart from each other at equal intervals.

More specifically, the second element 242 may be disposed at the exact center of the lower surface of the housing 210 with respect to the lower surface of the housing 210.

The low-output optical energy treatment device 200 is disposed on the lower side of the first circuit board 230, is in contact with the housing 210, and is formed with a through hole 251 disposed corresponding to the light transmission hole 211, so that the through hole ( It may further include a heat sink 250 that transfers heat generated from the light energy element 240 to the lower surface of the housing 210 as it comes into contact with the light energy element 240 inserted into the 251).

In this case, the heat sink 250 receives the heat generated from the light energy element 240 when low-output light energy is irradiated and transfers it to the lower surface of the housing 210, so that low-output light energy treatment and thermal treatment can be performed, and through this, low-output light energy treatment is performed. The effect of energy treatment can be further improved.

At this time, the temperature of the thermal treatment performed by the heat sink 250 may be 30 to 60 degrees, specifically 40 to 56 degrees.

The low-output optical energy treatment device 200 is mounted on the lower part of the first circuit board 230, spaced apart from the optical energy element 240, and is disposed corresponding to the light transmission hole 211 to radiate infrared rays to the outside and reflect them from the skin. It may further include a detection sensor 260 that detects whether skin is approaching by receiving infrared rays.

If irradiation of low-output light energy by the light energy device 240 is performed indiscriminately other than during a procedure, there may be some risk and unnecessary battery consumption may occur.

Therefore, the detection sensor 260 radiates infrared rays to the outside through the light transmission hole 211 and detects whether the skin is approaching by receiving the infrared rays reflected from the skin, so that low-output light energy irradiation by the light energy element 240 is used during the procedure. It can be adjusted so that it only happens.

The housing 210 has a placement groove 212 formed on its lower surface, and the low-output light energy treatment device 200 is inserted into the placement groove 212 so that the plurality of light transmission holes 211 are covered by the cover case 460. A light transmitting plate 270 coupled to 210 and covering at least the light transmitting hole 211 with a cover case 460 may further include a light transmitting plate 270 that is transparent to transmit low-output light energy or infrared rays to the outside.

Through this light transmitting plate 270, water or foreign substances can be prevented from flowing into the housing 210 through the light transmitting hole 211 and the light energy element 240 and the detection sensor 260 can be protected from the outside. do.

At this time, the light energy element 240 may be inserted and placed into the passage hole 251 and the light transmission hole 211, and in this case, the irradiation end is protected from the outside as the cover case 460 is placed on the light transmission plate 270. It can be.

On the other hand, the detection sensor 260 may be arranged to be spaced apart from the light transmission hole 211 to prevent detection errors due to reception of low-output light energy emitted from the light energy element 240.

The low-output optical energy treatment device 200 includes a vibration motor 280 that is electrically connected to the first circuit board 230 and installed to contact the housing 210 to generate and transmit vibration energy to the lower surface of the housing 210. It may further include.

The vibration motor 280 generates vibration energy and transmits it to the skin through the lower surface of the housing 210, thereby producing effects such as improving blood flow and relieving pain.

In this case, the transmission of vibration by the vibration motor 280 can be performed simultaneously or alternately with the irradiation of low-output light energy by the light energy element 240, and thus the treatment effect by low-output light energy can be further improved.

The low-output optical energy treatment device 200 is installed on the upper surface of the housing 210, is connected to the first circuit board 230, and generates an electrical signal in the first circuit board 230 as it is pressed to turn the power on and off. , irradiation of low-output optical energy by the first element 241, irradiation of low-output optical energy by the second element 242, and simultaneous irradiation of low-output optical energy by the first element 241 and the second element 242. , an operation button 290 capable of selecting an operation mode including vibration transmission by a vibration motor 280 simultaneously with low-output light energy irradiation, and vibration transmission by a vibration motor 280 at an intersection with low-output light energy irradiation. At this time, the operation mode may be sequentially changed according to the operation button 290 being pressed.

Specifically, the operation button 290 can perform an operation mode of power on or power off by being pressed for a relatively long time, and the upper surface of the operation button 290 displays a mode that emits light in different colors depending on the operation mode. Light 292 may be installed.

FIG. 4 is a perspective view showing the ultrasonic treatment device 300 included in the complex treatment device 100 according to this embodiment, and FIG. 5 is a cross-sectional view taken along line C-C' of FIG. 4.

The complex surgical device 100 may further include an ultrasonic surgical device 300 capable of performing a surgical procedure using ultrasound.

The ultrasonic treatment method used by the ultrasonic treatment device 300 primarily utilizes the thermal effect of increasing tissue temperature as ultrasonic energy is absorbed into the tissue layer, thereby increasing blood flow, inducing inflammatory reactions, increasing biomembrane permeability, and increasing metabolism. , physiological effects such as increased collagen tissue stretching, pain relief due to increased pain threshold, muscle spasm relief, changes in nerve conduction speed, increased enzyme activity, and changes in skeletal muscle contractility occur.

In addition, when ultrasonic energy penetrates into the tissue according to the ultrasound procedure, the Soil sect performs mechanical work within the tissue. In this case, tension, pressure, and fluctuation and dispersion of deep tissue cells occur, accelerating tissue movement, and a micromassage phenomenon occurs. Accordingly, it increases the collagen content of the tendon, promotes cell membrane permeability, enhances protein synthesis performance, promotes wound healing, cavity formation, enhances microcirculation, destroys tissue, stimulates secondary transmitters such as calcium across the cell membrane, induces myogenic cell proliferation, etc. Biological effects occur.

As shown in FIGS. 4 and 5, the ultrasonic treatment device 300 includes a handpiece 310, a second battery 320 disposed inside the lower portion of the handpiece 310 to supply electrical energy, and a second battery 320. A second circuit board 330 that is electrically connected to the battery 320, and a second circuit board 330 that is electrically connected to the second circuit board 330 and is coupled to one upper side of the handpiece 310 and supplied from the second battery 320. It may include an ultrasonic unit 340 that converts electrical energy into vibration energy to generate ultrasonic waves and generates ultrasonic waves of different frequency bands so that the ultrasonic waves can penetrate subcutaneous tissue at different depths, enabling single or cross-irradiation.

Using this ultrasonic treatment device 300, the user can perform ultrasonic treatment on the painful area. In particular, the ultrasonic treatment can be improved by single or cross-irradiating ultrasonic waves of different frequency bands to penetrate the subcutaneous tissue at different depths. You can get the effect.

Additionally, the ultrasonic treatment device 300 can be used simultaneously or in parallel with the low-output light energy treatment device 200 described above, thereby achieving a combined surgical effect.

Meanwhile, a plurality of low-output light energy treatment devices may be provided, and in this case, as they are attached to or worn on a plurality of body parts, a procedure using low-output light energy can be performed simultaneously on a plurality of body parts.

Hereinafter, each configuration of the ultrasonic treatment device 300 included in the complex treatment device 100 according to this embodiment will be described with reference to FIGS. 4 and 5.

The handpiece 310 may have an internal space where components to be described later can be placed.

Additionally, the handpiece 310 may be provided to the user as a handle, and may therefore have a shape including a curved surface to improve grip.

The second battery 320 may be disposed inside the lower portion of the handpiece 310 to supply electrical energy.

The second battery 320 may be provided to be rechargeable, and accordingly, a second charging terminal 317 for charging the second battery 320 is installed on the handpiece 310 to connect the second battery 320 and the second battery 320. Can be electrically connected.

The ultrasonic treatment unit may further include a second charging indicator light 350 that emits different colors depending on the charging state of the second battery 320. Specifically, the second charging indicator light 350 is a handpiece ( It may be installed between 310 and the ultrasonic head 342 of the ultrasonic unit 340, which will be described later.

The second circuit board 330 may be electrically connected to the second battery 320.

The second circuit board 330 is electrically connected to the second battery 320 and is electrically connected to various components such as the ultrasonic unit 340, thereby transmitting and controlling electrical energy to the corresponding components. .

The second circuit board 330 may be specifically a printed circuit board (PCB).

The ultrasonic unit 340 is electrically connected to the second circuit board 330 and coupled to one upper side of the handpiece 310 and converts the electrical energy supplied from the second battery 320 into vibration energy to generate ultrasonic waves. You can do it.

Specifically, the ultrasonic unit 340 can generate ultrasonic waves by boosting the electrical energy supplied from the second battery 320 to high voltage and then converting it to high frequency.

The ultrasonic unit 340 can generate ultrasonic waves of different frequency bands to perform single or cross-irradiation so that the ultrasonic waves can penetrate subcutaneous tissue at different depths.

The ultrasonic unit 340 can single irradiate any one of ultrasonic waves of different frequency bands.

Specifically, as described above, ultrasound with a frequency of 1 MHz can reach and be absorbed into the subcutaneous tissue at a depth of 3 to 5 cm, so it may be suitable for procedures on adipose tissue or deep tissue, and ultrasound with a frequency of 3 MHz can reach and absorb subcutaneous tissue at a depth of 3 to 5 cm. Because it reaches and absorbs subcutaneous tissue at a depth of 2 to 2 cm, it may be suitable for procedures on superficial tissue areas such as elbows.

Additionally, the ultrasonic unit 340 can cross-irradiate ultrasonic waves of different frequency bands.

As mentioned above, the depth at which ultrasonic waves can penetrate the skin varies depending on the frequency band, so the ultrasonic unit 340 generates ultrasonic waves of different frequency bands and irradiates them alternately, thereby evenly penetrating the ultrasonic waves into the subcutaneous tissue at various depths to treat the painful area. The effect of ultrasound treatment can be further improved.

Specifically, the ultrasonic unit 340 can generate ultrasonic waves of different frequencies, including ultrasonic waves in the 0.8 to 1.2 MHz frequency band and ultrasonic waves in the 2.7 to 3.3 MHz frequency band, and more specifically, ultrasonic waves in the 1 MHz frequency band and ultrasonic waves in the 3 MHz frequency band. It is possible to generate ultrasonic waves of different frequencies, including:

Ultrasound at a frequency of 1 MHz can reach and be absorbed into subcutaneous tissue at a depth of 3 to 5 cm, and ultrasound at a frequency of 3 MHz can reach and be absorbed into subcutaneous tissue at a depth of 1 to 2 cm.

The output of ultrasound by the ultrasound unit 340 can be set to obtain sufficient surgical effect without causing pain or discomfort during the procedure, and may be specifically 0.5 to 1.5 W/cm2, and more specifically, It may be 1.0 W/cm2.

Specifically, the ultrasonic unit 340 is combined with the piezoelectric element 341, which converts electrical energy into vibration energy to generate ultrasonic waves, and the handpiece 310, and is in contact with the piezoelectric element 341 to transmit and irradiate ultrasonic waves to the skin. It may include an ultrasonic head 342.

Here, the piezoelectric element 341 is provided as a single unit and can generate ultrasonic waves of different frequency bands.

Meanwhile, in order to control the internal temperature of the ultrasonic treatment device 300 during ultrasonic treatment, the handpiece 310 is formed with a plurality of intake ports 311 penetrating on the lower surface and a plurality of exhaust ports (311) on the upper surface on the ultrasonic unit 340 side. 312) is formed by penetrating, and the ultrasonic treatment unit is installed inside the handpiece 310 and is disposed toward the plurality of exhaust vents 312 to heat generated as the ultrasonic unit 340 generates ultrasonic waves. It may further include a cooling fan 313 that discharges air to the outside through a plurality of exhaust vents 312 and introduces external air into the interior of the handpiece 310 through a plurality of intake ports 311.

On the other upper side of the handpiece 310, a power button 314 for turning the power on and off, an adjustment button 315 for adjusting the treatment mode including the treatment time, frequency of ultrasound, and output of ultrasound, and a treatment mode A first display 316 may be installed to display information including the contents of and the charging state of the second battery 320.

Specifically, looking at how an ultrasonic treatment is performed using an ultrasonic treatment unit, the user can perform the ultrasonic treatment by applying a gel or the like to the painful area and then rubbing the ultrasonic head 342 in close contact with the skin of the painful area.

The procedure performed using the aforementioned low-output optical energy treatment device and the ultrasonic treatment unit is as follows.

The low-output optical energy treatment device is provided in plural and is attached to or worn on multiple body parts, enabling procedures using low-output light energy to be performed simultaneously on multiple body parts, and the ultrasonic treatment device is capable of performing low-output light energy treatment on one body part. While a procedure using the device is being performed, a procedure using ultrasound can also be performed on other body parts.

In other words, the user can perform low-output light energy treatment in multiple areas by attaching or wearing multiple low-output light energy treatment devices to various parts at the same time, and while using the low-output light energy treatment device in one body part, in another body part. By performing ultrasound treatment using an ultrasonic treatment device, low-output light energy treatment and ultrasound treatment can be performed together in different body parts.

The low-output optical energy treatment device is provided in plural numbers and is attached to or worn on multiple body parts, enabling procedures using low-output light energy to be performed simultaneously on multiple body parts. The ultrasonic treatment device uses low-output light energy in one body part. So that the procedure using and the procedure using ultrasound can be performed sequentially, the procedure using ultrasound can be performed before or after the procedure using a low-output optical energy treatment device.

In other words, the user can attach or wear multiple low-output light energy treatment devices to various areas at the same time to perform low-output light energy treatment in several areas, and use low-output light energy to perform ultrasound on body parts where low-output light energy treatment has been performed or is to be performed. By performing ultrasonic treatment using a surgical device, low-output light energy treatment and ultrasonic treatment can be performed sequentially on the same body part.

FIG. 6 is a perspective view showing the complex surgical device 100 according to this embodiment, and FIG. 7 is a cross-sectional view taken along (a) line D-D' and (b) line E-E' of FIG. 6.

The complex surgical device 100 may further include a charging device 400 capable of charging the low-output light energy surgical device 200 and the ultrasonic surgical device 300 by placing them thereon.

As shown in FIGS. 6 and 7, the charging device 400 has a plurality of insertion holes 411 formed through the upper surface to enable insertion of the low-output light energy treatment device 200 or the ultrasonic treatment device 300. ), a main body case 410 having a power port disposed on the side of the main case 410 and electrically connected to an external power source, and a power port disposed inside the main case 410 and electrically connected to the power port and charging at the top. a third circuit board 430 on which charging pins 431 that transmit electrical energy for Alternatively, it is formed to correspond to the shape of the insertion part of the ultrasonic treatment device 300, is opened upward through the insertion hole 411, and is charged while the low-output optical energy treatment device 200 and the ultrasonic treatment device 300 are inserted and mounted. Possibly, it may include a plurality of charging cases 440 disposed on the upper side of the third circuit board 430 with charging pins 431 penetrating the bottom.

Using this charging device 400, the user can easily charge the low-output optical energy treatment device 200 or the ultrasonic treatment device 300 by inserting it into the charging case 440 through the insertion hole 411 and placing it there. and can be stored.

The main body case 410 may have a second display 450 installed on its upper surface to display information including the charging status of the low-output optical energy treatment device 200 and the ultrasound treatment device 300.

Meanwhile, in order to control the internal temperature when charging the charging station device 400, the main body case 410 is formed with a plurality of inlets 412 penetrating one side of the side and a plurality of heat dissipation holes 413 penetrating the other side of the main body case 410. The charging device 400 is installed inside the main body case 410 and is disposed toward the plurality of heat dissipation holes 413 to generate electricity as the low-output optical energy treatment device 200 and the ultrasonic treatment device 300 are charged. It may further include a heat dissipation fan that dissipates heat to the outside through a plurality of heat dissipation holes 413 and introduces external air into the interior of the main body case 410 through a plurality of inlets 412.

The charging station device 400 may further include a cover case 460 that is coupled to the main body case 410 to form a cover case 460 on the upper side of the main body case 410.

In relation to charging the low-output optical energy treatment device 200 through the charging device 400, the housing 210 has a first charging terminal 213 installed on the side that is electrically connected to the first battery 220. A fastening groove 214 is formed on the lower surface of the first charging terminal 213, and the plurality of charging cases 440 include a first case 441 formed to correspond to the side shape of the housing 210, , the first case 441 is formed with a heat dissipation hole 442 penetrating the inner surface of the charging pin 431, and a fastening bar 443 protrudes from the upper inner surface of the heat dissipation hole 442 and extends downward. A fastening protrusion 444 corresponding to the fastening groove 214 may be formed to protrude at the end of the bar 443.

The inner peripheral surface of the fastening groove 214 may be inclined from the lower surface of the housing 210 and inclined toward the bottom of the fastening groove 214 to facilitate insertion and removal of the fastening protrusion 444.

The housing 210 may be formed to be inclined from the side toward the fastening groove 214 so that the fastening protrusion 444 can be easily inserted into the fastening groove 214 as it is inserted into the first case 441. It can be formed by curved.

At this time, the first charging indicator light 215 may be installed on the side of the housing 210 opposite to where the charging terminal is located so that the charging state can be checked during charging.

In relation to charging the ultrasound treatment device 300 through the charging device 400, the handpiece 310 has a second charging terminal 317 installed at the bottom that is electrically connected to the second battery 320. , the plurality of charging cases 440 includes a second case 445 formed to correspond to the lower shape of the handpiece 310, and the charging holder 400 is located on the upper inner side of the main body case 410. A holding case 470 is formed to correspond to the side shape of the downward state of the ultrasonic unit 340 of the ultrasonic treatment device 300 inserted into the insertion hole 411, and opens upward through the insertion hole 411. It further includes, and the holding case 470 may be connected to the second case 445 and arranged to overlap.

Above, an embodiment of the present invention has been described, but those skilled in the art can add, change, delete or add components without departing from the spirit of the present invention as set forth in the patent claims. The present invention may be modified and changed in various ways, and this will also be included within the scope of rights of the present invention.

A1: Area 1
A2: Second area
100: Complex treatment device
200: Low-output light energy treatment device
210: housing
211: Transmission hole
212: Placement home
213: first charging terminal
214: Fastening groove
215: first charging indicator light
220: first battery
230: first circuit board
240: Light energy device
241: first element
242: Second element
250: heat sink
251: Passing hole
260: detection sensor
270: Lighting plate
280: vibration motor
290: operation button
292: Mode indicator
300: Ultrasound treatment device
310: handpiece
311: intake port
312: exhaust vent
313: cooling fan
314: Power button
315: adjustment button
316: first display
317: second charging terminal
320: second battery
330: second circuit board
340: Ultrasound unit
341: Piezoelectric element
342: Ultrasonic head
350: Second charging indicator light
400: Charging stand device
410: main body case
411: Insertion hole
412: inlet
413: Heat sink
430: Third circuit board
431: Charging pin
440: Charging case
441: Case 1
442: Heat dissipation hole
443: fastening bar
444: fastening protrusion
445: Second case
450: second display
460: Cover case
470: Holding case

Claims (11)

Ultrasound treatment equipment capable of performing procedures using ultrasound;
A low-output optical energy treatment device that can be used simultaneously or in parallel with the ultrasonic treatment device and is capable of performing procedures using low-output light energy; and
It includes a charging device capable of charging the low-output optical energy treatment device and the ultrasonic treatment device,
The low-output light energy treatment device,
A housing having a plurality of light transmission holes formed through penetrating the lower surface;
a first battery disposed inside the housing to supply electrical energy;
a first circuit board disposed below the first battery and electrically connected to the first battery; and
It is mounted on the lower part of the first circuit board to generate the low-output light energy of different wavelengths, and is disposed corresponding to the light transmission hole to irradiate the low-output light energy to the outside and irradiate the low-output light energy of different wavelengths together. A plurality of optical energy elements are arranged separately in a first area and a second area around the first area based on the lower surface of the housing according to the wavelength range of the low-output optical energy to improve the effect of the combined treatment effect generated accordingly. Contains,
The low-output light energy irradiated from the light energy device is absorbed into the electron transport system of the mitochondrial biological membrane within subcutaneous cells, generates ATP to increase the immunity and healing power of cells, and generates ROS to activate cell repair and healing. , produces NO, increases blood circulation, reduces inflammation, improves the transport of oxygen and immune cells to tissues,
The low-output light energy radiated from the light energy element disposed in the first region has a relatively small scattering coefficient and light absorption rate for melanin compared to the low-output light energy radiated from the light energy device disposed in the second region. Because this is low, the amount of light can penetrate to the trigger point, which is a musculoskeletal pain point located at a depth of 15 mm or more from the skin surface.
The low-output light energy irradiated from the light energy element disposed in the second region has a relatively large scattering coefficient and light absorption rate for melanin compared to the low-output light energy irradiated from the light energy device disposed in the first region. This is high, and the penetration depth is shorter than the low-output light energy irradiated from the light energy element disposed in the first area, but the complex treatment device is capable of penetrating light to a depth of 5 mm or more from the skin surface.
According to paragraph 1,
The plurality of light energy devices,
a first element disposed in the second area; and
A complex surgical device comprising a second element disposed in the first area and irradiating the low-output light energy in a relatively high wavelength range compared to the first element.
According to paragraph 1,
The plurality of light energy devices,
a first element disposed in the second area; and
A second element disposed in the first area and irradiating the low-output light energy in a relatively high wavelength range compared to the first element,
The first element is,
Irradiating the low-output light energy in the 630 to 680 nm wavelength range for at least one of pain relief, lymph node stimulation, and edema relief,
The second element is,
A complex surgical device that irradiates the low-output light energy in the 780 to 990 nm wavelength range for at least one of improving blood flow, strengthening blood flow, and activating cells.
According to paragraph 1,
The plurality of light energy devices,
a first element disposed in the second area; and
A second element disposed in the first area and irradiating the low-output light energy in a relatively high wavelength range compared to the first element,
The first element is,
A plurality of devices are provided, spaced apart from each other along the outer circumference of the first area with respect to the second element, and are arranged around the skin area where the low-output light energy is irradiated by the second element. A complex surgical device that irradiates the low-output light energy in the wavelength range.
According to paragraph 1,
The low-output light energy treatment device,
A pass-through hole disposed on the lower side of the first circuit board, in contact with the housing, and disposed to correspond to the light transmission hole is formed, and heat generated from the light energy element as it comes into contact with the light energy element inserted into the pass-through hole. A complex surgical device further comprising a heat sink that transmits heat to the lower surface of the housing.
According to paragraph 1,
The low-output light energy treatment device,
A detection sensor is mounted on the lower part of the first circuit board, spaced apart from the optical energy element, and is disposed corresponding to the light transmission hole to irradiate infrared rays to the outside and receive the infrared rays reflected from the skin to detect whether or not the skin is approaching. Including, a complex surgical device.
According to paragraph 1,
The low-output light energy treatment device,
A combination surgical device further comprising a vibration motor electrically connected to the first circuit board and installed in contact with the housing to generate and transmit vibration energy to a lower surface of the housing.
According to paragraph 1,
The ultrasonic treatment device is,
handpiece;
a second battery disposed inside the lower portion of the handpiece to supply electrical energy;
a second circuit board electrically connected to the second battery; and
It is electrically connected to the second circuit board and coupled to one upper side of the handpiece to convert electrical energy supplied from the second battery into vibration energy to generate the ultrasonic waves, and the ultrasonic waves penetrate into subcutaneous tissue at different depths. A complex surgical device comprising an ultrasonic unit capable of single or cross-irradiation by generating ultrasonic waves of different frequency bands.
According to paragraph 1,
The charging station device is,
a main body case having a plurality of insertion holes formed through an upper surface to enable insertion of the low-output optical energy treatment device or the ultrasonic treatment device;
a power port disposed on a side of the main body case and electrically connected to an external power source;
a third circuit board disposed inside the main body case, electrically connected to the power port, and having charging pins for transmitting electrical energy for charging mounted thereon;
It is formed on the upper inner side of the main body case and is formed to correspond to the shape of the insertion part of the low-output optical energy treatment device or the ultrasonic treatment device inserted into the insertion hole, and is opened upward through the insertion hole. The low-output light energy treatment device and A complex surgical device comprising a plurality of charging cases disposed on the upper side of the third circuit board and having the charging pins penetrate through the bottom of the third circuit board so that the ultrasonic surgical device can be charged while inserted and mounted.
According to paragraph 1,
The low-output light energy treatment device,
As it is provided in multiple pieces and attached to or worn on multiple body parts, a procedure using the low-output light energy can be performed simultaneously on multiple body parts,
The ultrasonic treatment device is,
A complex surgical treatment device capable of performing the treatment using the ultrasound on another body part while the treatment using the low-output optical energy treatment device is performed on one body part.
According to paragraph 1,
The low-output light energy treatment device,
As it is provided in multiple pieces and attached to or worn on multiple body parts, a procedure using the low-output light energy can be performed simultaneously on multiple body parts,
The ultrasonic treatment device,
A complex surgery device capable of performing the procedure using the ultrasound before or after the procedure using the low-output light energy procedure device, so that the procedure using the low-output light energy and the procedure using the ultrasound can be performed sequentially in one body part. .

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