KR20220157018A - High intensity focused ultrasonic device - Google Patents

Abstract

The present invention relates to a high-intensity focused ultrasound (HIFU) device, wherein pulsation of ceramics is minimized to enable focusing to be performed appropriately and stably and a short circuit and disconnection are properly prevented. The HIFU device of the present invention comprises: a focused ceramics (10) generating ultrasound; a first electrode layer (20) formed on an upper surface of the focused ceramics (10); a second electrode layer (30) formed on a lower surface of the focused ceramics (10); and a power source connection unit (40) connecting a negatively charged power source and a positively charged power source to the first electrode layer (20) and the second electrode layer (30) while a short circuit and disconnection are prevented.

Description

High intensity focused ultrasound device {HIGH INTENSITY FOCUSED ULTRASONIC DEVICE}

The present invention relates to a high-intensity focused ultrasound device used in ultrasound medical and surgical devices, and more particularly, to a high-intensity focused ultrasound device that minimizes the occurrence of lopsided vibration of ceramics, properly and stably focusing, and appropriately prevents short circuits and disconnections. It relates to a focused ultrasound device.

In general, ultrasound refers to waves having a frequency of 20 KHz or more, and has a property of penetrating water, and is widely used in medical fields such as ultrasound diagnostic devices and ultrasound therapy devices.

The most representative application of ultrasound in the medical field is an ultrasound imaging device using transmission and reflection properties of ultrasound. It is a device that obtains a cross-sectional image of the human body by visualizing the time and intensity of ultrasound waves being reflected while passing through the body and passing through each organ.

In addition, an ultrasonic surgical device is a medical device using the thermal effect of ultrasonic waves. Among them, the High Intensity Focused Ultrasonic surgical unit (HIFU) focuses ultrasonic waves generated from an ultrasonic transducer at a certain point (focus) and irradiates them into the tissue, thereby reducing the heat generated at the focus point (focus). It is a device that can treat liver cancer, cervical cancer, breast cancer, etc. with a heat treatment method using the effect. It is a patient-friendly cancer treatment device.

Compared to the existing invasive (skin resection) method of removing cancer tissue, since energy is transmitted through the body from the outside and irradiated, there is no skin resection, the treatment method is simple, and the patient's recovery is fast after treatment, so the demand is increasing. there is a trend

In addition, recently, among the medical methods to improve the quality of life, it is also applied to the treatment of wrinkles related to the skin, and the skin wrinkle improvement effect of relatively low-intensity ultrasound energy (less than 100W) and focused ultrasound that forms a fine focus point has been proven and is emerging as an alternative to the face lift procedure, which is an invasive procedure.

The structure of human skin consists of the epidermis layer, the dermis layer, the subcutaneous fat layer, the muscle layer, and the skeleton in order. Most of the components that make up the dermis layer are well-known collagen proteins, which function to maintain skin elasticity.

The superficial musculo-aponeurotic system (SMAS layer), which is a part of the muscle layer, is a muscle part that is pulled during face lift surgery. Clinical results have been reported overseas that it acts on the SMAS layer to induce coagulation, and by transmitting heat to the deep dermis layer with ultrasonic waves, collagen is regenerated and wrinkle removal and synergistic effects of skin elasticity can be obtained.

Ultrasound with a low intensity but a wide range of frequency bands is used to perform these skin procedures. In order to use such a wide range of ultrasonic waves, various devices with built-in ultrasonic transducers that irradiate ultrasonic waves of a specific band are provided. do.

In addition, during surgery or procedure, such an ultrasonic device is installed and used in an ultrasonic surgical or surgical device, and the operator or operator replaces the ultrasonic device according to the required ultrasonic frequency band to use ultrasonic waves of various frequency bands.

Such an ultrasonic device is illustrated in FIG. 1 and its configuration is described as follows. As shown in FIG. 1, a conventional ultrasonic device includes a focusing type ceramic 1 that is formed round to have a certain curvature and generates ultrasonic waves by applying power, and a conductive material on the upper surface of the focusing type ceramic 1. A first electrode layer 2 formed by applying the applied material, a second electrode layer 3 formed by applying a conductive material to the lower surface of the bundled ceramic 1, and a metal wire connected to the first electrode layer 2. A first wire 4 made of, a first soldering part 5 for fixing the end of the first wire 4 to the upper surface of the first electrode layer 2 by soldering, and the second electrode layer 3 It includes a second wire 6 connected and made of a metal wire, and a second soldering part 7 for fixing an end of the second wire 6 to one side of the lower surface of the second electrode layer 3 by soldering.

The first wire 4 and the second wire 6 are to connect the cathode and anode power to the first electrode layer 2 and the second electrode layer 3, and the first soldering part 5 The first wire 4 is connected to the first electrode layer 2 to be energized, and the second soldering part 7 conducts the second wire 6 to the second electrode layer 3. to make it possible to connect.

FIG. 2 is a graph in which a phase of an ultrasonic wave is analyzed through a phase analyzer of a conventional ultrasonic device configured as described above.

However, the prior art as described above has the following problems.

In the conventional ultrasonic device, since the first soldering part is provided eccentrically on the upper surface of the first electrode layer, partial vibration is generated in the focusing type ceramic, and focusing is properly performed such that the focusing area is focused in an elliptical shape without gathering as shown in the graph of FIG. 2. There was a problem with not being able to support it.

In addition, the conventional ultrasonic device has a problem in that a second wire made of a metal wire is provided close to the first electrode layer, so there is a high risk of short-circuiting, and the first wire and the second wire themselves are disconnected, resulting in a shortened lifespan.

Registered Patent No. 1700334 "Ultrasonic Cartridge and High-Intensity Focused Ultrasonic Surgical Device" (2017.01.20.)

Accordingly, the present invention was made to solve the above conventional problems,

An object of the present invention is to provide a high-intensity focused ultrasound device that minimizes the occurrence of partial vibration of ceramics, properly and stably focusing, and properly prevents short circuits and disconnections.

In order to achieve the above object, a "high-intensity focused ultrasound device" according to the present invention includes a focused ceramic that is formed round to have a constant curvature and generates ultrasonic waves by applying power; a first electrode layer formed by coating a conductive material on an upper surface of the bundled ceramic; a second electrode layer formed by coating a conductive material on the lower surface of the bundled ceramic; a power connection unit for connecting power to each of the first electrode layer and the second front side layer; The power connection unit includes a first thin film made of a metal thin film connected to the first electrode layer and having an insulating material layer formed on upper and lower surfaces, and an end of the first thin film at one end of the upper surface of the first electrode layer. A first soldering part for fixing a soldering portion so as to be energized, a second thin film made of a metal thin film connected to the second electrode layer on a side surface of the first thin film and having an insulating material layer formed on upper and lower surfaces, and 1 characterized in that it comprises a second soldering part for fixing the end of the second thin film to one end of the lower surface of the second electrode layer by soldering so as to be energized under the soldering part.

In addition, the power connection unit of the "high-intensity focused ultrasound device" according to the present invention is characterized in that it further includes an integrally formed unit formed between the first thin film and the second thin film and formed of an insulating material.

In addition, the insulating material of the first thin film, the second thin film, and the integral part of the "high-intensity focused ultrasound device" according to the present invention is a synthetic resin capable of being elastically restored while being bendable.

As described above, the present invention has the effect of minimizing the generation of single vibration of the ceramic, ensuring appropriate and stable focusing, significantly improving precision, and properly preventing short circuits and disconnections to improve operational stability and guaranteeing a long lifespan.

1 is a schematic longitudinal sectional view showing a conventional ultrasonic device;
2 is an ultrasound phase graph of a conventional ultrasound device;
3 is a schematic perspective view of an ultrasonic device according to the present invention;
4 is a schematic longitudinal cross-sectional view of an ultrasonic device according to the present invention;
Figure 5 is an enlarged view of the main part of Figure 4;
6 is an ultrasound phase graph of an ultrasound device according to the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings shown. However, it should be understood that this invention may be embodied in many different forms and is not limited to the described embodiments.

3 to 6 are schematic views of an ultrasonic device according to the present invention. As shown therein, the high-intensity focused ultrasound device according to the present invention includes a focused ceramic 10 generating ultrasonic waves, a first electrode layer 20 formed on an upper surface of the focused ceramic 10, and the focused ceramic 10. The second electrode layer 30 formed on the lower surface of the molded ceramic 10, and a power source for connecting the cathode and anode power to the first electrode layer 20 and the second electrode layer 30 in a state in which short circuits and disconnections are prevented. It includes a connection part 40.

The focused ceramic 10 is a known focused ultrasonic vibration element made of a ceramic material and rounded to have a certain curvature, and serves to generate ultrasonic waves having a specific frequency band by applying power.

The first electrode layer 20 is formed by coating a conductive material on the upper surface of the lumped ceramic 10, so that the power of the cathode, for example, can be evenly connected to the upper surface of the lumped ceramic 10 as a whole. will be.

The second electrode layer 30 is formed by coating a conductive material on the lower surface of the bundled ceramic 10, so that, for example, the power supply of the anode can be evenly connected to the lower surface of the bundled ceramic 10 as a whole. will be.

In this way, as the cathode is caught on the upper surface of the lumped ceramic 10 and the anode is caught on the lower surface of the lumped ceramic 10 by the first electrode layer 20 and the second electrode layer 30, the lumped ceramic 10 vibrates. ultrasound is generated.

The power connection part 40 serves to connect the power of the cathode and anode to the first electrode layer 20 and the second front layer.

The power connection unit 40 is connected to the first electrode layer 20 and includes a first thin film 41 made of a metal thin film on top and bottom surfaces of which layers of insulating material are formed, and the first electrode layer 20. A first soldering part 42 for fixing the end of the first thin film 41 by soldering so as to be energized at one end of the upper surface, and connected to the second electrode layer 30 at the side of the first thin film 41, A second thin film 43 made of a metal thin film having an insulating material layer formed on the upper and lower surfaces, and the second thin film 43 at one end of the lower surface of the second electrode layer 30 under the first soldering part 42 It includes a second soldering part 44 for fixing the end of 43 by soldering so that current can be passed.

The first thin film 41 serves to connect, for example, a negative power supply to the first electrode layer 20 through the metal thin film M. Here, in the first thin film 41, a layer P of insulating material is formed on the upper and lower surfaces of the metal thin film M, so that the metal thin film M is properly protected to prevent disconnection and short circuit with other power sources. completely prevented.

The first soldering part 42 serves to connect and fix the metal thin film of the first thin film 41 to the first electrode layer 20 in a conductive manner.

The second thin film 43 serves to connect, for example, an anode power source to the second electrode layer 30 through a metal thin film. Here, the second thin film 43 is formed of an insulating material layer on the upper and lower surfaces of the metal thin film, so that the metal thin film is properly protected and disconnection is prevented, and short circuit with other power sources is completely prevented.

The second soldering part 44 serves to connect and fix the metal thin film of the second thin film 43 to the second electrode layer 30 in a conductive manner.

In this way, the first soldering part 42 and the second soldering part 44 are provided vertically at one end of the focusing type ceramic 10, so that they are fixed by a housing surrounding the focusing type ceramic 10. The focusing is performed appropriately and stably while the generation of lopsided vibration of the focused ceramic 10 is fundamentally prevented. It can be seen from the ultrasonic phase graph of the present invention shown in FIG. 6 that focusing is performed appropriately and stably according to the prevention of such side vibration.

The power connection part 40 further includes an integrally formed part 45 integrally formed between the first thin film 41 and the second thin film 43 and made of an insulating material. The integrally formed part 45 integrally fixes the first thin film 41 and the second thin film 43 so that a soldering operation can be performed more easily and a lifespan is extended.

The insulating material of the first thin film 41, the second thin film 43, and the integrally formed portion 45 is preferably a synthetic resin that can be bent and elastically restored, which stably supports the metal thin film and prevents disconnection due to external force. This is to ensure that it is adequately prevented.

Although preferred embodiments of the present invention have been described above, the present invention can use various changes, modifications, and equivalents. It is clear that the present invention can be equally applied by appropriately modifying the above embodiment. Therefore, the above description does not limit the scope of the present invention, which is defined by the limits of the following claims.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but it will be apparent to those skilled in the art that various modifications are possible without departing from the scope of the present invention.

10: Concentrated ceramics
20: first electrode layer
30: second electrode layer
40: power connection
41: first thin film 42: first soldering part
43: second thin film 44: second soldering part
45: integrally formed part
M: metal thin film
P: layer of insulating material

Claims (3)

a focusing type ceramic 10 which is formed round to have a constant curvature and generates ultrasonic waves by application of power;
a first electrode layer 20 formed by coating a conductive material on the top surface of the bundled ceramic 10;
a second electrode layer 30 formed by coating a conductive material on the lower surface of the bundled ceramic 10;
A power connection unit 40 for connecting power to the first electrode layer 20 and the second front layer, respectively; include,
The power connection part 40,
A first thin film 41 made of a metal thin film connected to the first electrode layer 20 and having insulating material layers formed on upper and lower surfaces;
A first soldering part 42 for fixing an end of the first thin film 41 to one end of the upper surface of the first electrode layer 20 by soldering so as to be energized;
A second thin film 43 made of a metal thin film connected to the second electrode layer 30 to the side of the first thin film 41 and having layers of insulating material formed on upper and lower surfaces;
A second soldering part 44 for fixing the end of the second thin film 43 to one end of the lower surface of the second electrode layer 30 under the first soldering part 42 by soldering so as to be energized. High-intensity focused ultrasound device, characterized in that for doing.
According to claim 1,
The power connection part 40,
An integrally formed portion 45 formed of an insulating material and integrally formed between the first thin film 41 and the second thin film 43,
High-intensity focused ultrasound device further comprising.
According to claim 2,
The insulating material of the first thin film 41, the second thin film 43 and the integrally formed portion 45 is,
A high-intensity focused ultrasound device characterized in that it is a synthetic resin capable of being bendable and elastically restorable.

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