KR20190028411A - Extracorporeal therapy device with easy adjusting focus - Google Patents

Abstract

An extracorporeal therapy device can be provided according to an exemplary embodiment of the present disclosure. The device comprises: a housing including a medium filling space filled with a shock wave transmitting medium and a membrane surface formed in contact with the medium filling space to transmit shock waves to the outside; a concave-shaped shock wave generating unit for generating shock waves and focusing the shock waves to a focus area, wherein the shock wave generating unit is formed in the medium filling space so that the generated shock waves pass through the membrane surface; and a moving unit for moving the shock wave generating unit in a predetermined direction in the medium filling space to adjust the focus area. The present disclosure can provide a device that can be used for extracorporeal shock wave therapy.

Description

TECHNICAL FIELD [0001] The present invention relates to an extracorporeal therapeutic device,

TECHNICAL FIELD The present invention relates to an extracorporeal therapeutic apparatus, and more particularly, to an apparatus for use in extracorporeal shock wave therapy that is easy to focus.

Shockwaves can be created in a very short time by a variety of methods, creating strong pressure waves that can be used to stimulate damaged tissues to produce therapeutic effects.

Extracorporeal Shock Wave Therapy (ESWT) is largely divided into focus type and radial type according to the principle of occurrence.

The concentrated type collects the shock wave at a spot through the dust collecting plate, and the radial type is a pneumatic type in which shock waves are generated by compressing the air using a pendulum or the like. The concentrated type generates a strong shock wave by collecting a shock wave to a point and applies a stimulus, and the radial type spreads radially from the shock wave generation site. Therefore, the strength of the shock wave gradually decreases as the distance increases.

The concentrated type is classified into electrohydraulic, electromagnetic, and piezoelectric according to the method of generating the shock wave. Among them, the electro magnetic type can generate the most stable and constant shock wave, It is widely used and has been known to have good clinical effect.

Electro-hydraulic is a method of collecting the waves generated by the electric spark, reflected at the collecting plate and collected at one point, and the electromagnetic wave is collected by collecting the shock waves generated by the magnetic field at one point.

The piezoelectric equation is a method of collecting shock waves generated from a small-sized input device and collecting them at a single point. Since the focal length is fixed for each device in the concentrated type, it is inconvenient to adjust the thickness of the pad according to the depth of the lesion. In addition, due to the nature of the shock wave, the patient may feel pain and discomfort due to sharp and strong stimulation.

Since the radial type compresses air by pendulum to make shock waves, the strength of the shock wave is lower than that of the concentrated type, so the shock wave can not be transmitted to the deep lesion. The intensive therapeutic effect appears mainly at the cellular level and the radial type at the tissue level.

The present disclosure intends to provide a technical feature relating to an apparatus for treating and treating an affected part of a patient by irradiating a shock wave.

According to an exemplary embodiment of the present disclosure, there is provided a shock absorber comprising: a housing including a medium filling space filled with a shock propagating medium; and a membrane surface formed in contact with the medium filling space to transmit a shock wave to the outside; A shock wave generating part formed in a concave shape for generating the shock wave and focusing the shock wave in a focus area, the shock wave generating part being formed inside the medium filling space and passing the generated shock wave through the membrane surface; A moving unit for moving the shock wave generating unit in a predetermined direction in the medium filling space to adjust the focus area;

And an extracorporeal treatment device including the extracorporeal treatment device.

The present disclosure can provide an apparatus that can be used for extracorporeal shock wave therapy.

1 is a perspective view of an extracorporeal treatment apparatus according to an embodiment of the present invention.
2 is a block diagram illustrating an extracorporeal device according to an embodiment of the present invention.
3 is a cross-sectional view of an extracorporeal treatment device according to an embodiment of the present invention.
Figure 4 is an exploded view of Figure 3, in accordance with one embodiment of the present invention.
Figure 5 is a partially cutaway perspective view of Figure 3, in accordance with an embodiment of the present invention.

Various embodiments and / or aspects are now described with reference to the drawings. In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of one or more aspects. However, it will also be appreciated by those of ordinary skill in the art that such aspect (s) may be practiced without these specific details. The following description and the annexed drawings set forth in detail certain illustrative aspects of one or more aspects. It is to be understood, however, that such aspects are illustrative and that some of the various ways of practicing various aspects of the principles of various aspects may be utilized, and that the description set forth is intended to include all such aspects and their equivalents.

In addition, various aspects and features will be presented by a system that may include multiple devices, components and / or modules, and so forth. It should be understood that the various systems may include additional devices, components and / or modules, etc., and / or may not include all of the devices, components, modules, etc. discussed in connection with the drawings Must be understood and understood.

As used herein, the terms "an embodiment," "an embodiment," " an embodiment, "" an embodiment ", etc. are intended to indicate that any aspect or design described is better or worse than other aspects or designs. .

In addition, the term "or" is intended to mean " exclusive or " That is, it is intended to mean one of the natural inclusive substitutions "X uses A or B ", unless otherwise specified or unclear in context. That is, X uses A; X uses B; Or when X uses both A and B, "X uses A or B" can be applied to either of these cases. It should also be understood that the term "and / or" as used herein refers to and includes all possible combinations of one or more of the listed related items.

Before describing the embodiments of the present invention in detail, it is to be understood that the present invention is not limited to the above-described embodiments, but may be modified and changed without departing from the scope and spirit of the invention. It is also to be understood that the terminology or words used in the present specification and claims should be interpreted with reference to the meaning of the inventive concept of the present invention based on the principle that the inventor can define the concept of appropriate terms to describe his invention in the best way It should be interpreted as a concept.

The term " extracorporeal device " as used herein may be referred to as including a pendulum 1000, a connection 1100, and an external device 1200, but may also be used with reference to the pendulum 1000 as a matter of convenience .

1 is a perspective view of an extracorporeal treatment device 2000 according to an embodiment of the present invention.

[0001] The present invention relates to an extracorporeal therapeutic apparatus which is used effectively for treating a diseased part by delivering shock wave energy to a diseased part, and more particularly to a focused shock wave therapy apparatus capable of easily controlling a focus region, , FSWT).

At first, the shock wave treatment method was used for lithotripsy because the effect of shock wave was considered to be caused by simple mechanical stimulation. However, several studies have shown that the extracorporeal shock wave treatment method has been reported to increase the expression of cytokine at the cell level, stem cell injection effect and antibacterial effect, and its use is expanding to various fields.

Generally, the extracorporeal shock wave treatment method repeatedly transmits the shock wave to the body by contacting the extracorporeal treatment device to the part of the operation feeling pain such as degenerative lesion of the musculoskeletal system, rupture of the ligament, lime formation around the joint, It is a therapy that promotes the healing of lesion tissue by inducing damage and inducing the generation of new blood vessels and increasing blood flow supply.

Extracorporeal shock wave therapy (ESWT) is largely divided into centralized (FSWT) and radial (RSWT) depending on the generation principle.

The concentrated type collects the shock waves at one point through the dust collecting plate. The radial type is a pneumatic type in which shock waves are generated by compressing air using a pendulum or the like. The concentrated type generates a strong shock wave by collecting shock waves to a point and applying a stimulus. Since the radial shape is a shape in which the shock wave radially spreads from the generation site, the strength of the shock wave is gradually weakened as the distance becomes larger.

To prevent shock waves from attenuating through air with low conductivity, the therapy device is used in contact with the affected part of the patient. At this time, a gel pad is used to adjust the focus area where the shock waves are focused. The gel pad includes a medium capable of transmitting a shock wave therein, and has a predetermined shape so that the generated shock wave can be refracted in a desired direction. The constant shape of the gel pad can focus the shockwave only in one focus area. Therefore, in order to adjust the focus area, the user has to change the gel pad of the other type one by one.

The extracorporeal treatment apparatus 2000 includes a shock unit 1000 and an external unit 1200 and a connection unit 1100 for supplying signals, power, refrigerant, and the like between the impact unit 1000 and the external unit 1200. [ ). However, this configuration may be partially changed depending on the method of use and manufacturing method, and some components may be replaced or omitted with other components. For example, the external device 1200 may be included in the impactor 1000, in which case the connection may be omitted.

The present invention can provide an apparatus for providing an effective shock wave treatment method while solving the problem that the focus adjustment of the conventional FSWT is inconvenient. Specifically, the impactor 1000 may include a configuration capable of adjusting the focus area while moving the shock wave generator. In addition, the impactor 1000 may include a structure in which a shock wave generator is disposed in an inner space filled with a medium. This configuration allows the medium to move easily to another space when the shock wave generator is moved to adjust the focus area, thereby simplifying the structure of the extracorporeal treatment device 2000. [

2 is a block diagram for explaining an extracorporeal treatment apparatus 2000 according to an embodiment of the present invention.

In an embodiment of the present invention, the extracorporeal treatment device 2000 includes a medium filling space 211 filled with a shock wave transmission medium, and a membrane surface 212 formed to transmit a shock wave to the outside in contact with the medium filling space And may include a housing 210.

In an embodiment of the present invention, the extracorporeal treatment device 2000 includes a shock wave generating part 220 having a concave shape for generating shock waves to focus on a focus area, and shock waves generated inside the medium filling space are arranged to pass through the membrane surface And a moving unit 230 for moving the shock wave generating unit 220 in a predetermined direction in the medium filling space to adjust the focus area.

In detail, the housing 210 may include a medium filling space 211 in which the shock wave transmission medium is filled to transmit the shock wave generated in the inside to the outside. The shock wave generating part 220 may be present in the medium filling space 211. Therefore, the shock wave generating part 220 can be locked in the shock wave transmission medium in the medium filling space 211.

The shock wave transmission medium may be an arbitrary medium capable of propagating the shock wave generated in the shock wave generating part 220 and may be a liquid easy to transmit shock waves such as distilled water and oil. In case of using distilled water or oil as the medium, the attenuation coefficient is very low, so that the attenuation of the shock wave hardly occurs and the advantage can be obtained that the focus can be focused well. However, the present invention is not limited thereto.

The shock wave generating part 220 can be moved by the moving part in a state where the shock wave generating part 220 is immersed in the shock wave medium in the medium filling space 211. The focus area may refer to the point at which the shock wave is focused. The shock wave generating part 220 may be formed in a concave shape to focus the shock wave and the shock wave may be focused in the focus area geometrically by the concave shape of the shock wave generating part 220. Since the concave shape of the shock wave generating part 220 can be fixed, the focus area can be constant. When the extracorporeal treatment device 2000 is located far away from the affected part of the patient to move the focus area, the shock wave passes through the air having low conductivity and is greatly attenuated. Therefore, the conventional concentrated-type external shock wave therapy apparatus is used while replacing various gel pads having a certain shape. The extracorporeal treatment apparatus 2000 of the present invention can easily adjust the focus area by moving the shock wave generating part disposed in the medium filling space in a predetermined direction.

When the shock wave generating part 220 is moved within the medium filling space 211, the shock wave transmitting medium can move to an empty space formed when the shock wave generating part 220 moves. The medium filling space 211 may be formed in a sufficient space such that the shock wave generating unit 220 is in a submerged state by the shock wave transmission medium. Therefore, the extracorporeal treatment device 2000 of the present invention can be manufactured with a simple structure in which the shock wave transmission medium, in which the shock wave generating part 220 moves while being moved, can easily move to the empty space. Therefore, the present invention can prevent the manufacturing process from being complicated to form a path through which the shock wave transmitting material can move.

In an embodiment of the present invention, the extracorporeal treatment device 2000 may include a moving part for moving the shock wave generating part in a predetermined direction in the medium filling space to adjust the focus area. Here, the predetermined direction may be a longitudinal axis passing through the center of the focus region and the concave-shaped generation wave generation portion. The shock wave generating part 220 can move the focus area on the vertical axis while moving forward or backward by the moving part 230 along the vertical axis. However, the present invention is not limited to this, and the predetermined direction can be variously determined.

The moving part 230 includes a driving part 231 for providing power, an induction part 232 for moving the shock wave generating part in a predetermined direction, a supporting part 233 connected to and supported by the shock wave generating part, . ≪ / RTI >

More specifically, the driving unit 231 can receive electric power from the power supply unit 1220 and convert electric energy into kinetic energy. The driving unit 231 may include various power sources such as a motor and a pump. The driving unit 231 can move the shock wave generating unit 220 using the converted kinetic energy.

The guide portion 232 may be formed to be engaged with a space formed in the body portion 213 and to be movable in a predetermined direction. For example, the guide portion 232 may be formed in a cylindrical shape, and may be inserted into a cylindrical hole formed in the body portion 213 to allow the shock wave generating portion 220 to move forward and backward. The portion where the induction portion 232 and the body portion 213 are in contact with each other can form a space that is spaced apart to reduce friction, and the spaced space can be filled with lubricating oil to facilitate movement. The inside of the guide portion 232 may be formed to pass through and may provide a passage through which power or refrigerant may be supplied from the external device 1200.

The support portion 233 may be connected to the shock wave generating portion 220. The supporting portion 233 can transmit the generated power from the driving portion to move the shock wave generating portion 220. The support portion 233 can form a space through which refrigerant or electric power can be transferred, and the space formed can be used to transfer refrigerant or electric power to the shock wave generating portion 220. However, the support portion 233 may be formed in various shapes depending on the shape of the shock wave generating portion 220.

In one embodiment of the present invention, the housing 210 may include a body portion 213. The body portion 213 may be formed to have a large area to accommodate components included in the extracorporeal device 2000. The body portion 213 may include a handle portion for facilitating a user's easy use and may include a membrane surface 212 which is engaged with the body portion 213 to form a medium filling space 211. However, the present invention is not limited thereto.

The membrane surface 212 may transmit the shock wave generated by the shock wave generator 220 to the outside. The membrane surface 212 may be constructed of a thin metal plate capable of transmitting shock waves well. The membrane surface 212 may support a thin metal plate and may include a rim that may be connected to the body portion 213. The rim portion may be made of various materials such as, but not limited to, plastic, steel, aluminum, glass fiber, carbon, fiber reinforced plastic (FRP)

The body portion 213 may have a certain accommodation space for accommodating the components constituting the impactor 1000. In addition, the accommodation space may also include a movement space that enables the operation of the components. For example, the body part 213 may include a passage formed so that the shock wave generating part 220 and the moving part 230 can be moved. In addition, the body 213 may include a structure in which the inside of the body 213 is penetrated so that the refrigerant or the power line can pass therethrough.

The body portion 213 may be made of various materials such as, but not limited to, plastic, steel, aluminum, glass fiber, carbon, fiber reinforced plastic (FRP) Also, the body portion 213 may be coated with an insulating material.

The housing 210 according to an embodiment of the present invention may be configured as a single component. Also, the housing 210 can be easily separated for ease of replacement or repair of the components housed therein. For example, the housing 210 can be divided into and / or separated by at least one of the housing components 212 and 213.

In addition, the extracorporeal device 2000 may have a fastening (not shown) to facilitate coupling and / or separation of the housing components 212, 213. The fastening part may be at least one of a one-touch fastening method, a one-push fastening method, a fitting fastening method, a rotary fastening method, a snap fastening method, a slide fastening method and a screw fastening method.

Although not shown, the housing 210 may be opened and closed in a pivotal manner about one side. The components of the extracorporeal device 2000 can be easily replaced and / or repaired. For example, the membrane surface 212 may be fitted or detached to the body portion 213.

The housing 210 may have an elastic member attached to one side thereof. Such elastic members may include, but are not limited to, polyvinyl acetate, polyurethane, rubber and / or silicone. For example, the grip portion included in the body portion 213 of the housing 210 may further include a silicon member or the like. The grip portion can improve the grip feeling when using the extracorporeal treatment device 2000 and prevent slippage in the user's hand.

The outer surface of the housing 210 may be made of the same material as the inner surface of the housing 210 according to a further embodiment of the present invention. Or the outer surface of the housing 210 may be made of a member different from the inner surface of the housing 210. For example, the material constituting the inner surface of the housing 210 may be an elastic member, such as a synthetic resin having elasticity such as polyvinyl acetate, polyurethane, rubber, silicone, or the like. Further, the material constituting the outer surface of the housing 210 may be made of a hardening member such as a plastic material or a plastic member. The above description is only an example according to one embodiment of the present invention, and the outer surface and / or inner surface of the housing 210 may be composed of various materials.

In an embodiment of the present invention, the shock wave generator 220 may be in the form of a concave shape that generates shock waves and focuses the shock waves in the focus area. The shock wave generating part 220 may be formed inside the medium filling space. The shock wave generating part 220 may be disposed so that the generated shock wave passes through the membrane surface.

The shock wave generating unit 220 may use piezoelectric, electro hydraulic, or electromagnetic (electromagnetic) as an energy output method. However, the present invention is not limited thereto.

In an embodiment of the present invention, the shock wave generator 220 includes a concave focus plate that focuses the shock wave in the focus area, a plurality of piezoelectric elements attached to the focus plate and generating shock waves using pulse pressure waves .

More specifically, the shock wave generating unit 220 may include a hemispherical focusing plate and a plurality of piezoelectric elements. A plurality of piezoelectric elements can be attached to the curved surface of the focusing plate. When the shock wave generating part 220 instantaneously supplies power to a plurality of piezoelectric elements through the power supply part 1220, each of the piezoelectric elements can generate a short pulse pressure wave. The generated pressure wave is focused on the focus area through the focusing plate and can be used for treatment or surgery.

In an embodiment of the present invention, the shock wave generator 220 includes a concave shaped reflector that reflects shock waves and focuses on the focus area, an impact wave generator that generates shock waves using the vibration generated by the electromagnetic field, . ≪ / RTI >

Specifically, the shock wave source may include a circular support having an electric coil, which may be formed of a circular strong ceramic, an insulating foil, and a metal membrane. The electric coil may be connected to the power supply unit 1220 to receive power. When an electric current of about 10 to 20 kA is applied by the power supply unit 1220, an electromagnetic force, that is, a repulsive force, can be generated between the electric coil and the metal membrane by Lentz's law. The generated repulsive force can vibrate the metal membrane. The vibration of the metal membrane generates shock waves according to the shape of the metal membrane in the surrounding fluid. The generated shock wave can be focused on the focus area by a concave reflector and used for treatment and treatment.

In an embodiment of the present invention, the shock wave generator 220 includes a concave reflection plate that reflects shock waves and is concentrated in a focus area, and an impact wave source that is formed at the center of the interior of the shock wave generator, can do.

More specifically, the shock wave generator 220 may include a hemispherical reflector, and an electrode for generating a wavelength may be provided on the reflector. This electrode may be connected to the power supply 1220 to receive power. According to this structure, both ends of the electrodes disposed in the water can cause a spark discharge when a voltage is applied. When a spark discharge occurs, a pressure wave in the water is generated by a spark discharge, and a spherical wave source is formed. The spherical wave can be reflected from the reflector as it spreads out, or it can be focused on the direct focus area to generate a shock wave. The generated shock wave can be used for treatment or surgery by irradiating the focus area with the treatment device directed to the affected part desired by the patient.

In an embodiment of the present invention, the in vitro treatment device 2000 includes a control unit 1210 for controlling the operation of the extracorporeal treatment device 2000, a power supply unit 1220 for supplying power to the shock wave generating unit, And may include a cooling unit 1230.

In an embodiment of the present invention, the controller 1210 may be included in the external device 1200. It is possible to adjust the intensity of the shock wave or the like by receiving a user's input, or to collect various information and provide it to the display unit. In addition, when the extracorporeal therapeutic device is overheated due to an error, the controller 1210 can perform an operation such as shutting off the power supply. However, the present invention is not limited thereto.

In an embodiment of the present invention, the power supply unit 1220 may be included in the external device 1200 and may be connected to the impactor 1000 through the connection unit 1100. However, the present invention is not limited to this, and the power supply unit 1220 may be included in the impactor 1000. In this case, the connection unit 1100 may be omitted.

The power supply unit 1220 may be configured to adjust the power supplied from a general commercial power supply unit (not shown) to suit the shock wave generation and supply the power to the shock wave generating unit 220. In addition, the power supply unit 1220 can supply power required for various operations of the extracorporeal treatment device 2000. [

In an embodiment of the present invention, the cooling portion 1230 may be included in the external device 1200 and may be connected to the impactor 1000 through the connection portion 1100. However, the present invention is not limited to this, and the cooling unit 1230 may be included in the impactor 1000, and in this case, the connection unit 1100 may be omitted.

The in vitro therapy device 2000 may include the following components to efficiently solve the heat generation due to the continuous power supply and the vibration of the diaphragm. More specifically, the cooling unit 1230 can supply the coolant to the impactor 1000 through the connection unit 1100. [ The refrigerant supplied to the impactor can be supplied to the surroundings of the body portion 213 and the guide portion 232 and around the shock wave generating portion.

The refrigerant may include components such as a shock wave transmission medium. Specifically, the refrigerant may include at least one of distilled water and oil. In this case, the refrigerant can be injected into the medium filling space 211. The injected refrigerant circulates around the shock wave generating part 220 and may be discharged to the cooling part 1230 again. The discharged refrigerant may be injected again into the medium filling space 211 after releasing heat to the outside from the cooling part 1230 again.

In another embodiment of the present invention, the cooling unit 1230 may include a plurality of refrigerant tubes through which the refrigerant can pass around the shock wave generating unit 220.

More specifically, the refrigerant is not injected into the medium filling space 211 but may be injected into a plurality of refrigerant tubes (not shown) disposed around the shock wave generating section 220 to absorb heat. The injected refrigerant may be passed through the plurality of refrigerant tubes and may be recovered to the cooling section 1230 again. The recovered refrigerant discharges the heat absorbed by the cooling part 1230 to the outside, and can be injected again to pass through the refrigerant pipe. The refrigerant tube can be formed in various thicknesses and shapes. The area where the refrigerant tube connects to or passes through each element can be sealed to prevent leakage.

In an embodiment of the present invention, the extracorporeal treatment device 2000 may be an integrated type (not shown) in which the impactor 1000, the controller 1220, and the external device 1200 are integrated. In addition, the extracorporeal treatment device 2000 may have a separate type in which the impactor 1000 and the external device 1200 are separated from each other and connected to each other through the connection part 1100. However, the present invention is not limited thereto and the extracorporeal treatment device 2000 can be manufactured in various forms.

3 is a cross-sectional view of an extracorporeal treatment device according to an embodiment of the present invention.

In one embodiment of the present invention, Fig. 3 shows an extracorporeal device 2000 that generates a shock wave using a piezoelectric element. However, the present invention is not limited to this, and the extracorporeal device 2000 of the present invention can generate shock waves using various methods.

In an embodiment of the present invention, the shock wave generating part 220 can adjust the focus area while moving in a predetermined direction by the moving part. 3, the driving part 231 included in the moving part 230 is fixed to the body part 213 to provide a power for moving the shock wave generating part 220 in the middle axis direction passing through the center of the extracorporeal treatment device. have. The guiding portion 232 can be fitted in a cylindrical hole formed in the body portion 213. In this case, the supporting portion 223 can be moved along the vertical axis by receiving power from the driving portion 231 . Therefore, the shock wave generating part 220 connected to the support part 233 can move forward or backward along the vertical axis. However, the present invention is not limited to this, and the shock wave generating part 220 can be moved in various directions.

 Since the focus region to which the shock wave is irradiated is fixed in accordance with the concave shape of the shock wave generating section 220, when the shock wave generating section 220 moves, the focus region also moves. 3 (a) and 3 (b) show that the focus region is adjusted by moving the shock wave generating unit 220. The extracorporeal treatment device 2000 of the present invention can easily adjust the focus area by moving the shock wave generating part 220 and can irradiate shock waves to the affected part of various patients.

In an embodiment of the present invention, the extracorporeal treatment device 2000 of the present invention may include a structure in which the shock wave generating part 220 is disposed inside the medium filling space 211 so as to be used in a state of being locked to the shock wave transmission medium . This configuration allows the medium to be compressed as the shock wave generating part 220 moves back and forth along the vertical axis to easily move to the empty space. Therefore, the extracorporeal treatment apparatus 2000 does not include a complicated structure for moving the compressed medium, so that the structure of the extracorporeal treatment apparatus 2000 can be simplified.

Figure 4 is an exploded view of Figure 3, in accordance with one embodiment of the present invention.

In an embodiment of the present invention, as shown in FIG. 4, the medium filling space 211 may be formed by combining the membrane surface 212 and the body 213. A shock wave transmission medium may be filled in the formed medium filling space 211. The shock wave generating part 220 and the moving part 230 may be present in the medium filling space 211.

The membrane surface 212, the shock wave generating part 220, the moving part 230, and the body part 213 constituting the extracorporeal device 2000 may be arranged in order along one longitudinal axis. With this configuration, the shock wave generating portion 220 can move in a predetermined direction, and therefore, the focus region can also move in a predetermined direction. Here, the predetermined direction may be a longitudinal axis passing through the center of the focus region and the concave-shaped generation wave generation portion. The shock wave generating part 220 can move the focus area on the vertical axis while moving forward or backward by the moving part 230 along the vertical axis. However, the present invention is not limited to this, and the predetermined direction can be variously determined.

More specifically, the shock wave generating unit 220 and the moving unit 230, which are connected together by the supporting unit 233, can move in the same direction. The guide portion 232 is formed in a cylinder shape and can be inserted into a cylindrical hole formed in the body portion 213. [ Thus, the shock wave generating part 220 can move back and forth along the longitudinal axis passing through the center like a syringe. The portion where the induction portion 232 and the body portion 213 are in contact with each other can form a space that is spaced apart to reduce friction, and the spaced space can be filled with lubricating oil to facilitate movement. The inside of the guide portion 232 may be formed to pass through and may provide a passage through which power or refrigerant may be supplied from the external device 1200.

The housing 210 according to an embodiment of the present invention may be configured as a single component. Also, the housing 210 can be easily separated for ease of replacement or repair of the components housed therein. For example, the housing 210 can be divided into and / or separated by at least one of the housing components 212 and 213.

In addition, the extracorporeal device 2000 may have a fastening (not shown) to facilitate coupling and / or separation of the housing components 212, 213. The fastening part may be at least one of a one-touch fastening method, a one-push fastening method, a fitting fastening method, a rotary fastening method, a snap fastening method, a slide fastening method and a screw fastening method.

Although not shown, the housing 210 may be opened and closed in a pivotal manner about one side. The components of the extracorporeal device 2000 can be easily replaced and / or repaired. For example, the membrane surface 212 may be fitted or detached to the body portion 213.

Figure 5 is a partially cutaway perspective view of Figure 3, in accordance with an embodiment of the present invention.

In an embodiment of the present invention, as shown in FIG. 5, the housing 210 may include a medium filling space 211 in which a shock wave transmission medium is filled to transmit the shock wave generated in the inside. The shock wave generating part 220 may be present in the medium filling space 211. Therefore, the shock wave generating part 220 can be locked in the shock wave transmission medium in the medium filling space 211.

The shock wave transmission medium may be an arbitrary medium capable of propagating the shock wave generated in the shock wave generating part 220 and may be a liquid easy to transmit shock waves such as distilled water and oil. In case of using distilled water or oil as the medium, the attenuation coefficient is very low, so that the attenuation of the shock wave hardly occurs and the advantage can be obtained that the focus can be focused well. However, the present invention is not limited thereto.

The shock wave generating part 220 can be moved by the moving part in a state where the shock wave generating part 220 is immersed in the shock wave medium in the medium filling space 211. The focus area may refer to the point at which the shock wave is focused. The shock wave generating part 220 may be formed in a concave shape to focus the shock wave and the shock wave may be focused in the focus area geometrically by the concave shape of the shock wave generating part 220. Since the concave shape of the shock wave generating part 220 can be fixed, the focus area can be constant. When the extracorporeal treatment device 2000 is located far away from the affected part of the patient to move the focus area, the shock wave passes through the air having low conductivity and is greatly attenuated. Therefore, the conventional concentrated-type external shock wave therapy apparatus is used while replacing various gel pads having a certain shape. The extracorporeal treatment apparatus 2000 of the present invention can easily adjust the focus area by moving the shock wave generating part disposed in the medium filling space in a predetermined direction.

When the shock wave generating part 220 is moved within the medium filling space 211, the shock wave transmitting medium can move to an empty space formed when the shock wave generating part 220 moves. The medium filling space 211 may be formed in a sufficient space such that the shock wave generating unit 220 is in a submerged state by the shock wave transmission medium. Therefore, the extracorporeal treatment device 2000 of the present invention can be manufactured with a simple structure in which the shock wave transmission medium, in which the shock wave generating part 220 moves while being moved, can easily move to the empty space. Therefore, the present invention can prevent the manufacturing process from being complicated to form a path through which the shock wave transmitting material can move.

In an embodiment of the present invention, the extracorporeal treatment device 2000 of the present invention may include a structure in which the shock wave generating part 220 is disposed inside the medium filling space 211 so as to be used in a state of being locked to the shock wave transmission medium . This configuration allows the medium to be compressed as the shock wave generating part 220 moves back and forth along the vertical axis to easily move to the empty space. Therefore, the extracorporeal treatment apparatus 2000 does not include a complicated structure for moving the compressed medium, so that the structure of the extracorporeal treatment apparatus 2000 can be simplified.

The description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features presented herein.

Claims (1)

A housing including a medium filling space filled with the shock wave transmitting medium and a membrane surface formed in contact with the medium filling space to transmit the shock wave to the outside;
A shock wave generating part of a concave shape for generating the shock wave and focusing the shock wave into a focus area, the shock wave generating part being located inside the medium filling space, the generated shock wave being arranged to pass through the membrane surface; And
A moving part for moving the shock wave generating part in a predetermined direction in the medium filling space to adjust the focus area;
/ RTI >
In vitro therapy.

Images