KR20100005766A - External pressure wave curer - Google Patents

Abstract

PURPOSE: An external pressure wave curer is provided to simply cure a soft tissue or hard tissue by transmitting the impulse wave to a painful part through an impulse wave output surface of a probe tip. CONSTITUTION: A head unit(5) is screwed in a leading end of a housing(4). A striking unit(10) is movably arranged on a pneumatic cylinder(6) inside a housing. A transmission device(2) is arranged on the head unit. The transmission device receives the impulse wave generated by the impact power of the striking unit. A driving unit(14) is connected to the rear part of the housing by the connection unit. The driving unit drives the striking unit. A magnetic holder(28) is arranged on the rear end of the pneumatic cylinder.

Description

Extracorporeal Shock Wave Therapy {EXTERNAL PRESSURE WAVE CURER}

1 is a cross-sectional structural view of the treatment device of the present invention.

Figure 2 is a side structure diagram of the transfer device according to an embodiment of the present invention.

Figure 3 is a side structure diagram of the transfer device according to another embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

1: handpiece 2: transmission element

3: ring flange part 4: housing

5 head 6 compressed air cylinder

8: dust compression chamber 10: blow part

12 sleeve 14 drive means

18: front end 20: rear end

22: probe tip 24: shock wave discharge surface

25,35 O-ring 26 Shock wave inflow surface

28: magnet holder 30: spring

32: connection part

The present invention relates to an extracorporeal shock wave treatment device, and more particularly, to a therapeutic apparatus for effectively treating biological tissues of a specific human body by generating mechanical shock waves from the outside of the human body.

In general, the extracorporeal shock wave therapy device is used to increase the therapeutic effect by using pressure waves or shock waves in the case of fractures, nerve compression symptoms, tendon-related diseases as well as dental support organ diseases.

That is, the extracorporeal shock wave treatment device generates a pressure wave or shock wave by spark discharge at the focal point of the acoustic reflector, and then the pressure wave or shock wave is focused on an object exposed to the pressure wave by the reflector. The pressure wave causes microscopic damage to be formed in biological tissue causing body regeneration measures.

Known pressure pulse sources use focused shockwaves and only work in a narrowly limited focus area. In this case, for satisfactory treatment results, the entire fracture area must be exposed to pressure waves at the same time.

This type of treatment requires a complex operating mechanism for the pressure pulse source and can also be very time intensive because it repeatedly examines the treatment locations.

On the other hand, when a pressure pulse source is used for pain treatment, a position detection system (ultrasound) used to find a place to be treated during treatment cannot specifically indicate a pain source, and the doctor in charge of the treatment can assume an estimated pain source. There was a problem that the effective treatment is not made by exposing to a plurality of individual pulses.

SUMMARY OF THE INVENTION The present invention has been proposed to solve the above problems in the prior art, and an object thereof is to provide a pressure wave generator capable of uniformly distributing pressure wave energy over a wide range of working areas in a simple and economical manner. have.

The object is a transmission configured to be coupled to the head portion so that the head portion is coupled to the front end, the striking portion accommodated linearly in the air cylinder inside the housing, and the shock wave due to the flow of the striking portion is transmitted. The device and the driving means connected to the connecting portion at the rear end side of the housing for driving the hitting portion can be achieved through an extracorporeal shock wave therapy device comprising a configuration.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The handpiece 1 of the shock wave treatment device of the present embodiment has a coupling structure of a housing 4 accommodating a compressed air cylinder 6 therein and a head portion 5 screwed to the tip of the housing. The rear end of the housing 4 is provided with a connecting portion 32 which is connected to the drive means 14.

The driving means 14 may be a hydraulic pump, a pneumatic pump or an electronic pump.

On the other hand, the inside of the compressed air cylinder (6) is a metal hitting portion 10 is accommodated in a linear motion, the rear end portion 20 of the cylinder holder for pulling the striking portion 10 by magnetic force (28) ) Is configured.

The front end portion 18 of the compressed air chamber cylinder 6 is provided with a transmission element 2 for transmitting an impact force and a sleeve 12 surrounding the outer circumference. Reference numeral 8 denotes a dust compression chamber.

The transmission element 2 has a length in the range of about 20 ~ 100mm Looking at the structure in more detail, the tip is provided with a probe tip 22 forming a shock wave discharge surface 24 protruding in a certain curved shape The shock wave inflow surface 26 and the taper surface 23 are formed in the rear end, and the ring-shaped flange part 3 protrudes integrally in the middle part.

The transmission element 2 is airtight at the front and rear ends by two O-rings 25 and 35 when the head part 5 is mounted, and the ring-shaped flange part 3 protruding in the middle is a spring 30. By the elastic support is achieved.

In particular, each of the components constituting the transmission element 2 is preferably composed of different materials to improve the transmission characteristics of the pressure wave, which causes the pressure wave to be coupled to the inside of the body as much as possible without loss. This is to enable impedance adaptation.

The transfer element 2 can form the shock wave discharge surface 24 flat as shown in the embodiment of FIG.

An intermediate element may be disposed between the striking portion 10 and the transfer element 2 to continuously transmit the impact power of the striking portion 10 to the transfer element 2. The intermediate element can be used to improve the shielding action of the drive means for the application area or to change the direction of the pressure wave or to influence the characteristics of the pressure wave.

Reference numeral 16 denotes a ring-shaped slot, and 21 denotes a rounded edge portion to prevent damage to the skin surface.

3 illustrates a structure of the transmission element 2 according to another embodiment of the present invention, and as illustrated, the diameter of the shock wave discharge surface 24 is larger than the shock wave inflow surface 26 to maximize the shock wave discharge area. You can do it.

The effect of using the shock wave treatment device of the present invention constituting such a configuration will be described.

The treatment device of the present invention is suitable for the type of treatment in which the probe tip 22 is in contact with the body surface, such as elbows, calcaneus or gums supporting the teeth.

An impedance adaptation medium may be formed between the probe tip 22 and the skin surface to improve the pressure wave transmission force into the biological tissue. For example, an ultrasonic gel or a paste material or petrolatum may be used.

That is, when the driving means 14 is operated in a state where the probe tip 22 is positioned at the corresponding portion, the striking portion 10 moves forward in the compressed air cylinder 6, and thus the striking portion 10 is moved. Compressed air, which is compressed by), is guided along the sleeve 12 via the ring-shaped slot 16 at the tip of the cylinder 6 and then temporarily stored in the dust compression chamber 8.

On the other hand, the forward-moving striking part 10 collides with the shock wave inflow surface 26 of the transmission element 2, so that a pulse replacement is performed, whereby the ring-shaped flange portion 3 to pressurize the spring 30 At this time, the shock wave is discharged through the shock wave discharge surface 24 to be transmitted to the biological tissue of the skin.

That is, the mechanically generated pressure wave generates a pressure wave having a high pressure value due to the flow of the probe tip 22. The pressure wave continues to propagate inside the biological tissue and is not focused and applied inside the biological tissue. It propagates radially to the place.

The strike frequency at this time is about 1 to 30 Hz, preferably 6 to 20 Hz.

In addition, the probe tip 22 may perform a stroke of less than 1 mm, preferably less than 0.5 mm due to the impact power applied to the shock wave inflow surface 26 of the transfer element 2.

Then, the transmission element 2 can be moved back to the original position for receiving the shock wave by the elastic restoring force of the spring 30, the striking portion 10 is the magnetic force of the magnet holder 28 and the dust compression chamber 8 It is returned to its original position by the repulsive force of the compressed air moved inside.

Therefore, when the impact power is exerted one or more times in succession, it is possible to uniformly distribute over a wide range of biological tissues while minimizing the loss in the pressure wave transmission process.

And while specific embodiments of the present invention have been described and illustrated above, it is obvious that the structure of the shock wave treatment device of the present invention may be variously modified and implemented by those skilled in the art.

However, such modified embodiments should not be understood individually from the technical spirit or the prospect of the present invention, and such modified embodiments should fall within the appended claims of the present invention.

In the present invention as described above, the impact portion and the transmission element is provided in the handpiece to be able to linearly coaxially flow within the mechanical pain due to the mechanically generated non-focused shock wave through the shock wave discharge surface of the tip of the probe tip area To be delivered to.

Therefore, the therapeutic apparatus of the present invention can be used to treat biological hard tissue (soft tissue) or soft tissue (soft tissue) by a simple method.

In particular, by forming the shock wave discharge surface of the tip of the tip to a flat surface shows the advantage that the skin contact can be made in a larger area.

Claims (9)

A housing 4 screwed to the distal end so that the head 5 is dismountable; A striking portion (10) accommodated in a compressed air cylinder (6) inside the housing (4) so as to be capable of linear flow; A transmission element (2) coupled and configured in the coaxial head portion (5) so that a shock wave by a direct impact force generated by the linear flow of the striking portion (10) is transmitted; And a driving means (14) connected through the connecting portion (32) at the rear end side of the housing (4) to drive the striking portion (10). The method according to claim 1, An extracorporeal shock wave therapy device, characterized in that a magnet holder 28 is formed at the rear end side of the compressed air cylinder 6. The method according to claim 1 or 2, An external shock wave therapy device, characterized in that the outer side of the compressed air cylinder (6) is provided with a sleeve (12) and the dust compression chamber (8). The method according to claim 1, The transmission element 2 has a shock wave inflow surface 26 is formed at the rear end and a shock wave discharge surface 24 is formed on the tip side tip 22, and the middle of the transmission element is wrapped around the outer circumferential surface in a ring shape. Extracorporeal shock wave treatment device, characterized in that the ring-shaped flange portion (3) is configured. The method according to claim 4, The shock wave inlet surface 26 and the shock wave discharge surface 24 is in vitro shock wave treatment device, characterized in that formed in a flat plane shape. The method according to claim 4 or 5, The shock wave inlet surface (26) is an extracorporeal shock wave treatment device, characterized in that provided with a larger diameter than the shock wave discharge surface (24). The method according to claim 1 or 4, The external shock wave treatment device, characterized in that the spring (30) for supporting the ring-shaped flange portion (3) of the interruption of the transmission element (2) is provided on the inner circumference of the head portion (5). The method according to claim 1, Extracorporeal shock wave treatment device, characterized in that the blow frequency of the hitting portion 10 is 1 ~ 30Hz. The method according to claim 4, The probe tip (22) is an extracorporeal shock wave therapy device, characterized in that to form a rounded edge portion 21 to the leading edge to prevent damage to the skin surface.

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