KR20240075076A - In vitro shock wave therapy device with energy recovery function - Google Patents

Abstract

The present invention discloses an extracorporeal shock wave therapy device having an energy recovery function. The present invention consists of an energy recovery unit that recovers power other than the power used to generate extracorporeal shock waves when supplying power to a probe that outputs extracorporeal shock waves, thereby reducing power usage due to repeated use of the extracorporeal shock wave therapy device. By increasing the charging amount of the charging unit without expanding the power conversion function, the output efficiency is improved through repeated use of the extracorporeal shock wave therapy device, and the output speed is increased while maintaining the output intensity of the extracorporeal shock wave constant.

Description

{In vitro shock wave therapy device with energy recovery function}

The present invention relates to an electromagnetic extracorporeal shock wave therapy (ESWT; Extracorporeal Shock Wave Therapy), and more specifically, to a device used by the shock wave generator when supplying power required for shock wave generation in the shock wave generator. It relates to an extracorporeal shock wave therapy device that has an energy recovery function that allows it to recover power sources other than the power source.

A shockwave is a compressed and expanded part that is usually transmitted together at a constant speed like sound, but when a sudden change in pressure occurs, the expanded part changes slowly and the compressed part changes rapidly, distorting the waveform and causing the pressure to change as the wave passes. , density, speed, etc. are felt to suddenly increase. In electrical engineering, impulse voltage or current is also called a shock wave. Impulse current or voltage refers to the generation of very high energy for a very short period of time (several ㎱~㎲).

Shock wave therapy is being developed to treat specific diseases of the human body using the biological effects of low energy using shock waves. This method destroys stones in the human body with powerful pulse waves from outside the body without surgical operation, causing urinary flow. Treatment of diseases such as degenerative lesions of the musculoskeletal system, rupture of ligaments, and formation of limestone around joints, or by stimulating the regeneration of damaged tissues in areas of the body where diseases occur, can be used to treat diseases such as those mentioned above without surgical intervention. It can be treated.

Extracorporeal shock wave therapy devices used in the shock wave therapy are largely divided into focus type and radial type depending on the generation principle, which includes a shock wave generator (transducer) and a shock wave transmitter, and is a handpiece structure. Includes an in-probe (or impactor), a control terminal (or external device) including a control unit, a power supply unit for power supply, and/or a cooling unit, and a connection unit that supplies signals, power, refrigerant, etc. between the probe and the control terminal. It is done.

However, in a conventional extracorporeal shock wave therapy device, even though extracorporeal shock waves are generated by supplying power to the shock wave generator, all of the power supplied from the shock wave generator is not consumed.

Accordingly, it is necessary to recover the power that is not consumed in the shock wave generator, but conventionally there is no power recovery function, and therefore, there is a disadvantage in that the output efficiency is low when repeated use of the conventional extracorporeal shock wave therapy device. To solve this disadvantage, the output speed is increased. There was a problem that the output intensity decreased when increased, and therefore, in the past, it was not possible to increase the output speed while maintaining the output intensity.

Registered Patent Publication No. 10-1967355 (announcement date 2019.04.10.) Registered Patent Publication No. 10-2000971 (announcement date 2019.07.17.) Registered Patent Publication No. 10-2051307 (announcement date 2019.12.03.)

The problem to be solved by the present invention is to construct an energy recovery unit that recovers power other than the power used to generate extracorporeal shock waves when supplying power to a probe that outputs extracorporeal shock waves, thereby reducing the risk of repeated use of the extracorporeal shock wave therapy device. By reducing power usage and increasing the charging amount of the charging unit without expanding the power conversion function, the output efficiency can be improved upon repeated use of the extracorporeal shock wave therapy device, and the output speed can be increased while maintaining the output intensity of the extracorporeal shock wave at a constant level. The goal is to provide an extracorporeal shock wave therapy device with an energy recovery function.

An extracorporeal shock wave therapy device with an energy recovery function, which is a means of solving the problem of the present invention, includes a probe including a transducer that generates extracorporeal shock waves; A control terminal including a control unit and a power unit; And, a connection part connecting the probe and the control terminal and supplying a signal and driving power; Including, an energy recovery unit is formed at the output end of the power unit to recover power other than the power used for generating extracorporeal shock waves of the transducer.

In addition, the power supply unit includes a rectifier that receives commercial power and rectifies it; a switching circuit switched on or off by the control unit to determine whether to supply power rectified by the rectifier; a charging circuit that charges the rectified power when the switching circuit is switched on; a discharge circuit that discharges the power charged in the charging circuit to the transducer; Including, the energy recovery unit is a diode element formed in a recovery line connecting the output terminal of the discharge circuit and the input terminal of the charging circuit.

In addition, the power supply unit includes: a boost transformer connected to the output terminal of the switching circuit, which primarily boosts the power rectified by the rectifier when the switching circuit is switched on; and a quadruple voltage circuit that secondarily boosts the power source that is primarily boosted by the boost transformer to charge the charging circuit. It further includes.

Additionally, the discharge circuit is a switching element that is switched on or off to supply power charged in the charge circuit to the transducer.

Additionally, a safety circuit for protecting the diode element is connected in parallel to the recovery line.

In addition, the safety circuit includes a safety capacitor element and a resistance element that are connected in parallel to the diode element to prevent damage while mitigating the impact of energy recovery.

As such, the present invention constitutes an energy recovery unit that recovers power other than the power used to generate extracorporeal shock waves when supplying power to a probe that outputs extracorporeal shock waves, and through this, the power source for repeated use of the extracorporeal shock wave therapy device. By increasing the charging amount of the charging unit without expanding the power conversion function while reducing usage, the output efficiency is expected to improve through repeated use of the extracorporeal shock wave therapy device, and the effect of increasing the output speed while maintaining the output intensity of the extracorporeal shock wave constant is expected. It is possible.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

Figure 1 is a perspective view showing the structure of an extracorporeal shock wave therapy device according to an embodiment of the present invention.
Figure 2 is a schematic block diagram of a power supply unit according to an embodiment of the present invention.
Figure 3 is a detailed circuit diagram of an energy recovery unit according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the attached drawings.

Figure 1 is a perspective view showing the structure of an extracorporeal shock wave therapy device as an embodiment of the present invention, Figure 2 is a schematic block diagram of the power supply unit as an embodiment of the present invention, and Figure 3 is an energy recovery unit as an embodiment of the present invention. It shows a detailed circuit diagram for.

Referring to the attached FIGS. 1 to 3, an extracorporeal shock wave therapy device with an energy recovery function according to an embodiment of the present invention includes a probe 10 including a transducer 11 as a shock wave generator, and a control unit 21. In a known extracorporeal shock wave therapy device including a control terminal 20 including a power supply unit 22, and a connection unit 30 for supplying signals and power while connecting the probe 10 and the control terminal 20. , An energy recovery unit 40 is configured at the output terminal of the power unit 22 to recover power other than the power used for generating extracorporeal shock waves of the transducer 11.

Here, the transducer 11, although not specifically shown in the drawings, is a known transducer assembly including a bobbin, a solenoid-type coil layer, an insulating layer, a copper foil layer, a reflective layer, and/or a sealing portion, and the probe ( 10) may be formed with a space in which the transducer assembly is accommodated, and the space may be sealed by a membrane cover 10a that transmits the shock wave generated by the transducer assembly to the outside. may be filled with degassed water that is circulated to transmit shock waves or cool the heat generated in the transducer assembly.

In addition, the control unit 21 controls shock wave generation by the transducer assembly, the power unit 22 is capable of supplying power to the transducer assembly, and the control terminal 20 includes the transducer assembly. It may further include an air-cooled cooling processing unit that circulates air to cool the heat generated in the. As this is a known technology, detailed description thereof will be omitted below.

The power unit 22 includes a rectifier 221 that receives commercial power and rectifies it, and a switching circuit that is switched on or off by the control unit 21 to determine whether to supply the power rectified by the rectifier 221. 222), a charging circuit 223 that charges the rectified power when the switching circuit 223 is switched on, and a discharge circuit that discharges the power charged in the charging circuit 223 to the transducer 11 ( 224), and a boosting transformer 225 connected to the output terminal of the switching circuit 222 for first boosting the power rectified by the rectifier 221 when the switching circuit 222 is switched on, and the boosting transformer 225 It may include a quadruple pressure circuit 226 that secondarily boosts the power source that is primarily boosted by the transformer 225 to charge the charging circuit 223. Accordingly, the energy recovery unit 40 It is a diode element (D1) formed in the recovery line (L1) connecting the output terminal of (224) and the input terminal of the charging circuit (223).

Meanwhile, a safety circuit 50 for protecting the diode element D1 may be connected in parallel to the recovery line L1, and the safety circuit 50 is connected in parallel to the diode element D1. It may include a safety capacitor element (C1) and a resistance element (R1) that prevent damage while alleviating the impact of energy recovery.

Here, the charging circuit 223 is capable of charging 1-20kV as a charging condition (actual 15kV-18kV range, 0.35kV/Step, 10 steps (10MPa~60Mpa range, 4MPa/Step output intensity control), 1~ 1.2uF, 20kV Capacitor, HV Source capacity is set so that there is no decrease in output even at a discharge frequency of 20Hz, while as a discharge condition, it can have 20kV, 1000Arms (10kA/peak) discharge switch, and 20Hz discharge maintenance characteristics. The discharge circuit 224 may be a switching element that is switched on or off to supply the power charged in the charging circuit 223 to the transducer 11.

As such, the extracorporeal shock wave therapy device with energy recovery function according to an embodiment of the present invention, as shown in Figures 1 to 3 attached, first of all, the control unit 21 formed in the control terminal 20 is a power supply unit ( 22) controls the power supply.

Then, the high-voltage pulse current according to the power supplied by the power supply unit 22 is applied to the shock wave generator 11 formed in the probe 10 through the connection unit 30.

That is, since commercial power is supplied to the power unit 22, the commercial power is rectified by the rectifier 221 included in the power unit 22, and when the switching circuit 222 is switched on, the boost transformer 225 is activated. After being firstly boosted by the 4x pressure circuit 226, it is boosted secondarily by the 4x pressure circuit 226 and then charged in the charging circuit 223.

Thereafter, when the operator switches on the switching element forming the discharge circuit 224, the power boosted and charged in the charging circuit 223 is connected to the transducer 11 in the probe 10 through the connection part 30. While being supplied, the transducer 11 generates an extracorporeal shock wave through vibration, and the extracorporeal shock wave generated by the transducer 11 is directed to the affected area desired by the treatment subject through the radial surface of the probe 10. It can be used for treatment or procedures.

At this time, when an extracorporeal shock wave is generated from the power supply to the transducer 11, power is supplied to the transducer 11 through the discharge circuit 224, so power is supplied based on the time when the extracorporeal shock wave is generated. The power is not supplied to the transducer 11, but is recovered by the energy recovery unit 40 through the recovery line L1 and can be charged in the charging circuit 223.

That is, the recovery line (L1) connects the output terminal of the discharge circuit 224 and the input terminal of the charging circuit 223, and the recovery line (L1) includes a diode element (D1) as the energy recovery unit 40. Since is formed, the diode element (D1) charges the charging circuit (223) with power flowing through the recovery line (L1) rather than being supplied to the transducer (11).

At this time, since the safety circuit 50 including a safety capacitor element (C1) and a resistance element (R1) is connected in parallel to the recovery line (L1), the safety circuit 50 is connected to the diode element (D1) It is possible to prevent the diode element D1 from being damaged while alleviating the impact caused by energy recovery.

Therefore, the extracorporeal shock wave therapy device according to an embodiment of the present invention can improve output efficiency by increasing the charging amount of the charging circuit 223 without expanding the power conversion function while reducing power usage due to repeated use. Even if the output intensity of the extracorporeal shock wave is kept constant, the output speed can be increased.

In the above, the technical idea of the extracorporeal shock wave therapy device having an energy recovery function of the present invention has been described along with the accompanying drawings, but this is an illustrative description of the best embodiment of the present invention and does not limit the present invention.

Accordingly, the present invention is not limited to the specific preferred embodiments described above, and various modifications may be made by anyone skilled in the art without departing from the gist of the present invention as claimed in the claims. Of course, such changes are possible and fall within the scope of the claims.

10; Probe 11; transducer
20; control terminal 21; control unit
22; power unit 221; rectifier
222; switching circuit 223; charging circuit
224; discharge circuit 225; step-up transformer
226; 4 double pressure circuit 30; connection
40; Energy recovery unit 50; safety circuit
D1; Diode element C1; capacitor element
R1; resistance element

Claims (6)

A probe including a transducer that generates extracorporeal shock waves; A control terminal including a control unit and a power unit; And, a connection part connecting the probe and the control terminal and supplying a signal and driving power; Including,
An extracorporeal shock wave therapy device with an energy recovery function, characterized in that an energy recovery unit is formed at the output end of the power unit to recover power other than the power used for generating extracorporeal shock waves of the transducer. According to claim 1,
The power supply unit,
A rectifier that receives commercial power and rectifies it; a switching circuit switched on or off by the control unit to determine whether to supply power rectified by the rectifier; a charging circuit that charges the rectified power when the switching circuit is switched on; a discharge circuit that discharges the power charged in the charging circuit to the transducer; Including,
An extracorporeal shock wave therapy device with an energy recovery function, wherein the energy recovery unit is a diode element formed in a recovery line connecting the output terminal of the discharge circuit and the input terminal of the charging circuit. According to claim 2,
In the power supply unit,
a boost transformer connected to the output terminal of the switching circuit to first boost the power rectified by the rectifier when the switching circuit is switched on; and a quadruple voltage circuit that secondarily boosts the power source that is primarily boosted by the step-up transformer and charges the charging circuit. An extracorporeal shock wave therapy device with an energy recovery function, further comprising: According to claim 2,
An extracorporeal shock wave therapy device with an energy recovery function, wherein the discharge circuit is a switching element that is switched on or off to supply power charged in the charging circuit to the transducer. According to claim 2,
An extracorporeal shock wave therapy device with an energy recovery function, characterized in that a safety circuit for protecting the diode element is connected in parallel to the recovery line. According to claim 5,
The safety circuit is,
An extracorporeal shock wave therapy device with an energy recovery function, comprising a safety capacitor element and a resistance element connected in parallel to the diode element to prevent damage while mitigating the shock caused by energy recovery.