KR102376384B1 - RF frequency generator for radio frequency therapeutic apparatus - Google Patents

Abstract

An object of the present invention is to provide a high-frequency generator for a high-frequency treatment device that can be used for a long period of time and can achieve constant performance. In the high-frequency generator for a high-frequency treatment device that generates a high frequency applied to a high-frequency treatment device that generates deep heat, the present invention to achieve the above object comprises: a power switch that turns on and off the power of the entire device; a power module that converts external power into direct current; a booster module that boosts the voltage of the power supply of the power module; a frequency oscillation module that selectively generates and outputs a plurality of predefined frequencies using the power of the power module; a control module that sets a frequency output from the power switch and the frequency oscillation module; a plurality of amplification modules that amplifies the output of a signal output from the frequency oscillation module; a switching module that operates with the signals generated by the amplification modules and converts the DC power of the booster module into a pulse signal; a third amplification module that boosts the voltage of the pulse generated by the switching module; and an output module that is connected to an output terminal of the third amplification module and is connected to an external electrode. The frequency of the high-frequency signal output from the output module is 1 MHz to 5 MHz.

Description

RF frequency generator for radio frequency therapeutic apparatus

The present invention relates to a high-frequency generator for a high-frequency therapy device, and more particularly, to a high-frequency generator for a high-frequency therapy device that provides an output suitable for a high-frequency therapy device.

In recent years, various devices have been proposed to support the treatment of various diseases by generating deep heat in the human body. Here, when a radio frequency (RF) current is applied to a living tissue, the deep heat generates heat in the tissues of cells constituting the living body. This heat is also referred to as biothermal heat.

At this time, since the applied high frequency is non-ionized energy, not ionized energy, it does not destroy living tissue except in special cases and generates heat in the deep part of the body, so it stimulates cells to promote hair growth, relieve pain, It is used because it has effects such as promotion of blood circulation, treatment of hemorrhoids, inhibition of cancer cell proliferation, decomposition of body fat, removal of acne or blemishes, and improvement of dry eye syndrome.

A device for generating deep heat by applying a high-frequency current to the human body as described above is called a high-frequency therapy device, and various methods have been proposed.

For example, there may be mentioned configurations such as Patent Publication No. 2019-0105451 and Patent Publication No. 2017-0055369.

As described above, the high-frequency treatment device consists of a casing having a space formed therein, an electrode that is in contact with the user's body and generates a high-frequency current, a high-frequency generator that applies a high-frequency current to the electrode, and a control unit that controls the entire device.

In particular, the electrode may be implemented in various ways to be in direct contact with the user. For example, it is implemented in various forms most suitable for the body part to be applied, such as a handpiece form in contact with the hand, a bar form in contact with a local part of the human body, and a flat plate form in which the sole is in contact.

On the other hand, in the case of a high-frequency generator that directly supplies a high-frequency current to an electrode, it is generally implemented in a configuration that outputs only a preset frequency, so that it exhibits appropriate performance in the initial stage. There are disadvantages in that performance is deteriorated because it is continuously generated in the device, and in severe cases, a failure due to heat generation occurs.

An object of the present invention is to provide a high-frequency generator for a high-frequency treatment device that can be used for a long period of time and can achieve a certain performance in order to overcome the disadvantages of the prior art as described above.

In order to achieve the above object, the present invention is applied to a high-frequency treatment device for generating deep heat in a high-frequency generator for a high-frequency treatment device for generating a high frequency, comprising: a power switch for turning on/off the power of the entire device; a power module that converts external power into direct current; a booster module boosting the voltage of the power supply of the power module; a frequency oscillation module for selectively generating and outputting a plurality of predefined frequencies using the power of the power module; a control module for setting a frequency output from the power switch and the frequency oscillation module; a plurality of amplification modules for amplifying the output of the signal output from the frequency oscillation module; a switching module operating with the signals generated by the plurality of amplification modules and converting the DC power of the booster module into a pulse signal; a third amplification module boosting the voltage of the pulse generated by the switching module; and an output module connected to the output terminal of the third amplification module and connected to an external electrode, wherein the frequency of the high frequency signal output from the output module is 1 MHz to 5 MHz.

Preferably, the frequency oscillation module comprises a first frequency module for generating a signal of a predefined frequency, a second frequency module for generating a frequency different from the frequency generated by the first frequency module, and the first frequency module; It characterized in that it comprises a selection switch for selecting the operation of the second frequency module to output the corresponding frequency.

More preferably, the selection switch is controlled by the control module.

More preferably, the frequency oscillation module further comprises an oscillation noise filter for removing noise of the signal output by the selection switch.

Preferably, the plurality of amplification modules include a first amplification module for amplifying the signal output from the frequency oscillation module and a second amplification module for re-amplifying the signal amplified by the first amplification module characterized in that

More preferably, each of the first amplification module, the second amplification module, and the third amplification module includes a transformer and a primary module connected to the primary side of the transformer and a secondary module connected to the secondary side of the transformer. and the secondary module are electrically separated.

More preferably, the first-order amplification module further includes a first-order noise filter connected to an output of the secondary module, and the second-order amplification module includes a second-order noise filter connected to an output of the secondary module. Further comprising a noise filter, the third-order amplification module is characterized in that it further comprises a third-order noise filter connected to the output of the secondary module.

Preferably, the switching module is driven in a push-pull manner.

Preferably, the control module further comprises a temperature sensor for sensing the temperature of the plurality of amplification modules, the control module is a control to turn off the power switch when the temperature sensed by the temperature sensor is equal to or greater than a preset temperature characterized by performing

Preferably, the control module further includes a pressure sensor for sensing the contact pressure of the electrode, and the control module performs control to turn off the power switch when the value of the pressure sensor is greater than or equal to a preset value do it with

The high-frequency generator for a high-frequency treatment device according to the present invention can selectively drive two frequencies, and operates a switching module using the high-frequency signal amplified through a plurality of amplification steps to increase the power of the booster module to a third It is driven by input to the amplification module to minimize the heat generated in the signal amplification stage, and it is possible to prevent performance degradation due to temperature rise in advance by managing the temperature of the transformer applied to each amplification stage. In addition, it has the effect of exhibiting good performance.

1 is a block diagram of a high-frequency generator for a high-frequency treatment device according to the present invention,
Figure 2 is a block diagram of the frequency oscillation module shown in Figure 1,
Figure 3 is a graph showing the state of the signal output in Figure 2,
Figure 4 is a block diagram of the first amplification module shown in Figure 1,
5 is a block diagram of the switching module and the third amplification module shown in FIG. 1,
FIG. 6 is a configuration diagram of sensors connected to the control module shown in FIG. 1 .

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function interferes with the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the component from other components, and the essence, order, or order of the component is not limited by the term. When it is described that a component is “connected”, “coupled” or “connected” to another component, the component may be directly connected or connected to the other component, but between each component another component It is to be understood that may also be “connected”, “coupled” or “connected”.

The high frequency generator 100 for a high frequency treatment device according to the present invention is to be mounted inside the high frequency treatment machine, and as shown in FIG. 1 , a power switch 1 , a control module 10 , a frequency oscillation module 20 , and a second 1st amplification module 30, 2nd amplification module 40, 3rd amplification module 50, output module 60, switching module 70, power module 80 and booster module 90 consists of including

First, the power switch 1 serves as a general switch to turn on/off power provided from the outside. When on, power is supplied to the entire device, and when off, the power supply is stopped and the operation of the device is also stopped.

If necessary, the operation of the power switch 1 may be controlled by the control module 10, and the control module 10 controls on/off according to a user's input, and the internal temperature When it is determined as an emergency state, such as when the temperature rises above a preset temperature or when the user puts the electrode in excessive contact with the skin, the control module 10 may control it to be turned off.

In addition, the control module 10 controls the operation of the entire device, and serves to stop the operation by determining an abnormal state using a separate sensor as described above, and also receives the user's input through the high frequency treatment device. It performs the function of controlling the operation of the device based on the basis.

On the other hand, the power module 80 performs a function of converting commercial power into a DC voltage of a specific size, and the entire device operates based on the DC power of the power supply module 80, and the power module 80 The power generated by DC is 24V, but it can be generated with other voltages if necessary.

The power module 80 is suitable if the capacity is about 300W for a general high-frequency treatment device, but if necessary, the capacity can be increased.

And, the booster module 90 is a boosting device that serves to increase the DC power of the power module 80 to a maximum of 80V.

The output power of the booster module 90 is input to the third amplifier 60 .

On the other hand, the frequency oscillation module 20 is used to generate a necessary high-frequency signal, and as shown in FIG. 2 , a first frequency module 21 and a second frequency module 22, a selection switch 23, and generation It may include an oscillation noise filter 24 that removes noise of the specified frequency.

First, the first frequency module 21 and the second frequency module 22 generate a pulse as shown in FIG. 3, but generate different frequencies.

For example, when the first frequency module 21 generates a frequency of 1 MHz, the second frequency module 22 may be set to generate a frequency of 4 MHz, and if necessary, the frequencies of both may be set to different values. .

Preferably, the frequency is 1 MHz to 5 MHz, and the best deep heat is generated in the above range.

The selection switch 23 is operated by the control module 10, and the selection switch 23 is operated according to a user input or an internal program to operate the first frequency module 21 or the second frequency module 22 ) to selectively operate.

On the other hand, the oscillation noise filter 24 is used to remove noise of a frequency generated by the frequency modules 21 and 22, and is used to remove high-frequency components higher than the generated frequency, and if necessary, a predefined It may be implemented in a configuration that removes frequency components below the frequency.

Since the pulse generated through the frequency oscillation module 20 has a low output, the output is sequentially amplified through the first amplification module 30 and the second amplification module 40, and the amplified output is output to the switching module ( 70) as an operation signal.

Of course, the frequency of the pulse generated through the frequency oscillation module 21 is not changed and only the output voltage is amplified.

The voltage generated by the frequency oscillation module 20 is about 5V, amplified to about ±12V through the first amplification module 30, and amplified to a voltage of about ±24V through the second amplification module 40 and, if necessary, the current may be increased for the operation of the switching module 70 .

Of course, if necessary, the voltages output from the frequency oscillation module 20 , the first amplification module 30 , and the second amplification module 40 can be changed.

First, the basic pulse signal output through the oscillation noise filter 24 is input to the first amplification module 30 and the amplified primary amplified signal is output.

As shown in FIG. 4 , the primary amplification module 30 includes a primary module 31 connected to the primary side of the transformer 33 with respect to the transformer 33 and a secondary module connected to the secondary side of the transformer 33 . (32) is included.

The primary module 31 and the secondary module 32 are electrically separated by the transformer 33 , and the secondary-side signal is amplified by induction.

In addition, when the transformer 33 is applied as an insulating transformer, the primary module 31 and the secondary module 32 are completely electrically insulated, so that they are separated from each other in terms of heat generation and do not affect each other. In addition, there is an advantage in that the movement of noise between each circuit is minimized and the DC component is automatically removed.

Meanwhile, a first-order noise filter is connected to the output of the secondary module 32, and the signal amplified through the primary module 31, the transformer 33, and the secondary module 32 is applied to the first-order noise filter. high-frequency or low-frequency noise is removed.

Meanwhile, as shown in FIG. 4 , the secondary amplification module 40 also has the same structure as the primary amplification module 30 , and is a primary module connected to the primary side of the transformer 43 based on the transformer 43 . (41) and the transformer (43) includes a secondary module 42 connected to the secondary side, and a secondary noise filter connected to the output of the secondary module (42).

However, in each of the transformer 43 , the primary module 41 , the secondary module 42 , and the secondary noise filter, there is a difference in specific capacity and setting values of each component.

The output of the secondary amplification module 40 is input to the switching module 70 , and the switching module 70 converts the DC high voltage of the booster module 90 to the output frequency of the secondary amplification module 40 and It is converted into pulses of the same frequency and applied to the input side of the third amplification module 50 .

As shown in FIG. 5 , the switch module 70 is configured as a push-pull switching circuit to generate the output voltage 80V of the booster module 90 at the same frequency as the output frequency of the secondary amplification module 40 . It is applied to the tertiary amplification module 50, and at this time, +80V and -80V are repeatedly inputted to both terminals of the primary side to which the primary module 51 of the transformer 53 of the tertiary amplification module 50 is connected.

On the other hand, the transformer 53 amplifies the voltage signal input to the primary side by 6 to 8 times and outputs it to the secondary side connected to the secondary module 53 to implement a high voltage pulse, but an appropriate amplification ratio is used according to the purpose. can be set.

If necessary, the third-order amplification module 50 may include a third-order noise filter connected to the secondary side of the transformer 53 .

The output module 60 functions to connect the signal finally output through the tertiary amplification module 50 to an external electrode. That is, it is configured to include components for connection with the electrode.

The high frequency generator 100 for a high frequency treatment device according to the present invention may include a separate temperature sensor 2 and a pressure sensor 3 attached to the electrode to sense the pressure of the electrode and the human body as shown in FIG. there is.

In particular, the temperature sensor 2 is attached to the transformers 33, 43, 53 with a high possibility of generating high heat to detect the temperature, and when a single sensor is applied, the tertiary amplification module 50 showing the highest output It is preferable to attach it to the transformer 53 of

For safety, when the temperature detected by the temperature sensor 2 is higher than or equal to a preset temperature, the control module 10 operates the power switch 1 to 'off' to stop the operation of the entire device. can do.

In addition, for safety, even when the pressure value sensed by the pressure sensor 3 is greater than or equal to a predefined value, the control module 10 operates the switch 1 to 'off' to control the operation of the entire device. You can control it to stop.

That is, when the user strongly attaches the electrode to the skin, there is a risk of high heat, so the above safety control is performed.

What has been described above is merely an embodiment for implementing the high-frequency generator for a high-frequency treatment device according to the present invention, and the present invention is not limited to the above-described embodiment, and is not limited to the scope of the present invention as claimed in the following claims. Without it, anyone with ordinary knowledge in the technical field to which the present invention belongs will say that the technical spirit of the present invention exists to the extent that it can be implemented with various modifications.

1: Power switch 2: Temperature sensor
3: pressure sensor 10: control module
20: frequency oscillation module 21: first frequency module
22: second frequency module 23: select switch
24: oscillation noise filter 30: first-order amplification module
31: primary module 32: secondary module
33: trans 40: tertiary amplification module
41: primary module 42: secondary module
43: trans 50: tertiary amplification module
51: primary module 52: secondary module
53: transformer 60: output module
70: switching module 80: power module
90: booster module 100: high frequency generator

Claims (10)

A high-frequency generator for a high-frequency therapy device that is applied to a high-frequency therapy device that generates deep heat and generates high frequency, the device comprising:
a power switch that turns the power of the entire device on and off;
a power module that converts external power into direct current;
a booster module boosting the voltage of the power supply of the power module;
a frequency oscillation module for selectively generating and outputting a plurality of predefined frequencies using the power of the power module;
a control module for setting a frequency output from the power switch and the frequency oscillation module;
a plurality of amplification modules for amplifying the output of the signal output from the frequency oscillation module;
a switching module operating with the signals generated by the plurality of amplification modules and converting the DC power of the booster module into a pulse signal;
a third amplification module boosting the voltage of the pulse generated by the switching module; and
An output module connected to the output terminal of the third amplification module and connected to an external electrode,
The frequency of the high-frequency signal output from the output module is 1 MHz to 5 MHz,
The plurality of amplification modules include a first amplification module for amplifying the signal output from the frequency oscillation module and a second amplification module for re-amplifying the signal amplified by the first amplification module,
Each of the first amplification module, the second amplification module and the tertiary amplification module includes a transformer and a primary module connected to the primary side of the transformer and a secondary module connected to the secondary side of the transformer so that the primary module and the secondary module are electrically A high-frequency generator for a high-frequency treatment device, characterized in that it is separated into a.
The method according to claim 1, wherein the frequency oscillation module is a first frequency module for generating a signal of a predefined frequency, a second frequency module for generating a frequency different from the frequency generated by the first frequency module, and the first frequency module and a selection switch for selecting the operation of the second frequency module and outputting the corresponding frequency.
The high frequency generator for a high frequency treatment device according to claim 2, wherein the selection switch is controlled by the control module.
The high frequency generator for a high frequency treatment device according to claim 3, wherein the frequency oscillation module further comprises an oscillation noise filter for removing noise from the signal output by the selection switch.
delete delete The method according to claim 1, wherein the first-order amplification module further comprises a first-order noise filter connected to the output unit of the secondary module, the second-order amplification module is a second-order amplification module connected to the output unit of the secondary module A high-frequency generator for a high-frequency treatment device, further comprising a noise filter, wherein the third-order amplification module further comprises a third-order noise filter connected to the output unit of the secondary module.
The apparatus of claim 1, wherein the switching module is driven in a push-pull manner.
The method according to claim 1, wherein the control module further comprises a temperature sensor for sensing the temperature of the plurality of amplification modules, wherein the control module turns off the power switch when the temperature sensed by the temperature sensor is equal to or greater than a preset temperature A high-frequency generator for a high-frequency treatment device, characterized in that the control is performed.
The method according to claim 1, wherein the control module further comprises a pressure sensor for sensing the contact pressure of the electrode, and the control module performs control of turning off the power switch when the value of the pressure sensor is greater than or equal to a preset value A high-frequency generator for a high-frequency treatment device, characterized in that it.

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