KR20200124848A - A Vacuum wave device for promoting blood circulation - Google Patents

Abstract

The present invention relates to a vacuum wave device for promoting blood circulation, capable of minimizing damage to skin. According to the present invention, the vacuum wave device for promoting the blood circulation includes: a wave device body; a positive electrode substrate; a plurality of positive electrode pins; a negative electrode substrate; a plurality of negative electrode pins; an eccentric cam configured to eccentrically rotate the negative electrode substrate on which the negative electrode pins are installed in a horizontal direction; a driving motor; a low frequency regulator; a regulator connection unit; a vacuum adsorption protrusion; a flow path member; a selection valve configured to selectively connect an air inhaler for inhaling air and a fumigator for discharging steam to the flow path member; a ball reception space; an infrared LED; and an optical ball having a circumference making close contact with the eccentric cam in the ball reception space to rotate according to the rotation of the eccentric cam, and configured to focus light of the infrared LED to a center of the optical ball, diffuse the light of the infrared LED, and provide the light of the infrared LED to a human body.

Description

A vacuum wave device for promoting blood circulation

The present invention relates to a vacuum wavelength device for promoting blood circulation for stimulating blood circulation by stimulating capillaries of the skin by vacuum, electricity, or wavelength of light.

When the blood circulation in the body is not good, various diseases occur, so it is treated by taking medicines or giving massage to smooth the blood circulation.

However, in the case of taking a drug, there is a concern about side effects caused by the drug, and since a prescription must be given to a doctor, a lot of treatment is performed with a massage that is relatively less cumbersome and can be easily performed.

On the other hand, massage promotes blood circulation by stimulating the relaxation of muscles or capillaries, and since there is a limit to stimulating capillaries by hand massage, various types of devices for performing massage have recently been developed. .

As a device for performing a conventional massage, a "skin care device" of Korean Patent Publication No. 10-1705067 (announced on September 9, 2017) has been disclosed.

The above-described conventional skin care device is used for physical massage, irradiation of light rays having a therapeutic and improving effect of the skin, vibration to promote blood circulation of capillaries, application of appropriate active ingredients, and effective absorption of active ingredients. It was possible to easily and effectively manage the skin, including the scalp, by making it possible to easily combine and use the thermal and cooling functions through iontophoresis and temperature control as needed.

However, in the conventional skin care device, vibration is generated by ultrasonic waves, and the brush pin stimulates the skin by the vibration, so that the effect of stimulating capillaries only by the vibration decreases.

In addition, although the light irradiation unit irradiates light with a wavelength suitable for the skin condition, since the light is concentrated and irradiated, there is a risk of skin damage depending on the wavelength of the light. There was a problem that the effect of stimulating capillaries distributed in the body in a form is not high.

In addition, since capillaries are stimulated by relying on vibration, light, and heat, there is a limit to promoting blood circulation by stimulating capillaries that exist in various forms.

The present invention has been conceived to solve the above problems, and the problem to be solved by the present invention is that it is possible to stimulate capillaries in the form of mechanical rubbing to promote blood circulation according to stimulation of capillaries, and at low frequencies. It stimulates capillaries by stimulating the capillaries, and can improve the irritation of capillaries by changing the intensity of low-frequency and infrared rays, and a vacuum wavelength for promoting blood circulation that can minimize damage to the skin such as burns due to the concentration of infrared rays. It aims to provide qi.

The vacuum wavelength device for promoting blood circulation according to an embodiment of the present invention for achieving the above object is a wavelength base body including a bottom portion through which a plurality of pinholes are formed, and a low-frequency anode is located above the bottom portion of the wavelength base body. An anode substrate printed with an electrically connected anode pattern, a plurality of anode pins that are electrically connected to the anode pattern to flow a low-frequency current of the anode and protrude from the pin hole, and are positioned spaced apart from the upper portion of the cathode substrate within the wavelength body And a negative electrode pattern on which a negative electrode of a low frequency current is connected so that the low frequency current provided to the positive electrode substrate flows through the body and stimulates capillaries, and the negative electrode pattern is electrically connected to the negative electrode pattern on the negative electrode substrate to connect the positive electrode pin. A plurality of cathode pins protruding through the pin hole flows through the body through the low-frequency current through the pin hole, the cathode pin rotates eccentrically, rubs the body, and rotates the anode substrate installed with the cathode pin in a horizontal direction so that low-frequency current passes A low-frequency controller having an eccentric cam that drives the eccentric cam, a driving motor that drives the eccentric cam, a low-frequency controller installed on the negative electrode substrate to adjust the intensity of the low-frequency current provided to the positive electrode substrate, and the adjustment shaft by the eccentric rotational motion of the negative electrode substrate A controller connection part connecting the control shaft to the negative electrode substrate so as to provide the body by varying the intensity of the low-frequency current through this movement, a vacuum adsorption protrusion through which air is sucked or vapor is discharged so that the skin is adsorbed by protruding from the bottom of the bottom part, A flow path member that is installed on the upper surface on which the anode substrate is located at the bottom and connects each of the adsorption protrusions to inhale air or discharges steam, and inhales air from the vacuum adsorption protrusions or to discharge steam. A selection valve that selectively connects the air intaker and the fumigant for discharging steam to the flow path member, and is formed by dividing the negative electrode substrate, the positive electrode substrate, and the bottom portion so as to expose the eccentric cam to the lower portion. A ball receiving space, an infrared LED installed in the ball receiving space to irradiate infrared rays to stimulate capillaries by infrared rays, And an optical ball that is in close contact with the eccentric cam in the ball receiving space, rotates according to the rotation of the eccentric cam, collects and diffuses the light of the infrared LED to the center and provides it to the body.

The infrared LED includes an infrared controller including a rotating wheel that adjusts the intensity of infrared rays irradiated by the infrared LED, and the rotating wheel is installed in the ball receiving space so as to be in close contact with the optical ball to prevent rotation of the optical ball. Accordingly, it can be rotated together and irradiated by varying the intensity of infrared rays irradiated to the body.

The negative electrode pin has a convex curved surface with respect to the negative electrode pattern so that electrical connection to the negative electrode pattern is maintained even if the negative electrode pin rotates, and the negative electrode pin rotates in opposite directions around the positive electrode substrate. It may include a ball support portion rotatably fitted to the positive electrode substrate.

The optical ball may include light exit grooves having different sizes around the optical ball to diffuse and irradiate infrared rays introduced from the infrared LED in various forms.

According to the present invention, the eccentric cam rotates the negative electrode by eccentric rotation of the negative electrode substrate, thereby stimulating the capillaries in the form of the negative electrode rubbing the skin, thereby improving the irritation of the capillaries, as well as the negative electrode pin and the positive electrode. There is an advantage in that blood circulation can be promoted by supplying a low frequency current to the pin to improve the stimulation of capillaries by the low frequency.

In addition, as the control shaft of the low frequency controller rotates according to the rotation of the eccentric cam, the intensity of the low frequency current can be variably adjusted to improve the stimulation of the capillaries. As the optical ball rotates according to the rotation of the eccentric cam, infrared rays are transmitted to the skin. It is concentrated and can prevent damage to the skin.

In addition, the infrared regulator adjusts the intensity of infrared rays by an optical ball rotating by an eccentric cam, and irradiates infrared rays of various intensity to the skin, thereby improving the stimulation of capillaries, thereby promoting blood circulation.

In addition, there is an advantage in that the skin is adsorbed by the vacuum adsorption protrusion to remove foreign substances or by supplying steam to improve the irritation of capillaries.

1 is an exploded perspective view showing a vacuum wavelength device for promoting blood circulation according to an embodiment of the present invention.
2 is a side cross-sectional view showing a vacuum wavelength device for promoting blood circulation according to an embodiment of the present invention.
3 is a side cross-sectional view showing a vacuum wavelength device for promoting blood circulation according to an embodiment of the present invention, showing an operating state of an eccentric cam.
4 is a schematic configuration diagram showing an electrical connection state of the vacuum wavelength device for promoting blood circulation according to an embodiment of the present invention.

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

The vacuum wavelength device 100 for promoting blood circulation according to an embodiment of the present invention irradiates the skin of the body with infrared light, applies low-frequency electricity, or stimulates capillaries in the form of massage or vacuum adsorption to the skin. , It is to help health by promoting blood circulation.

As shown in FIGS. 1 and 2, the vacuum wavelength device 100 for promoting blood circulation according to an embodiment of the present invention may include a wavelength base body 110.

The wavelength base body 110 may be formed in a hollow shape, and the wavelength base body 110 is a form in which the upper housing 111 and the bottom part 115 are combined to form a space for accommodating each component therein. I can.

The upper housing 111 may be formed by protruding from the upper portion of the handle 113 so that the body can be easily rubbed and treated.

In addition, a pin hole 116 in which ends of the cathode pin 135 and the anode pin 123 to be described below protrude from the bottom portion 115 may be formed in the bottom portion 115, and the anode pin 123 ), the size of the pin hole 116 from which the negative pin 135 protrudes is larger than the size of the pin hole 116 from which the negative pin 135 protrudes, so that the rotation of the negative pin 135 can be ensured.

On the other hand, in the central portion of the bottom portion 115, a portion in which the ball receiving space 160, which will be described below, is to be formed may be formed through, and a plurality of vacuum adsorption protrusions around the portion where the ball receiving space 160 is to be formed (117) can be formed.

The vacuum adsorption protrusion 117 may be in communication with the inner side of the bottom portion 115, and the vacuum adsorption protrusion 117 may be formed of a material having elasticity, and the vacuum adsorption protrusion 117 is in close contact with the skin to allow an air inhaler. Air may be sucked in by the vacuum generated in 193 to bring the skin into close contact with the vacuum adsorption protrusion 117, or the vapor generated from the fumigator 195 may be supplied to the skin.

Here, it may be a known air inhaler 193 that inhales air by a cylinder, and the fumigator 195 is implemented as a known fumigator 195 that generates steam by adding herbs or additives used for skin care to water Can be.

In addition, when air is sucked from the vacuum adsorption protrusion 117, not only the capillaries are stimulated according to the adsorption, but also the function of adsorbing foreign substances accumulated on the skin may be performed.

A flow path member 150 for sucking air or supplying vapor through a plurality of vacuum suction protrusions 117 may be installed on the bottom 115.

The flow path member 150 is formed in the shape of a donut so that the ball accommodation space 160 can be located at the center, and the inside may be empty so that steam or air can pass, and the flow path member 150 has a wavelength base body outside It is interconnected by the air intake unit 193 and the fumigator 195 and the connection hose 155 located outside of 110 to inhale air or supply steam.

In addition, the flow path member 150 is connected to pass through the bottom portion 115 and communicates with the flow path of the vacuum suction protrusion 117 so that the vapor supplied to the flow path member 150 is discharged through the vacuum suction projection 117, Air is sucked into the flow path member 150 through the vacuum adsorption protrusion 117, and the vacuum adsorption protrusion 117 can be stimulated to the capillaries in the form of pulling the skin.

Here, the fumigator 195 supplies warm steam to the skin to expand capillaries by heat, or expands the pores by a component of the additive mixed in the fumigator 195 to remove foreign substances, or to generate the effect of the additive. Can be supplied directly to the skin.

In addition, an insertion hole into which a connection hose 155 connecting the flow path member 150 and the air inhaler 193 or the fumigator 195 is inserted may be formed through the upper portion of the wavelength base body 110.

In the embodiment, the insertion hole is described as being formed on the upper portion of the wavelength base body 110, but it is obvious that the insertion hole may be formed on the side of the wavelength base body 110.

On the inner side of the upper housing 111, a cathode substrate 130 is disposed on the anode substrate 120 on the upper side of the anode fitting portion 111a and the anode fitting portion 111a, which are installed by inserting the anode substrate 120 to be described below. A negative electrode fitting portion 111b that is spaced apart and fitted may be formed, and the negative electrode substrate 130 fitted in the negative electrode fitting portion 111b is fitted in a state with a margin so as to rotate eccentrically in the horizontal direction in the negative electrode fitting portion 111b. I can lose.

As shown in FIGS. 1 to 3, the vacuum wavelength device 100 for promoting blood circulation according to an embodiment of the present invention includes a negative electrode pin 135, a negative electrode substrate 130, and a low-frequency electric stimulation to capillaries. A positive electrode pin 123 and a positive electrode substrate 120 may be included.

The anode substrate 120 may be formed in the shape of a plate and may be fitted and fixed to the anode fitting portion 111a of the upper housing 111.

A plurality of anode pins 123 may be installed in the circumferential direction of the anode substrate 120, and a plurality of anode pins 123 may be installed on a plurality of different concentric circles and spaced apart from each other along the circumferential direction of each concentric circle. .

Meanwhile, a positive electrode pattern 121 printed with a conductor electrically connected to the positive electrode of a low frequency current may be formed on all the positive electrode pins 123 on the positive electrode substrate 120, and a ball receiving space in the center of the positive electrode substrate 120 It may be formed in a shape through which 160 is positioned.

The positive electrode pin 123 may penetrate the upper portion of the positive electrode substrate 120 and protrude downward, and the end protruding toward the lower portion of the positive electrode substrate 120 may protrude through the pin hole 116 of the bottom portion 115. Can be located.

The end of the positive electrode pin 123 may be formed to have a spherical curved surface in order to smooth contact with the skin.

In addition, the anode substrate 120 may be formed through a pin support hole 125, which is rotatably supported by passing through the cathode pin 135 to be described below, and the pin support hole 125 includes each negative pin ( 135) may be formed in a plurality of portions corresponding to the cathode pin 135 so that each can be fitted.

The negative electrode substrate 130 may be connected to a negative electrode having a low frequency current so that the low frequency current supplied to the positive electrode substrate 120 flows, and a plurality of negative electrode pins 135 are spaced apart from each other in the circumferential direction to the negative substrate 130. Can be.

In addition, a negative electrode pattern 131 printed with a conductor connected to a negative electrode of a low frequency current may be formed on the negative substrate 130 by electrically connecting all of the plurality of negative pins 135.

On the other hand, the negative pin 135 may be arranged to be spaced apart from the positive pin 123, in the embodiment, the negative pin 135 is in a concentric circle having a diameter different from the plurality of concentric circles in which the positive pin 123 is arranged. Although the cathode pins 135 are shown to be arranged along the circumference of each concentric circle, the cathode pins 135 may be alternately disposed along the circumferential direction on the same concentric circle, or may be arranged and disposed in a regular or irregular mixture with each other.

In addition, a portion of the cathode substrate 130 corresponding to the ball receiving space 160 may be provided with a cam support portion formed therethrough, and the cathode substrate 130 is fitted into the cathode fitting portion 111b of the upper housing 111. In this state, it may be installed on the negative electrode fitting part 111b to rotate eccentrically in the horizontal direction.

The cathode pin 135 may include a pin head 135a and a ball support part 135b.

The pin head 135a has a larger circumference than the circumference of the cathode pin 135, so that the cathode pin 135 is inserted through the anode substrate 130, and the cathode pin 135 is separated from the anode substrate 130 Can be prevented.

On the other hand, the pinhead 135a is formed in a curved surface with a convexly protruding lower portion, so that when the negative electrode substrate 130 rotates eccentrically in the horizontal direction, it is possible to prevent the electrical connection from the negative electrode pattern 131 from being disconnected. .

The ball support part 135b may support the negative pin 135 so that the pin support hole 125 formed in the positive substrate 120 is rotatable. The ball support part 135b may be formed in a spherical shape to support the negative electrode pin 135 so as to rotate eccentrically according to the eccentric rotation movement of the negative electrode substrate 130 in the pin support hole 125.

In this case, the ball support part 135b only supports the negative electrode pin 135 in the pin support hole 125 of the positive electrode substrate 120, and is not electrically connected to the positive electrode pattern 121 of the positive electrode substrate 120.

On the other hand, the end of the anode pin 123 in the opposite direction where the pin head 135a is located may protrude downward through the pin hole 116 formed in the bottom portion 115 by protruding from the bottom of the anode substrate 120, and , The protruding length of the positive pin 123 and the protruding length of the negative pin 135 from the bottom 115 may protrude to the same length.

The positive pin 123 and the negative pin 135 may be formed of metal to allow low-frequency current to pass, and the positive pin 123 and the negative pin 135 are in contact with the body and Through the cathode pin 135, a low-frequency current may be applied to the body to stimulate capillaries and muscles.

The negative pin 135 and the positive pin 123 may be formed of metal to allow low-frequency current to pass, and the negative pin 135 and the positive pin 123 are made of an alloy to prevent bending easily when rubbed on the body. Can be formed.

The alloy forming the cathode pin 135 and the anode pin 123 may be any one or two or more of iron, nickel, silicon, copper, silver, gold, and the anode pin 135 and the anode pin 123 are Low-frequency currents of various intensities can be formed of different metals to stimulate capillaries through the body.

In addition, although not shown in the drawing, a silicone pad having elastic force is adhered to the upper surface of the negative electrode substrate 130 to prevent the negative electrode pin 133 from being separated, and at the same time, the pin head 133a of the negative electrode pin 133 is lowered by elastic force. The pin head 133a may be in close contact with and fixed to the negative electrode pattern 131 by pressing in close contact with each other.

Here, the silicon pad may be attached to the negative electrode substrate 130 in such a manner that the remaining portions of the negative electrode substrate 130 are adhered to the negative electrode substrate 130 except for a portion where the pinhead 133a is positioned.

The vacuum wave device 100 for promoting blood circulation according to an embodiment of the present invention includes an eccentric cam 140 and a driving motor 145 so that the negative pin 135 rubs the skin and stimulates capillaries to promote blood circulation. I can.

The eccentric cam 140 may be installed so as to be rotatable in the cam support portion of the cathode substrate 130, and the eccentric cam 140 rotates eccentrically in the horizontal direction as the eccentric cam 140 rotates eccentrically in the cam support portion. I can.

The eccentric cam 140 may be formed of synthetic resin, and the eccentric cam 140 may be positioned so that the rotation shaft is eccentric, and the eccentric cam 140 rotates and presses the inner circumference of the cam support portion of the top dead center. (130) can be rotated eccentrically.

The driving motor 145 can rotate the eccentric cam 140, and the driving motor 145 is located above the eccentric cam 140 and is accommodated and fixed inside the handle part 113 of the upper housing 111 Can be.

The drive shaft of the drive motor 145 is coupled to an eccentric portion of the eccentric cam 140 so that when the drive motor 145 rotates, the eccentric cam 140 is eccentric and can rotate, and the negative substrate ( 130) can be rotated eccentrically.

Here, when the negative substrate 130 rotates eccentrically, all the negative pins 135 connected to the negative substrate 130 rotate eccentrically around the cardboard hole of the positive substrate 120 and rotate to rub the skin like a massage. It can stimulate blood vessels and promote blood circulation.

And the lower portion of the eccentric cam 140 may be located above the ball receiving space 160, the lower portion of the eccentric cam 140 has a concave curved surface so that the optical ball 175 to be described below is supported and rotated. It can be formed to have.

1 to 3, the vacuum wavelength device 100 for promoting blood circulation according to an embodiment of the present invention includes an infrared LED 170 and an optical ball 175 to promote blood circulation by an infrared wavelength. can do.

The infrared LED 170 may be installed in the viewing space 160 and may irradiate infrared rays.

The infrared LED 170 may emit light by electricity to generate infrared rays, and since the infrared LED 170 may be implemented as a known infrared LED 170, a detailed description of the structure for generating infrared rays will be omitted.

Infrared LED 170 may be installed in the upper inner circumference of the viewing space 160, the infrared LED 170 is a viewing acceptance to irradiate infrared rays to the center of the optical ball 175 to be installed in the viewing space 160 It may be installed inclined toward the optical ball 175 in the space 160.

The optical ball 175 may be installed in the ball receiving space 160, and is in contact with the eccentric cam 140 located at the top of the receiving space, so that the optical ball in the ball receiving space 160 is rotated according to the rotation of the eccentric cam 140. The ball 175 can rotate.

On the other hand, the optical ball 175 may collect and diffuse the infrared rays irradiated from the infrared LED 170 to the body, and the infrared rays are concentrated on the outer surface of the optical ball 175 to be concentrated on the skin, thereby damaging the tissues of the skin. In order to prevent occurrence, a plurality of light exit grooves 175a that are diffused and irradiated to the body may be formed around the optical ball 175.

In this case, the light exit groove 175a may have various sizes of light exit grooves 175a formed around the optical ball 175 so that infrared rays are diffused and irradiated with various intensities.

The optical ball 175 may be formed of a transparent body so that infrared rays can be introduced from the infrared LED 170, and the optical ball 175 rotates in the viewing space 160 according to the rotation of the eccentric cam 140 and In the form of changing the position of the diffused and emitted light exit groove 175a, infrared rays are concentrated on any one of the skin, thereby preventing damage to the skin.

Here, infrared rays emitted from the infrared LED 170 may be near infrared rays having a light wavelength of 0.75 to 3 μm, and near infrared rays generate heat, so when exposed for a long time, there is a concern of an image.

Accordingly, it is possible to prevent damage to the skin such as an image that occurs as the optical ball 175 rotates by the eccentric cam 140 to focus and irradiate infrared rays at one place.

As shown in FIG. 4, the vacuum wavelength device 100 for promoting blood circulation according to an embodiment of the present invention may include a controller 180.

The controller 180 can control the driving motor 145, the negative substrate 130 and the positive substrate 120, and the infrared LED 170, and the driving motor 145 and the infrared LED 170 for operation Power can be supplied from the outside.

The power line may be connected to the controller 180 through a hole formed through the handle part 113 of the upper housing 111.

On the other hand, the controller 180 may include a manipulation unit, and although not shown in the drawing, the manipulation unit is installed so that buttons for manipulation on the upper housing 111 are exposed to turn on or off the infrared LED 170 as necessary. , The driving motor 145 can be turned on or off, or the generation of low-frequency current can be turned on or off.

In addition, the controller 180 controls the air inhaler 193 and the fumigator 195 to suck air from the vacuum adsorption protrusion 117 by the air intake of the air inhaler 193, or the steam generated from the fumigator 195. It may be configured to be discharged through the vacuum adsorption protrusion 117.

The controller 180 may include a low frequency generator 181 that receives power and converts it into a low main plate current, and the low frequency current generated in the low frequency generator 181 has an anode of the anode pattern of the anode substrate 120 ( It is electrically connected to 121 and the negative electrode is electrically connected to the negative electrode pattern 131 of the negative electrode substrate 130, it is possible to provide a low-frequency current to the positive electrode pin 123 and the negative electrode pin 135.

The low-frequency generator 181 can be converted into a low-frequency current of a square wave having a width of 0.01 to 1 ms and a frequency of 1 to 500 Hz to be provided to the positive substrate 120 and the negative substrate 130, and the low frequency is a muscle, or nerve or It can improve blood circulation by stimulating skin and the like by electric waves.

The low frequency generator 181 may control the intensity of the low frequency current provided to the body by controlling the intensity of the current generated from the low frequency generator 181.

On the other hand, the low frequency controller 183 may be implemented by a variable resistance, and the low frequency controller 183 is installed on the anode substrate 120, and is positioned on the anode substrate 120 to rotate eccentrically. ) May be configured to adjust the intensity of the low-frequency current by being coupled to the regulator connector (183a) to which the control shaft for changing the intensity of the low-frequency current is coupled, and rotating the control shaft together according to the eccentric rotational motion of the negative electrode substrate (130). .

Here, when the low frequency provided to the body is provided with only a preset intensity, it performs a function of relaxing the muscles rather than stimulating the capillaries, but when the intensity of the low frequency current is variably provided, the capillaries are variably provided to stimulate the capillaries. By improving the irritation, it is possible to further improve the promotion of blood circulation.

The control shaft of the low frequency controller 183 is configured to gradually increase or decrease the resistance value while rotating around a certain starting point, and when it is located back to the starting point, it is configured to have an initial resistance value. It can be provided to the body by changing the intensity of the current.

The controller connection part (183a) connecting the control shaft to the negative electrode substrate 130 forms a control shaft on the disk having a path through which the negative electrode substrate 130 moves eccentrically, and the eccentric portion is coupled to the negative electrode substrate 130. According to the rotation of the negative electrode substrate 130, the regulator connector 183a rotates together and may be configured to rotate the control shaft.

The controller 180 may include an infrared control unit 185.

The infrared control unit 185 can control the infrared LED 170, and the infrared control unit 185 turns on or off the infrared LED 170, or can provide the infrared LED 170 by changing the power required. TEk.

The infrared control unit 185 may include an infrared controller 187.

The infrared controller 187 may adjust the intensity of infrared rays irradiated from the infrared LED 170.

Meanwhile, the infrared controller 187 may be implemented as a variable resistor so that the intensity of the irradiated infrared rays is changed by adjusting the intensity of the current provided to the infrared LED 170, and the infrared controller 187 is Since the resistance value is different, the intensity of the infrared ray may be changed in a form of changing the intensity of the current supplied to the infrared LED 170.

The infrared controller 187 is installed in the ball receiving space 160 so that the rotating wheel is in close contact with the optical ball 175, and the rotating wheel rotates by the optical ball 175 rotated by the eccentric cam 140. You can change the intensity of.

Here, when the intensity of infrared rays provided by the infrared LED 170 is variably changed and provided to the body rather than a constant case, the depth and position of the infrared rays penetrating change according to the intensity of the infrared rays. The effect of stimulating blood vessels can be further improved.

On the other hand, the infrared controller 187 drives the infrared LED 170 in a form that changes to the initial resistance value when the resistance value increases or decreases around a certain starting point when the rotating wheel rotates and is again located at a starting point. The intensity of infrared rays can be adjusted by changing the intensity of the current to be used.

The controller 180 may include a selection valve 190.

The selection valve 190 is installed in the connection hose 155 connected to the flow path member 150, and the air inhaler 193 and the fumigator 195 are connected to the connection hose 155 together to selectively suck in the air inhaler 193 The suction force acts on the vacuum adsorption protrusion 117 to stimulate the capillaries in the form of adsorbing the skin, or the vapor generated from the fumigator 195 is transferred to the skin through the vacuum adsorption protrusion 117 to stimulate the capillaries. It can promote blood circulation in the form.

The selection valve 190 is implemented as a three-way valve, and a connection hose 155 is connected to one of the valve ports, an air inhaler 193 is connected to the other, and a fumigator 195 is connected to the other, so that the selection valve 190 Depending on the operation of ), the connection hose 155 connected to the flow path member 150 and the air inhaler 193 may be connected, or the connection hose 155 and the fumigator 195 may be selectively connected.

The controller 180 includes a timer and stimulates the capillaries by connecting the connection hose 155 and the fumigator 195 for a preset time when the selection valve 190 is preset by a time preset in the timer, and then after a preset time. In this case, the selection valve 190 may control the selection valve 190 to stimulate capillaries in the form of connecting the connection hose 155 and the air inhaler 193 to adsorb the skin.

The selection valve 190 may be implemented as an electromagnetic valve operated by an electric signal.

It will be described the action and effect between each of the components described above.

In the vacuum wavelength device 100 for promoting blood circulation according to an embodiment of the present invention, the anode substrate 120 is installed inside the wavelength body 110, and the cathode substrate 130 is installed on the anode substrate 120. And, a plurality of anode pins 123 are electrically connected to the anode substrate 120 by a cathode pattern 131 and protrude through the pin holes 116 of the bottom 115 of the wavelength base body 110.

In addition, a negative electrode pin 135 electrically connected to the negative electrode pattern 131 is installed on the negative electrode substrate 130, and the negative electrode pin 135 has a pin head 135a of the negative electrode pin 135 and a negative electrode pattern 131 The ball support part 135b formed in the central part of the positive electrode pin 123 is installed rotatably by being inserted into the pin support hole 125 formed in the positive electrode substrate 120 while being electrically connected, and the end is installed at the bottom ( 115).

A plurality of vacuum adsorption protrusions 117 are formed to protrude downward in the bottom portion 115, and a flow path member 150 is installed above the bottom 115 in which the vacuum adsorption protrusions 117 are formed.

The flow path member 150 is connected to the air inhaler 193 and the fumigator 195 located outside the wavelength body 110 by a connecting hose 155, and the connecting hose 155 has an air inhaler 193 and a fumigator. A selection valve 190 capable of selectively connecting 195 to the connection hose 155 is installed.

On the other hand, the eccentric cam 140 is installed in the cam support portion formed in the central portion of the cathode substrate 130, the eccentric cam 140 is rotatably installed by the drive motor 145, when the eccentric cam 140 rotates. The negative electrode substrate 130 is installed to rotate eccentrically in the horizontal direction.

In the center of the bottom portion 115 and the anode substrate 120, a ball receiving space (a space) that penetrates the bottom portion 115 and the anode substrate 120 to partition the circumference of the eccentric cam 140 formed on the cathode substrate 130 160) is formed, the infrared LED 170 is installed in the viewing space 160, and the optical ball 175 is accommodated.

In this case, the optical ball 175 is in contact with the lower portion of the eccentric cam 140 so that when the eccentric cam 140 rotates, the optical ball 175 may be rotated.

In addition, a low frequency controller 183 is installed on the anode substrate 120 so that the control shaft of the low frequency controller 183 is connected to the cathode substrate 130 to rotate the control shaft according to the rotation of the anode substrate 130 to increase the intensity of the low frequency current. In the ball receiving space 160, an infrared controller 187 for adjusting the output intensity of the infrared LED 170 is installed to be in close contact with the optical ball 175.

Meanwhile, the cathode of the low-frequency generator generating the low-frequency current of the controller 180 is electrically connected to the cathode pattern 131 of the cathode substrate 130, and the anode of the low-frequency generator is the anode pattern 121 of the anode substrate 120. The low-frequency current is electrically connected to the low-frequency generator and is controlled by the low-frequency controller 183 to be provided by the negative electrode substrate 130 and the positive electrode substrate 120.

In addition, the infrared control unit 185 is connected to the infrared LED 170 to control the infrared LED 170, and the infrared controller 187 adjusts the intensity of the current provided to the infrared LED 170 to adjust the intensity of the infrared light emitted. Adjust.

In addition, the controller 180 controls the selection valve 190 to connect the air inhaler 193 with the connection hose 155 to inhale air through the vacuum suction protrusion 117 or connect the fumigator 195 to the connection hose ( In connection with 155), the steam of the fumigator 195 can be controlled to be discharged through the vacuum adsorption protrusion 117.

The vacuum wavelength device 100 for promoting blood circulation according to an embodiment of the present invention configured as described above is in a state in which the negative pin 135 and the positive pin 123 of the vacuum wavelength device 100 are in contact with a part of the body to be treated. While moving the wavelength body 110, the treatment is carried out in the form of rubbing on the body, and before performing the treatment, a vacuum wavelength device in a state in which a conductive gel containing an electric current and an additive useful for treatment is applied to the body to be treated ( 100) can be performed by rubbing the body.

When power is supplied to the controller 180 by the operation unit of the vacuum wavelength device 100, the controller 180 operates the driving motor 145.

The driving motor 145 rotates the eccentric cam 140, and when the eccentric cam 140 rotates, the cathode substrate 130 supporting the eccentric cam 140 is horizontally eccentric around the eccentric cam 140 When the negative electrode substrate 130 rotates and the negative electrode substrate 130 rotates, the ends of all the negative electrode pins 135 connected to the negative electrode substrate 130 are rotated by the negative electrode substrate 130.

Here, when the negative pin 135 rotates, the ball support part 135b located at the center of the negative electrode pin 135 is rotatably supported in the pin support hole 125 of the positive electrode substrate 120, so that the ball support part ( 135b), both ends of the negative electrode pin 135 rotate in opposite directions to each other to stimulate capillaries in the form of each negative electrode pin 135 rubbing the skin.

At the same time, a low frequency current is generated in the low frequency generator 181 to provide a low frequency current through the anode pattern 121, and the low frequency current transmitted to the body through the anode pin 123 flows through the adjacent cathode pin 135. It stimulates capillaries by low frequency.

Here, the low-frequency current generated by the low-frequency generator 181 is not constantly generated, but is supplied to the body while the intensity of the low-frequency current is varied in the low-frequency control unit installed between the negative electrode substrate 130 and the positive electrode substrate 120 It can improve the effect of stimulating capillaries.

In addition, the low-frequency current is provided to the body by the low-frequency generator 181 and the controller 180 operates the infrared LED 170 through the infrared control unit 185, and the infrared rays generated from the infrared LED 170 are optically It flows into the ball 175 and exits toward the body.

However, since the optical ball 175 is in contact with the eccentric cam 140, it rotates in the ball receiving space 160, and the optical ball 175 rotates in the ball receiving space 160 has different sizes of light exit grooves ( 175a), it is possible to shape the effect of stimulating capillaries by providing infrared rays of various intensities to the body.

Here, when the optical ball 175 rotates on the eccentric cam 140, infrared rays are concentrated on the body by the light exit groove 175a whose position is changed to prevent an image accident, as well as the optical ball 175 The rotation wheel of the infrared controller 187 is closely installed to rotate the rotation wheel while the optical ball 175 rotates to vary the intensity of infrared rays irradiated from the infrared LED 170 to provide the optical ball 175 , Low frequencies of various intensities can be provided to the body.

In addition, the controller 180 controls the selection valve 190 to connect the connecting hose 155 and the fumigator 195 to provide steam from the fumigator 195 to the body. Is provided to the flow path member 150 through the connection hose 155, and the fumigator 195 provided as the flow path member 150 is discharged through the vacuum adsorption protrusion 117 to provide steam to the body.

In addition, the controller 180 controls the selection valve 190 so that the vacuum adsorption protrusion 117 adsorbs the skin and connects the air inhaler 193 and the connection hose 155 to remove foreign substances, and the air inhaler 193 Air is sucked through the vacuum suction protrusion 117 by the suction force of ), and the sucked air may be provided to the air inhaler 193 through the flow path member 150 and the connection hose 155.

Here, the selection valve 190 is controlled to connect the connection hose 155 and the fumigator 195 for a preset time by a timer, and to connect the connection hose 155 and the air inhaler 193 after a preset time. I can.

Therefore, the vacuum wavelength device 100 for promoting blood circulation according to an embodiment of the present invention stimulates capillaries by the wavelength of electricity and light to promote blood circulation, thereby improving diseases caused by uneven blood circulation. have.

In addition, the capillaries are stimulated by the negative pin 135 and the positive pin 123, and at the same time, a low-frequency current flows through the negative pin 135 and the positive pin 123 to improve the stimulation effect of stimulating the capillaries. In addition, the negative electrode pin 135 rotates like a massage and stimulates capillaries to improve blood circulation.

In addition, when the eccentric cam 140 is operated to drive the cathode pin 135, the optical ball 175 rotates and irradiates the body with infrared rays of different intensities. Such as can prevent skin damage.

In addition, when the eccentric cam 140 rotates, the intensity of the low-frequency current is adjusted and provided by the low-frequency controller 183, and the intensity of the infrared ray is changed by the infrared controller 187 by the optical ball 175 to By providing to, it is possible to improve blood circulation by stimulating capillaries according to the provision of low frequencies and infrared rays of various intensities.

In addition, the cathode pin 135 and the optical ball 175 rotate together by the eccentric cam 140, and the low-frequency controller 183 and the infrared controller 187 work together, making it structurally simple and complex electronic control. There is an advantage in that the manufacturing cost can be reduced by minimizing the components.

In the above, the embodiments of the present invention have been described, but the scope of the present invention is not limited thereto, and the embodiments of the present invention are easily changed by those of ordinary skill in the technical field to which the present invention pertains and are recognized as equivalent. It includes all changes and modifications to the extent that it becomes available.

100: vacuum wavelength device for promoting blood circulation 110: wavelength base body
111: upper housing 111a: anode fitting portion
111b: cathode fitting portion 113: handle portion
115: bottom part 116: pin hole
117: vacuum adsorption protrusion 120: anode substrate
121: positive pattern 123: positive pin
130: negative substrate 131: negative electrode pattern
125: pin support hole 135: negative pin
135a: pin head 135b: ball support
140: eccentric cam 145: drive motor
150: flow path member 155: connection hose
160: viewing space 170: infrared LED
175: optical ball 175a: light exit groove
180: controller 181: low frequency generator
183: low frequency controller 185: infrared control unit
187: infrared controller 190: selection valve
193: air inhaler 195: fumigator

Claims (4)

Wavelength base body including a bottom portion formed through a plurality of pin holes,
An anode substrate on which an anode pattern is printed, which is located above the bottom of the wavelength body and electrically connected to the anode of low frequency,
A plurality of positive electrode pins electrically connected to the positive electrode pattern to flow a low-frequency current of the positive electrode and protruding from the pin hole,
A negative electrode substrate on which a negative electrode pattern of a low-frequency current is connected to each other so that the low-frequency current provided to the positive electrode substrate flows through the body and stimulates capillaries, and
A plurality of negative electrode pins that are electrically connected to the negative electrode pattern in the negative substrate to flow a low-frequency current transmitted to the body through the positive electrode pin and protrude through the pin hole,
An eccentric cam for eccentric rotation of the negative electrode substrate on which the negative electrode pin is installed in a horizontal direction so that the negative electrode pin rotates eccentrically and rubs the body and passes a low-frequency current,
A driving motor driving the eccentric cam,
A low frequency controller installed on the negative electrode substrate and having a control shaft for adjusting the intensity of the low frequency current provided to the positive electrode substrate,
A regulator connector connecting the control shaft to the negative electrode substrate so that the control shaft moves by eccentric rotation of the negative electrode substrate to vary the intensity of the low-frequency current and provide it to the body;
A vacuum adsorption protrusion protruding from the bottom of the bottom and inhaling air so that the skin is adsorbed or discharging vapor,
A flow path member installed on an upper surface on which the anode substrate is located in the bottom portion to connect each of the adsorption protrusions to suck in air or discharge steam,
A selection valve selectively connecting an air inhaler for inhaling air from the vacuum adsorption protrusion or for inhaling air to discharge steam and a fume for discharging steam to the flow path member,
A ball accommodation space formed by penetrating the negative electrode substrate, the positive electrode substrate, and the bottom portion so that the eccentric cam is exposed downward, and dividing the penetrating portion;
An infrared LED installed in the ball receiving space to irradiate infrared rays to stimulate capillaries by infrared rays, and
For promoting blood circulation, characterized in that it comprises an optical ball that is in close contact with the eccentric cam in the ball receiving space, rotates according to the rotation of the eccentric cam, collects and diffuses the light of the infrared LED to the body, and provides it to the body. Vacuum Wavelength. The method of claim 1,
The infrared LED is
Including an infrared controller including a rotating wheel for adjusting the intensity of the infrared irradiated from the infrared LED,
The rotary wheel is installed in the ball receiving space so as to be in close contact with the optical ball and rotates together with the rotation of the optical ball to vary and irradiate the intensity of infrared rays irradiated to the body. The method of claim 1,
The negative pin,
A pin head having a convex curved surface with respect to the negative electrode pattern so that electrical connection to the negative electrode pattern is maintained even if the negative electrode pin rotates, and
And a ball support portion rotatably fitted to the anode substrate so that both ends of the cathode pin rotate in opposite directions with respect to the anode substrate. The method of claim 1,
The optical ball
A vacuum wavelength device for promoting blood circulation, characterized in that it comprises light exit grooves having different sizes around the optical ball to diffuse and irradiate infrared rays introduced from the infrared LED in various forms.

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