KR101420575B1 - face rinse and massage apparatus - Google Patents

Abstract

Disclosed is a face rinse and massage device. Disclosed in an embodiment is a face rinse and massage device. The face rinse and massage device comprises a bubble generating pad arranged inside a solution and generating a first bubble inside the solution by receiving air; a washing pad comprising a sound wave generating part arranged inside the solution and converting a first electrical energy applied from the outside into a vibration energy to generate a second bubble inside the solution; and a body for supplying the air and the first electrical energy to the bubble generating pad and the sound wave generating part respectively. The sound wave generating part coverts the first electrical energy into the vibration energy using at least one ultrasonic vibration.

Description

BACKGROUND OF THE INVENTION [0002] Face rinse and massage apparatus [0003]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention generally relates to a rinsing and massaging apparatus, and more particularly, to a rinsing and massaging apparatus that uses air bubbles generated through a bubble generating pad and a sound- To massage the skin to the inside of the skin surface.

Recently, as the social activities of women have increased, interest in appearance has been increasing day by day. It can be said that the attention is focused on the central face part among them. Especially, facial area is more exposed to the outside than other body parts, so various functional cosmetics are widely used for skin elasticity and aging prevention. In addition, many cosmetics are used to make the face look beautiful. However, because of the various cosmetics used to make beautiful skin look good, the skin may be damaged. Skin experts say it is more important to erase than make-up, and it makes a lot of sense in the beginning and the end of facial skin care. Cleansing does not simply wash away the foreign material on your face. What is lacking in the skin is the most important step in skin care that adds and removes unnecessary. Even if you wash your face well, your blood circulation will be smooth and your skin will be alive and you can see effects such as pore contraction, skin relaxation, elasticity recovery, oil and moisture balance.

Therefore, it is necessary to develop a new cleansing device which can completely wash away the foreign matter and pores attached to the skin. An example of a cleansing device using a sound wave generator has been proposed in 'Ultrasonic Bathtub', KR 20-0317614 for registration room, and 'Ultrasonic Cleanser' in Patent Document JP 2003-111688. However, as in the case of the cited invention, the conventional general cleansing method using only ultrasonic vibration has a disadvantage that it can not completely wash away the foreign materials and pores attached to the skin. In this respect, the cited invention differs from the rinsing and massaging apparatus using air bubbles and micro-bubbles, which are presented in this specification.

In one embodiment, the rinsing and massaging device is disclosed. The rinsing and massaging device may include a bubble generating pad disposed inside the solution and generating air bubbles in the solution to generate a first bubble, a first bubble generating pad disposed inside the solution and converting the first electric energy applied from the outside into vibrational energy, A cleansing pad including a sound wave generating unit for generating a second bubble in the solution, and a body for providing the air and the first electric energy to the bubble generating pad and the sound wave generating unit, respectively. The sound wave generator converts the first electric energy into the vibration energy using at least one ultrasonic vibration.

The foregoing provides only a selective concept in a simplified form as to what is described in more detail hereinafter. The present disclosure is not intended to limit the scope of the claims or limit the scope of essential features or essential features of the claims.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a view of a container equipped with a rinsing and massaging device of the present disclosure;
2 is a view of one embodiment of a body applied to the rinsing and massaging device of the present disclosure.
3 is a view showing another embodiment of a cleansing pad applied to the rinsing and massaging apparatus of the present invention.

Hereinafter, embodiments disclosed in this specification will be described in detail with reference to the drawings. Like reference numerals in the drawings denote like elements, unless the context clearly indicates otherwise. The exemplary embodiments described above in the detailed description, the drawings, and the claims are not intended to be limiting, and other embodiments may be utilized, and other variations are possible without departing from the spirit or scope of the disclosed technology. Those skilled in the art will appreciate that the components of the present disclosure, that is, the components generally described herein and illustrated in the figures, may be arranged, arranged, combined, or arranged in a variety of different configurations, all of which are expressly contemplated, As shown in FIG. In the drawings, the width, length, thickness or shape of an element, etc. may be exaggerated in order to clearly illustrate the various layers (or films), regions and shapes.

When a component is referred to as being " deployed "to another component, it may include the case where the component is directly disposed on the other component, as well as the case where additional components are interposed therebetween.

The description of the disclosed technique is merely an example for structural or functional explanation and the scope of the disclosed technology should not be construed as being limited by the embodiments described in the text. That is, the embodiments are to be construed as being variously embodied and having various forms, so that the scope of the rights of the disclosed technology should be understood to include equivalents capable of realizing the technical ideas.

It is to be understood that when an element is referred to as being "connected" to another element, it may be directly connected to the other element, but there may be other elements in between. On the other hand, when an element is referred to as being "directly connected" to another element, it should be understood that there are no other elements in between. On the other hand, other expressions that describe the relationship between components, such as " between " and " between "

It is to be understood that the singular " include " or " have " are to be construed as including the stated feature, number, step, operation, It is to be understood that the combination is intended to specify that it is present and not to preclude the presence or addition of one or more other features, numbers, steps, operations, components, parts or combinations thereof.

In each step, the identification codes (e.g., 110, 120, 130, ...) are used for convenience of explanation and the identification codes do not describe the order of the steps, Unless the specific order is described, it may occur differently from the order specified. That is, steps may occur in the same order as described, may be performed substantially concurrently, or may be performed in reverse order.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the disclosed technology belongs, unless otherwise defined. Terms defined in commonly used dictionaries should be interpreted to be consistent with meaning in the context of the relevant art and can not be construed as having ideal or overly formal meaning unless expressly defined in the present application.

1 is a view of a rinsing and massaging device in accordance with one embodiment. 1 (a) is a view showing a container equipped with the rinsing and massaging apparatus of the present specification. 1 (b) is a view showing one embodiment of a cleansing pad applied to the rinsing and massaging apparatus of the present invention. 2 is a view of one embodiment of a body applied to the rinsing and massaging device of the present disclosure. 3 is a view showing another embodiment of a cleansing pad applied to the rinsing and massaging apparatus of the present invention.

Referring to FIG. 1, the rinsing and massaging apparatus 100 includes a cleansing pad 150 and a main body 130 including a bubble generating pad 110 and a sound wave generating portion 120. In some other embodiments, the rinsing and massaging device 100 may optionally further include a temperature sensor 140. In some other embodiments, the rinsing and massaging device 100 may optionally further include a light emitting portion 160. [ In some other embodiments, the rinsing and massaging device 100 may optionally further include a piezoelectric element 170. [

The bubble generating pad 110 is disposed inside the solution, and generates air bubbles in the solution by receiving air. The solution may be water, for example. As another example, the solution may be water containing a disinfectant, a lotion, and the like. As an example for the understanding, the above-mentioned examples are not limited to the above examples, and all the solutions used for managing the skin can be used. In one example, the bubble generating pad 110 includes at least one bubble outlet for receiving the air to create the first bubble within the solution. Hereinafter, the at least one bubble outlet of the bubble generating pad 110 will be referred to as a first bubble outlet 112. The bubble generating pad 110 may include a nozzle connection part 114 to which the air is supplied. In the drawing, a nozzle connecting portion 114 disposed on a side surface of the bubble generating pad 110 is shown as an example. As long as the air can be supplied to the bubble generating pad 110, the nozzle connection part 114 may be disposed at any position of the bubble generating pad 110. The bubble generation pad 110 may be placed in a washstand receiving the cleansing water for cleansing the user or in a cleansing bowl for receiving the cleansing water. In the drawing, bubble generating pad 110 placed in washstand 180 is shown as an example. The bubble generating pad 110 may be manufactured using various kinds of materials. The material of the bubble generation pad 110 may include at least one selected from, for example, silicon, plastic, a common metal material, and a combination thereof. The bubble generation pad 110 may be, for example, a human face shape. As another example, bubbling pad 110 may be in a circular shape. As an example for the sake of understanding, the bubble generating pad 110 may have various shapes depending on the shape of the container in which the bubble generating pad 110 is placed. The bubble generating pad 110 may have a shape corresponding to the skin shape of the user to which the first bubble generated by the bubble generating pad 110 is applied. The above example is an example for understanding, and there is no limit to the material or the shape of the bubble generating pad 110 as long as the first bubble generated by the bubble generating pad 110 can effectively contact the user's skin.

The first bubble generated by the bubble generating pad 110 may contact the skin of the user contained in the solution to massage the skin. The first bubble outlet 112 of the bubble generating pad 110 may have various sizes or shapes. For example, the first bubble outlet 112 may be in the form of a hole having a diameter of 2 mm or less. In this case, the bubble generating pad 110 receives the air to generate air bubbles as the first bubbles, and the air bubbles can contact the skin of the user contained in the solution. Thus, waste matter on the surface of the skin can be removed or the skin can be massaged. The size of the first bubble may be adjusted by adjusting the size of the first bubble outlet 112. In addition, the generation period of the first bubbles may be adjusted by adjusting the pressure of the air.

The sound wave generator 120 is disposed inside the solution and converts the first electrical energy applied from the outside into vibrational energy to generate a second bubble in the solution. The sound wave generator 120 may include a power transmission unit 122 for receiving the first electrical energy. The sound wave generator 120 receiving the first electrical energy may vibrate. In one embodiment, the sound wave generator 120 may include at least one ultrasonic vibrator (not shown). The ultrasonic vibrator may generate ultrasonic vibrations in the solution using the first electric energy. As the ultrasonic oscillator, at least one oscillator selected from a piezoelectric oscillator, a magnetostrictive oscillator, an electromagnetic induction oscillator, and a combination thereof may be used. For reference, a piezoelectric vibrator refers to a vibrator that generates ultrasonic waves by utilizing a piezoelectric effect of a piezoelectric element. A magnetostrictive vibrator is a vibrator that uses a phenomenon that a magnetic field is distorted when a magnetic field is applied to the ferromagnetic body. The electromagnetic induction type oscillator refers to a vibrator that generates ultrasonic waves using the force received by an electron placed in a magnetic field. The above example is an example for understanding, and there is no limit to the selection of the ultrasonic vibrator as long as the sound wave generator 120 converts the first electric energy into the vibration energy to generate the second bubble.

The sound wave generator 120 converts the first electric energy into the vibration energy using at least one ultrasonic vibration. The second bubbles may be generated by a cavitation phenomenon occurring in the solution by the sound wave generator 120. Cavitation phenomenon refers to a phenomenon in which micro bubbles are generated and extinguished by pressure when ultrasonic energy is propagated in a solution. Large pressure and high temperature may accompany this process. The minute bubbles generated at this time can be used to remove waste materials or foreign substances on the user's skin surface. When the first electric energy applied to the sound wave generator 120 is adjusted, the intensity of the vibration energy or the frequency of the vibration energy can be adjusted. Further, even when an ultrasonic vibrator suitable for the frequency of use is selected, the vibration frequency of the vibration energy can be adjusted. Whereby the second bubble suitable for the skin condition of the user can be generated.

In one embodiment, the sound wave generator 120 may convert the first electric energy into the vibration energy using one ultrasonic vibration. Accordingly, the sound wave generator 120 can generate the second bubbles inside the solution. In another embodiment, the sound wave generator 120 may convert the first electric energy into the vibration energy using a plurality of ultrasonic vibrations having different frequencies. The plurality of ultrasonic vibrations having the different frequencies may occur at a time interval or simultaneously. That is, any one of the plurality of ultrasonic vibrations having different frequencies may occur at a time interval with at least one other ultrasonic vibration among the plurality of ultrasonic vibrations, or may occur at the same time. In addition, a plurality of ultrasonic vibrations having different frequencies may be generated in succession. In addition, the plurality of ultrasonic vibrations having different frequencies may overlap each other for a predetermined time. For example, a user may use ultrasonic vibration of less than 1 MHz at the time of cleansing by adjusting the frequency of ultrasonic vibrations, and remove waste materials and foreign substances on the surface of the skin using minute bubbles generated by the cavitation effect. As another example, the user can remove waste materials and foreign substances in the skin surface by using minute bubbles generated by a cavitation effect by using an ultrasonic wave of 1 MHz or more at the time of massage by adjusting the ultrasonic vibration frequency. As another example, the user can remove waste materials and foreign matter from the skin by a plurality of ultrasonic vibrations having different frequencies occurring at the same time. That is, by using the ultrasonic vibration of the multiple waveforms of the composite waveforms other than the short frequency waves, waste matter and foreign substances in the skin can be removed. In other words, the user can simultaneously remove wastes and foreign substances in the skin surface and skin surface by using ultrasonic waves of less than 1 MHz and ultrasonic waves of more than 1 MHz simultaneously. As another example, a user can remove waste matter and foreign matter from the skin by using ultrasonic vibrations generated in succession. In other words, the user first removes wastes and foreign matter on the surface of the skin using ultrasound of less than 1 MHz. Subsequently, ultrasonic waves of 1 MHz or more can be used to remove waste products and foreign substances in the skin surface. For reference, when the frequency of the ultrasonic wave is 3 MHz, the vibration energy is transmitted by about 1.5 cm on the surface of the skin. The user can adjust the frequency of the ultrasonic vibration of the sound wave generator 120 to generate the second bubble according to the skin condition.

In the figure, a sound wave generating portion 120 disposed on the bubble generating pad 110 is shown as an example. In this case, the bubble generating pad 110 includes a first bubble outlet 112 disposed around the sound wave generator 120 and discharging the first bubble. As another example, unlike the one shown in the drawings, the sound wave generator 120 may include at least one bubble outlet. Hereinafter, the at least one bubble outlet of the sound wave generator 120 will be referred to as a second bubble outlet (not shown). The second bubble outlet may receive the air to generate the first bubble in the solution. The bubble generating pad 110 and the sound wave generating part 120 may be integrally formed. As another example, the bubble generating pad 110 and the sound wave generating part 120 may be spaced apart from each other by a predetermined distance. The role of the first bubble generated through the second bubble outlet acting on the user's skin is substantially the same as the role of the first bubble generated through the first bubble outlet, It will be omitted.

The main body 130 provides the air and the first electrical energy to the bubble generating pad 110 and the sound wave generator 120, respectively. 2, the main body 130 may include a power source 131, an air pump 132, a regulator 133, and a central processing unit 134. In this embodiment, In some other embodiments, the body 130 may further include an adjuster 135. In this case, the main body 130 may further include a display window 136. [ In some other embodiments, the main body 130 may further include a transformer 131a, an on-off switch 131b, a motor 132a, a nozzle 132b, and an ultrasonic signal generator 133a.

The power supply 131 provides electrical energy. The air pump 132 supplies outside air to the bubble generating pad 110. The regulator 133 regulates the electric energy supplied from the power source 131 to apply the first electric energy to the sound wave generator 120. The central processing unit 134 controls the operation of the air pump 132 and the regulator 133. In this case, the central processing unit 134 controls the operation of the air pump 132 and the regulator 133 according to an external input command, or controls the operation of the air pump 132 and the regulator 133 according to a previously input pattern .

The operation of the main body 130 related to the sound wave generator 120 will be described with reference to FIG. 2 as an example. For example, as shown in the figure, the electric energy supplied by the power source 131 may be different from the first electric energy required by the sound wave generator 120. In this case, the electric energy supplied from the power source 131 can be converted in voltage through the transformer 131a. For example, the transformer 131a may convert the electric energy supplied from the power source 131 into electric energy having a predetermined voltage according to an input value previously input into the transformer 131a. In another example, the transformer 131a may convert the electric energy supplied from the power source 131 into electric energy having a predetermined voltage according to an input value pre-inputted to the central processing unit 134. [ According to another example, the transformer 131a may convert the electric energy supplied from the power source 131 into electric energy having a predetermined voltage according to a user's input command through the controller 135. [ In this case, the user can confirm the input command through the display window 136. [ The electric energy whose voltage has been converted via the transformer 131a can be intermittently supplied to the sound wave generator 120 through the on-off switch 131b. That is, the on-off switch 131b can control the electric energy provided to the sound wave generator 120. [ In this case, the operation of the on-off switch 131b can be controlled by the central processing unit 134. [ As another example, the operation of the on-off switch 131b can be controlled by the user. The amount of electric energy converted by the voltage passing through the on-off switch 131b can be regulated by the regulator 133. The current amount adjustment by the regulator 133 may be performed by an input value pre-input to the central processing unit 134. [ Alternatively, it may be performed according to a user's input instruction through the control unit 135. [ In this case, the user can confirm the input command through the display window 136. [ The electric energy whose amount of current is regulated by the regulator 133 is transmitted to the ultrasonic signal generating unit 133a, and the ultrasonic signal generating unit 133a generates the ultrasonic signal. For example, the ultrasonic signal generator 133a may generate an ultrasonic signal according to an input value previously input therein. In another example, the ultrasound signal generator 133a may generate an ultrasound signal in accordance with an input value previously input to the central processing unit 134. [ As another example, the ultrasonic signal generator 133a may generate an ultrasonic signal according to a user's input command through the controller 135. [ In this case, the user can confirm the input command through the display window 136. [ The ultrasonic signal generated by the ultrasonic signal generator 133a may be an ultrasonic signal having a single frequency. Alternatively, the ultrasound signal generated by the ultrasound signal generator 133a may be an ultrasound signal having at least one different frequency. For example, the ultrasonic signals having different frequencies may be simultaneously generated. As another example, the ultrasonic signals having different frequencies may be generated at intervals of time. As another example, the ultrasonic signals having different frequencies may be generated successively. As another example, the ultrasonic signals having different frequencies may be generated by overlapping each other for a predetermined time. The ultrasonic signal generated by the ultrasonic signal generator 133a is transmitted to the ultrasonic wave generator 120 and the ultrasonic wave generator 120 vibrates according to the ultrasonic signal. The operation, function, and the like of the sound wave generator 120 will be omitted for the sake of explanation.

Referring to FIG. 2, the operation of the main body 130 related to the bubble generating pad 110 will be described as an example. For example, as shown in the drawing, the air pump 132 may supply the air to the bubble generating pad 110 by introducing outside air. In this case, the air pump 132 can be operated by receiving rotational power from a motor 132a connected through a shaft (not shown). The motor 132a may be driven using electric energy supplied from the power source 131. [ In this case, the electric energy supplied from the power source 131 can be converted in voltage through the transformer 131a. For example, the transformer 131a may convert the electric energy supplied from the power source 131 into electric energy having a predetermined voltage according to an input value previously input into the transformer 131a. In another example, the transformer 131a may convert the electric energy supplied from the power source 131 into electric energy having a predetermined voltage according to an input value pre-inputted to the central processing unit 134. [ According to another example, the transformer 131a may convert the electric energy supplied from the power source 131 into electric energy having a predetermined voltage according to a user's input command through the controller 135. [ In this case, the user can confirm the input command through the display window 136. [ The air sucked through the suction port of the air pump 132 is transferred to the bubble generating pad 110 connected to the discharge port. In this case, the air sucked through the suction port of the air pump 132 may be compressed and transferred to the bubble generating pad 110. The air pump 132 and the bubble generating pad 110 are connected to the nozzle connecting portion 114 of the bubble generating pad 110 and the nozzle 132b connected to the discharge port of the air pump 132. In other words, And can be connected to each other. The generation period of the first bubble generated by the bubble generation pad 110 can be controlled by adjusting the operation period, the compressive force, and the like of the air pump 132. The operation, function, etc. of the bubble generation pad 110 are omitted for the sake of explanation.

A temperature sensor 140 is disposed inside the solution to measure the temperature of the solution. Various types of temperature sensors can be used as the temperature sensor 140. [ The temperature sensor 140 may be, for example, a temperature sensor using a thermal conductor. The above examples are examples for understanding, and there is no limit to the types of temperature sensors that can be used as long as the temperature of the solution can be measured. The temperature of the solution measured through the temperature sensor 140 may be displayed using a display unit provided in the temperature sensor 140 itself. As another example, the temperature of the solution measured via the temperature sensor 140 may be provided to the central processing unit 134. [ In this case, the central processing unit 134 can display the temperature of the temperature sensor 140 through the display window 136. [ The user can recognize the temperature of the solution displayed through the display window 136 and then proceed to skin massage or the like. For example, when the sound wave generator 120 is used, the temperature of the solution may increase. The user can see the temperature of the solution displayed on the display window 136 or directly displayed on the temperature sensor 140 and can stop using the sound generator 120 until the temperature of the solution falls to an appropriate temperature level . In one embodiment, unlike that shown in the drawings, the rinsing and massaging device 100 may further include a heating element (not shown). For example, the heating element may be spaced apart from the cleansing pad 150 by a predetermined distance. As another example, the heating element may be disposed on the eyelash pad 150. In this case, the heating element may be disposed on the bubble generating pad 110. The heating element may be, for example, a resistance heating element using an electric resistance method. As the resistance heating element, a metal heating element using a metal material such as iron, chrome, nickel, or a non-metallic heating element using a non-metallic material such as ceramic or carbon material may be used. As an example for the sake of understanding, examples related to the type of the heating element may include various types of heating elements as long as the heating element can generate heat. A power source 131 may be used as a power source to be applied to the heating element. The electric energy supplied from the power source 131 may be converted to a voltage via the transformer 131a and applied to the heating element. In addition, the power source applied to the heating element may be controlled by the central processing unit 134. For example, the temperature of the solution measured through the temperature sensor 140 may be transmitted to the central processing unit 134. The central processing unit 134 may increase the temperature of the solution by controlling the power supply to the heating element when the temperature of the solution received from the temperature sensor 140 is lower than the reference temperature. On the other hand, if the temperature of the solution transferred from the temperature sensor 140 is higher than the reference temperature, the central processing unit 134 may control the power supply to the heating element to shut down to lower the temperature of the solution. In addition, the user may directly control the power supplied to the heating element. In the drawing, a temperature sensor 140, which is disposed separately from the cleansing pad 150 as a temperature sensor 140, is shown as an example. As another example, the temperature sensor 140 may be disposed on the eyelash pad 150, as shown in the figure. In this case, the temperature sensor 140 may be disposed on the bubble generating pad 110.

The light emitting unit 160 is disposed in the bubble generating pad 110 or the sound wave generating unit 120 and irradiates light that can treat the skin contained in the solution. That is, the light emitting unit 160 can be used to treat the skin by irradiating the skin with light. As the light source used in the light emitting unit 160, at least one selected from a laser, a fluorescent lamp, a UV lamp, a light emitting diode (LED), and a combination thereof may be used. In the drawing, a case where a light emitting diode is used as the light emitting portion 160 is shown as an example. As another example, unlike the light emitting unit shown in the drawings, a light emitting unit other than a light emitting diode may be used as the light emitting unit 160. For example, the power source 131 may be used as a power source to be applied to the light emitting unit 160. The electric energy supplied from the power source 131 may be converted into a voltage through the transformer 131a and applied to the light emitting unit 160. [

Light therapy has long been used to treat a variety of diseases, and the use of sunlight to treat skin diseases has been used in Egypt, India and China for thousands of years. Phototherapy for the treatment of skin diseases is a phototherapy technology that treats damaged skin through selective regeneration or destruction of skin tissue using the principle that light promotes biochemical reaction in skin using various light sources such as sunlight . The effects of light on skin treatment can be confirmed in various documents such as the Korean Society of Dermatology.

The light emitting unit 160 may include at least one light emitting diode that emits the light to the skin contained in the solution. When a plurality of light emitting diodes are used as the light emitting unit 160, the plurality of light emitting diodes may include at least one light emitting diode that emits light having a different wavelength range. For example, the light emitting diode may irradiate the skin containing the solution with light having a wavelength range of about 400 nm to about 1000 nm. According to related documents such as the Korean Journal of Dermatology, it has been reported that irradiation with light having a wavelength range of about 400 to about 650 nm is effective for improving skin diseases such as acne and warts. It has also been reported that irradiating the skin with light having a wavelength range of about 600 to about 700 nm is effective for healing inflammation. Further, it has been reported that when skin is irradiated with light having a wavelength range of about 650 to about 1000 nm, skin resistance against ultraviolet rays can be increased. In addition, it has been reported that when the skin is irradiated with light having a wavelength range of about 800 to about 1000 nm, scarring prevention effect can be obtained. In addition, it has been reported that when the skin is irradiated with light having a wavelength range of about 850 to about 1000 nm, it is possible to obtain an effect of preventing pigment deposition after the skin laser treatment. The light emitting diode is a semiconductor element that emits light when a voltage is applied in the forward direction. The luminescent color differs depending on the material and material composition of the device used, and can emit light from the ultraviolet region to the visible region and the infrared region. The use of light emitting diodes effectively treats large areas of diseased areas with appropriate light output, as opposed to intensive treatment of high power lasers on localized areas. Since the light source of the light emitting diode emits light of a specific wavelength due to a narrow wavelength bandwidth, harmful ultraviolet rays (UV) and unnecessary infrared rays (IR) are not emitted, so that side effects are small. And has been approved by the US FDA for use in humans in the treatment of visible light and near-infrared light emitting diode light sources. The physical characteristics of the light emitting diode light source are long life, low power consumption, environment friendly, small volume, and easy space utilization. The rinsing and massaging apparatus 100 including the light emitting unit 160 can simultaneously obtain the effect of skin treatment in addition to removal of waste materials, removal of foreign substances, and massage through the bubble generating pad 110 and the sound wave generating unit 120 There are advantages. When light emitting diodes that emit light having different wavelength ranges are used as the light emitting unit 160, various wavelength treatment effects can be provided by adjusting or selecting the wavelength range of each of the light emitting diodes to a predetermined value. In one embodiment, each of the light emitting diodes that emit light in different wavelength ranges may irradiate light to the skin contained in the solution simultaneously or at predetermined time intervals. The predetermined time interval may be, for example, a time interval input by the user. As another example, the predetermined time interval may be a time interval previously input to the central processing unit 134. [ When the time interval is adjusted, at least one of the light emitting diodes may be operated successively after one of the light emitting diodes that emit light of different wavelength ranges operates. Further, when the time interval is adjusted, the operation time of any one of the light emitting diodes and at least one of the light emitting diodes that emit light of different wavelength ranges may overlap with each other. It has been described above that different light treatment effects can be obtained depending on the light wavelength. When using light emitting diodes that emit light in different wavelength ranges, the user can obtain various phototherapy effects. For example, the light emitting portion 160 may include a light emitting diode having a wavelength range of about 400 to about 650 nm, a light emitting diode having a wavelength range of about 600 to about 700 nm, a light emitting diode having a wavelength range of about 650 to about 1000 nm, A light emitting diode having a wavelength range of about 1000 nm to about 1000 nm, a light emitting diode having a wavelength range of about 850 to about 1000 nm, and a combination of at least one of the light emitting diodes. The user can select the light emitting diodes of the light emitting unit 160 having different wavelength ranges according to his or her own selection or input values preliminarily input to the central processing unit 134. [ The light emitting diodes of the light emitting unit 160 may be simultaneously selected or selected at predetermined time intervals. This allows the user to illuminate the skin with light in the wavelength range appropriate for the skin condition. Although the light emitting unit 160 is described as the light emitting unit 160 in the above example, the light emitting unit 160 may be a light emitting diode as well as a laser, a fluorescent lamp, a UV lamp, a light emitting diode (LED) It is obvious that at least one selected from among them can be used.

The piezoelectric element 170 is disposed adjacent to the bubble generating pad 110 or the sound wave generating portion 120 and vibrates by the first bubble or the second bubble to generate second electric energy. The piezoelectric element 170 may be disposed on the sound wave generator 120 to generate the second electric energy by being vibrated by the ultrasonic vibrations generated by the sound wave generator 120. The light emitting unit 160 may emit light by the second electric energy generated by the piezoelectric element 170. The piezoelectric element 170 refers to an electronic component which causes a polarization of electric charge due to mechanical deformation, or conversely, a mechanical deformation due to a change in an electric field. The piezoelectric element 170 can be implemented in various ways. For example, the piezoelectric element 170 may be formed by arranging a piezoelectric material on a structure subjected to repeated mechanical deformation by an external force, and arranging first and second electrodes on one surface and the other surface of the piezoelectric material, respectively . The structure may be, for example, a beam or a cantilever. The piezoelectric material disposed on the structure experiences tension and compression as the structure is deformed. When a periodic external force is applied to the structure, the piezoelectric material experiences repetitive tension and compression. Through repetitive tensioning and compression, the piezoelectric material can generate alternating electrical signals. As an example for the sake of understanding, the above examples are not limited to the above-mentioned examples and the type and type of the piezoelectric element 170 as long as electric signals can be generated using the piezoelectric phenomenon. The AC electric signal generated by the piezoelectric element 170 may be directly supplied to the light emitting unit 160 as the second electric energy. In another example, the AC electric signal generated by the piezoelectric element 170 is converted into a DC electrical signal through at least one diode and at least one capacitor that stores a current output from the at least one diode, As shown in FIG. In Fig. 3, the piezoelectric element 170 disposed in the first bubble outlet 112 is shown as an example. In Fig. 3, a piezoelectric element 170 obtained by using the cantilever 172 as a structure is shown as an example. In other words, the cantilever 172 structure is disposed in the first bubble outlet 112. A piezoelectric material 174 is disposed on the cantilever 172. Electrodes (first electrode, second electrode, not shown) may be disposed on one surface of the piezoelectric material 174 and on the other surface corresponding to the one surface. In this case, the cantilever 172 vibrates in the process of discharging the first bubble 116 through the first bubble outlet 112. Through which the piezoelectric element 170 can generate the alternating electrical signal. As mentioned above, the above examples are for illustrative purposes, and there is no limit to the type and type of the piezoelectric element 170 as long as an electric signal can be generated using the piezoelectric phenomenon.

Referring to FIG. 3, the first bubble 116 discharged from the first bubble outlet 112 rises by buoyancy, and the first bubble 116 lifts the piezoelectric element 170 upward. When the first bubble 116 is pushed out of the piezoelectric element 170, the piezoelectric element 170 returns to its original position by the restoring force. When the first bubble 116 is continuously generated from the first bubble outlet 112, the piezoelectric element 170 is repeatedly raised and restored. In this process, the piezoelectric element 170 generates the AC electric signal. Alternatively, the piezoelectric element 170 may be spaced apart from the first bubble outlet 112 by a predetermined distance, as shown in the drawings. As another example, if the bubble generating pad 110 and the sound wave generator 120 are integrated, the piezoelectric element 170 may be disposed at the second bubble outlet (not shown). Alternatively, the piezoelectric element 170 may be disposed on the sound wave generator 120 to generate the AC electric signal by being vibrated by the ultrasonic vibrations generated by the sound wave generator 120 have. As another example, unlike the drawings, the piezoelectric element 170 may generate an alternating electric signal by the second bubble generated by the sound wave generator 120. In each of these processes, the process of generating the AC electric signal by the piezoelectric element 170 includes a process of generating the AC electric signal from the first bubble 116 discharged from the first bubble outlet 112 by the piezoelectric element 170 The detailed description thereof will be omitted for the convenience of explanation. When the electric energy is supplied to the light emitting portion 160 through the piezoelectric element 170, an external power source is not needed, which simplifies the wiring. In addition, when the light emitting unit 160 is operated by using a separate external power source, it is possible to avoid problems such as a short circuit that may occur when the user forgets to cut off the power after using the rinsing and massager.

Hereinafter, the functions and effects of the rinse and massager device 100 disclosed herein will be described by way of one example. Although it is an example of cleansing, it is obvious that it can be applied to other skin besides cleansing. It should also be noted that the following is an example for illustrating the function and effect of the rinsing and massaging apparatus 100 and is not intended to limit the spirit of the disclosure herein.

The user puts the temperature sensor 150 and the cleansing pad 150 into the cleansing water and supplies power to the body 130 after receiving the cleansing water from the washstand 180 after forming the face on the face during cleansing. In this case, the user may place the heating element on the cleansing water together. The main body 130 receives electric energy from the power source 131 and converts it into an appropriate voltage through the transformer 131a. The user can control the electric energy supplied through the on-off switch 131b. The central processing unit 134 receiving the electric energy senses the temperature of the cleansing water through the temperature sensor 140 in the cleansing water and displays the temperature of the cleansing water on the display window 136. After the user adjusts the temperature of the cleansing water to a desired temperature, the user receives a command through the control unit 135 of the main body 113. When the user inputs a command, the central processing unit 134 transmits the recognized command to the ultrasonic signal generator 133a through the controller 135. [ At this time, the regulator 133 adjusts the current supplied through the transformer 131a to a predetermined value or lower, and sends it to the ultrasonic signal generator 133a. For example, the predetermined value of the current supplied through the regulated transformer 131a through the regulator 133 may be 500 mA or less. In this case, the ultrasonic signal generator 133a generates high-frequency electric vibration by the components mounted therein. The ultrasonic signal generator 133a generates ultrasonic waves of a variable state at a constant or stepwise frequency by recognizing a command selected by the user through the central processing unit 134 in the controller 135, . The sound wave generating unit 120 located outside the upper end of the bubble generating pad 110 may generate a cavitation phenomenon by vibrating at 1 MHz or less per second. At this time, when the user faces the surface of the face formed in the cleansing water, the foreign substances and waste materials on the face surface are separated not only by the surface of the face but also by the waste in the pores. The ultrasonic waves used in the rinsing may be a "short wave" and a "complex wave" of a complex wave. Then, if the user desires ultrasound massage, the control unit of the control unit 135 is adjusted and operated. Then, the central processing unit 134 transmits a command recognized through the control unit 135 to the ultrasonic signal generation unit 133a . The ultrasonic signal generator 133a recognizes the command and generates high-frequency electric vibration by the components installed therein. The ultrasonic signal generator 133a generates ultrasonic waves having a variable frequency or an ultrasonic frequency at a constant frequency, . Then, the sound wave generator 120 located at the upper end of the bubble generating pad 110 emits a high frequency of 1 MHz or more per second, and is transmitted through the surface of the skin, so that the massage effect can be seen. The above operation can be operated differently or connected. When the user selects and operates the regulating unit of the regulating unit 135 after the rinsing and massaging using the ultrasonic wave is finished, the central processing unit 134 receives the transformed and rectified current through the transformer 131a to be regulated The motor 132a is operated and the rotational power of the motor 132a is transmitted to the air pump 132 through the shaft connected to the motor 132a And the air pump 132 is operated. At this time, the air sucked through the suction port of the air pump 132 is compressed and is sent to the nozzle 132b connected to the discharge port and discharged through the bubble generation pad 110 connected to the nozzle 132b, . According to the user's selection, the operation may be performed by rubbing with normal bubbles, exfoliation, ultrasonic wave cavitation, microbubbles to rinse foreign substances in the pores and skin wastes, and massage effects using high frequencies. The above operations may be performed sequentially in a desired order, or only one operation may be used. In this process, the skin treatment effect can be simultaneously obtained by using the light emitted from the light emitting unit 160.

From the foregoing it will be appreciated that various embodiments of the present disclosure have been described for purposes of illustration and that there are many possible variations without departing from the scope and spirit of this disclosure. And that the various embodiments disclosed are not to be construed as limiting the scope of the disclosed subject matter, but true ideas and scope will be set forth in the following claims.

Claims (12)

A bubble generating pad disposed inside the solution and generating air bubbles inside the solution by receiving air;
A cleansing pad disposed within the solution and including a sound wave generator for converting a first electrical energy applied from the outside into vibrational energy to generate a second bubble in the solution; And
And a body for providing the air and the first electrical energy to the bubble generating pad and the sound wave generator,
Wherein the sound wave generator converts the first electric energy into the vibration energy using at least one ultrasonic vibration,
The second bubbles are generated by the cavitation phenomenon occurring in the solution by the sound wave generating unit and are in contact with the skin contained in the solution to remove the waste matter of the skin, The skin is brought into contact with the skin contained in the skin,
The ultrasonic vibrators generate ultrasonic vibrations having different frequencies and the ultrasonic vibrations having different frequencies are generated simultaneously or at predetermined time intervals to generate the second bubbles having different frequency characteristics. And a massage device. delete delete The method according to claim 1,
And a light emitting unit disposed in the bubble generating pad or the sound wave generating unit for emitting light capable of treating the skin contained in the solution. 5. The method of claim 4,
Wherein the light emitting part includes at least one light emitting diode for irradiating the skin with the light contained in the solution, and the light emitting diode emits light having a wavelength range of 400 nm to 1000 nm. 6. The method of claim 5,
Wherein the light emitting unit includes light emitting diodes having different wavelength ranges, and each of the light emitting diodes having different wavelength ranges irradiates light to the skin contained in the solution at the same time or at a predetermined time interval, . A bubble generating pad disposed inside the solution and generating air bubbles inside the solution by receiving air;
A cleansing pad disposed within the solution and including a sound wave generator for converting a first electrical energy applied from the outside into vibrational energy to generate a second bubble in the solution;
A body for providing the air and the first electrical energy to the bubble generating pad and the sound wave generating unit, respectively;
A light emitting portion disposed in the bubble generating pad or the sound wave generating portion, for emitting light capable of treating the skin contained in the solution; And
And a piezoelectric element disposed adjacent to the bubble generating pad or the sound wave generating section and generating a second electric energy by being vibrated by the first bubble or the second bubble,
Wherein the sound wave generator converts the first electric energy into the vibration energy using at least one ultrasonic vibration,
Wherein the light emitting unit emits light by the second electric energy generated by the piezoelectric element. The method according to claim 1,
And a temperature sensor disposed within the solution for measuring the temperature of the solution. The method according to claim 1,
Wherein the sound wave generating portion is disposed on the bubble generating pad, and the bubble generating pad includes at least one bubble outlet disposed around the sound wave generating portion to discharge the first bubble. The method according to claim 1,
Wherein the sound wave generating unit includes at least one bubble outlet and the bubble outlet is provided with the air to generate the first bubble inside the solution so that the bubble generating pad and the sound wave generating unit are integrally formed. 11. The method according to any one of claims 1 to 10,
The body
A power source providing electrical energy;
An air pump for introducing outside air to supply the air to the bubble generating pad;
A regulator for regulating the electrical energy supplied from the power source to apply the first electrical energy to the sound wave generator; And
And a central processing unit for controlling operations of the air pump and the regulator,
Wherein the central processing unit controls the operation of the air pump and the regulator according to an external input command or controls the operation of the air pump and the regulator according to a pattern input in advance. 11. The method according to claim 9 or 10,
The body
A power source providing electrical energy;
An air pump for introducing outside air to supply the air to the bubble generating pad;
A regulator for regulating the electrical energy supplied from the power source to apply the first electrical energy to the sound wave generator; And
And a central processing unit for controlling operations of the air pump and the regulator,
The central processing unit controls the operation of the air pump and the regulator according to an external input command or controls the operation of the air pump and the regulator according to a previously inputted pattern,
Wherein the bubble generating pad includes a nozzle connection portion to which the air supplied by the air pump is supplied, and the sound wave generating portion includes a power transmission portion for receiving the first electric energy supplied by the regulator.

Images