KR101675194B1 - washstand using minute bubble - Google Patents

Abstract

A basin using micro-bubbles is disclosed. In one embodiment, the wash basin using the micro-bubbles includes a container capable of containing a solution, a bubble generator disposed inside the vessel, for generating bubbles inside the solution, and a body for controlling the operation of the bubble generator . The container has at least one opening on a surface in contact with the solution, and the bubble generator generates the bubble inside the solution through the opening. In some other embodiments, the wash basin using the microbubbles may further optionally include an exhaust pipe, a first supply pipe, a second supply pipe, a second heating heat generating portion, and a mixing valve. The discharge pipe is disposed in the container, and can discharge the solution to the container. The first supply pipe is connected to the discharge pipe, and supplies the first solution to the discharge pipe. The second supply pipe is connected to the discharge pipe, and supplies the second solution to the discharge pipe. And the second heating heater is disposed on at least a part of the surface of the second supply pipe to heat the second solution. The mixing valve is connected to the discharge pipe, the first supply pipe, and the second supply pipe, respectively, and regulates a mixing ratio of the first solution and the heated second solution to supply the solution to the discharge pipe. The first solution and the second solution may be supplied from the outside. The second heating heating part includes a second heating element for generating heat and at least a part of the second supply pipes disposed on the surface of the second heating heating part may be disposed inside the vessel. Wherein the mixing ratio of the first solution and the second solution heated by the mixing valve is controlled by the opening direction and the opening amount of the mixing valve by the user, . In this case, the main body senses the opening direction and the opening amount of the mixing valve by the user, and then controls the operation of the second heating heat generating unit so that the solution supplied to the discharge pipe has a predetermined temperature have.

Description

A washstand using minute bubble

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention generally relates to a washing basin using micro-bubbles, and more specifically, it can be used in a narrow space by integrally forming an electric heating element and a bubble generator in a container. The present invention relates to a sink capable of providing hot water as much as possible.

Conventionally, the method of using hot water for cleansing can be roughly divided into two methods. One is a method of using heated hot water stored, and the other is a method of using a hot water heater to instantaneously warm water to provide hot water when necessary. In the case of the former, the boiler must be operated to use the hot water, and operation of the boiler only for the hot water has a disadvantage in terms of energy efficiency. As the latter method of instantaneous hot water, electric heating or gas heating can be used. Electricity heating type water heaters are mainly used in a way that hot water is used after heating the stored water to a desired temperature by flowing into a water storage tank. In this case, it takes a lot of time to heat the water stored in the water storage tank to a desired temperature. In addition, since the hot water remaining in the water tank after the user uses the hot water is left unused, the energy is wasted, which is disadvantageous in terms of energy efficiency. The gas heating method has a disadvantage in that there is a risk of suffocation or fire due to gas leakage in a closed space by heating a supply pipe to which water is supplied through gas firing. Also, in the case of the instantaneous hot water method, the instantaneous water heater is generally disposed below the side wall or the container in the space where the container using the hot water is disposed. In this case, unnecessary space waste is generated in terms of space utilization, and there is a disadvantage in that it is not very good in appearance. It is difficult to completely wash away the foreign materials and pores attached to the skin by simple facial cleansing using hot water. Accordingly, there is a need to develop a technology that can provide hot water without unnecessary waste of space, damage to the aesthetics, and effectively provide foreign substances attached to the skin.

In one embodiment, the wash basin with microbubbles is disclosed. The wash basin using the fine bubbles includes a container capable of containing a solution, a bubble generator disposed inside the container, for generating bubbles inside the solution, and a body for controlling the operation of the bubble generator. The container has at least one opening on a surface in contact with the solution, and the bubble generator generates the bubble inside the solution through the opening. In some other embodiments, the wash basin using the microbubbles may further optionally include an exhaust pipe, a first supply pipe, a second supply pipe, a second heating heat generating portion, and a mixing valve. The discharge pipe is disposed in the container, and can discharge the solution to the container. The first supply pipe is connected to the discharge pipe, and supplies the first solution to the discharge pipe. The second supply pipe is connected to the discharge pipe, and supplies the second solution to the discharge pipe. And the second heating heater is disposed on at least a part of the surface of the second supply pipe to heat the second solution. The mixing valve is connected to the discharge pipe, the first supply pipe, and the second supply pipe, respectively, and regulates a mixing ratio of the first solution and the heated second solution to supply the solution to the discharge pipe. The first solution and the second solution may be supplied from the outside. The second heating heating part includes a second heating element for generating heat and at least a part of the second supply pipes disposed on the surface of the second heating heating part may be disposed inside the vessel. Wherein the mixing ratio of the first solution and the second solution heated by the mixing valve is controlled by the opening direction and the opening amount of the mixing valve by the user, . In this case, the main body senses the opening direction and the opening amount of the mixing valve by the user, and then controls the operation of the second heating heat generating unit so that the solution supplied to the discharge pipe has a predetermined temperature .

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 FIG. 1 is a view showing a washstand using fine bubbles of the present specification; FIG.
2 is a view showing an embodiment of a second supply pipe applied to a washstand using fine bubbles of the present specification.
3 is a view showing an embodiment of a first heating heating part applied to a washstand using microbubbles of the present invention.
FIG. 4 is a view showing one embodiment of a second supply pipe and a first heating heating unit applied to a washstand using fine bubbles of the present invention.
5 is a view showing an air blowing device using an impeller as an external air injector applied to a washstand using fine bubbles of the present specification.

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.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a washstand using fine bubbles of the present specification; FIG. 2 is a view showing an embodiment of a second supply pipe applied to a washstand using fine bubbles of the present specification. 3 is a view showing an embodiment of a first heating heating part applied to a washstand using microbubbles of the present invention. FIG. 4 is a view showing one embodiment of a second supply pipe and a first heating heating unit applied to a washstand using fine bubbles of the present invention. 5 is a view showing an air blowing device using an impeller as an external air injector applied to a washstand using fine bubbles of the present specification. FIG. 5 (a) is a conceptual view of the external air injector, and FIG. 5 (b) is a view showing an example of an impeller. Fig. 5 (a) illustrates the operation of the air injector for introducing and discharging outside air.

Referring to FIG. 1, a basin 100 using micro-bubbles includes a container 110, a bubble generator 120, and a main body 130. In some other embodiments, the wash basin 100 using micro-bubbles may further include a first heating heating unit 140 selectively. In some other embodiments, the wash basin 100 with microbubbles may optionally include a discharge tube 10, a first feed tube 20, a second feed tube 30, a second heating heat generator 150, 160). In some other embodiments, the wash basin 100 with micro-bubbles may optionally further include a first temperature sensor 170. In some other embodiments, the wash basin 100 with micro-bubbles may optionally further comprise a second temperature sensor 180. In some other embodiments, the wash basin 100 with micro-bubbles may optionally further include a thermal insulation 190.

The container 110 may contain the solution 1. The solution (1) may be water, for example. As another example, water containing disinfectant, lotion, etc. may be used as the solution (1). 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. The container 110 may be, for example, a washstand, a bathtub, or the like. As the material of the container 110, various materials such as ceramic, plastic, and metal can be used. There is no limitation on the material of the container 110 as long as it can contain the solution (1).

The bubble generating part 120 is disposed inside the container 110 and generates bubbles inside the solution 1. [ The bubble generator 120 may be inserted into the container 110 and disposed therein. In this case, the container 110 has at least one opening 122 on the surface in contact with the solution 1, and the bubble generator 120 generates the bubble inside the solution 1 through the opening 122 . In other words, the bubbles inside the solution 10 can be generated by supplying the bubbles generated by the bubbler 120 into the solution 1 through the openings 122. The bubble generator 120 may include an external air injector 121 or may be connected to an external air injector 121 disposed outside the container 110 or disposed within the interior of the body 130 have. The operation of the external air injector 121 can be controlled by the main body 130 and the bubble generating unit 120 connected to the external air injector 121 can control the air supplied from the external air injector 121 So that the bubbles can be generated. In this case, the external air supplied from the external air injector 121 can be transferred to the solution 1 through the opening 122 to generate the bubbles. For example, the size of the bubbles can be adjusted by adjusting the size of the opening 122. As another example, the size of the bubbles can be adjusted by adjusting the injection period, the amount of injection, etc. of the external air through the external air injector 121. The control of the injection period, the injection amount, etc. of the external air can be controlled by the main body 130. The external air injector 121 may be, for example, an air pump (not shown), a blower (not shown), or the like. For example, the sink 100 using micro-bubbles may include an air pump (not shown). The air pump may be disposed inside the container 110 together with the bubble generator 120 or may be disposed outside the container 110 or may be disposed inside the main body 130 . In this case, the bubble generator 120 may be connected to the air pump. The operation of the air pump can be controlled by the main body 130. The bubble generator 120 connected to the air pump can generate the bubbles by using external air supplied by the air pump. As another example, the wash basin 100 with fine bubbles may include a blower (not shown), as shown by way of example in FIG. The blowing device may be disposed inside the container 110 together with the bubble generator 120 or may be disposed outside the container 110 or inside the main body 130. In this case, the bubble generator 120 may be connected to the blower. The fan device may include an electric motor 121a and a fan 121b. The fan 121b may be a propeller-type fan formed at the center of a fixing portion (not shown) to which the rotation shaft of the motor 121a is fixed, and a plurality of blades formed laterally from the fixing portion. As another example, the fan 121b may include a hub (not shown) in which the fixing portion to which the rotation shaft of the motor 121a is fixed is formed at a central portion thereof, and a plurality The impeller 121b may include a plurality of blades. In other words, for example, the external air injector 121 may include an electric motor 121a whose operation is controlled by the main body 130 and an impeller 121b which is driven by the electric motor 121a and rotates. In this case, the external air injector 121 can transmit the external air introduced in accordance with the rotation of the impeller 121b to the solution 1 through the opening 122 to generate the bubble in the solution 1 have. The operation of the blowing device can be controlled by the main body 130. In other words, the operation of the electric motor 121a of the picnic apparatus can be controlled by the main body 130. [ The air bubble generating unit 120 connected to the air blowing apparatus can generate the air bubbles using the external air supplied by the air blowing apparatus. In the drawing, an external air injector 121 included in the bubble generator 120 is shown as an example. As another example, unlike the one shown in the drawings, the external air injector 121 may be disposed outside the container 110 or inside the main body 130. In this case, the air discharged from the external air injector 121 may be collected through a pipe (not shown) and transferred to the bubble generator 120.

In another embodiment, the sink 100 using micro-bubbles may include a sound wave generator (not shown). The sound wave generator may be included in the bubble generator 120 and disposed inside the container 110 together with the bubble generator 120. The operation of the sound wave generating unit can be controlled by the main body 130. For example, the sound wave generator may receive electrical energy from the main body 130 and convert it into ultrasonic vibration energy. In this case, bubbles may be generated in the solution (1) in contact with the sound wave generating part by ultrasonic vibration. The bubbles generated by the ultrasonic vibration can be supplied into the solution 1 through the opening 122. The sound wave generator may include, for example, at least one ultrasonic vibrator (not shown) and an ultrasonic vibration plate (not shown). The ultrasonic vibrator is controlled by electric energy supplied from the main body 130 to generate ultrasonic vibration, and the ultrasonic vibration plate transmits the ultrasonic vibration to the solution 1 to generate bubbles. In this case, the sound wave generator may convert the electric energy into the vibration energy using at least one ultrasonic vibration. For example, the sound wave generator may generate a plurality of ultrasonic vibrations having different frequencies. The plurality of ultrasonic vibrations having different frequencies may be generated simultaneously or at predetermined time intervals to generate bubbles having different frequency characteristics. 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, when the user uses the solution (1) contained in the container 110 by adjusting the frequency of the ultrasonic vibration, the user uses ultrasonic waves of less than about 1 MHz and uses microbubbles generated by the cavitation effect, Waste and foreign matter can be removed. As another example, a user can remove waste materials and foreign substances in the surface of the skin by using minute bubbles generated by a cavitation effect by using an ultrasonic wave of about 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 about 1 MHz and ultrasonic waves of about 1 MHz or more 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 skin surface using ultrasound of less than about 1 MHz. Then, by using an ultrasonic wave of about 1 MHz or more, it is possible to remove waste matter and foreign substances in the surface of the skin. For reference, when the frequency of the ultrasonic wave is about 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 generating unit to generate the bubbles corresponding to the skin condition.

In another embodiment, the washstand 100 using fine bubbles may include at least one selected from the air pump, the blower, the sound wave generator, and combinations thereof. As described above, the washstand 100 using fine bubbles may generate bubbles in the solution 10 through them. In this case, the bubbles include bubbles generated by external air supplied from the outside and bubbles generated by ultrasonic vibration.

The main body 130 controls the operation of the bubble generator 120. For example, when external air is supplied to the bubble generator 120 through the air pump or the blower, the main body 130 may control the operations of the air pump or the blower to generate bubbles in the bubble generator 120, The amount of air to be supplied to the fuel cell, or the supply period of the air. As another example, when bubbles are generated in the solution 1 through the sound wave generator, the main body 130 adjusts the electric energy applied to the sound wave generator, thereby controlling the bubble generator 120 including the sound wave generator The amount of bubbles generated in the solution 1 or the supply period can be controlled. The main body 130 may include an adjustment unit (not shown), a display window (not shown), an acoustic system (not shown), and the like. The user can control the operation of the sink 100 using the micro bubbles disclosed in the present specification through the control unit. That is, the user may issue a general command through the control unit so that the wash basin 100 using the micro bubbles disclosed herein is operated or not operated. In addition, the user can confirm the temperature of the solution (1) set by the user and the temperature of the present solution (1) at the time of use through the display window. In addition, the user may access the first heating heating unit 140, the second heating heating unit 150, the mixing valve 160, the first heating heating unit 150, the second heating heating unit 150, The operation state of the temperature sensor 170, the second temperature sensor 180, etc., and the current state. Also, the user can be informed of the temperature of the solution (1) set by the user and the temperature of the present solution (1) at the time of use through the sound system. In addition, the user can access the first heating heating unit 140, the second heating heating unit 150, the mixing valve 160, and the second heating heating unit 150, which are used in the sink 100 using the micro bubbles, 1 temperature sensor 170, the second temperature sensor 180, and the like.

The first heating heating unit 140 is disposed in the vessel 110 and can heat the solution 1 contained in the vessel 110. The first heating heating unit 140 includes a first heating element (not shown) that generates heat, and the first heating element can be controlled through the main body 130. The first heating element may be a resistance heating element using, for example, 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. Further, a linear or planar heating element may be used as the first heating element. As an example for the sake of understanding, examples related to the type of the first heating element may be various kinds of heating elements as long as the first heating element can generate heat. For example, the first heating heating portion 140 may be disposed on the inner surface of the container 110 to be in contact with the solution 1. The first heating heating unit 140 may be controlled by the main body 130 to heat the solution 1. [ The first heating heating part 140 may be disposed on the inner surface of the container 110 so as to directly contact the solution 1, as shown in the figure. In this case, the first heating heating unit 140 can directly transmit heat to the solution 1. [ As another example, the first heating heating portion 140 may be disposed inside the container 110, unlike the one shown in the drawings. In this case, the heat generated by the first heating heater 140 can be transferred to the solution 1 through the vessel 110 to heat the solution 1.

The discharge tube 10 is disposed in the container 110 and can discharge the solution 1 to the container 110. [ The first supply pipe 20 is connected to the discharge pipe 10 and can supply a first solution (not shown) to the discharge pipe 10. The second supply pipe 30 is connected to the discharge pipe 10 and can supply a second solution (not shown) to the discharge pipe 10. The mixing valve 160 is connected to the discharge pipe 10, the first supply pipe 20 and the second supply pipe 30, and controls the mixing ratio of the first solution and the second solution, (1). In other words, the solution 1 discharged into the container 110 through the discharge pipe 10 is a solution in which the first solution and the second solution are mixed at a predetermined ratio by the mixing valve 160. The predetermined mixing ratio of the first solution and the second solution may be adjusted by the operation of the mixing valve 160. [ That is, the user can control the mixing ratio of the first solution and the second solution by adjusting the mixing valve 160. The first solution and the second solution may be supplied from the outside. In one embodiment, the sink 100 utilizing micro-bubbles disclosed herein may further comprise a third supply tube 40. The third supply pipe 40 may supply the first solution and the second solution separately to the first supply pipe 20 and the second supply pipe 30 by receiving the fluid from the outside. In the drawing, a first supply pipe 20, a second supply pipe 30 and a third supply pipe 40 of a separable type connected to each other by using a T-shaped connecting member are shown. As another example, unlike the drawings, the first supply pipe 20 and the second supply pipe 30 may be connected to each other integrally with the third supply pipe 40. Through this, the user can separate the fluid supplied from one supply pipe, heat a part of the fluid, and mix the heated part with the unheated part to obtain the solution (1) having the desired temperature. That is, the sink 100 using the fine bubbles disclosed in the present specification has an advantage that the user can provide the solution 1 at a desired temperature when at least one supply pipe for supplying the fluid exists. (10), a first supply pipe (20), a second supply pipe (30), a third supply pipe (40) and a second supply pipe (40) as long as they can discharge, supply or mix the first solution and the second solution. The material and shape of the mixing valve 160 are not limited.

As the mixing valve 160, a valve having various structures and shapes can be used. As an example, a three-way valve may be used as the mixing valve 160. The three-way valve is configured to supply the first solution and the second solution flowing into the three-way valve in the x: 1-x And may be supplied to the discharge pipe 10 by mixing. In other words, as shown in the figure, the mixing valve 160 may include the valve regulator 161, the first solution inlet 162, and the second solution inlet 163. In this case, the first solution and the second solution supplied through the first supply pipe 20 and the second supply pipe 30 are supplied to the first solution inlet 162 and the second solution inlet 163, respectively, And may be delivered to the mixing valve 160. The mixing valve 160 is connected to the discharge tube 10 through the solution 1 obtained by mixing the first solution and the second solution introduced into the first solution inlet 162 and the second solution inlet 163, . As an example for the sake of understanding, the above example can be used as the mixing valve 160 in various forms or structures as long as the first solution and the second solution can be mixed in addition to the example described above. For example, the mixing ratio of the first solution and the second solution may be adjusted by rotating the valve adjusting part 161 of the mixing valve 160 or moving the valve adjusting part 161 to the right or left. In addition, the mixing valve 160 may block or transfer the amount of the solution 1, which is obtained by mixing the first solution and the second solution, to the discharge pipe 10 according to the user's selection. For example, by moving the valve regulating portion 161 of the mixing valve 160 in the direction perpendicular to the rotating direction for mixing or in the vertical direction vertical to the mixing direction for mixing, (1). The user can adjust the degree of movement of the valve adjusting portion 161 of the mixing valve 160 in the direction perpendicular to the mixing direction for mixing or in the vertical direction perpendicular to the mixing direction for mixing, The amount of the solution 1 to be delivered can be controlled.

The second heating heating part 150 may be disposed on at least a part of the surface of the second supply pipe 30 to heat the second solution. As shown in FIG. 5, the second heating heat generating unit 150 may include a first heater 170 disposed on the surface of the second supply pipe 30 corresponding to a portion from the rear end of the first temperature sensor 170 to the front end of the second solution inflow unit 163. 2 heating heating unit 150 is shown as an example. As another example, the second heating heating portion 150 may be disposed at a portion of the second supply pipe 30, unlike the one shown in the drawings. The second heating unit 150 may include a second heating unit (not shown) for generating heat, and the second heating unit may be controlled through the main unit 130. The second heating element may be a resistance heating element using, for example, 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. Further, a linear or planar heating element may be used as the second heating element. Examples related to the type of the second heating element are, for the sake of understanding, various kinds of heating elements may be used as the second heating element as long as it can generate heat. In this case, at least a part of the second supply pipes 30, on which the second heating heating portion 30 is disposed on the surface, may be disposed inside the container 110. That is, as shown in the drawing, a part of the second supply pipe 30 on which the second heating heating part 150 is disposed may be disposed inside the container 110. The heat provided by the second heating heater 30 may not only heat the second solution but also heat the solution 1 contained in the vessel 110.

The second solution heated by the second heating heating unit 150 may be mixed with the mixing valve 160 and supplied to the container 110. The temperature of the solution (1) supplied to the discharge pipe (10) can be adjusted. In other words, the user can adjust the opening / closing direction of the mixing valve 160, the opening direction and the opening amount. The user can adjust the mixing ratio of the first solution and the heated second solution by the mixing valve 160 by adjusting the opening direction and the opening amount of the mixing valve 160. [ Through this, the user can cause the solution (1) having the desired temperature to be discharged through the discharge pipe (10). The supply of the solution (1) having the predetermined temperature through the discharge pipe (10) can be controlled by the main body (130). In one embodiment, the main body 130 senses the opening direction and the opening amount of the mixing valve 160 of the user, and then controls the operation of the second heating heating unit 150 to be supplied to the discharge pipe 10 So that the solution 1 has a predetermined temperature. A detailed description thereof will be given later.

The first temperature sensor 170 is disposed in the second supply pipe 30 and can measure the temperature of the second solution supplied to the second supply pipe 30 from the outside. For example, the first temperature sensor 170 may be disposed at the front end of the second supply pipe 30. The first temperature sensor 170 can measure the temperature of the second solution before being heated by the second heating heat generating unit 150. The main body 130 receives the temperature of the second solution measured by the first temperature sensor 170 and supplies the solution 1 to the discharge tube 10 to the second heating heater 150 Can be controlled. The main body 130 may include a main body connection part 132 for connecting the mixing valve 160 and the main body 130 to each other and a motion detection part (not shown) connected to the main body connection part 132 have. The operation detecting unit may detect whether the mixing valve 160 is opened or closed by the user through the main body connection unit 132 and the opening direction and the opening amount of the mixing valve 160 by the user. For example, the main body connecting part 132 includes a main body connecting rod, and the mixing valve 160 and the motion sensing part can be connected to each other through the main body connecting rod. In this case, the motion sensing unit may detect whether the mixing valve 160 is opened or closed by the user, the moving direction of the main body connecting rod according to the opening direction of the mixing valve 160, have. For example, movement of the main body connecting rod in accordance with the opening direction of the mixing valve 160 and the opening amount can be performed by a cam method. That is, the center axis (not shown) of the mixing valve 160 can be connected to the cam shaft, and the main connecting rod can be connected to the cam. In this case, rotation of the central axis of the mixing valve 160 by the user causes rotation of the cam, and rotation of the cam may cause movement of the main body connecting rod. Accordingly, the operation sensing unit can sense whether the mixing valve 160 is opened or closed, the opening direction of the mixing valve 160, and the opening amount. As another example, the motion sensing unit may include a variable capacitor (not shown). The variable capacitor is composed of a fixed electrode and a variable electrode, and is an electric element that utilizes a change in capacitance due to a change in the relative area of the electrode plate as the variable electrode rotates. The variable capacitor may be connected to the main body connecting rod. That is, the body connecting rod may be connected to the variable electrode of the variable capacitor. The variable electrode can rotate according to the opening direction of the mixing valve 160 by the user and the adjustment of the opening amount. In this case, the capacitance of the variable capacitor may change. Accordingly, the operation sensing unit can sense whether the mixing valve 160 is opened or closed, the opening direction of the mixing valve 160, and the opening amount.

Then, the main body 130 stores the opening / closing information of the mixing valve 160 received from the operation sensing unit, information on the opening direction of the mixing valve 160 and the opening amount, The temperature of the solution 1 supplied from the discharge pipe 10 according to the opening direction and the opening amount of the mixing valve 160 by the user can be calculated from the database (not shown) set and stored. The main body 130 may inform the user of the temperature of the calculated solution (1). Hereinafter, the temperature of the calculated solution 1 will be referred to as a user set temperature. The user-set temperature may be communicated to the user in a voice or visual manner. In one example, the user-set temperature can be communicated to the user in a visual manner via a display disposed in the body 130. As another example, the user-set temperature may be communicated to the user by voice through an acoustic system disposed in the body 130. Accordingly, the user of the wash basin 100 using the fine bubbles disclosed herein can predict the temperature of the solution 1 discharged to the discharge pipe 10 according to the opening direction and the opening amount of the mixing valve 160, Can be set. The wash basin 100 using the micro bubbles disclosed in the present specification can provide the user with information on the temperature of the solution 1 discharged to the discharge pipe 10 in advance to the user, You can provide them.

The main body 130 compares the temperature of the second solution measured from the first temperature sensor 170 with the user set temperature and controls the temperature of the solution 1 discharged from the discharge pipe 10 to be the user set temperature The operation of the second heating heating unit 150 can be controlled. Accordingly, the wash basin 100 using fine bubbles disclosed in this specification can allow the user 1 to discharge the solution 1 having a predetermined or desired temperature to the discharge pipe 10 stably.

The second temperature sensor 180 is disposed in the container 110 and is capable of measuring the temperature of the solution 1 discharged from the discharge pipe 10 and contained in the container 110. The measured temperature of the solution 1 may be notified to the user in a negative or visual manner. In this case, the main body 130 can compare the measured temperature of the solution 1 from the second temperature sensor 180 with the user set temperature. When the difference between the temperature of the solution 1 and the user set temperature occurs, the main body 130 controls the temperature of the solution 1 discharged from the discharge pipe 10 to the second heating heater 150 Can be controlled. The main body 130 can notify the user of the temperature of the solution 1 measured by the second temperature sensor 180 when the temperature of the solution 1 matches the user set temperature. The notification that the temperature of the solution 1 matches the user set temperature can be performed in a voice or visual manner. The detailed description thereof is substantially the same as the above-mentioned description, and thus will be omitted for convenience of explanation. Then, the main body 130 can stop the operation of the second heating unit 150 when the user closes the mixing valve 160 through the motion sensing unit. The operation of the second heating heating part 150 by the main body 130 may be interrupted immediately after the closing of the mixing valve 160 is sensed or may be performed at a predetermined time interval preset by the user.

The main body 130 can continuously measure the temperature of the solution 1 in the container 110 that the user is using through the second temperature sensor 180. [ Through this, the main body 130 can maintain the temperature of the solution 1 in the vessel 110 at the user set temperature. For example, the main body 130 compares the temperature of the solution 1 contained in the container 110 measured from the second temperature sensor 180 with the user set temperature to determine the temperature of the solution 1 contained in the container 110 The user can set the temperature of the solution 1 to the user set temperature by controlling the operation of the first heating unit 140. [ Through this, the wash basin 100 using the micro-bubbles disclosed in this specification can provide the solution 1 in which the user-set temperature is maintained.

The user set temperature may be, for example, from about 10 캜 to about 60 캜. Water may be used as the solution (1). The effects on the skin according to the water temperature are as follows. Water having a temperature of about 10 < 0 > C to about 15 < 0 > C can provide vasoconstriction and freshness to the skin. Water having a temperature of about 15 ° C to about 21 ° C gives the skin a sense of stability, has a light cleansing effect, and can have a mild exfoliating effect. Water having a temperature of about 21 ° C to about 35 ° C can widen the blood vessels lightly, help blood circulation, provide the cleansing effect to the skin, and can make skin condition easy to exfoliate and have a sense of stability . Water having a temperature of about 35 째 C to about 60 째 C strongly induces vasodilation, has a large cleansing effect, and can produce a skin condition that is well exfoliated. In addition, water having a temperature of about 35 캜 to about 60 캜 promotes the secretion of skin secretions, causing blood vessels to stretch, and to promote blood circulation. Dermatologists say it is more important to erase than make-up, and it is important to start and finish the 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. In one embodiment, the body 130 of the sink 100 using micro-bubbles disclosed herein is configured such that the temperature of the solution 1 measured by the second temperature sensor 180 matches the user- Two or more different voice notifications may be provided depending on the range of the user set temperature. Two or more of the above different voice notifications can be used to "clean", "rinse", "massage", "ready to wash", "ready to rinse", "ready to massage" May be two or more voice announcements selected from the same voice announcement tones. The two or more different voice notifications may be stored in the database of the main body 130 in advance according to the temperature range of the solution 1. In this case, when the user set temperature coincides with the temperature of the solution 1 measured by the second temperature sensor 180, the main body 130 selects the voice notification stored in the database, And can output the voice announcement through the sound system.

The wash basin 100 using fine bubbles disclosed in this specification can provide the solution 1 in which the user-set temperature set by the user is maintained. Further, the sink 100 using the micro-bubbles disclosed in this specification can generate bubbles inside the solution 1 through the bubble generator 120. That is, a user using the washbasin 100 using fine bubbles disclosed in this specification can set the temperature of the solution 1 suitable for cleansing by adjusting the user-set temperature. Then, the user can soak the skin in the solution (1), and the skin of the user contained in the solution (1) can enjoy the above-mentioned effect. In addition, the user may use the bubbles generated in the bubble generator 120 to drink the skin. Accordingly, the sink 100 using the micro-bubbles disclosed in the present specification may provide functions such as cleansing, rinsing, and massage according to the skin condition or purpose of the user.

The heat insulating material 190 may be disposed inside the container 110. The heat insulating material 190 may include at least a part of the second supply pipe 30 disposed on the surface of the second heating heat generating part 150 disposed inside the container 110, The heat generating unit 140, the first heating heat generating unit 140, and a combination thereof. The heat generated from the heated second solution contained in the first heating heat generating unit 140, the second heating heat generating unit 150, and the second supply pipe 30 can be prevented. In other words, by arranging the heat insulating material 190 inside the container 110, the heat of the solution 1 contained in the container 110 can be delayed from being discharged outside the container 110. The heat generated in the heated second solution contained in the first heating heating part 140, the second heating heating part 150 and the second supply pipe 30 is mixed with the solution 1 So that the thermal efficiency can be improved. Various kinds of materials can be used as the insulating material 190. As the material of the heat insulating material 190, for example, styrofoam, heat insulating tanning film, urethane foam, heat insulating sheet, glass fiber and the like can be used. The above example is an example for understanding, and various materials capable of preventing heat loss can be used as the heat insulating material 190 in addition to the above-mentioned examples.

A valve (not shown) may be disposed adjacent to an inlet of the second supply pipe 30 through which the second solution flows into the second supply pipe 30. The valve is controlled by the main body 130. When the closing of the mixing valve 160 is sensed through the motion sensing part, the valve is closed to block the entrance and exit of the second solution through the inlet of the second supply pipe 30. [ Accordingly, it is possible to prevent the heated second solution from flowing backward when the sink 100 using the fine bubbles stops operating or when the operation of the second heating heating unit 150 is stopped. By preventing the heated back-flow of the second solution, the second solution with a certain temperature maintained at the time of use of the sink 100 using fine bubbles by an additional user can be used. This can prevent unnecessary energy waste. As this valve, a solenoid valve can be used as an example. A solenoid valve refers to a valve that controls the flow of fluid through a solenoid valve by moving the plunger using the magnetic force generated by the coil from an external electrical signal. In this case, the electric signal externally applied may be provided by the main body 130 or may be provided by the user according to a previously input pattern or a sensing signal of the motion sensing unit.

Hereinafter, the function and effect of the wash basin 100 using the micro-bubbles disclosed herein will be described with reference to one example. It should be further noted that the following description is an example for illustrating the function and effect of the sink 100 using micro-bubbles, and is not intended to limit the spirit of the present invention disclosed in the following description.

Referring to FIG. 1, a user may control a mixing ratio, a mixing amount, and the like of the first solution and the second solution through a mixing valve 160. In addition, the user can determine whether the washstand 100 operates using minute bubbles through the control unit of the main body 130. When the operation command of the washstand 100 using fine bubbles is input through the control unit of the main body 130, the main body 130 is put in a standby state for operation. Thereafter, when the user moves the mixing valve 160, the main body 130 can recognize the user's command through the motion detection unit connected to the main body connection unit 132. The operation detecting unit may calculate the user set temperature by recognizing the opening amount and the opening amount of the mixing valve 160 by the user and may display it on the display window of the main body 130. In this case, the user can set a desired temperature through the user set temperature displayed on the display window of the main body 130. Then, the main body 130 senses the temperature of the second solution flowing into the second supply pipe 30 through the first temperature sensor 170, calculates the temperature difference between the user-set temperature and the second solution And the second solution may be heated by applying electrical energy to the second heating heater 150. The main body 130 can set the temperature of the solution 1 contained in the container 110 to the user set temperature. In this case, the main body 130 can measure the temperature of the solution 1 contained in the container 110 through the second temperature sensor 180. The temperature of solution 1 contained in the measured container 110 may be communicated to the user in a voice or visual manner. Also, the temperature of the solution 1 contained in the measured container 110 can be compared with the user set temperature. In this case, when the temperature of the solution (1) is lower than the user-set temperature, the main body (130) controls the second heating unit (150) to make the temperature of the solution (1) have. Alternatively, when the temperature of the solution 1 is lower than the user-set temperature, the main body 130 may control the first heating heating unit 140 so that the temperature of the solution 1 becomes the user- have. In this case, the main body 130 continuously measures the temperature of the solution 1 through the second temperature center 180 and controls the first heating heater 140 so that the temperature of the solution 1 is maintained at the user- Can be controlled. That is, when the temperature of the solution 1 is higher than the user set temperature, the main body 130 stops the operation of the first heating heating unit 140, and when the temperature of the solution 1 is lower than the user set temperature The temperature of the solution (1) may be maintained at the user set temperature through the operation of the first heating heater (140). The first heating heat generating unit 140 and the second heating heat generating unit 150 may be surrounded by a thermal insulating material 190 having a heat insulating function to prevent heat loss and improve thermal efficiency. The user can immerse the skin in the solution (1) maintained at the user-set temperature, and the skin of the user contained in the solution (1) can enjoy the above-mentioned effect. In addition, the user may use the bubbles generated in the bubble generator 120 to drink the skin. The operation of the bubble generator 120 may be controlled by the main body 130 according to the user's command or a previously inputted pattern.

Accordingly, the sink 100 using the micro-bubbles disclosed in the present specification may provide functions such as cleansing, rinsing, and massage according to the skin condition or purpose of the user. When the use of the sink 100 using the micro-bubbles of the user is terminated, the user can issue an operation stop command to the adjustment unit of the main body 130 to terminate the use of the sink 100 using micro-bubbles. In this case, the electric energy applied to the first heating heating unit 140 and the second heating heating unit 150 is blocked by the main body 130. In addition, the operation of the bubble generator 120 can also be blocked by the main body 130. As another example, the user may not issue an operation stop command to the control unit of the main body 130 while completing the use of the washstand 100 using micro-bubbles. At this time, the main body 130 can recognize the closing action of the mixing valve 160 by the user through the operation detecting part connected to the main body connecting part 132. In this case, the main body 130 may block the electric energy applied to the first heating heating unit 140 and the second heating heating unit 150 after a predetermined time has elapsed. Also, the main body 130 may block the operation of the bubble generator 120 after a predetermined time has elapsed. As a result, the wash basin 100 using micro-bubbles disclosed in this specification can provide a safe washing machine that effectively provides hot water and air bubbles but does not have the danger of a topic. In addition, by disposing the first heating heating unit 140 and the second heating heating unit 150, which are heating elements for heating, in the container 110 and the second supply pipe 30, unnecessary space waste, . In addition, by preventing the backflow of the second solution heated by using the valve disposed at the inlet of the second supply pipe 30, it is possible to prevent the backflow of the second solution when the temperature of the washbasin 100 is maintained The second solution may be used. This can prevent unnecessary energy waste.

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 (15)

A container capable of containing a solution;
A bubble generator disposed inside the vessel, the bubble generator generating bubbles inside the solution;
A body for controlling an operation of the bubble generator;
A drain disposed in the vessel and capable of draining the solution into the vessel;
A first supply pipe connected to the discharge pipe and supplying the first solution to the discharge pipe;
A second supply pipe connected to the discharge pipe and supplying a second solution to the discharge pipe;
A third supply pipe for supplying the first solution and the second solution separately from the first supply pipe and the second supply pipe by supplying the fluid from the outside;
A second heating unit disposed on at least a part of the surface of the second supply pipe to heat the second solution; And
And a mixing valve connected to the discharge pipe, the first supply pipe and the second supply pipe, respectively, for controlling the mixing ratio of the first solution and the heated second solution to supply the solution to the discharge pipe,
Wherein the container has at least one opening on a surface in contact with the solution, and the bubble generator generates the bubble inside the solution through the opening,
Wherein at least a part of the second supply pipe arranged on the surface of the second heating heating part is disposed inside the container, the second heating heating part includes a second heating element for generating heat,
Whether the mixing valve is open or closed is controlled by a user,
Wherein the mixing ratio of the first solution and the heated second solution by the mixing valve is controlled by the opening direction and the opening amount of the mixing valve by the user,
Wherein the main body senses the opening direction and the opening amount of the mixing valve by the user and controls the operation of the second heating heat generating unit so that the solution supplied to the discharge pipe has a predetermined temperature,
Wherein the fluid supplied to the third supply pipe as one supply pipe from the outside is separated into the first solution and the second solution and the second solution which is a part of the fluid is heated through the second heating heating unit, Wherein the first solution is a remaining part of the fluid and is mixed through the mixing valve. The method according to claim 1,
Further comprising: a first heating heating unit disposed in the vessel for heating the solution contained in the vessel,
Wherein the first heating heating part includes a first heating element for generating heat, and the first heating element is controlled through the main body. A container capable of containing a solution;
A bubble generator disposed inside the vessel, the bubble generator generating bubbles inside the solution;
A body for controlling an operation of the bubble generator;
A drain disposed in the vessel and capable of draining the solution into the vessel;
A first supply pipe connected to the discharge pipe and supplying the first solution to the discharge pipe;
A second supply pipe connected to the discharge pipe and supplying a second solution to the discharge pipe;
A first temperature sensor disposed in the second supply pipe and measuring a temperature of the second solution supplied from the outside to the second supply pipe;
A second heating unit disposed on at least a part of the surface of the second supply pipe to heat the second solution; And
And a mixing valve connected to the discharge pipe, the first supply pipe and the second supply pipe, respectively, for controlling the mixing ratio of the first solution and the heated second solution to supply the solution to the discharge pipe,
Wherein the container has at least one opening on a surface in contact with the solution, and the bubble generator generates the bubble inside the solution through the opening,
Wherein the first solution and the second solution are supplied from the outside,
Wherein at least a part of the second supply pipe arranged on the surface of the second heating heating part is disposed inside the container, the second heating heating part includes a second heating element for generating heat,
Whether the mixing valve is open or closed is controlled by a user,
Wherein the mixing ratio of the first solution and the heated second solution by the mixing valve is controlled by the opening direction and the opening amount of the mixing valve by the user,
Wherein the main body controls the operation of the second heating heating unit after sensing the opening direction and the opening amount of the mixing valve by the user so that the solution supplied to the discharge pipe has a predetermined temperature,
Wherein the main body includes a main body connection portion connecting the mixing valve and the main body, and a motion detection portion connected to the main body connection portion,
Wherein the operation sensing unit senses whether the mixing valve is opened or closed by the user through the main body connection unit, the opening direction and the opening amount of the mixing valve by the user,
Wherein the main body is configured to receive information on the opening / closing amount of the mixing valve from information on whether the opening / closing of the mixing valve is received from the operation detecting unit, the opening direction of the mixing valve, Calculating a temperature of the solution supplied from the discharge pipe according to the opening direction and the opening amount of the mixing valve and notifying the user of the calculated temperature of the solution,
The main body compares the temperature of the second solution measured from the first temperature sensor with the user set temperature and controls the operation of the second heating unit so that the temperature of the solution discharged from the discharge pipe becomes the user set temperature Control,
Wherein the main body connecting part includes a main body connecting rod, the mixing valve and the motion sensing part are connected to each other through the main body connecting rod,
Wherein the operation sensing unit senses whether the mixing valve is open or closed by the user, the moving direction of the main body connecting rod in accordance with the opening direction of the mixing valve, And a minute bubble for sensing the opening direction and the opening amount of the mixing valve. 4. The method according to any one of claims 1 to 3,
Wherein the bubble generating unit includes an external air injector connected to the container to supply external air to the container so that the external air is transferred to the solution through the opening to generate the bubbles in the solution,
Wherein the external air injector is controlled by the main body. 5. The method of claim 4,
The external air injector
An electric motor whose operation is controlled by the main body; And
And an impeller which is driven by the electric motor and rotates,
Wherein the external air injector transfers the external air introduced in accordance with the rotation of the impeller to the solution through the opening to generate the air bubbles in the solution. delete 5. The method of claim 4,
The bubble generator may further include a sound wave generator for converting electrical energy applied from the main body into vibrational energy to generate additional bubbles in the solution,
The sound wave generator
At least one ultrasonic vibrator controlled through the body to generate ultrasonic vibration; And
And an ultrasonic diaphragm connected to the ultrasonic vibrator and transmitting the ultrasonic vibrations generated by the ultrasonic vibrator to the solution,
Wherein the external air injector and the sound wave generator are controlled by the main body to operate simultaneously or at predetermined time intervals,
Wherein the sound wave generator converts the electric energy into the vibration energy using at least one ultrasonic vibration. delete The method of claim 3,
Further comprising a second temperature sensor disposed in the container and measuring the temperature of the solution discharged from the discharge pipe and contained in the container,
The main body compares the temperature of the solution measured from the second temperature sensor with the user set temperature and controls the operation of the second heating unit so that the temperature of the solution discharged from the discharge pipe becomes the user set temperature Sink with fine bubbles. 10. The method of claim 9,
Wherein the main body notifies the user when the temperature of the solution measured by the second temperature sensor coincides with the user set temperature, and when the closing of the mixing valve by the user is sensed through the motion sensing unit, 2 Washing basin with micro-bubbles that stops the operation of the heating unit. 11. The method of claim 10,
Further comprising: a valve disposed adjacent to an inlet of the second supply pipe through which the second solution flows into the second supply pipe, hereinafter referred to as a second supply pipe inlet port,
Wherein the valve is controlled by the main body and is closed when the closing of the mixing valve is sensed through the motion sensing unit to block entry and exit of the second solution through the second supply pipe inlet, A basin using micro-bubbles that prevents the second solution from flowing backward. 11. The method of claim 10,
Further comprising: a first heating heating unit disposed in the vessel for heating the solution contained in the vessel,
Wherein the first heating heating part includes a first heating element that generates heat,
The main body compares the temperature of the solution contained in the container measured by the second temperature sensor with the user set temperature and controls the operation of the first heating heating part so that the temperature of the solution contained in the container becomes the user set temperature Sink with micro bubbles to control. 13. The method of claim 12,
And a heat insulating material disposed inside the container,
The heat insulating material may include at least a portion of the second supply heat pipe disposed on the surface of the second heating heat generating portion disposed inside the container, the second heating heat generating portion disposed inside the container, the first heating heat generating portion, And at least one selected from a combination of these. delete 14. The method according to any one of claims 9 to 13,
Wherein the user set temperature is in the range of 10 ° C to 60 ° C and the body is different from the user set temperature when the temperature of the solution measured by the second temperature sensor matches the user set temperature Sink with micro-bubbles to provide more than one voice notification.

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