TWM550741U - Electric energy auxiliary infiltration device and subassembly with electric energy auxiliary infiltration device - Google Patents

Description

Power assisted osmosis device and dispensing assembly with power assisted osmosis device

An osmotic device, in particular an osmotic device with electrical energy assistance, and a dispensing assembly having the electrical energy osmosis device.

Generally speaking, according to the gender, the total surface area of the skin is about 1.6~1.8 square meters, the thickness is about 0.2~0.5 cm, and the weight is about 15% of the total weight of the human body. It is a huge and multi-purpose. The organ, like a protective cover, prevents microorganisms such as harmful substances and bacteria from entering the body, and also slows the loss of water. In addition, the skin provides a sensory receptor for the body, helps the body regulate body temperature, removes some metabolites, and synthesizes Many chemical substances and absorbing substances have many functions; and the structure of the skin 9 is basically composed of three parts of the epidermis 91, the dermis 93 and the subcutaneous tissue 95 as shown in FIG.

Because the skin is the largest organ in the human body and has the function of absorbing substances, many people from various medical and cosmetic perspectives try to use this pipe to deliver certain substances into the body through the skin. The so-called percutaneous absorption.

But in fact, the most important function of the skin is to form a barrier to prevent the loss of water or nutrients in the body, and to block the invasion of harmful substances such as bacteria. The barrier is mainly the stratum corneum 911 of the outermost layer of the epidermis. And sebum secreted by sebaceous glands and sweat secreted by sweat glands, mixed with flaky lipids of keratinocytes, emulsified and fused to form a layer of skin outside the stratum corneum 911 The lipid film 913 is composed of both, so the sebum film 913 and the stratum corneum 911 are the most important obstacles to absorption through the skin; however, under certain environmental conditions, such as high humidity, high temperature and closed environment, the stratum corneum is lowered. The resistance makes the skin easier to absorb the external substances; in addition, since the sebum film is a weakly acidic lipid, the fat-soluble component is more easily absorbed by the skin than the water-soluble component, and the weakly acidic substance is less likely to cause skin discomfort.

Due to the mastery of skin characteristics, the transdermal drug delivery system (TDDS) has become a way for doctors to administer drugs. When drugs enter the skin, they can be divided into local and systemic effects. The former refers to the drug after the skin is absorbed and stays in the skin. Local tissues such as skin, muscles, and joints are effective. These drugs include topical preparations for treating sore creams and skin diseases. As for the penetration of drugs through the skin to achieve systemic efficacy, it is a relatively new technology. Its principle is that the drug enters the skin and is absorbed by the peripheral microvasculature close to the epidermis, and enters the systemic circulatory system. In this way, there are nicotine smoking cessation patches, contraceptive patches, and morphine pain-relieving patches.

In addition to medical use, the skin care mask on the market uses the same principle to seal the local skin, hinder the evaporation of skin moisture, thereby increasing the water content of the skin and increasing the degree of hydration of the skin. In molecular motion (infiltration), it also promotes the absorption of active ingredients to a certain extent. Therefore, some doctors believe that the mask is equivalent to the dermatological package treatment, which can increase the skin's absorption of skin care products.

In addition, for the introduction of certain ionic or charged chemicals into the human body through skin absorption, iontophoresis can be used. The so-called iontophoresis method uses continuous DC current to The principle of repelling electrical properties, while increasing the interaction between ions or charged chemicals and the skin.

At present, there are many types of related products that use iontophoresis technology on the market, but Inductively, the power supply mode can be roughly divided into two types. The first type is the way in which the AC power of the mains is converted into a direct current by using a substation; the second type is a method of applying DC power to the storage device. The power storage device can be further subdivided into two ways: using a rechargeable battery that can be recharged or using a disposable battery.

However, the rapid development of paper battery technology in recent years, due to the extremely low pollution of the materials used, and the simple production process is conducive to low cost, making it very environmentally friendly, more economically competitive, and most importantly because the paper battery is like Lithium-ion batteries, like the characteristics of supercapacitors, provide a long-term and stable power output, combined with their light and thin appearance, thus providing another way for iontophoresis applications, but limited by volume. The amount of energy that can be accumulated is relatively limited.

The electric energy assisted osmosis device disclosed in the present invention uses the basic principle of electric power to change the local ion concentration of the ion solution to achieve the purpose of enhancing the interaction between the ions and the skin; and the electric energy generating unit made by using the paper battery technology The existing iontophoresis device using a substation or a power storage device as a power source on the market is more economical and conforms to the environmental protection trend, and the application of the paper battery can generate electric energy by itself, without the need of external power supply or additional charging characteristics, so that the iontophoresis technology is enabled. The use is more convenient; furthermore, the display is provided in the power-on indicating unit, which can prompt the user to display the current status of the power generating unit, thereby increasing the convenience in use. In addition, the present invention provides a dispensing assembly with a power-assisted osmotic device, which can be carried around by storing the ion solution in isolation, so that the iontophoresis device can be carried around, and can be carried out anytime and anywhere with an appropriate shelf life. Therefore, the device disclosed in the present invention can improve the efficiency of transdermal absorption and reduce the use limit of iontophoresis technology, making it more practical and convenient.

One of the purposes of the present invention is to provide an electric energy assisted osmosis device, which uses the electric energy generated by the electric energy generating unit, uses the basic principle of electric power, changes the local ion concentration of the ion solution, and achieves the purpose of enhancing the interaction between the ions and the skin, and improves the use. effectiveness.

Another object of the present invention is to provide an electric energy assisted osmosis device, which can directly generate electric energy characteristics by using an electric energy generating unit without external power supply or additional charging, thereby increasing the convenience of use.

A further object of the present invention is to provide an electric energy assisted osmosis device which uses a paper battery to form an electric energy generating unit, which is more economical and more environmentally friendly than an ion guiding device using a substation or a power storage device in the market.

Another object of the present invention is to provide a power assisted osmosis device that applies a display of an energization indicating unit to prompt the user of the immediate status of the power generating unit and to increase the convenience of use.

Another object of the present invention is to provide a dispensing assembly with an electric energy assisted osmosis device, which is isolated and stored by an electrochemical solution for generating electrical energy by electrochemical reaction with positive and negative electrodes in an electric energy generating unit, so as to be ion-implanted. The device can be carried around and can be carried out anytime, anywhere, increasing the range of use and having an appropriate shelf life.

An electric energy assisted osmosis device disclosed in the present invention is capable of optimizing the permeability of an ionic solution by the action of electrical energy, wherein the ionic solution is an electrolyte compound ionized into ions, and the electric energy assisted osmotic device comprises: an ion permeable solution; An adsorption film adsorbed on the surface of the object; an electric energy generating unit for generating electric energy and assisting the ionic solution carried by the adsorbing film; and an electric power indicating unit for displaying an instantaneous state of electric energy generated by the electric energy generating unit.

The above-mentioned electric power assisting and osmosis device is combined with a suitable sub-container to constitute a sub-assembly of the electric energy-assisted osmosis device, comprising: at least one sub-container, including a sub-container body, and a sealing unit, The sealing unit further has a partitioning film which can completely separate the space of the packaging container body into two parts: a solid receiving interval and a liquid receiving interval; and at least one set of electric energy assisting osmosis device, comprising: one for carrying the ion solution And an adsorption film adsorbed on the surface of the object; an electric energy generating unit for generating electric energy and assisting the ionic solution carried by the adsorption film to perform osmosis; and an electric power indicating unit for displaying the instantaneous state of electric energy generated by the electric energy generating unit .

The electric energy assisted osmosis device of the present case uses the basic principle of electricity to change the local ion concentration of the ion solution to achieve the purpose of enhancing the interaction between the ions and the skin; and the electric energy generating unit made by using the paper battery technology is more available on the market. The use of a substation or a power storage device as a power source for the iontophoresis device is more economical and environmentally friendly, and the application of the paper battery can generate electric energy by itself, without the need of external power supply or additional charging characteristics, and also enables the use of iontophoresis technology. Further, it is installed in the power-on instruction unit, and can prompt the user to display the current status of the power generation unit, thereby increasing the convenience in use. In addition, the present invention provides a dispensing assembly with a power-assisted osmotic device, which can be carried around by storing the ion solution in isolation, so that the iontophoresis device can be carried around, and can be carried out anytime and anywhere with an appropriate shelf life. Therefore, the device disclosed in the present invention can improve the efficiency of transdermal absorption and reduce the use limit of iontophoresis technology, making it more practical and convenient.

1‧‧‧Packing containers

11‧‧‧Packing container body

13‧‧‧ Sealing unit

131‧‧‧Separate film

15‧‧‧ accommodating space

151‧‧‧Solid storage interval

153‧‧‧Liquid accommodation interval

2, 2'‧‧‧electric energy assisted osmosis device

22, 22’‧‧‧Power Generation Unit

222‧‧‧ positive electrode

224‧‧‧negative electrode

226‧‧‧Isolation

228, 228'‧‧‧ ion solution

24, 24'‧‧‧Adsorption film

26, 26'‧‧‧Power Directing Unit

262‧‧‧ display

264‧‧‧Connected lines

9‧‧‧ skin

91‧‧‧ skin

911‧‧‧ horny layer

913‧‧ ‧ sebum film

93‧‧‧ leather

95‧‧ ‧Subcutaneous organization

Figure 1 is a schematic view of the human skin structure, which briefly describes the human skin associated with the present invention. Figure 2 is a top plan view of the dispensing container in the first preferred embodiment of the present invention; Figure 3 is a front cross-sectional view of the dispensing container of Figure 2; Figure 4 is a power assisted infiltration device of the first preferred embodiment of the present invention; FIG. 5 is a front cross-sectional view showing a portion of the power assisted osmosis device; FIG. 5 is a front cross-sectional view showing a portion of the first preferred embodiment of the present invention, and a partially enlarged view thereof; FIG. 7 is a front cross-sectional view of FIG. 6 and a partially enlarged schematic view thereof; FIG. 8 is a schematic view of the use of FIG. 6 illustrating the ion-assisted osmosis device for iontophoresis when the ion-contained container is disassembled; FIG. 9 is a front view showing the state of use of the power assisted infiltration device of the second preferred embodiment of the present invention.

The above and other technical contents, features, and advantages of the present invention will be apparent from the following detailed description of the embodiments of the present invention. .

The dispensing container 1 in this embodiment is as shown in Figs. 2 and 3, and is divided into a dispensing container body 11 and a sealing unit 13 which can be torn apart from each other for convenience of explanation, and is common to both. The sealing unit 13 further includes a partition film 131 extending into the accommodating space 15, and the sealing unit 13 is further partitioned by the partition film 131 into a solid-state accommodating section below the figure. 151 and the liquid accommodating section 153 above the figure.

The power assisted osmosis device 2 is as shown in FIG. 4, and includes an electric energy generating unit 22, For the adsorption film 24 and the power-instructing unit 26, please refer to FIG. 5 together. In this example, the positive electrode 222 of the electric energy generating unit 22 is located at the uppermost layer, and the negative electrode 224 is located below the negative electrode 224, and a layer of the insulating layer which can completely isolate each other is sandwiched therebetween. 226, and the adsorption film 24 is located under the negative electrode 224 for the user to attach to the skin surface; in addition, the two ends of the display 262 are respectively connected to the positive electrode 222 and the negative electrode 224 via the guiding line 264; Four layers, such as the electrode 222, the negative electrode 224, the isolation layer 226, and the adsorption film 24, are integrated as shown in a partially enlarged schematic view of FIG. 5, and are stored in the solid-state accommodating section 151 of the dispensing container 1, and The ionic solution 228 is stored in the liquid accommodating section 153, and the positive electrode 222 and the negative electrode 224 are not in contact with the ionic solution 228, and no electrochemical reaction occurs, so that the ionic solution 228 has a long shelf life.

In this example, the electric energy generating unit 22 is exemplified as a paper battery structure, the adsorption film 24 is a skin care mask, and the display 262 is at least one light emitting diode (LED). When the electric energy assisting permeation device 2 is to be used, as shown in FIGS. 6 and 7, the dispensing container body 11 is separated from the sealing unit 13, and the separation film 131 is peeled off from the dispensing container body 11 together with the sealing unit 13. Thus, the ion solution 228 comes into contact and infiltrates into the positive electrode 222, the separation layer 226, and the negative electrode 224, and is turned on to generate an electrochemical reaction, and gradually infiltrates into the adsorption film 24.

When the electrical energy gradually increases with the increase of the electrochemical reaction, the effect of ion introduction is generated. At this time, as shown in FIG. 8, the ionic solution 228 carried in the adsorption film 24 is electrically repelled by the same sex, and The negative electrode 224 is electrically driven away from the negative electrode 224; in addition, due to the action of electrical energy, the display 262 is also activated to illuminate, reminding the user that the power assisting osmosis device 2 is in an applicable state, and the electrical energy can be assisted. The adsorption film 24 of the osmotic device 2 is attached to an appropriate position on the skin of the body surface. Due to the aforementioned electrical action, after the ions are pushed to the side close to the skin, a localized ion concentration is increased, thereby increasing the interaction between the ions and the skin.

When the battery is continuously used, the reaction continues to occur, the elements on the electrode that can react are gradually reduced, and the reaction rate is also gradually decreased, so that the electric energy supplied by the battery is gradually weakened, and when the display 262 (LED) is extinguished, the electrochemistry of the electric energy generating unit 22 is indicated. The reaction has been completed and can be easily identified by the user, at which point the power assisted osmosis device 2 is removed.

Of course, as can be easily understood by those skilled in the art, the structure of the power generating unit is not limited to the above embodiment, and the use of other flexible power supply devices is also a simple conversion other than the core technology of the present invention; and the power-on indicating unit 26 The change of the installation position, for example, is installed in the dispensing container body 11, and only the initial state of the electrochemical reaction of the electric energy generating unit 22 is displayed, and the implementation of the core technology of the present invention is not affected.

The above-mentioned encapsulation method is not limited to the present invention. As shown in FIG. 9, the multi-layer structure such as the electric energy generating unit 22' and the energization indicating unit 26' may be separately stored in a dry manner as in the second preferred embodiment of the present invention. In use, the user attaches the above structure to the adsorption film 24' and drops the ion solution 228' by itself, thereby constituting the electric energy assisting permeation device 2' of the present invention.

However, the above is only the preferred embodiment of the present invention, and the scope of the novel implementation cannot be limited thereto. Any simple equivalent changes and modifications made according to the scope of the novel application and the contents of the new specification should be It is still within the scope of this new patent.

2‧‧‧Power assisted osmosis device

22‧‧‧Electric energy generation unit

222‧‧‧ positive electrode

224‧‧‧negative electrode

226‧‧‧Isolation

228‧‧‧Ion solution

24‧‧‧Adsorption film

26‧‧‧Power instruction unit

262‧‧‧ display

264‧‧‧Connected lines

Claims (6)

An electric energy assisted osmosis device for optimizing the permeability of an ionic solution by the action of electrical energy, the ionic solution being an electrolyte compound ionized into ions, the electric energy assisted osmotic device comprising: an ion transportable solution and adsorbed on the surface of the object An adsorption film; an electric energy generating unit for generating electric energy and osmotically assisting an ion solution carried by the adsorbing film; and an electric power indicating unit for displaying an instantaneous state of electric energy generated by the electric energy generating unit. The electric energy assisting osmosis device according to claim 1, wherein the electric energy generating unit further comprises a pair of sheet-shaped positive and negative electrodes, and one of the positive and negative electrodes disposed between the positive and negative electrodes and completely isolating the positive and negative electrodes The isolation layer, and an ionic solution that generates electrical energy due to electrochemical reaction with the aforementioned positive and negative electrodes. The power-assisted osmosis device of claim 1, wherein the power-on indicating unit further comprises a display and a guiding line for conducting the display with the positive and negative electrodes of the power generating unit. A dispensing assembly having a power assisted osmosis device, comprising: at least one dispensing container comprising a dispensing container body, and a sealing unit further having a space for completely separating the contents of the dispensing container body into a solid a partitioning film between the accommodating section and the liquid accommodating section; and at least one set of electric energy assisting osmosis device, comprising: an adsorption film capable of carrying an ion solution and adsorbing on the surface of the object; one for generating electric energy and for assisting Ion solution carried on the adsorption film for permeation And an electric energy generating unit; wherein the adsorbing film and the electric energy generating unit are stored in the solid-state accommodating section of the sub-package container; and an electric-power indicating unit for displaying an instantaneous state of electric energy generated by the electric energy generating unit. The dispensing assembly of the electric energy assisted osmosis device according to claim 4, wherein the electric energy generating unit further comprises a pair of sheet-shaped positive and negative electrodes, and one of the positive and negative electrodes is disposed between the electrodes and can be completely isolated. An isolation layer for the positive and negative electrodes, and an ionic solution that generates electrical energy due to electrochemical reaction with the positive and negative electrodes. The dispensing assembly of the electric energy assisted infiltration device of claim 4, wherein the energization indicating unit further comprises a display and a guiding line for conducting the display and the positive and negative electrodes of the electric energy generating unit.