SELF-HEATING THERMAL-INSULATION FILM AND FACE MASK AND EYE MASK MANUFACTURED THEREFROM

Abstract

Disclosed is a self-heating thermal-insulation multilayer film comprising a structure of at least three layers, which from outside to inside are respectively: an outer layer (1) formed of an air permeable material; a heat-generating layer (2) loaded with heat-generating composition (21) that generates heat on contact with air, at least an upper sealing surface of the heat-generating layer that is in contact with the outer layer being formed of an air permeable material; and an thermal-insulation layer (3) formed of a material having waterproof and thermal-insulation properties. The present self-heating thermal-insulation film is structurally simple, is not constrained by environmental resources, does not require energy supply from an external energy source, is safe and stable, uniformly generates heat, and can effectively prolong heating time and reduce peak heating temperature. The present self-heating thermal-insulation film can be manufactured into a three-dimensional face mask, a face mask, or an eye mask.

Claims

1. A self-heating thermal-insulation film, comprising a structure of at least three layers, which, from outside to inside, are respectively: an outer layer formed of an air permeable material; a heat-generating layer loaded with heat-generating composition that generates heat on contact with air, at least an upper sealing surface of the heat-generating layer that is in contact with the outer layer being formed of an air permeable material; and an thermal-insulation layer formed of a material having waterproof and thermal-insulation properties; wherein the thermal-insulation layer is a metal plating film made of metal and polyethylene terephthalate, oriented polypropylene, nylon, polyethylene or cast polypropylene film.

2. The self-heating thermal-insulation film according to claim 1, wherein the thermal-insulation layer is a metallized polyethylene terephthalate film made of polyethylene terephthalate film and metal.

3. The self-heating thermal-insulation film according to claim 2, wherein the metal used for the metalized polyethylene terephthalate film is aluminum, nickel, chromium or a mixture thereof.

4. The self-heating thermal-insulation film according to claim 1, wherein the thermal-insulation layer is provided with griddings, and the heat-generating composition is evenly distributed in the griddings.

5. The self-heating thermal-insulation film according to claim 4, wherein the griddings are formed by thermal bonding of the upper sealing surface of the heat-generating layer in contact with the outer layer and a lower sealing surface of heat-generating layer in contact with the thermal-insulation layer.

6. The self-heating thermal-insulation film according to claim 1, wherein the outer layer is made of nonwoven or woven fabric of natural or synthetic fiber.

7. The self-heating thermal-insulation film according to claim 1, wherein the self-heating thermal-insulation film is loaded in a sealed package before using.

8. The self-heating thermal-insulation film according to claim 1, wherein the heat-generating composition in the heat-generating layer comprises an oxidizable metal, active carbon, an inorganic metal salt, water, a polymer moisturizer, and an absorbent.

9. The self-heating thermal-insulation film according to claim 1, wherein the film is ergonomically designed in shape to be applied to various body parts.

10. The self-heating thermal-insulation film according to claim 9, wherein there is provided a layer of water-soluble hydrogel on the surface of the thermal-insulation layer that is in contact with the skin, the layer of soluble hydrogel being used for adhering the film to the skin.

11. The self-heating thermal-insulation film according to claim 10, wherein there is provided an active ingredient of a topically-applied health care product, a topically-applied medicine or a skincare product in the layer of water-soluble hydrogel.

12. (canceled)

13. The self-heating thermal-insulation film according to claim 9, wherein the heat-generating layer of the film maintains a heating temperature at 38° C. to 55° C., and the heating time lasts 10 to 25 minutes.

14. The self-heating thermal-insulation film according to claim 13, wherein the heat-generating composition in the heat-generating layer comprises 30 to 50 parts by weight medical iron powder, 10 to 15 parts by weight active carbon, 1 to 5 parts by weight a metal salt, 3 to 13 parts by weight vermiculite, 1 to 5 parts by weight a water-absorbent resin, and 1 to 5 parts by weight water.

15. The self-heating thermal-insulation film according to claim 13, wherein the heat-generating composition in the heat-generating layer comprises 30 to 50 parts by weight medical iron powder, 10 to 15 parts by weight active carbon, 1 to 5 parts by weight a metal salt, 3 to 13 parts by weight vermiculite, 1 to 5 parts by weight a water-absorbent resin, 1 to 5 parts by weight water, and 1 to 5 parts by weight diatomite.

16. The self-heating thermal-insulation film according to claim 14, wherein the film is 2-8 mm thick.

17. A method of using the self-heating thermal-insulation film according to claim 9, wherein the film is used in combination with a topically-applied medicine, a health care product, a skincare product or a traditional nourishing face mask.

18. (canceled)

19. A self-heating thermal-insulation three-dimensional face mask which has a facial concave-convex shape formed by joining two sheets together, wherein the face portion of the three-dimensional face mask is made of the self-heating thermal-insulation film according to claim 9.

20-32. (canceled)

33. The self-heating thermal-insulation three-dimensional face mask according to claim 19, wherein the three-dimensional face mask comprises a left side sheet and a right side sheet respectively matching the left area of the face and the right area of the face, front edge portions of the left side sheet and the right side sheet are provided with an adhesive material, the left side sheet and the right side sheet are thereby adhered together by the adhesive material along a median line of the face to form a facial concave-convex shape.

34. The self-heating thermal-insulation three-dimensional face mask according to claim 33, wherein either of the front edge portions of the left side sheet and the right side sheet has a protrusion projecting outwards from above down and matching the shape of the left area or right area of the external nose, a mouth portion which is a notch matching the mouth is provided below the protrusion, a portion of the front edge portion below the notch has an arc shape with a certain radian and extends downwards to the bottom the face mask; except the notch matching the mouth, either of the front edge portions of the left side sheet and the right side sheet is provided with an adhesive material, and the left side sheet and the right side sheet are thereby adhered together by the adhesive material.

35. The self-heating thermal-insulation three-dimensional face mask according to claim 34, wherein a glabella portion of either of the front edge portions of the left side sheet and the right side sheet which faces a space between the user's eyebrows, just above the protrusion, is formed as an arc which is slightly concaved inwards.

36. The self-heating thermal-insulation three-dimensional face mask according to claim 34, wherein an eye-and-glabella portion of either of the front edge portions of the left side sheet and the right side sheet which faces the user's eyes and glabella, just above the protrusion, is formed as a notch which is concaved inwards; except the eye-and-glabella portion and the mouth portion, either of the front edge portions of the left side sheet and the right side sheet are provided with an adhesive material, and the left side sheet and the right side sheet are thereby adhered together by the adhesive material.

37. The self-heating thermal-insulation three-dimensional face mask according to claim 33, there is a fixing strap provided on either of the rear edge portions of the left side sheet and the right side sheet, and there is a velcro provided at the end of the fixing strap.

38. A method of using the self-heating thermal-insulation three-dimensional face mask according to claim 33, wherein the three-dimensional face mask is used in combination with a topically-applied medicine, a health care product, a skincare product or a traditional nourishing face mask.

39. A self-heating thermal-insulation face mask, wherein the face portion of the face mask is made of the self-heating thermal-insulation film according to claim 9.

40-52. (canceled)

53. The self-heating thermal-insulation face mask according to claim 39, wherein the face mask has notches matching the user's nose and mouth, respectively.

54. The self-heating thermal-insulation face mask according to claim 53, wherein the face mask also has notches matching the user's eyes.

55. The self-heating thermal-insulation face mask according to claim 54, wherein there is a fixing strap provided on either side of the face mask, and there is a velcro provided at the end of the fixing strap.

56. A method of using the self-heating thermal-insulation face mask according to claim 39, wherein the face mask is used in combination with a topically-applied medicine, a health care product, a skincare product or a traditional nourishing face mask.

57. A self-heating thermal-insulation eye mask, wherein the eye portion of the eye mask is made of the self-heating thermal-insulation film according to claim 9.

58-70. (canceled)

71. The self-heating thermal-insulation eye mask according to claim 57, wherein the eye mask comprises hanging parts which have ears slits and can hang on the user's ears.

72. The self-heating thermal-insulation eye mask according to claim 71, wherein a slit is vertically cut along a lower half of a central vertical axis of the eye mask.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0084] FIG. 1 is a schematic view of a self-heating thermal-insulation multilayer film according to one embodiment of the present invention.

[0085] FIG. 2 is a schematic view showing the self-heating thermal-insulation multilayer film of FIG. 1, with the film being in use.

[0086] FIG. 3 is a schematic view of a self-heating thermal-insulation multilayer film according to another embodiment of the present invention.

[0087] FIG. 4 is a schematic view of a face mask made from the self-heating thermal-insulation multilayer film according to the present invention.

[0088] FIG. 5 is a schematic showing the structure of the self-heating thermal-insulation three-dimensional face mask according to Example 4 of the present invention.

[0089] FIG. 6 is a schematic view showing a face mask consisting of the right side sheet and left side sheet of FIG. 5 when the right side sheet and left side sheet are adhered together.

[0090] FIG. 7 is a schematic view showing a concave-convex shape of the three-dimensional face mask of FIG. 5 when the three-dimensional face mask is attached to the user's face.

[0091] FIG. 8 shows a sectional view of a face portion of the three-dimensional face mask of FIG. 5, with the face portion having a structure of three layers.

[0092] FIG. 9 is a schematic view showing the structure of a self-heating thermal-insulation three-dimensional face mask according to Example 5 of the present invention.

[0093] FIG. 10 is a schematic view showing a face mask consisting of the right side sheet and left side sheet of FIG. 9 when the right side sheet and left side sheet are adhered together.

[0094] FIG. 11 is a schematic view showing a concave-convex shape of the three-dimensional face mask of FIG. 9 when the three-dimensional face mask is attached to the user's face.

[0095] FIG. 12 is a schematic view of a self-heating thermal-insulation face mask according to Example 8 of the present invention.

[0096] FIG. 13 shows a sectional view of a face portion of the face mask of FIG. 12, with the face portion having a structure of three layers.

[0097] FIG. 14 is a schematic view of a self-heating thermal-insulation face mask according to Example 9 of the present invention.

[0098] FIG. 15 is a schematic view of a self-heating thermal-insulation eye mask according to Example 12 of the present invention.

[0099] FIG. 16 shows a sectional view of an eye portion of the eye mask of FIG. 15, with the eye portion having a structure of three layers.

[0100] FIG. 17 is a schematic view of a self-heating thermal-insulation eye mask according to Example 13 of the present invention.

DETAILED DESCRIPTION OF ILLUSTRATED EMBODIMENTS

[0101] The present invention will be described in detail in connection with the following preferred embodiments, and it will be appreciated that such embodiments are merely exemplary, the invention is not to be limited to the disclosed embodiments, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope thereof.

Example 1

[0102] As shown in FIG. 1, the self-heating thermal-insulation multilayer film comprises a structure of three layers: an outer layer 1, a heat-generating layer 2, and an thermal-insulation layer 3, and the heat-generating composition in powder or granule form is loaded in heat-generating layer 2. FIG. 2 is a schematic view showing the state during use of the self-heating thermal-insulation multilayer film shown in FIG. 1, the thermal-insulation layer 3 is in contact with the skin 4.

[0103] In this example, the above three layers of the self-heating thermal-insulation multilayer film are adhered together by, for example, the adhesive or thermal bonding, so they are applied to the skin as a whole. In some cases, the thermal-insulation layer is not adhered together with the outer layer and heat-generating layer. That is, in use, the thermal-insulation layer is first applied to the skin, then the outer layer and heat-generating layer are applied, and the similar self-heating thermal-insulation effect can also be obtained.

[0104] In this example, the outer layer 1 is made of nonwoven, and the upper sealing surface and lower sealing surface of the heat-generating layer 2 are made of air permeable film. In practice, as long as the outer layer and the upper sealing surface of the heat-generating layer (with or without the lower sealing surface) are made of air permeable material, there is no specific limitation to the air permeable material, all materials which can make air permeate into the heat-generating composition are suitable. The air permeability of the air permeable material can be controlled by adjusting the size and number of the aperture on the air-permeable film, which vary depending upon the heat-generating composition and the amount thereof, and the desired heating temperature. There is no limitation to the thickness of the air permeable material, as long as it has no affection on the desired effect. Thinner air permeable material is better while achieving the air-permeable property and supporting function. The thermal-insulation layer 3 is formed by a PET aluminum film made of PET and silvery aluminum. Aluminum has a lower melting point, so it can be easily changed from solid to gas by heating under vacuum. Compared with other film, PET film has better heat resistance and compatibility with aluminum. PET aluminum film has a reflective silvery surface, which can reflect heat back. The heat reflectivity of a PET aluminum film with a thickness of 400 A° is almost 90%, so it has excellent heat-insulation effect. In addition, PET aluminum film also has good water and gas barrier property.

[0105] In this example, the heat-generating composition comprises (by weigh): 50 parts medical iron powder; 15 parts active carbon; 5 parts metal salt; 3 parts vermiculite; 1 part water-absorbent resin; 5 parts water; and 1 part diatomite. In practice, the heat-generating composition which can generate heat by reacting with oxygen in the air is a mixture of oxidizable metal, active carbon, inorganic metal salt, water, polymer moisturizer etc.

[0106] Examples of the oxidizable metals include iron and aluminum, iron (such as, reduced iron powder, atomized iron powder, electrolytic iron powder) is preferred. There is no limitation to the particle size of iron powder, as long as the likelihood and efficiency of the desired exothermal reaction is achieved, usually, 10 to 300 μm, preferably 10 to 100 μm. The iron powder is present in an amount of 30 to 80 wt. %, preferably 30 to 50 wt. %.

[0107] Active carbon may help dissipate heat energy equally, so as to avoid too high or too low local temperature. Active carbon has excellent water absorption capacity, which can also absorb the water vapor vaporized by the reaction heat, so as to prevent water from escaping, so active carbon can act as moisture retainers. In addition, active carbon can also absorb the bad smell produced during oxidization. The active carbon may be formed from coconut shells, wood, charcoal, coal, animal charcoal etc. There is no limitation to the particle size of active carbon as long as the likelihood and efficiency of the desired exothermal reaction is achieved, usually, 10 to 300 μm, preferably 10 to 100 μm. The active carbon is present in an amount of 3 to 25 wt. %, preferably 10 to 15 wt. %.

[0108] Inorganic metal salt makes it easier to perform oxidation of iron powder and oxygen. Inorganic metal salt can activate the surface of iron powder, so as to promote the oxidation of iron. Suitable inorganic metal salts may include sulfate, such as ferric sulfate, potassium sulfate, sodium sulfate, manganese sulfate, magnesium phosphate etc.; chloride, such as copper chloride, potassium chloride, sodium chloride, calcium chloride, manganese chloride, magnesium chloride, cuprous chloride etc. In addition, carbonate, nitrate, nitrate and other salts may also be used. These inorganic metal salts can be used independently or in combination. There is no limitation to the particle size of metal salts as long as the likelihood and efficiency of the desired exothermal reaction is achieved, usually, 10 to 700 μm, preferably 200 to 600 μm. The metal salt is present in an amount of 0.5 to 10 wt. %, preferably 1 to 5 wt. %.

[0109] Water contained in the heat-generating composition may be distilled water or tap water, which is present in an amount of 1 to 20 wt. %, preferably 1 to 5 wt. %.

[0110] Besides the above components, other additives may also be employed in the heat-generating composition as needed. For example, a water-absorbent resin may be employed, which may retain moisture in the heat-generating composition when the self-heating thermal-insulation multilayer film is encapsulated, furthermore, after the reaction has proceeded to a certain extent, the water-absorbent resin may release the moisture to allow the oxidation to continue. Suitable water-absorbent resins may include, but are not limited to, isobutylene/maleic acid copolymer, poly (vinyl alcohol)/acrylic copolymer, starch/acrylate graft copolymer, polyacrylate polymer, acrylate/acrylic acid copolymer, acrylate/acrylamide copolymer, polyacrylonitrile etc. These water-absorbent resins can be used independently or in combination. There is no limitation to the particle size of water-absorbent resins as long as the likelihood and efficiency of the desired exothermal reaction is achieved, usually, 100 to 500 μm, preferably 200 to 400 μm. The water-absorbent resin is present in an amount of 0.5 to 10 wt. %, preferably 1 to 5 wt. %. The heat-generating composition may also contain vermiculite, which has thermal-insulation function, so as to maintain the temperature. There is no limitation to the particle size of vermiculite as long as the likelihood and efficiency of the desired exothermal reaction is achieved, usually, less than 300 μm, preferably less than 200 μm. The vermiculite is present in an amount of 1 to 20 wt. %, preferably 3 to 13 wt. %.

Example 2

[0111] FIG. 3 is a schematic view of a self-heating thermal-insulation multilayer film according to another embodiment. Compared with example 1, the heat-generating layer 2 in this example is provided with griddings 22, and the heat-generating composition in powder or granule form is evenly distributed in the griddings 22. Due to griddings 22, the heat-generating composition 21 in powder or granule form would not accumulate in a certain area of the thermal-insulation layer 2 under gravity action during use or transit, so that the thermal-insulation layer gives off heat evenly and local high temperature would not occur.

Example 3

[0112] FIG. 4 is a schematic view of a face mask made from the self-heating thermal-insulation multilayer film shown as FIG. 3. Besides a structure of the above three layers and griddings 22, the face mask is provided with a fixture 5. The face mask is applied to the user's face, so it comprises no adhesive layer. A fixture 5 is provided to attach the face mask to the face. In practice, the fixture 5 may be a strap, velcro or fastener extending from the two sides of the face mask.

[0113] In this example, the heat-generating composition comprises (by weigh): 30 parts medical iron powder; 10 parts active carbon; 1 part metal salt; 13 parts vermiculite; 5 parts water-absorbent resin; 1 part water; and 1 part diatomite. The thickness of the face mask depends upon the heat-generating layer, since both the outer layer and thermal-insulation layer are made of films very thin. In order to maintain heating temperature of 38-55° C. and heating time of 10-25 minutes, the mask is 2-8 mm thick, that is, the total heat-generating composition loaded in the heat-generating layer is 2-8 mm thick. Within the thickness range, the mask fits tightly to the face.

Technical Advantage of Examples 1-3

[0114] In order to test the skincare and cosmetic effect of the present self-heating thermal-insulation multilayer film, 50 testees were recruited. All testees first applied a commercial available traditional mask of some brand to the whole face, then applied the self-heating thermal-insulation multilayer film in Example 3 to the left face or right face and held the film for 15 minutes. After removing the traditional mask and the present film, the testees were asked and observed how well the present film worked. As a result, these testees wildly believed that it was more comfortable on the side of the face applied with the present film, and it was verified by monitoring the changes of moisture content of the face skin that it had higher moisture content on the side of the face applied with both the present film and the traditional mask compared with the other side only applied with the traditional mask. In addition, it was observed that the side of the face applied with both the present film and traditional mask appeared more smooth and nutritious.

Example 4

[0115] The example mainly relates to a three-dimensional face mask which has a facial concave-convex shape formed by joining two sheets together. Compared with the traditional face mask made from a single sheet of material, the three-dimensional face mask can fit the face better, so as to uniformly clean and nourish the face skin.

[0116] As shown in FIG. 5, the three-dimensional face mask 10 comprises a left side sheet 11 and a right side sheet 12 respectively matching the left area of the face and the right area of the face. Either of the front edge portions 111, 121 of the left side sheet 11 and the right side sheet 12 is provided with an adhesive material, and the left side sheet 11 and the right side sheet 12 are thereby adhered together by adhesive material along the median line of the face. FIG. 6 is a schematic view showing a face mask consisting of the right side sheet and left side sheet of FIG. 5 when the right side sheet and left side sheet are adhered together.

[0117] In this example, the left side sheet 11 and the right side sheet 12 are symmetrical along the median line of the face. Of course, the present application is not limited to this, the left side sheet 11 and the right side sheet 12 may also be unsymmetrical in other examples. However, from the perspective of somatology, it is easier to fit the face when the two sheets are symmetrical. Since the two sheets are adhered together to form a facial concave-convex shape, it is possible to keep this three-dimensional face mask compGiletely adhering to every facial curve, so as to overcome the deficiencies of the traditional face mask, which is built from a single mask sheet and is liable to wrinkle and slack, thereby the traditional one-piece face mask cannot be uniformly and reliably applied to the face and affects the cosmetic and cleaning effect.

[0118] As shown in FIG. 5, either of the front edge portion 111 of the left side sheet 11 and the front edge portion 121 of the right side sheet 12 is provided with a protrusion 112,122 projecting outwards from above down and matching the shape of the left area or right area of the external nose. A notch 113,123 corresponding to the mouth is respectively provided below the protrusion 112, 122. After the two sheets are joined together, the notch 113, 123 are joined and form a mouth portion matching the mouth. There is no adhesive material provided on the notch 113, 123 of the front edge portion 111,121. The portion of the front edge portion below the notch 113,123 respectively has an arc shape 114,124 with a certain radian and extends downwards to the bottom the face mask. Since either of the front edge portion 111 of the left side sheet 11 and front edge portion 121 of the right side sheet 12 has a protrusion projecting outwards from above down and matching the shape of the left area or right area of the external nose, after the left side sheet 11 and the right side sheet 12 are joined together, the three-dimensional face mask would naturally have a nose-like protrusion from above down on the user's nose, so as to reliably fit the nose. Since the portion of the front edge portion 111, 121 below the notch 113, 123 respectively has an arc shape with a certain radian and extends downwards to the bottom the face mask, after the left side sheet 11 and the right side sheet 12 are joined together, the lower half of the face mask has a curved surface which can reliably fit the jaw, so as to improve the adherence to the face.

[0119] FIG. 7 shows the concave-convex shape of the three dimensional face mask which has been applied to the user's face. A nose-like protrusion is formed after the protrusion 112, 122 are joined together, and an elliptical notch corresponding to the mouth is formed after the notch 113, 123 are joined together, and a curved surface is formed after the arc shape 114,124 are joined together, so as to fit the lower face and jaw. It can be seen that compared with the traditional sheet-mask, the present three-dimensional face mask fits the user's face which has a concave-convex shape better, so that it can be uniformly applied to the entire face and uniformly clean and nourish the face skin.

[0120] Preferably, a notch 114, 124 which is concaved inwards is provided on the eye-and-glabella portion of either of the front edge portion 111, 121 of the left side sheet 11 and the right side sheet 12 which faces the user's eyes and glabella, just above the protrusion 112, 122. The notch 114, 124 can be almost semielliptical or semicircular, as long as the eyes are uncovered but the skin around the eyes is almost covered. On either of the front edge portions 111,121 of the left side sheet 11 and the right side sheet 12, neither the notch 113, 123 corresponding to the mouth nor the notch 114,124 corresponding to the eye-and-glabella is provided with adhesive material. That is, the left side sheet and the right side sheet are provided with an adhesive material on either of the front edge portions, except the notch 113, 123 corresponding to the mouth and the notch 114,124 corresponding to the eye-and-glabella, and the left side sheet and the right side sheet are thereby adhered together by the adhesive material.

[0121] Preferably, as shown in FIG. 5, the rear edge portions of the left side sheet 11 and the right side sheet 12 are respectively provided with a fixing strap 118, 128, and preferably, the fixing strap 118, 128 are respectively provided with a velcro 119, 129. After applied to the face, the three-dimensional face mask can be attached to the user's head by the fixing strap and tighten by the velcro. The velcro, also known as hook-and-loop or hook-and-pile, is a common fastener used on the clothes, which is consisted of two components, typically, the first component features tiny hooks; the second features even smaller and “hairier” loops.

[0122] In this example, as shown in FIG. 5, either of the face portions 116, 126 of the left side sheet 11 and the right side sheet 12 of the three-dimensional face mask 10 comprises a structure of at least three layers. FIG. 8 shows the section view of the structure of three layers, which from outside to inside are respectively: an outer layer 131 formed of air permeable material; a heat-generating layer 132 loaded with heat-generating composition 1321 that generates heat on contact with air, at least an upper sealing surface of the heat-generating layer that is in contact with the outer layer being formed of an air permeable material; and an thermal-insulation layer 133 formed of a material having waterproof and thermal-insulation properties. The heat-generating composition 1321 in powder or granule form is loaded in heat-generating layer 132, and the thermal-insulation layer 133 is in contact with the skin 14.

[0123] In this example, the above three layers of the three-dimensional face mask are adhered together by, for example, using the adhesive or thermal bonding, which are applied to the skin as a whole. In some cases, the thermal-insulation layer is not adhered together with the outer layer and heat-generating layer. That is, in use, the thermal-insulation layer is first applied to the skin, then the outer layer and heat-generating layer are applied, and the similar self-heating thermal-insulation effect can also be obtained.

[0124] The face mask is mainly used for cleaning the skin. On the basis of cleaning, it also has other skincare effects, such as moisturizing, whitening and anti-aging. The aim of face mask improvement and development is to achieve these effects. In this example, the face portions of the two sheets comprises a structure of three layers, especially, an additional thermal-insulation layer formed of a material having waterproof and thermal-insulation properties is provided between the heat-generating layer and the skin. When used, the thermal-insulation layer ensures the heat given off from the heat-generating layer is evenly and stably transferred to the skin, and the heat will not spread out quickly from the skin, so as to avoid scalding caused by too high initial temperature and maintain stable and suitable holding temperature. In addition, the thermal-insulation layer prevents the water or oil in the skincare product, topically-applied medicine or healthcare product or sweat from permeating into the heat-generating composition, so as to avoid uncontrollable peak heating temperature and cross-contamination between the chemical reaction products of the heat-generating composition and the water or oil in the skincare product, or healthcare product or the sweat, which may cause skin infection. When applied to the face, the heat given off by the heat-generating layer and maintained by the thermal-insulation layer makes the skin comfortable, improves blood circulation and enlarges facial pores, so as to clean skin dirt and sebaceous secretion. When used in combination with a traditional nourishing face mask or skincare product, the absorption of the effective ingredients in the traditional face mask or skincare product is improved, so the amount of skincare product used is reduced and skincare effect is enhanced. In addition, the use is convenient, environmentally friendly and low-cost. Furthermore, besides the advantages brought by the above three layers, the present three-dimensional face mask can fit the face better, so as to uniformly clean and nourish the face skin. It can be said that the present three-dimensional face mask has made a real progress in cleaning and caring the skin in the field of face mask.

[0125] In this example, the outer layer 131 is made of nonwoven, the upper sealing surface and lower sealing surface of the heat-generating layer 132 are made of air permeable film, and the thermal-insulation layer 133 is a metal-plating film made of medicinal thermal-insulation film and silvery or golden metal. In practice, as long as the outer layer 131 and the upper sealing surface of the heat-generating layer 132 (with or without the lower sealing surface) are made of air permeable material, there is no specific limitation to the air permeable material, all materials which can make air permeate into the heat-generating composition are suitable. The air permeability of the air permeable material can be controlled by adjusting the size and number of the aperture on the air-permeable film, which vary depending upon the heat-generating composition and the amount thereof, and the desired heating temperature. There is no limitation to the thickness of the air permeable material, as long as it has no affection on the desired effect. Thinner air permeable material is better while achieving the air-permeable property and supporting function.

[0126] The thermal-insulation layer 133 is a metallized polyethylene terephthalate (MPET) film made of PET film and silvery or golden metal. In this example, the thermal-insulation layer is formed by a physical vapor deposition process, during which the PET film is coated with a layer of metal. The metal is heated and vaporized under vacuum, then the vaporized metal condenses or deposits on the cold PET film which is near the metal vapor source. In this example, aluminum is used for the MPET. Aluminum can be easily changed from solid to gas by heating under vacuum. Compared with other film, PET film has better heat resistance and compatibility with aluminum. The PET aluminum film has a reflective silvery surface, which can reflect heat back. The heat reflectivity of a PET aluminum film with a thickness of 400 A° is almost 90%, so it has excellent heat-insulation effect. In addition, PET aluminum film also has good water and gas barrier property. In other example, other metals, such as nickel, chromium or metal mixture, can also be used. The MPET is much thinner than a metal foil, with a thickness equal to or less than 0.5 μm. The MPET has good flexibility and waterproofness, and will not fade or discolor over time. Reflective golden or silvery surface can reflect heat back and prevent heat loss through radiation, so as to reserve more than 90% heat between the thermal-insulation layer and the skin. The addition of metal helps the heat given off from the heat-generating layer transfer to the skin evenly and stably, so as to increase and maintain skin temperature. In addition, golden or silvery surface can suit the user's aesthetic needs. Besides polyethylene terephthalate (PET), oriented polypropylene (OPP), nylon, polyethylene and cast polypropylene can also be used.

[0127] Further, the heat-generating layer 132 in this example is provided with griddings 1322, and the heat-generating composition in powder or granule form is loaded in each gridding 1322. Due to the griddings 1322, the heat-generating composition 1321 in powder or granule form would not accumulate in a certain area of the thermal-insulation layer 132 under gravity action during use or transit, so that the thermal-insulation layer gives off heat evenly and local high temperature would not occur.

[0128] In this example, the griddings 1322 are formed by thermal bonding of the upper sealing surface of heat-generating layer 132 in contact with the outer layer 131 and the lower sealing surface of heat-generating layer 132 in contact with the thermal-insulation layer 133. The griddings 1322 and the upper/lower sealing surface of heat-generating layer 132 are directly molded in one. In production, the bonding mold of thermal-insulation layer is provided with gridding patterns. After heating, the upper/lower sealing surface will be bonded together on the bulge of the bolding mold. Of course, the griddings can be formed by any other known method in the prior art.

[0129] In this example, the self-heating thermal-insulation three-dimensional face mask is loaded in a sealed package before using, so as to prevent the heat-generating composition in heat-generating layer from being oxidized by oxygen and water in the air before using. The sealed package can be made from any air impermeable material, such as plastic film.

[0130] In this example, the heat-generating composition comprises (by weigh): 50 parts medical iron powder; 15 parts active carbon; 5 parts metal salt; 3 parts vermiculite; 1 part water-absorbent resin; 5 parts water; and 1 part diatomite.

[0131] In this example, the thickness of the face mask depends upon the heat-generating layer, since both the outer layer and thermal-insulation layer are made of films very thin. In order to maintain heating temperature of 38-55° C. and heating time of 10-25 minutes, the mask is 2-8 mm thick, that is, the total heat-generating composition loaded in the heat-generating layer is 2-8 mm thick. Within the thickness range, the mask fits tightly to the face.

Example 5

[0132] FIG. 9 shows another example of the present three-dimensional face mask. The difference of example 5 over example 4 is that the three-dimensional face mask in example 5 is inclosed except that there is provided a notch corresponding to the user's mouth. That is to say, there is no notch provided on the eye and eyebrow portions of the front edge portion 211 of the left side sheet 21 and the front edge portion 221 of the right side sheet 22. In this example, either of the glabella portions of the front edge portions 211, 221 of the left side sheet 21 and the right side sheet 22 which faces a space between the user's eyebrows, just above the protrusion 212, 222, is formed as an arc 215, 225 which is slightly concaved inwards. The arc 215, 225 is provided with an adhesive material. Due to the arc 215, 225, after the left side sheet 21 and the right side sheet 22 are joined together, the three-dimensional face mask would have a slight concave on the arc 215, 225, such that the three-dimensional face mask reliably fits the concave on the user's glabella-and-nasion portion, just as shown in FIGS. 10-11.

[0133] The three-dimensional face mask in this example only has a notch on the portion corresponding to the mouth (including the portion below the nostril), other areas are inclosed, so it can clean and rejuvenate most areas of the face. In addition, the heat-generating layer and thermal-insulation layer of the three-dimensional face mask can warm and nourish the user's eyes, and thus preventing dry eye syndrome.

Example 6

[0134] In this example, there is provided a layer of water-soluble hydrogel on the surface of the thermal-insulation layer that is in contact with the skin, so as to adhere the three-dimensional face mask to the user's face. Soluble hydrogel can be used as a body adhesive to adhere the film to the body.

[0135] In soluble hydrogel, water is the dispersion medium. When soluble hydrogel is adhered to the skin, it turns from a solid to a liquid state due to body temperature, and permeates into the skin. Therefore, preferably, there is provided some active ingredients in the hydrogel matrix, such as, collagen, hyaluronic acid, arbutin, niacinamide, aromatic essential oil, or other health care products, topically-applied medicine etc. Since the present self-heating thermal-insulation film comprises an additional thermal-insulation layer formed of a material having waterproof and thermal-insulation properties, the water in the hydrogel can't permeate into the heat-generating layer, so as to avoid affecting peak heating temperature and heating effect. Furthermore, hydrogel is helpful to prevent heat from quickly spreading out from the skin.

Example 6

[0136] Example 7 differs from example 4 only in the heat-generating composition, which comprises (by weigh): 30 parts medical iron powder; 10 parts active carbon; 1 part metal salt; 13 parts vermiculite; 5 part water-absorbent resin; 1 part water; and 5 parts diatomite.

Technical Advantage of Examples 4-7

[0137] In order to test the skincare and cosmetic effect of the three-dimensional face mask, 50 testees were recruited. All testees first applied a commercial available traditional mask of some brand the whole face, then applied the three-dimensional face mask in Example 7 on their left face or right face and held the face mask for 15 minutes. After removing the traditional mask and the present three-dimensional face mask, the testees were asked and observed how well the three-dimensional face mask worked. As a result, these testees wildly believed that it was more comfortable on the side of the face applied with the present film, and it was verified by monitoring the changes of moisture content of the face skin that it had higher moisture content on the side of the face applied with both the present three-dimensional face mask and the traditional mask compared with the other side of the face only applied with the traditional mask. In addition, it was observed that the side of the face applied with both the present three-dimensional face mask and traditional mask appeared more smooth and nutritious.

[0138] The present three-dimensional face mask is structurally simple, is not constrained by environmental resources, does not require energy supply from an external energy source, is safe and stable, uniformly generates heat, and can effectively prolong heating time and reduce peak heating temperature. The heat given off by the heat-generating layer and maintained by the thermal-insulation layer makes the skin comfortable, improves blood circulation and enlarges facial pores, so as to clean skin dirt and sebaceous secretion. When used in combination with a traditional nourishing face mask or skincare product, the absorption of the effective ingredients in said traditional face mask or skincare product is improved, so the amount of skincare product used is reduced and skincare effect is enhanced. In addition, the use is convenient, environmentally friendly and low-cost. The existing face mask only has single function, without self-heating function, so it is difficult for the skin to absorb the active ingredients (especially in the case that the environment temperature is low and the facial pores are constringed). In addition, during winter months or in cold areas, the cold feeling caused by traditional sheet-mask or mud-mask usually makes the user give up using the mask, so the skin is not nursed when the nutrient is needed the most. The present three-dimensional face mask has overcome the above shortcomings of the existing mask and has expanded the functionality of the existing mask.

[0139] Furthermore, the present three-dimensional face mask is low cost and disposable, it is safe and hygienic when in contact with face skin or other susceptible body parts, and avoids the need for disinfecting the physical heating apparatus which is reused and in direct contract with the skin and potential health risk caused by irregular disinfection. The used face mask will not cause toxin pollution, and the heat-generating composition can be recycled and used as materials improving the quality of the earth.

Example 8

[0140] As shown in FIG. 12, in example 8, the face mask 10 has notches 11 corresponding to the user's eyes, and notch 12 corresponding to the mouth, and notch 13 corresponding to the nostril. The two sides of the face mask 10 are provided with a fixing strap 14, and the fixing strap 14 is provided with a velcro 15.

[0141] After applied to the face, the face mask 10 can be attached to the user's head by the fixing strap 14 and tighten by the velcro 15.

[0142] In this example, as shown in FIG. 12, the face portion 16 of the face mask 10 comprises a structure of at least three layers. FIG. 13 shows the section view of the structure of three layers, which from outside to inside are respectively: an outer layer 161 formed of air permeable material; a heat-generating layer 162 loaded with heat-generating composition 1621 that generates heat on contact with air, at least an upper sealing surface of the heat-generating layer that is in contact with the outer layer being formed of an air permeable material; and an thermal-insulation layer 163 formed of a material having waterproof and thermal-insulation properties. The heat-generating composition 1621 in powder or granule form is loaded in heat-generating layer 162, and the thermal-insulation layer 163 is in contact with the skin 17.

[0143] In this example, the above three layers of the face mask 10 are adhered together by, for example, using the adhesive or thermal bonding, which are applied to the skin as a whole. In some cases, the thermal-insulation layer is not adhered together with the outer layer and heat-generating layer. That is, in use, the thermal-insulation layer is first applied to the skin, then the outer layer and heat-generating layer are applied, and the similar self-heating thermal-insulation effect can also be obtained.

[0144] In this example, the outer layer 161 is made of nonwoven, the upper sealing surface and lower sealing surface of the heat-generating layer 162 are made of air permeable film, and the thermal-insulation layer 163 is a metal-plating film made of medicinal thermal-insulation film and silvery or golden metal. In practice, as long as the outer layer 161 and the upper sealing surface of the heat-generating layer 162 (with or without the lower sealing surface) are made of air permeable material, there is no specific limitation to the air permeable material, all materials which can make air permeate into the heat-generating composition are suitable.

[0145] The thermal-insulation layer 163 is a metallized polyethylene terephthalate (MPET) film made of PET film and silvery or golden metal. In this example, the thermal-insulation layer is formed by a physical vapor deposition process, during which the PET film is coated with a layer of metal.

[0146] Further, the heat-generating layer 162 in this example is provided with griddings 1622, and the heat-generating composition 1621 in powder or granule form is loaded in each gridding 1622. Due to the griddings 1622, the heat-generating composition 1621 in powder or granule form would not accumulate in a certain area of the thermal-insulation layer 162 under gravity action during use or transit, so that the thermal-insulation layer gives off heat evenly and local high temperature would not occur.

[0147] In this example, the griddings 1622 are formed by thermal bonding of the upper sealing surface of heat-generating layer 162 in contact with the outer layer 161 and the lower sealing surface of heat-generating layer 162 in contact with the thermal-insulation layer 163. The griddings 1622 and the upper/lower sealing surface of heat-generating layer 162 are directly molded in one. In production, the bonding mold of thermal-insulation layer is provided with gridding patterns. After heating, the upper/lower sealing surface will be bonded together on the bulge of the bolding mold.

[0148] In this example, the self-heating thermal-insulation face mask is loaded in a sealed package before using, so as to prevent the heat-generating composition in heat-generating layer from being oxidized by oxygen and water in the air before using. The sealed package can be made from any air impermeable material, such as plastic film.

[0149] In this example, the heat-generating composition comprises (by weigh): 50 parts medical iron powder; 15 parts active carbon; 5 parts metal salt; 3 parts vermiculite; 1 part water-absorbent resin; 5 parts water; and 1 part diatomite.

[0150] In this example, the thickness of the face mask depends upon the heat-generating layer, since both the outer layer and thermal-insulation layer are made of films very thin. In order to maintain heating temperature of 38-55° C. and heating time of 10-25 minutes, the mask is 2-8 mm thick, that is, the total heat-generating composition loaded in the heat-generating layer is 2-8 mm thick. Within the thickness range, the mask fits tightly to the face.

Example 9

[0151] FIG. 14 shows another example of the present face mask. The difference of example 9 over example 8 is that there is no notch provided on the portions corresponding to the user's eyes. That is to say, the face mask is inclosed on eye portions.

[0152] Since there is no notch on the portions corresponding to the user's eyes, so the face mask can clean and rejuvenate most areas of the face except the mouth and nostril. In addition, the heat-generating layer and thermal-insulation layer of the face mask can warm and nourish the user's eyes, and prevent dry eye syndrome.

Example 10

[0153] In this example, there is provided a layer of water-soluble hydrogel on the surface of the thermal-insulation layer that is in contact with the skin, which is used for adhering the face mask to the skin.

Example 11

[0154] Example 11 differs from example 8 only in the heat-generating composition, which comprises (by weigh): 30 parts medical iron powder; 10 parts active carbon; 1 part metal salt; 13 parts vermiculite; 5 parts water-absorbent resin; 1 part water; and 5 parts diatomite.

Technical Advantage of Examples 8-11

[0155] In order to test the skincare and cosmetic effect of the face mask, 50 testees were recruited. All testees first applied a commercial available traditional mask of some brand to the whole face, then applied the three-dimensional face mask in Example 11 on their left face or right face and held the face mask for 15 minutes. After removing the traditional mask and the present face mask, the testees were asked and observed how well the face mask worked. As a result, these testees wildly believed that it was more comfortable on the side of the face applied with the present film, and it was verified by monitoring the changes of moisture content of the face skin that it had higher moisture content on the side of the face applied with both the present face and the traditional mask compared with the other side of the face only applied with the traditional mask. In addition, it was observed that the side of the face applied with both the present face mask and traditional mask appeared more smooth and nutritious.

[0156] The present self-heating thermal-insulation face mask is structurally simple, is not constrained by environmental resources, does not require energy supply from an external energy source, is safe and stable, uniformly generates heat, and can effectively prolong heating time and reduce peak heating temperature. The heat given off by the heat-generating layer and maintained by the thermal-insulation layer makes the skin comfortable, improves blood circulation and enlarges facial pores, so as to clean skin dirt and sebaceous secretion. When used in combination with a traditional nourishing face mask or skincare product, the absorption of the effective ingredients in said traditional face mask or skincare product is improved, so the amount of skincare product used is reduced and skincare effect is enhanced. In addition, the use is convenient, environmentally friendly and low-cost. The existing face mask only has single function, without self-heating function, so it is difficult for the skin to absorb the active ingredients (especially in the case that the environment temperature is low and the facial pores are constringed). In addition, during winter months or in cold areas, the cold feeling caused by traditional sheet-mask or mud-mask usually makes the user give up using the mask, so the skin is not nursed when the nutrient is needed the most. The present face mask has overcome the above shortcomings of the existing mask and has expanded the functionality of the existing mask.

[0157] Furthermore, the present self-heating thermal-insulation face mask is low cost and disposable, it is safe and hygienic when in contact with face skin or other susceptible parts, and avoids the need for disinfecting the physical heating apparatus which is reused and in direct contract with the skin and potential health risk caused by irregular disinfection. The used face mask will not cause toxin pollution, and the heat-generating composition can be recycled and used as materials improving the quality of the earth.

Example 12

[0158] As shown in FIG. 15, in example 12, the eye portion 16 of the eye mask 10 comprises a structure of at least three layers. FIG. 16 shows the section view of the structure of three layers, which from outside to inside are respectively: an outer layer 161 formed of air permeable material; a heat-generating layer 162 loaded with heat-generating composition 1621 that generates heat on contact with air, at least an upper sealing surface of the heat-generating layer that is in contact with the outer layer being formed of an air permeable material; and an thermal-insulation layer 163 formed of a material having waterproof and thermal-insulation properties. The heat-generating composition 1621 in powder or granule form is loaded in heat-generating layer 162, and the thermal-insulation layer 163 is in contact with the skin 17.

[0159] In this example, the above three layers of the eye mask 10 are adhered together by, for example, using the adhesive or thermal bonding, which are applied to the skin as a whole. In some cases, the thermal-insulation layer is not adhered together with the outer layer and heat-generating layer. That is, in use, the thermal-insulation layer is first applied to the skin, then the outer layer and heat-generating layer are applied, and the similar self-heating thermal-insulation effect can also be obtained.

[0160] The eye mask is mainly used for eye care, such as moisturizing, eliminating fatigue, relieving swelling and black eyes, and anti-aging. In this example, the eye portion of the eye mask comprises a structure of three layers, the heat given off from the heat-generating layer can relax the muscle around the eyes, enlarge blood vessel and accelerate blood circulation, so as to relieve swelling, dry eye syndrome and eye irritation. In addition, a thermal-insulation layer formed of a material having waterproof and thermal-insulation properties is provided between the heat-generating layer and skin. When used, the thermal-insulation layer ensures the heat given off from the heat-generating layer is evenly and stably transferred to the skin, and the heat will not spread out quickly from the skin, so as to avoid scalding caused by too high initial temperature and maintain stable and suitable holding temperature. Further, the thermal-insulation layer prevents the water or oil in the skincare product, topically-applied medicine or healthcare product or sweat from permeating into the heat-generating composition, so as to avoid uncontrollable peak heating temperature and cross-contamination between the chemical reaction products of the heat-generating composition and the water or oil in the skincare product, or healthcare product or the sweat, which may cause skin infection. When applied to the face, the heat given off by the heat-generating layer and maintained by the thermal-insulation layer makes the skin comfortable, improves blood circulation and enlarges facial pores, so as to clean skin dirt and sebaceous secretion. When used in combination with a skincare product, the absorption of the effective ingredients in said traditional face mask or skincare product is improved, so the amount of skincare product used is reduced and skincare effect is enhanced. In addition, the use is convenient, environmentally friendly and low-cost.

[0161] In this example, the outer layer 161 is made of nonwoven, the upper sealing surface and lower sealing surface of the heat-generating layer 162 are made of air permeable film, and the thermal-insulation layer 163 is a metal-plating film made of medicinal thermal-insulation film and silvery or golden metal. In practice, as long as the outer layer 161 and the upper sealing surface of the heat-generating layer 162 (with or without the lower sealing surface) are made of air permeable material, there is no specific limitation to the air permeable material, all materials which can make air permeate into the heat-generating composition are suitable. The air permeability of the air permeable material can be controlled by adjusting the size and number of the aperture on the air-permeable film, which vary depending upon the heat-generating composition and the amount thereof, and the desired heating temperature. There is no limitation to the thickness of the air permeable material, as long as it has no affection on the desired effect. Thinner air permeable material is better while achieving the air-permeable property and supporting function.

[0162] The thermal-insulation layer 163 is a metallized polyethylene terephthalate (MPET) film made of PET film and silvery or golden metal.

[0163] Further, the heat-generating layer 162 in this example is provided with griddings 1622, and the heat-generating composition 1621 in powder or granule form is loaded in each gridding 1622. Due to the griddings 1622, the heat-generating composition 1621 in powder or granule form would not accumulate in a certain area of the thermal-insulation layer 162 under gravity action during use or transit, so that the thermal-insulation layer gives off heat evenly and local high temperature would not occur.

[0164] In this example, the griddings 1622 are formed by thermal bonding of the upper sealing surface of heat-generating layer 162 in contact with the outer layer 161 and the lower sealing surface of heat-generating layer 162 in contact with the thermal-insulation layer 163. The griddings 1622 and the upper/lower sealing surface of heat-generating layer 162 are directly molded in one. In production, the bonding mold of thermal-insulation layer is provided with gridding patterns. After heating, the upper/lower sealing surface will be bonded together on the bulge of the bolding mold. Of course, the griddings can be formed by any other known method in the prior art.

[0165] In this example, the self-heating thermal-insulation eye mask is loaded in a sealed package before using, so as to prevent the heat-generating composition in heat-generating layer from being oxidized by oxygen and water in the air before using. The sealed package can be made from any air impermeable material, such as plastic film.

[0166] In this example, the heat-generating composition comprises (by weigh): 50 parts medical iron powder; 15 parts active carbon; 5 parts metal salt; 3 parts vermiculite; 1 part water-absorbent resin; 5 parts water; and 1 part diatomite.

[0167] In this example, the thickness of the eye mask depends upon the heat-generating layer, since both the outer layer and thermal-insulation layer are made of films very thin. In order to maintain heating temperature of 38-55° C. and heating time of 10-25 minutes, the mask is 2-8 mm thick, that is, the total heat-generating composition loaded in the heat-generating layer is 2-8 mm thick. Within the thickness range, the mask fits tightly to the face.

[0168] In this example, a slit 15 is vertically cut along a lower half of a central vertical axis of the eye mask. Due to this, after applied to the eyes, a left side piece and a right side piece of the eye mask can naturally splay outward on the portion of nose bridge, so as to fit the user's eyes in shape, that is, the left side piece and the right side piece of the eye mask are symmetrically arranged along the nose bridge and naturally splay outward to the two sides of the slit so as to be reliably adhered to the eyes.

Example 13

[0169] FIG. 17 shows another example of the present eye mask. The difference of example 13 over example 12 is that besides the structure of three layers on the eyes portions, the eye mask 10 is also provided with two hanging parts 21. The hanging parts 21 are adhered to the main body of the eye mask, and drawing reference 23 represents the adhering site. The hanging parts 21 have ears slits 22 which can hung on the user's ears. In use, the eye mask can be reliably attached to the user's eyes by the hanging parts 21, so the eye mask would not easily move or fall off from the eyes.

Example 14

[0170] In this example, there is provided a layer of water-soluble hydrogel on the surface of the thermal-insulation layer of the eye mask that is in contact with the skin.

Example 15

[0171] Example 15 differs from example 12 only in the heat-generating composition, which comprises (by weigh): 30 parts medical iron powder; 10 parts active carbon; 1 pars metal salt; 13 parts vermiculite; 5 parts water-absorbent resin; 1 part water; and 5 parts diatomite.

Technical Advantage of Examples 12-15

[0172] In order to test the skincare and cosmetic effect of the eye mask, 50 testees were recruited. All testees first applied a commercial available traditional eye mask of some brand, then applied the eye mask in example 15 on their left eye or right eye and held the eye mask for 15 minutes. After removing the traditional eye mask and the present eye mask, the testees were asked and observed how well the eye mask worked. As a result, these testees wildly believed that the eye applied with the present eye mask was more comfortable, and the eye fatigue could be eased to some extent.

[0173] The present self-heating thermal-insulation eye mask is structurally simple, is not constrained by environmental resources, does not require energy supply from an external energy source, is safe and stable, uniformly generates heat, and can effectively prolong heating time and reduce peak heating temperature. The heat given off by the heat-generating layer and maintained by the thermal-insulation layer makes the skin comfortable, improves blood circulation and enlarges facial pores, so as to clean skin dirt and sebaceous secretion. When used in combination with a traditional nourishing eye mask or skincare product, the absorption of the effective ingredients in said traditional eye mask or skincare product is improved, so the amount of skincare product used is reduced and skincare effect is enhanced. In addition, the use is convenient, environmentally friendly and low-cost. The existing eye mask only has single function, without self-heating function, so it is difficult for the skin to absorb the active ingredients (especially in the case that the environment temperature is low and the facial pores are constringed). In addition, during winter months or in cold areas, the cold feeling caused by traditional sheet-mask or mud-mask usually makes the user give up using the mask, so the skin is not nursed when the nutrient is needed the most. The present eye mask has overcome the above shortcomings of the existing eye mask and has expanded the functionality of the existing eye mask.

[0174] Furthermore, the present self-heating thermal-insulation eye mask is low cost and disposable, it is safe and hygienic when in contact with face skin or other susceptible parts, and avoids the need for disinfecting the physical heating apparatus which is reused and in direct contract with the skin and potential health risk caused by irregular disinfection. The used eye mask will not cause toxin pollution, and the heat-generating composition can be recycled and used as materials improving the quality of the earth.