KR102639359B1 - Manufacturing method of a candle with anion and far_infrared radiation emissions and antibiotic and deodorization function - Google Patents

Abstract

The present invention includes an input step (S1) of putting the basic material powder for candle manufacturing into a separate container; A mixing and stirring step (S2) of the basic material powder for candle manufacturing in which the basic material powder for candle manufacturing is mixed and stirred in a separate container; A heating step (S3) of heating the container with a separate heating means until the mixed and stirred basic material powder for manufacturing Sangik candles becomes a semi-molten liquid; A wick planting step (S4) of planting the wick 13 in the center of the semi-molten liquid; A copper powder spraying step (S5) of spraying copper powder on the upper surface of the semi-molten solution before the semi-molten solution cools and hardens; A mixing and stirring step (S6) of mixing and stirring the copper powder in the semi-molten liquid using a separate stirring tool within a certain thickness range from the upper surface of the semi-molten liquid; A cooling step (S7) of cooling the semi-molten liquid in which the copper powder is mixed and stirred to a certain thickness; Negative ions, characterized by comprising a candle obtaining step (S8) of obtaining a candle (10) including a copper powder layer (12) of a certain thickness formed on the upper surface of the candle body (11) by cooling the semi-molten liquid. and a method for manufacturing a candle that emits far-infrared rays and has an antibacterial and deodorizing function.

Description

Method for manufacturing a candle with anion and far-infrared ray emission and antibacterial and deodorizing function

The present invention includes an input step (S1) of putting the basic material powder for candle manufacturing into a separate container; A mixing and stirring step (S2) of the basic material powder for candle manufacturing in which the basic material powder for candle manufacturing is mixed and stirred in a separate container; A heating step (S3) of heating the container with a separate heating means until the mixed and stirred basic material powder for manufacturing Sangik candles becomes a semi-molten liquid; A wick planting step (S4) of planting the wick 13 in the center of the semi-molten liquid; A copper powder spraying step (S5) of spraying copper powder on the upper surface of the semi-molten solution before the semi-molten solution cools and hardens; A mixing and stirring step (S6) of mixing and stirring the copper powder in the semi-molten liquid using a separate stirring tool within a certain thickness range from the upper surface of the semi-molten liquid; A cooling step (S7) of cooling the semi-molten liquid in which the copper powder is mixed and stirred to a certain thickness; Negative ions, characterized by comprising a candle obtaining step (S8) of obtaining a candle (10) including a copper powder layer (12) of a certain thickness formed on the upper surface of the candle body (11) by cooling the semi-molten liquid. and a method for manufacturing a candle that emits far-infrared rays and has an antibacterial and deodorizing function.

Below, we will look at the background technology along with the attached drawings.

In general, a candle consists of a combustion part whose main material is paraffin, and a wick buried in the combustion part.

Paraffin wax is separated as a by-product in the process of producing light lubricating oil from paraffin distillate, then the oil is removed through a deoiling process and decolorized in a refining process. Paraffin wax is a mixture of various hydrocarbons, and is mainly composed of straight-chain saturated hydrocarbons. It is mostly solid at room temperature, but also contains a small amount of liquid oil. Most of the crystals are plate-shaped and needle-shaped and are large and distinct in shape and are easily separated from the oil. do. These paraffin waxes are colorless or white, have tasteless, odorless, slippery properties, and are harder and have lower viscosity than micro waxes.

As paraffin is purified by collecting and refining paraffin obtained by cooling and solidifying the wax oil fraction of paraffinic crude oil, when a candle burns, it releases harmful substances such as toluene, benzene, and formaldehyde into the air, which are harmful to the human body in a closed space. Not only is there a problem, but when discarded candles are buried underground like general waste, they are causing soil pollution.

As an example of using such paraffin, the conventional registration utility No. 20-0410847 (2006.03.02.) states 'Paraffin solution, the main ingredient of scented candles, is 70% by weight and the basic material (natural mixture) phytoncide stock solution 1 to 5'. Weight%, fragrance 1 to 5% by weight, amethyst powder 1 to 5% by weight, jade 1 to 5% by weight, natural dye 1 to 5% by weight, red clay 1 to 5% by weight, elvan stone 1 to 5% by weight, sunstone 1 to 5% by weight, wood liquor 1 to 5% by weight, anionic material 1 to 5% by weight, torwarin stone 1 to 5% by weight, nano silver (silver nanomaterial) pulverizing polymer nanotechnology material components within the range of 10 PPM to 950 PPM. Then, using the result of mixing and stirring the basic material (natural mixed material) 20 including powder, the basic material (natural mixed material) 20 was placed in the anion cup 10a by a conventional manufacturing method. A support in a penetrating circular shape in which a wick is planted in the center in the longitudinal direction in a pulp or cotton yarn material in a semi-molten state before being injected and solidified, and has a safety structure made of aluminum to prevent the wick (21) from tilting. (22) A 'health functional negative ion scented candle', which includes a structure fastened to the upper side of the scented candle wick (21) and has the characteristics of emitting far-infrared rays and negative ions as well as antibacterial and sterilizing, has been proposed, but the above conventional registration utility No. 20-0410847 (2006.03.02.)'s health functional negative ion scented candle also uses paraffin solution as its main ingredient, so when the candle burns, it releases harmful substances such as toluene, benzene, and formaldehyde into the air, which poses a problem that is harmful to the human body in a closed space. In addition, there are still problems such as the cause of soil pollution when discarded candles are buried in the ground like general waste.

*In addition, the health functional negative ion scented candle of the above conventional registration utility No. 20-0410847 (2006.03.02.) contains expensive amethyst, jade, sunstone, and nano silver as materials for emitting far-infrared rays and negative ions in addition to the above basic materials. The use of (silver nanomaterial) increases the manufacturing cost, and in addition to amethyst, jade, sunstone, and nanosilver, it also contains various types of materials such as red clay, elvan stone, anion material, and torwarin stone that are rare or difficult to purchase. The problem was that preparing all of these ingredients was not simple.

In addition, the health functional negative ion scented candle of the above conventional registered utility No. 20-0410847 (2006.03.02.) had the problem of having to add a separate scent such as a fragrance agent during the manufacturing process in order to emit the scent, and this problem was caused by paraffin. This also existed in other conventional candles manufactured using wax.

Republic of Korea Patent Publication No. 10-2017-0039543 (2017.04.11.)

The method for manufacturing a candle with negative ion and far-infrared ray emission and antibacterial and deodorizing functions according to the present invention seeks to solve the following issues.

The purpose of the present invention is to provide a method of manufacturing a candle that emits negative ions and far-infrared rays and has an antibacterial and deodorizing function, which produces a candle that is harmless to the human body by not emitting substances harmful to the human body when the candle is burned.

Another object of the present invention is to provide a method of manufacturing a candle that emits far-infrared rays and anions when the candle is burned, thereby producing a candle that is antibacterial and has low manufacturing costs, emitting anions and far-infrared rays, and has an antibacterial and deodorizing function.

Another object of the present invention is to provide a method of manufacturing a candle that emits far-infrared rays and anions when the candle burns, emits far-infrared rays and anions, has antibacterial properties, has low manufacturing costs, but is common and easy to purchase, and has an antibacterial and deodorizing function. It is done.

A further object of the present invention is to provide a method for manufacturing a candle with negative ion and far-infrared ray emission and antibacterial and deodorizing functions, which produces a candle containing wax that emits a soft scent itself without adding additional fragrance during the manufacturing process. It is done.

In order to solve the above problems, the method for manufacturing a candle with negative ion and far-infrared ray emission and antibacterial and deodorizing function according to the present invention,

An input step (S1) of putting the basic material powder for candle manufacturing into a separate container; A mixing and stirring step (S2) of the basic material powder for candle manufacturing in which the basic material powder for candle manufacturing is mixed and stirred in a separate container; A heating step (S3) of heating the container with a separate heating means until the mixed and stirred basic material powder for manufacturing Sangik candles becomes a semi-molten liquid; A wick planting step (S4) of planting the wick 13 in the center of the semi-molten liquid; A copper powder spraying step (S5) of spraying copper powder on the upper surface of the semi-molten solution before the semi-molten solution cools and hardens; A mixing and stirring step (S6) of mixing and stirring the copper powder in the semi-molten liquid using a separate stirring tool within a certain thickness range from the upper surface of the semi-molten liquid; A cooling step (S7) of cooling the semi-molten liquid in which the copper powder is mixed and stirred to a certain thickness; A candle obtaining step (S8) of obtaining a candle (10) including a copper powder layer (12) of a certain thickness formed on the upper surface of the candle body (11) by cooling the semi-molten liquid, wherein the certain thickness is 1.5 to 5 mm, and at this time, the diameter of the candle body 11 and the diameter of the semi-molten liquid are 30 to 90 mm, and the amount of copper powder mixed and stirred in the semi-molten liquid with a thickness of 1.5 to 5 mm is 3.3 g to 7.2 g, It is characterized in that it further includes a flavor component addition and mixing step in which Hasperides flavor, acacia flavor, or coffee bean flavor is added and mixed between the heating step (S3) and the wick planting step (S4).

The basic material powder for candle manufacturing is characterized in that it contains one or more of palm wax, soy wax, and bees wax.

The basic material powder for candle manufacturing is characterized in that it contains 60 to 70% by weight of palm wax, 22 to 28% by weight of soy wax, and 8 to 12% by weight of bees wax.

The method of manufacturing a candle with negative ion and far-infrared ray emission and antibacterial and deodorizing function according to the present invention is achieved by the above solution.

First, there is an effect of providing a method of manufacturing a candle that emits negative ions and far-infrared rays and has an antibacterial and deodorizing function, producing a candle that is harmless to the human body by not emitting substances harmful to the human body when the candle is burned.

Second, there is an effect of providing a method of manufacturing a candle that emits far-infrared rays and anions when the candle burns, producing a candle that has antibacterial properties but is inexpensive to manufacture.

Third, it has the effect of providing a method of manufacturing a candle that emits far-infrared rays and anions when the candle burns, has antibacterial properties, has low manufacturing costs, but is common and easy to purchase, and has an antibacterial and deodorizing function.

Fourth, it is effective in providing a method of manufacturing candles that emit negative ions and far-infrared rays and have an antibacterial and deodorizing function, producing candles containing wax that emits a soft scent itself without adding additional fragrance during the manufacturing process.

Figure 1 is a perspective view of a candle manufactured by a method of manufacturing a candle with negative ion and far-infrared ray emission and antibacterial and deodorizing function according to a preferred embodiment of the present invention.
Figure 2 is a flowchart of a method for manufacturing a candle with negative ion and far-infrared ray emission and antibacterial and deodorizing functions according to a preferred embodiment of the present invention.

Hereinafter, the present invention will be examined with reference to the accompanying drawings, and the present invention will be described in detail with reference to preferred embodiments as follows.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, and may be implemented in various different forms. The present embodiments are merely provided to ensure that the disclosure of the present invention is complete and to provide a general understanding of the technical field to which the present invention pertains. It is provided to fully inform those with knowledge of the scope of the invention, and the present invention is only defined by the scope of the claims. Additionally, the same reference numerals refer to the same elements throughout the specification.

The present invention relates to a method for manufacturing a candle that emits negative ions and far-infrared rays and has an antibacterial and deodorizing function.

Figure 1 is a perspective view of a candle manufactured by a method of manufacturing a candle with an antibacterial and deodorizing function and emission of negative ions and far-infrared rays according to a preferred embodiment of the present invention, and Figure 2 is a perspective view of a candle manufactured by a method of emitting negative ions and far-infrared rays and having an antibacterial and deodorizing function according to a preferred embodiment of the present invention. This is a flowchart of the manufacturing method of a candle with an antibacterial and deodorizing function.

Referring to Figures 1 and 2, the method of manufacturing a candle with negative ion and far-infrared ray emission and antibacterial and deodorizing function of the present invention includes an input step (S1), a mixing and stirring step (S2) of the basic material powder for candle manufacturing, and a heating step ( S3), a wick planting step (S4), a copper powder spraying step (S5), a copper powder mixing and stirring step (S6), a cooling step (S7), and a candle obtaining step (S8).

In the input step (S1), the basic material powder for candle manufacturing is put into a separate container. Here, the basic material powder for manufacturing candles includes one or more of palm wax, soy wax, and bees wax.

Since the palm wax, soy wax, or bees wax is a natural material, unlike paraffin manufactured from petroleum products, there is no smoke or no harmful gases generated when a candle containing one or more of these ingredients is burned, so it is harmless to the human body. In particular, since the bead wax itself emits a soft bee scent, a separate fragrance addition process is not necessary during the manufacturing process of candles containing such bead wax. The bead wax is extracted from substances secreted by bees to create honeycombs. When bead wax is added as an ingredient in candles, letters or designs can be clearly engraved or engraved on the candle without adding chemicals. . The palm wax forms snowflake crystals as it cools in the cooling step (S7), which will be described later, so its appearance becomes more beautiful when viewed visually.

In one embodiment, the base material powder for candle manufacturing includes 60 to 70% by weight of palm wax, 22 to 28% by weight of soy wax, and 8 to 12% by weight of bees wax.

Here, if the palm wax is less than 60% by weight, the content of propolis contained in the palm wax is correspondingly reduced, so that the effect of improving the immunity of people around the burning candle when the candle is burned decreases, and the effect of inhibiting bacterial growth also decreases, If the palm wax is more than 70% by weight, it is 3 to 4 times more expensive than the soy wax, so the manufacturing cost of the candle manufactured by the method of manufacturing a candle with anion and far-infrared ray emission and antibacterial and deodorizing function of the present invention increases.

If the soy wax is less than 8% by weight, the content of its own scent is insufficient when the candle is burned compared to paraffin wax, so the scenting power is lowered and the combustion time is shortened. If the soy wax is more than 12% by weight, there is not much scent and paraffin wax is used. Since the price is higher than in the case of making candles, the manufacturing cost increases when manufacturing candles manufactured by the method of manufacturing candles with negative ion and far-infrared ray emission and antibacterial and deodorizing functions of the present invention.

If the bead wax is less than 8% by weight, the combustion time when burning the candle is shortened and the embossing or intaglio engraved on the candle may not be clear, and if the bead wax is more than 12% by weight, the bead wax itself has a transparent color, so that the present invention If pigment is added during the manufacturing process of a candle manufactured by a candle manufacturing method that emits negative ions and far-infrared rays and has an antibacterial and deodorizing function, the pigment becomes lighter, making it impossible to obtain the desired color of the candle, and also because the bead wax itself is expensive. The manufacturing cost of candles manufactured by the invention's method of manufacturing candles that emit negative ions and far-infrared rays and have an antibacterial and deodorizing function increases.

In the mixing and stirring step (S2) of the basic material powder for candle manufacturing, the basic material powder for candle manufacturing is mixed and stirred in a separate container.

In the heating step (S3), the container is heated using a separate heating means until the mixed and stirred base material powder for candle manufacturing becomes a semi-molten liquid. In this way, the container can be heated using a separate heating means to make the basic material powder for candle manufacturing into a semi-molten liquid state.

In the wick planting step (S4), the wick 13 is planted in the center of the semi-melted liquid.

In one embodiment, when planting the wick 13, the diameter of the wick 13 is 0.7 to 1.5 cm depending on the diameter of the candle body. At this time, when manufacturing the wick 13, the wick 13 is manufactured by passing the wick through a paraffin solution.

In another embodiment, when planting the wick 13, the diameter of the wick 13 is 0.7 to 1.5 cm depending on the diameter of the candle body. At this time, when manufacturing the wick 13, paraffin mixed with magnesium powder is used. Since the wick (13) is manufactured by passing the wick through a solution, the wick (13) contains magnesium powder. The amount of magnesium powder contained in the wick (13) is per 1 cm of length in the case of a wick (13) with a diameter of 0.7 cm. It is preferably 0.15 to 0.3 g, and in the case of a wick (13) with a diameter of 1 cm, it is preferably 0.3 to 0.49 g per 1 cm in length, and in the case of a wick (13) with a diameter of 1.3 cm, it is preferably 0.5 to 0.59 g per 1 cm in length. And, in the case of a wick (13) with a diameter of 2.0 cm, it is preferably 0.6 to 0.8 g per 1 cm of length.

The magnesium powder combines with oxygen to cause a combustion reaction when the wick (13) of the candle body is lit, and serves to re-ignite the candle even when the wind blows outdoors and the candle wick (13) is extinguished. Do it. In other words, if the wick 13 contains magnesium powder, it has the effect of preventing the wick from being extinguished even when the wind blows outdoors. The reason for using magnesium is that the more reactive the metal is, the more likely it is that a combustion reaction will occur. Usually, the reactivity order of metals is potassium > calcium > magnesium > aluminum, where potassium and calcium are more reactive than magnesium, but are dangerous. Therefore, magnesium is used, which is safer than that.

If the amount of magnesium powder contained in the wick 13 is less than the lower limit for each diameter of the wick 13, it will be easily extinguished even by a small wind, and if it exceeds the upper limit, the manufacturing cost will increase and it will burn too quickly, making it impossible to preserve the characteristics of the candle. .

In the copper powder spraying step (S5), copper powder is sprinkled on the upper surface of the semi-molten liquid before the semi-molten liquid cools and hardens. In this regard, melting refers to the melting of a substance in a solid state when it reaches its melting point. A liquid in which a substance in a solid state is completely melted at its melting point is called a melt. A liquid that is half-melted is called a semi-melt. This semi-melt contains It is possible for powders of other substances to be added and stirred.

In the mixing and stirring step (S6) of the copper powder, the copper powder is mixed and stirred within a certain thickness range from the upper surface of the semi-molten liquid using a separate stirring tool. In this way, the copper powder is mixed and stirred within a certain thickness range from the upper surface of the semi-molten liquid, so that the copper powder is evenly mixed and stirred in the portion within a certain thickness range from the upper surface of the semi-molten liquid.

In this embodiment, the constant thickness is 1.5 to 5 mm, and at this time, the diameter of the candle body 11 and the diameter of the semi-molten liquid are 30 to 90 mm, and the copper mixed and stirred in the semi-molten liquid with a thickness of 1.5 to 5 mm The amount of powder is preferably 3.3g to 7.2g, but the present invention is not limited thereto, and in another embodiment, the constant thickness is 5 to 8mm, and the diameter of the candle body 11 and the diameter of the semi-melt liquid are It is possible to have a configuration in which the amount of copper powder is greater than 35 mm and less than 55 mm, and the amount of copper powder mixed and stirred in the semi-molten solution with a thickness of 5 to 8 mm is 7.3 g to 11.2 g, and in another embodiment, another configuration is also possible.

In the cooling step (S7), the semi-molten liquid in which the copper powder is mixed and stirred to a certain thickness is cooled. When cooling occurs in this way, the semi-molten liquid solidifies and the copper powder becomes a solid state in which the copper powder is evenly mixed and stirred.

In the candle obtaining step (S8), the candle 10 including a copper powder layer 12 of a certain thickness formed on the upper surface of the candle body 11 is obtained by cooling the semi-molten liquid. When the semi-molten liquid is cooled and hardened as described above, and the copper powder is evenly mixed and stirred to become a solid state, the solid portion forms a copper powder layer of a certain thickness, ultimately forming the upper surface of the candle body 11. A candle 10 including a copper powder layer 12 of a certain thickness formed in is obtained. In the candle 10 manufactured in this way, when the candle combusts, the wick 13 catches fire, the temperature of the copper powder layer 12 around the wick rises to 230°C, and the copper powder layer 12 adjacent to the wick 13 ignites. This is heated, and as a result, the copper powder evenly distributed within the copper powder layer 12 is heated and emits negative ions and far-infrared rays to the surroundings. The emission of these negative ions and far-infrared rays is maintained until the temperature around the wick reaches 300°C. The negative ions and far-infrared rays are emitted to antibacterial or sterilize the area or space around the candle, and the copper powder in the heated copper powder layer 12 has a deodorizing effect that eliminates odors in the area or space around the candle.

In addition, in another embodiment, the method of manufacturing a candle with negative ion and far-infrared ray emission and antibacterial and deodorizing function of the present invention adds a natural colorant that is harmless to the human body between the heating step (S3) and the wick planting step (S4). It is also possible to further include steps of adding and mixing natural pigments. According to this, the candles manufactured by the method of manufacturing candles with negative ion and far-infrared ray emission and antibacterial and deodorizing functions of the present invention can have various colors, and at the same time, the natural pigments added and mixed are harmless to the human body, so the negative ions of the present invention Candles manufactured using a candle manufacturing method that emits far-infrared rays and has an antibacterial and deodorizing function are also harmless to the human body and eco-friendly.

The natural pigments include cochineal, lac pigment, gardenia yellow, gardenia greens, safflower yellow, beet red, purple sweet potato pigment, paprika pigment, grape skin pigment, and red cabbage pigment, rupain pigment, and black color. It is preferable that the pigment is a mixture of at least one of a pigment and a monascus pigment.

The cochineal is a dye used by drying female cochineal insects that live on cacti in the alpine desert of Peru and extracting only the pigments from the cochineal insects. It has a beautiful color and is manufactured using the candle manufacturing method of the present invention. The color of the candle can be beautifully displayed in red.

The origin of LAC, which embodies the LAC pigment, is India, Thailand, Nepal, Tibet, etc., and is a scale insect parasitic on the Buteamono sperma Taud. There is a record in <Cheongonggaemul> that it was used to make ancient rouge, and it contains the reddish-purple pigment laccaic acid, giving the candles manufactured by the candle manufacturing method of the present invention a reddish-purple color. It can be produced.

The gardenia yellow is a pigment extracted from gardenia fruit and has excellent heat resistance and light resistance.

The gardenia blue is a blue pigment produced by an enzyme reaction in gardenia extract, and may precipitate in acidic areas.

The safflower yellow is a flavonoid pigment extracted from safflower and has excellent acid resistance, heat resistance, and light resistance.

The beet red is a pigment obtained by extracting the dried rhizome of Beta Vulgaris L. with ethyl alcohol, fat or organic solvent. The main ingredient is betaine, and it has the disadvantage of poor heat resistance and light resistance. It is mainly used in neutral or slightly acidic environments.

The purple sweet potato pigment is a dark purple pigment extracted from purple sweet potatoes, and purple sweet potatoes are a variety spread by crossing Korean and Japanese varieties. These purple sweet potatoes have the characteristic of being dark purple in color, unlike regular sweet potatoes.

The paprika pigment is a pigment extracted from paprika, and since paprika has colors such as red, yellow, and orange, the paprika pigment can also be implemented in colors such as red, yellow, and orange.

The grape skin pigment is a red pigment obtained by extracting the skin of grapes (Vitis labrusca Linne or Vitis vinifera Linne) with water and contains anthocyanin as its main ingredient. However, diluents, stabilizers, and solvents may be added for color adjustment, quality preservation, etc.

The red cabbage pigment is a pigment obtained by extracting the leaves of cabbage (Brassica oleracea Linne) with a weakly acidic aqueous solution and contains cyanidin acylglycoside as its main ingredient. However, diluents, stabilizers, and solvents may be added for color adjustment, quality preservation, etc. This red cabbage coloring is a dark red liquid, powder, or paste-like substance.

The rupain pigment is a pigment extracted from lutein, and lutein is a type of carotenoid, a plant pigment, and is a yellow substance.

The black color pigment is a pigment made by mixing the three primary colors of the gardenia family and is mainly used to produce black color in cotton or rice cakes.

The Monascus pigment is a pigment produced by bacteria of the Monascus species, and is a water-soluble red pigment whose main ingredients are Monascolbulin and Rublophantachin, which can be obtained by extraction with alcohol from a culture containing the fungal cells. The characteristics of red yeast rice pigment, which belongs to the azaferone group of red pigments, include excellent heat resistance, a wide usable pH range, and good dyeing properties, but light resistance and acid resistance are somewhat weak.

As above, the natural pigments include cochineal, lac pigment, gardenia yellow, gardenia greens, safflower yellow, beet red, purple sweet potato pigment, paprika pigment, grape skin pigment, red cabbage pigment, rupain pigment, Since the candle is made of a mixture of at least one of black color pigment and monascus pigment, the candle is manufactured by the method of manufacturing a candle with negative ion and far-infrared ray emission and antibacterial and deodorizing function of the present invention by adding such natural pigment. The candle body 11 can be implemented in various desired colors.

In another embodiment, the method of manufacturing a candle with negative ion and far-infrared ray emission and antibacterial and deodorizing function of the present invention includes sandalwood scent and Hasperides scent between the heating step (S3) and the wick planting step (S4). , it further includes adding and mixing a flavor component in which acacia flavor, coffee bean flavor, or aroma flavor is added and mixed.

The sandalwood scent promotes good sleep, relieves tension, relaxes the mind, and has good effects on the bronchial tubes.

The Hasperides fragrance is a light citrus-based perfume that mixes a tangy grapefruit scent with a highly addictive citrus scent, making you feel good.

The acacia scent has a sweet yet unique scent, so it relieves physical and mental stress and prevents skin, scalp, and human body problems caused by it.

The coffee bean scent calms the mind and body and has a deodorizing effect.

In the above aroma fragrance, aroma refers to a scent or direction, and while herbs used for medicinal purposes or fragrances refer to plants in an unprocessed state, aroma refers to herbs collected and processed into an essential oil form that is easy to use. Aroma, which has been used in various fields such as treatment, beauty, aroma, bathing, food, and pharmaceuticals since ancient times, is loved to this day as a natural healing therapy (aromatherapy) that provides stability and rest to the tired mind and body.

Input step (S1) of putting palm wax powder into a separate container; A mixing and stirring step (S2) of the basic material powder for candle manufacturing in which the palm wax powder is mixed and stirred in a separate container; A heating step (S3) of heating the container with a separate heating means until the mixed and stirred palm wax powder becomes a semi-molten liquid; A wick planting step (S4) of planting the wick 13 in the center of the semi-molten liquid; A copper powder spraying step (S5) of spraying copper powder on the upper surface of the semi-molten solution before the semi-molten solution cools and hardens; A mixing and stirring step (S6) of mixing and stirring the copper powder in the semi-molten liquid using a separate stirring tool within a thickness of 3 mm from the upper surface of the semi-molten liquid; A cooling step (S7) of cooling the semi-molten liquid in which the copper powder is mixed and stirred to a thickness of 3 mm; A candle obtaining step (S8) of obtaining a candle 10 including a 3 mm thick copper powder layer 12 formed on the upper surface of the candle body 11 by cooling the semi-molten liquid, and the heating step ( It further includes a fragrance component addition and mixing step in which Hasperides fragrance is added and mixed between S3) and the wick planting step (S4), and the diameter of the candle body 11 and the diameter of the semi-melt are 25 mm and 3 mm. The candle manufactured by the method of manufacturing a candle with negative ion and far-infrared ray emission and antibacterial and deodorizing function of the present invention, in which the amount of copper powder mixed and stirred in the semi-melt of the thickness is 5.1 g, is taken as Experimental Example 1,

A candle manufactured using commercially available paraffin wax as the main ingredient was used as Control Example 1.

The results of measuring the amount of negative ions and far-infrared rays emitted from the candles of Experimental Example 1 and Control Example 1 were shown in Table 1 below.

division Negative ion emission Far infrared emissivity Experimental Example 1 24,500 Ion/cc 0.869 Control Example 1 - -

According to Table 1 above, while Experimental Example 1 emits anions and far-infrared rays, Control Example 1 does not emit anions and far-infrared rays, so it was confirmed that Experimental Example 1 emits more anions and far-infrared rays than Control Example 1.

10: Candle
11: Candle body
12: Copper powder layer
13: Wick
S1: Input stage
S2: Mixing and stirring step of basic material powder for candle manufacturing
S3: Heating step
S4: Wick planting stage
S5: Copper powder spraying step
S6: Mixing and stirring step of copper powder
S7: Cooling step
S8: Obtaining candles

Claims (3)

An input step (S1) of putting the basic material powder for candle manufacturing into a separate container;
A mixing and stirring step (S2) of the basic material powder for candle manufacturing in which the basic material powder for candle manufacturing is mixed and stirred in a separate container;
A heating step (S3) of heating the container with a separate heating means until the mixed and stirred base material powder for candle manufacturing becomes a semi-molten liquid;
A wick planting step (S4) of planting the wick 13 in the center of the semi-molten liquid;
A copper powder spraying step (S5) of spraying copper powder on the upper surface of the semi-molten liquid before the semi-molten liquid cools and hardens;
A mixing and stirring step (S6) of mixing and stirring the copper powder in the semi-molten liquid using a separate stirring tool within a certain thickness range from the upper surface of the semi-molten liquid;
A cooling step (S7) of cooling the semi-molten liquid in which the copper powder is mixed and stirred to a certain thickness;
A candle obtaining step (S8) of obtaining a candle (10) including a copper powder layer (12) of a certain thickness formed on the upper surface of the candle body (11) by cooling the semi-molten liquid,
The constant thickness is 1.5 to 5 mm, and at this time, the diameter of the candle body 11 and the diameter of the semi-molten liquid are 30 to 90 mm, and the amount of copper powder mixed and stirred in the semi-molten liquid with a thickness of 1.5 to 5 mm is 3.3 g to 3.3 g. It is 7.2g,
Negative ions and far-infrared rays emission, characterized in that it further comprises a flavor component addition and mixing step in which Hasperides scent, acacia scent, or coffee bean scent is added and mixed between the heating step (S3) and the wick planting step (S4). Method for manufacturing candles with antibacterial and deodorizing properties. According to paragraph 1,
A method of manufacturing a candle with negative ion and far-infrared ray emission and antibacterial and deodorizing functions, characterized in that the basic material powder for candle manufacturing includes one or more of palm wax, soy wax, and bees wax. According to paragraph 2,
The basic material powder for candle manufacturing contains 60 to 70% by weight of palm wax, 22 to 28% by weight of soy wax, and 8 to 12% by weight of bees wax. It emits negative ions and far infrared rays and has an antibacterial and deodorizing function. How to make candles.