JPH01240580A - Fluororesin coating composition containing powder of far infrared radiating material and container using said composition - Google Patents

Abstract

PURPOSE:To obtain the present composition useful for cooking containers, capable of providing non-tackiness to contents, reduction of heating power and time, by adding far infrared ray radiating powder to a composition consisting essentially of a fluororesin. CONSTITUTION:Powder of far infrared ray radiating material (e.g., alumina ceramic or metallic oxide consisting essentially of manganese) to generate much of 8-15mu wavelength useful for processing foods is added to a fluororesin (>=25mu total film thickness is required) to be applied to the inside of containers or undercoat or glaze thereof to give the aimed composition.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application This invention relates to containers, particularly food cooking containers whose insides are coated with fluororesin.

(B) Conventional technology Conventional food cooking containers whose inner surfaces are coated with fluororesin include frying pans, various pots, rice cookers, bread makers, rice cake makers, oven plates, and food preparation containers that are coated with fluororesin.
This is to prevent it from becoming sticky.

Further, methods for utilizing far infrared rays include irradiating far infrared rays from above a cooking container, or throwing a lump of far infrared rays into the cooking container, that is, into the food to be cooked. There are products that have far-infrared emitters baked into the inside of father's pots, but because they are heavy and break easily, their uses are limited and they cannot be used in pressure vessels.

(c) Problems to be Solved by the Invention The present invention is to obtain an even more excellent food cooking container by combining the non-adhesive properties of conventional fluorine coated containers with the effect of far infrared rays. With the goal.

2) Means for solving the problem This problem involves the use of powdered far-infrared emitters in the fluororesin coating on the inside of the container, or in its undercoat or glaze, that is, in the composition mainly composed of fluororesin. It is solved by letting

The fluororesin composition is, for example, EK-19 manufactured by Daikin Industries.
00 series (primer), EK-4300 series (enamel), etc. are used depending on the prescription, and the total film thickness is required to be 25 microns or more.

Further, the far-infrared radiator is preferably one that emits a large amount of wavelength of 8 to 15 microns, which is particularly useful for food processing, and it can also be applied in powder form to alumina-based cera E-), metal oxides mainly containing manganese, and the like.

The present invention will be described below based on an example in which the invention is applied to a food cooking container.

The inner surface of an aluminum alloy food cooking container 1 is roughened and coated with a primer as an undercoat 2, and then an intermediate coat of fluororesin enamel mixed with fine powder 3 of an alumina ceramic far-infrared emitter is mixed as a filler. Coating and baking as layer 4. Furthermore, a final top coat layer 5 is applied and fired to obtain a fluororesin coated container containing a far-infrared radiator.

If the required amount of far-infrared emitter and film thickness cannot be obtained in the coating obtained at this time, additional coatings can be applied.

The next example is as shown in Figure 2.
A glaze layer 8 is prepared by mixing far-infrared radiator powder 7 into a glaze that melts at a low temperature of 50C to 500C, and a fluororesin coating layer 9 is formed on this layer by a conventional method.

According to this embodiment, coarser powder can be used than in the previous embodiment, and a larger amount of far-infrared radiator can be utilized.

Effect) By incorporating a far-infrared ray emitter into the fluororesin coating as described above, the cooking container can be made non-stick to food and uniformly radiate far-infrared rays from all around.

(f) Effects As an example of the remarkable effects of this invention, the case where it is used as a pressure cooker will be described.

Conventionally, boiled beans can be cooked in 5 to 6 minutes after the pressure reaches 1 cup at 1.1 atm, but with the present invention, the same cooking can be done in 4 to 5 minutes after the pressure reaches 1 cup at 1.07 atm. Approximately 20% of firepower was saved. .

Furthermore, when extracting pork bone soup extract using the pressure vessel of the present invention, the pressure is as low as 1.07 atm compared to the conventional 1.1 atm pressure vessel due to the strong penetrating power of far infrared rays. It is effective in extracting the essence from the center of the bone more quickly and with less heat than conventional methods.

As mentioned above, when the present invention is used as a food cooking container, in addition to the non-stick properties of the conventional fluororesin coating, the effect of far-infrared radiation not only saves firepower and time during cooking, but also saves cooking time. As a result of this effect, food can be cooked from the core in a shorter amount of time, reducing deterioration such as vitamins in the food being destroyed, oil oxidizing, and the aroma and ingredients of the food evaporating and being lost due to excess heat. The pressure cooker has the effect of increasing the safety of the pressure cooker because the food ingredients are cooked in a state closer to its natural state and the pressure cooker can be used at a lower pressure than before, and it can perform better than before. .

In the examples, aluminum alloy was used, but it is not limited to this, and iron, iron,
Anything can be used, such as stainless steel brad or ceramic mold, as long as it can withstand the temperature required to bake the far-infrared radiator.

Further, the far-infrared radiator is not limited to alumina-based Cera F and Sox.

Further, when the container of the present invention is used as a container when not heated, in addition to the non-adhesive property, the effect of far-infrared radiation improves the shelf life of the food, and on the other hand, the ripening of the processed food is promoted.

In the above example, a fluororesin coating composition containing a far-infrared radiator is used for food containers, but the composition is not limited to this, and can be used for biofermentation tanks, heating rolls, industrial products, etc. Even if Ni and fluororesin are used separately, it is sufficient that the far-infrared radiator and fluororesin are finally formed as a coating layer.

It goes without saying that in addition to the far-infrared radiator powder, conventional additives can be added to the fluororesin composition.

[Brief explanation of the drawing]

The figure is an enlarged sectional view of the main part, and FIG. 1 shows the first embodiment. FIG. 2 shows a second embodiment. ■・−−1−−・−Food cooking container 2・−・−・−Undercoat layer 3−−−−−−−1 Far infrared ray emitter powder 4・−−−
--- Intermediate coating layer 5 --- Top coating layer 6 --- Aluminum alloy 7 --- Far infrared radiator powder 8 ---
−・−・Glaze layer

Claims (1)

[Scope of Claims] 1. A fluororesin coating composition comprising a far-infrared radiator contained in a composition mainly composed of a fluororesin. 2. A fluororesin-coated container characterized in that far-infrared radiator powder is dispersed in the coating layer of the fluororesin-coated container or provided in a layered manner. 3. A fluororesin-coated container, characterized in that the inside of the container is coated with the composition according to claim 1. 4. A method for manufacturing a fluororesin-coated container containing a far-infrared ray emitter, characterized by baking a glaze mixed with powder of a far-infrared ray emitter on the inside of the container, and coating the glaze with a fluororesin using a conventional method. .