JP4545159B2 - Heating or warming container provided in a steam atmosphere and method for producing the same - Google Patents

Description

The present invention relates to a heating or thermal insulation container provided in a steam atmosphere and a method for producing the same , and more specifically, one kind of a convex mold and a concave mold on the inner and outer surfaces of a thermosetting melamine resin molded container. Using a mold, a glaze coating layer of a composition for molding coating containing a melamine / guanamine cocondensation resin (or a picture or a pattern on the inner and outer surfaces as required, and a glaze coating layer on the outer surface) was added. The present invention relates to a heating or warming container provided in a steam atmosphere.

Conventionally, thermosetting melamine resins have been widely used for the production of molded products such as tableware, cooking utensils, food storage containers, etc. by compression molding. These thermosetting resin molding materials are usually filled with a reinforcing material such as a pulp material for reinforcement. However, a single molded product of the thermosetting resin molding material is easily contaminated during use due to the influence of a reinforcing material such as pulp material. Glaze coating molding is performed to coat only the glaze.

  When conventional products are used in a steam atmosphere for a long time, such as cooking with a steamer or keeping warm in a steam atmosphere, the glaze-coated surface is rough and whitened, but the uncoated surface is rough and whitened. There was a problem that the life as a tableware was shortened due to contamination and gloss reduction.

On the other hand, in hospitals and welfare facilities for collective meals, as well as for business lunches, school lunches, and university cafeterias, for example, cook chills, vacuum cooking, and cook freezes are reheated in bulk, and in some cases cooked. There is a system that assembles cooking in combination with dishes made by Saab, and this system has the following merits.
1) Since pre-preparation is a prerequisite, cooking work can be leveled, contributing to a reduction in labor costs.
2) Cooking by the conventional cook service required intuition, experience, and skill by skilled cooks, but cooking based on scientific cooking data is possible, and skilled cooks with high labor costs are not required. Costs can be reduced.
3) Since the introduction of HACCP (Hazard Analysis Critical Control Point) is essential, the safety and hygiene aspects of food are improved.
4) Cooking based on scientific cooking data is possible, and it is possible to provide high-quality and uniform dishes.
Since the cooking work can be completed on the previous day, the first cooking work on the next day is not necessary, and early departure in the morning is slightly relieved.
5) Since cooking can be made into parts and prepared, it is possible to contribute to increasing the number of foods on the menu and to improve services.
6) Since cook-chilled food, vacuum-cooked food, and frozen food can be used effectively, the central kitchen can be easily used.

However, this system still has the following problems.
1) Since the food is hot, it must be arranged with chopsticks and tongs, and it takes time to arrange.
2) Since it is not individually arranged, early breakfast cannot be eliminated.
3) It cannot contribute to leveling of the arrangement work.
4) The temperature of the dishes during the serving is lowered, making it difficult to provide the appropriate temperature service.
5) There is a question about safety due to a decrease in temperature at the time of placing.

  However, recently, foods prepared in advance using cooking utensils that are heated in a steam atmosphere such as a steam convection oven with a steam function and an oven function are used to provide a large amount of delicious dishes at appropriate temperatures. be able to. That is, according to this system, it is possible to perform the placing work in a cold state, so that it can be placed with both hands compared to the placing work with chopsticks and tongs, so the placing work can be done in a short time and labor costs can be reduced, Since it is possible to finish early, it is possible to eliminate early arrivals at breakfast, and pre-ordering is possible, so it is possible to work at lunchtime and dinner in a spare time, contributing to leveling of work, Because it is heated, there is no temperature drop of the dishes during the laying work, and an appropriate temperature service can be realized. It can be held, contributes to more appropriate temperature service, and can be reheated in a short time because a steam function can be added compared to conventional bulk reheating and reheating in a reheating cart. Since there is an advantage in that specific room it can be, has attracted attention.

  However, in a heating system using cooking utensils heated in a steam atmosphere such as a steam convection oven, it is necessary to use a container such as tableware that is resistant to heat and steam because of the steam function and the oven function. Currently, porcelain is used. However, since porcelain is heavy and burdensome on workability and may be damaged, there is a problem that the use of an automatic washing machine is limited.

  Patent Documents 1 and 2 describe a steam convection oven and a food cooking method using the same.

JP-A-9-119642 JP 2005-110570 A

Therefore, in view of the above-described conventional technology, the object of the present invention is to prevent contamination even when used in a long-time steam atmosphere such as heating in a steam atmosphere such as a steam convection oven or heat insulation in a steam atmosphere. The object of the present invention is to develop a thermosetting resin molded container and a method for producing the same that can suppress deterioration due to deterioration of gloss and the like.

According to the present invention, a cooked food is heated with a cooking utensil that is heated in a steam atmosphere, or a container for use in keeping warm in a steam atmosphere, the container having melamine on the inner and outer surfaces. A heating or heat retaining container provided in a steam atmosphere , which is a molded product of a thermosetting melamine resin having a glaze coating layer coated with a molding coating composition containing a guanamine cocondensation resin, is provided.

According to the present invention, when manufacturing a heating or heat-retaining container provided in the steam atmosphere using a concave mold and a convex mold, (a) the mold is closed. A thermosetting melamine resin base is molded on the convex mold (or in the concave mold), and (b) at least one molding coating composition containing a melamine / guanamine cocondensation resin on the surface of the base Perform glaze coating molding, (c) move the molding from the convex mold side to the concave mold side (or from the concave mold side to the convex mold side), and (d) concave mold side (or convex mold) It is manufactured by continuously performing a series of steps of performing glaze coating molding of a composition for molding coating containing at least one melamine / guanamine cocondensation resin on the surface of the molded article attached to the mold side), From the convex mold side of the molded product when opening the mold of c) The movement from the cavity side to the mold side (or from the concave mold side to the convex mold side) is carried out by placing the burr part that has flowed out of the cavity during molding of the substrate with a moving plate fixed to the mold. The manufacturing method of the container for the heating or the heat retention provided in a vapor | steam atmosphere characterized by these is provided.

According to the present invention, the cooked food is steam convection oven by glaze-coating a molding coating composition containing a melamine / guanamine cocondensation resin on the inner and outer surfaces of a container such as tableware obtained by compression molding a thermosetting melamine resin. When heating with, etc., problems such as degradation due to hydrolysis reaction in conventional synthetic resin containers are reduced, and it is lighter than conventional porcelain and there is no risk of breakage, so automatic washing machines can be used, so workability is extremely high It can be excellent, and the double-sided glaze coating eliminates the problems of prolonged steam exposure.

According to the present invention, as described above, a container that can withstand heating in a steam convection oven can be obtained by glaze-coating a molding coating composition containing a melamine / guanamine cocondensation resin on the inner and outer surfaces of a thermosetting melamine resin container. The following advantages can be obtained.

1) Compared with the conventional melamine tableware, it became possible to reheat and arrange in a steam convection oven.
2) Since it is arranged in the hotel pan with the serving, it can be solved that it is heavy like conventional porcelain and places a burden on workability.
3) Since there is less damage than porcelain, an automatic washing machine can be used, and a series of operations such as lowering, cleaning, disinfection and storage can be performed smoothly.
4) Since the functions and applications of the conventional melamine tableware remain as they are, the same container can be used as it is in the conventional cook chill system and cook serve system.
5) By coating both sides of the lid, it is possible to reheat the menu for a menu that should be reheated with the lid covered (also effective for steam generated from food).

Containers that can be used for heating with cooking utensils that use a steam atmosphere such as a steam convection oven used in the present invention are cellulose (α-cellulose), wood flour, sulfite pulp, kenaf pulp, linter pulp, hemp pulp, bamboo pulp, and the like. A thermosetting melamine resin containing a filler such as an organic material containing non-wood pulp is compression-molded and manufactured. As the thermosetting resin used here, it is most preferable to use a melamine resin from the viewpoint of high surface hardness, excellent heat retention and heat resistance, appropriate specific gravity for handling, and freedom of coloring. Can be used for tableware grade melamine resin, etc., which is suitable for food hygiene tests. As these resins, commercially available products (for example, Nicaret MC manufactured by Nippon Carbide Industries Co., Ltd.) can be used.

In the present invention, the inner and outer surfaces of the thermosetting resin molded container (both the lid and the main body in the case of a container with a lid) are formed once or more with a molding coating composition containing a melamine / guanamine cocondensation resin , The glaze coating is preferably performed once or twice. Although there is no restriction | limiting in particular in coating thickness, When durability is considered, it is preferable that it is 30-80 micrometers.

Although there is no limitation in particular in the composition for shaping | molding coating | cover containing the melamine guanamine cocondensation resin used by this invention, "Nika glaze" marketed by Nippon Carbide Industries Co., Ltd. can be used especially.

The melamine / guanamine cocondensation resin in the composition for molding coating containing the melamine / guanamine cocondensation resin used in the present invention is obtained by reacting melamine with guanamines such as benzoguanamine, acetoguanamine, CTU-guanamine and formaldehyde. It is done. The melamine / formaldehyde resin (hereinafter sometimes abbreviated as “melamine resin”) is preferably a molar ratio of melamine to formaldehyde of 1: 1.5 to 1: 4.5, more preferably 1: 2 to 1: 3. Can be obtained by reacting in an aqueous solution by a known method. At that time, the reaction is completed in about 10 to 100 minutes by reacting at a melamine concentration of 20 to 60%, a reaction temperature of 40 to 100 ° C., and weakly acidic to weakly alkaline. The obtained initial condensate aqueous solution is made into a solid powdery melamine resin by an industrial production method such as spray drying. At that time, if the molar ratio of formaldehyde to melamine is small, the processability is lowered and the reaction rate is slow, which is not preferable. If it is large, the melamine resin becomes slightly brittle, which is not preferable.

  On the other hand, a guanamine / formaldehyde resin (hereinafter sometimes abbreviated as “guanamine resin”) is a known method having about 1 to 12 moles of benzoguanamine, acetoguanamine, CTU-guanamine and formaldehyde with respect to 1 mole of guanamines. It can obtain by making it react. Furthermore, the melamine / guanamine / formaldehyde resin (hereinafter sometimes abbreviated as “co-condensation resin”) can be reacted in a known manner at about 2 to 10 moles with respect to 1 mole of the total mole ratio of melamine and guanamine. I can do it. By blending the melamine resin with a guanamine resin or a co-condensation resin, water resistance and stain resistance can be further improved.

The heating or heat retaining container provided in the steam atmosphere according to the present invention can be manufactured, for example, as follows. That is, in general, the thermosetting resin 1 is compression-molded using the concave mold 3 on the convex mold 2 as shown in steps (1) to (7) of FIG. Hold the molded product (substrate) 4 (see steps (1) and (2) in FIG. 1), and then, as shown in steps (5) and (6) in FIG. 1, the melamine / guanamine co-condensation The glaze 5 of the molding coating composition containing a resin is placed on the outer surface 6 of the molded product, and the glaze 5 is coated using the concave mold 3. In this case, the molded product 7 is glaze-coated on the outer surface, but the glaze 5 coating layer is not formed on the inner surface 8 thereof.

  Further, when these molded products are used particularly as tableware, a pattern or pattern is often put on the surface of the molded product 7 in order to increase the commercial value. In this case, the process (3 in FIG. ) To (4) are added, and special printed paper (foil) 9 with a resin impregnated and dried is molded, and gloss is lowered on it as described above in steps (5) to (6) of FIG. In general, the glaze 5 is coated by using the concave mold 3 in order to prevent deterioration due to contamination and the like.

  As described above, shallow flat tableware such as a normal dish is provided with a pattern on the inner surface on which food is to be placed, and in the case of a thermosetting resin molded product, this glaze layer is formed by performing a glaze coating on it. By this, it is possible to suppress the adhesion and stains of the dishes placed on the inner surface.

  However, deep three-dimensional tableware such as cups, cups, bowls, bowls, bowls, etc., especially in the case of thermosetting resin molded products, apply a pattern only to the outer surface that is often seen, and apply glaze coating molding on it. It is common to do it. Therefore, the glaze layer is not formed on the inner surface in contact with food. For this reason, teacups, cups, etc. are in direct contact with drinks, etc., so that dirt adheres to them due to tea astringents, coffee, etc., and the inner surface becomes dirty and the gloss also decreases. Also, if the dirt is removed with a hard object such as nylon scrubber or cleanser, the inner surface will be scratched and the dirt will be more easily attached. Also, when washing dishes, in order to soften the residue attached to the dishes, it is often immersed in hot water for a long time, but at this time, the residue remains attached to the surface without the glaze layer and is easily contaminated. is there.

  In order to solve such a problem, first, a glaze coating layer is provided on the inner surface of the molded product using two types of molds, and then the semi-molded product is taken out from the concave mold and transferred to the convex mold. A method of providing a glaze coating layer on the outer surface of an object is also known. However, in this method, the semi-molded product is taken out once in the middle of the process and transferred to the surface of another mold (convex mold), so the manufacturing process is discontinuous, and the semi-molded product is removed from the mold. Since it is left as it is, it is cooled and molding shrinkage begins. Since the shrinkage of this molding shrinkage changes with time, it must be manufactured in anticipation of the shrinkage when another mold (convex mold) is produced. However, it is difficult to determine the expected amount, and there is a problem that there is a restriction on the molding operation such as leaving the standing time after taking out the semi-finished product to some extent in order to ensure a constant deformation amount. . As those skilled in the art know that a thermosetting material is a material in which it is difficult to keep the molding shrinkage speed constant for each production lot of the material, the expected shrinkage depends on experience. In particular, there is a problem that control of process operation becomes complicated and defective products are likely to be generated.

  A preferred method for producing the thermosetting resin molded container according to the present invention is as shown in steps (1) to (11) in FIGS. 2 and 3, and steps (1) and (2) in FIG. As in the case, the thermosetting resin 11 is compression-molded on the convex mold 12 to hold the molded product. The glaze 15 of the melamine resin molding coating composition is formed on the outer surface 16 of the molded article 14 using the concave mold 13 in the same manner as in the conventional method (see step (5) in FIGS. 2 and 3). Then, as shown in steps (9) to (10) of FIGS. 2 and 3, the glaze surface of the molded product outer surface 16 is attached to the concave mold, and the molded product 17 The glaze 15 is coated on the inner surface 18 of the substrate. In order to obtain such a thermosetting resin molded article 17, when the outer surface 16 of the molding 14 is subjected to glaze coating, and the convex mold 12 and the concave mold 13 are opened during the inner glaze coating in the next process, As shown in step (9), the semi-molded product must be moved to the concave mold 13 side on which the glaze coating is applied.

  When a thermosetting resin molding material is compression molded, as is well known to those skilled in the art, the amount of resin input is adjusted so that some excess material overflows from the mold cavity. If this extra material is not supplied, sufficient pressure will not be applied to the molded product, resulting in poor strength and gloss, and a satisfactory molded product cannot be obtained. In the present invention, this overflowed portion 21 (called “burr”) is used so that the burr portion 21 comes into close contact with the moving plate 22 attached to the mold on one side, as shown in FIG. ing. In the following description, the burr portion 21 shown in FIG.

  Hook means 23 are attached to both ends of the moving plate 22, and as shown in FIGS. 4 (1) and (2), the moving plate fixing means is attached to one of the concave mold 13 and the convex mold 12. 23, for example, a structure that can be connected by hook means 23. If the hook means 23 for fixing the moving plate 22 is connected to the convex mold 12, the moving plate 22 moves to the convex mold side, and if connected to the concave mold 13, the moving plate 22 moves to the concave mold side. The fabricated burr 21 is also moved up and down by the movable plate 22.

  The shape of the moving plate 22 in contact with the portion of the fabrication burr 21 that holds the movement of the molded product is not particularly limited, and may be a circle, a square, an ellipse, or other shapes depending on the shape of the molded product. Further, the part of the moving plate 22 that is in contact with the fabrication burr 21 may be the entire circumference or a part of the fabrication burr 21 as long as the half-molded product being molded can be moved.

  According to the present invention, glaze coating can be applied to the inner surface 18 of the molded article 17 by the steps (9) and (10) of FIGS. 2 and 3 in the same manner as in the steps (5) and (6).

  In the preferred embodiment of the present invention, FIG. 1 has been described in steps (3) and (4) or / and steps (7) and (8) of FIGS. 2 and 3 on the outer surface and / or inner surface of the molded article 17. The pattern can be formed on the inner surface and / or the outer surface of the final molded product by foil molding in the same manner as described above.

Hereinafter, in an example of manufacturing a container using a melamine resin molding material (Nicarette MC manufactured by Nippon Carbide Industries Co., Ltd.), the embodiments of the present invention are shown in steps (1) to (11) shown in FIGS. In the following, an example in which the inner surface and the outer surface are respectively painted and glaze coating molding is performed on both surfaces will be described with reference to the drawings. In addition, Nippon Carbide Industries Co., Ltd. product Nika glaze C-6 (The composition for molding coating containing a melamine guanamine cocondensation resin) was used for the composition for melamine resin molding coating used for glaze coating.

The molding conditions of the sample used for the long-time exposure test with a steamer are as follows.
Molded product: 丼 of 16cm outer diameter x 7.5cm height Mold surface temperature: concave mold 176 ° C (measurement position bottom)
Convex mold 173 ° C (measurement position top surface)
Materials used: Nicarette MC CT5720Z or Nica Glaze C-6 manufactured by Nippon Carbide Industries Co., Ltd.
Preheating temperature: 120 ° C

  The molding pressure is a value calculated from the projected area of the molded product and the ram diameter of the press used, and the molding time is an elapsed time after reaching a predetermined molding pressure.

  Steps (1) to (6) in FIGS. 2 and 3 are steps for painting the outer surface of the molded product and performing glaze coating thereon, and steps (7) to (10) are for painting the inner surface. Step (11) shows a step of taking out the finished product.

  First, in step (1) of FIGS. 2 and 3, the melamine resin molding material 11 is supplied between the convex mold 12 and the concave mold 13, and in step (2) of FIGS. 2 and 3, the mold is closed and molded. A material base 14 is formed. The molding conditions are determined according to the type of the thermosetting resin to be used and the molded product as before, and there are no requirements specific to the present invention. In the step (3) of FIGS. 2 and 3, a printed paper (foil) 19 with a picture made by impregnating a resin (eg, melamine resin) on the outer surface 16 of the green molded body on the convex mold 12 and drying is supplied from the outside. In step (4), the mold is closed and the foil is fusion-molded under predetermined conditions (for example, 150 to 180 ° C. × 15 to 60 seconds, most preferably 160 ° C. × 30 seconds in the case of melamine resin). 2 and 3, the mold 19 is opened to form the foil 19, and the glaze 15 is supplied. In step (6), glaze coating is performed. In the step (7), when the mold is opened, the foil 19 is supplied to the convex mold 12 in the state that the molded product has moved toward the concave mold 13 as in the above. Close the mold and form the foil. As a result, the foil 19 is fused to the inner surface of the molded product. In step (9), glaze 15 is supplied between the foil layer on the inner surface and the convex mold, and in step (10), the mold is closed to perform glaze coating on the inner surface of the molded product. Through the above steps, a molded product 17 in which a foil and a glaze coating are applied to the inner and outer surfaces of the molded product can be obtained.

  The molded product thus obtained is painted on both the outer surface and the inner surface of the molded product and glaze-coated on both sides, so that contamination over time and gloss reduction with use, etc. There is an advantage that the deterioration due to can be suppressed.

  Next, supply of foil to the outer surface of steps (3) and (5) in FIGS. 2 and 3 and position of the molded product in supplying glaze and supply of foil to the inner surface of steps (7) and (9) The movement of the molded product when supplying the glaze will be described.

  This mold has the structure shown in (1) to (4) of FIG. 4, and (1) and (2) of FIG. 4 are side views of the mold closed, respectively. 4 shows a state in which it is hung on the lower mold, that is, the convex mold 12 and the concave mold 13 of the upper mold. FIG. 4 (3) shows a state between the concave mold 13 and the convex mold 12. The moving plate 22 is shown, and (4) in FIG. Reference numeral 25 denotes a molded product. By hooking the hook 23 on the rod 24 of either the concave mold or the convex mold with the mold closed, the movable plate 22 moves up and down in the connected direction when the mold is opened. It can be set as the structure which a molded article moves with it. The number of hooks 23 is usually two, one on the opposite side of FIGS. 4 (1) and 4 (2), but more may be provided. In order for the molded product to move up and down, as shown in FIG. 4 (4), since the molding burr 21 of the molded product is supported by the moving plate 22, the molding burr 21 needs to be strong. Become.

  The state of the moving plate 22 in the molding process is as shown in the side views (1) to (11) of FIG. That is, first, (1) to (6) in FIG. 3 shows a state in which the hook 23 is hung on the convex mold 12 from the molding of the substrate to the painting of the outer surface and the glaze coating molding, and the molding is attached to the convex mold 12. Indicates. Next, (7) to (10) in FIG. 3 sequentially show the state in which the hook 23 is hooked on the concave mold 13 and the moving plate 22 is attached to the concave mold 13 and the molded product is similarly moved accordingly.

  In addition, the dimension of the construction burr | flash part 21 which touches a movement plate is although it does not specifically limit, Thickness 0.2-5mm is preferable, Thickness 0.3-1mm is still more preferable, and width 0.3-50mm is preferable More preferably, the width is 1 to 20 mm.

  If the thickness is less than 0.2 mm, the molded burr is not strong enough to move the molded product, and the created burr may be damaged. If the thickness exceeds 5 mm, the finishing operation for removing the created burr becomes difficult. If the width is less than 0.3 mm, the burr portion may not be applied to the moving plate due to molding shrinkage. If the width exceeds 50 mm, it is difficult to finish the removal of the fabricated burr portion.

  About the melamine resin container manufactured as mentioned above, the contamination test was done with the following method. First, 1440 cc of water was put into a stainless steel container, and 80 g of Nescafe (trademark), 45 g of Creep (trademark) and 50 g of sugar were placed therein. This is about 4 to 5 times the concentration of normal coffee drinking. In this, the container of the embodiment of the present invention and the container of the conventional comparative example (similarly, painting and glaze coating only on the outer surface) are immersed, and then a holed lid is formed, and water is evaporated in the hole. Attach a reflux cooler to prevent this, and boil continuously for 6, 12 and 24 hours. The results are shown in Table II below.

  Contamination values in Table II are "0" for no coloration and "10" for brown coloration. At the same time, gloss is also inspected and "0" for no change. Was visually evaluated stepwise as “10”.

  As described above, the degree of contamination on the inner surface of the comparative example is very large, and the degree of contamination on the inner surface and the outer surface of the molded product is small for the contamination of the example. In addition, the gloss of the example did not decrease on the inner surface and the outer surface, whereas the gloss of the inner surface of the comparative example decreased.

  Thus, the containers manufactured as in the examples are very advantageous for preventing coffee contamination, and other foods such as tea and seasonings are considered to have the same effect. In addition, there is an effect of suppressing a reduction in gloss. Deteriorated gloss cannot be recovered with detergents or bleaches, so prevention of loss of gloss is very important for maintaining the value of tableware.

  The vapor exposure test of the double-sided glaze-coated molded product sample obtained above and the molded product without the glaze coating was performed as follows.

Prolonged vapor exposure and staining with rhodamine solution by inspection or testing type steamer

In the past cases of inspection / test purposes , there were complaints that the surface coated with glaze was rough and not whitened, but the surface not coated was rough and whitened. An investigation was made as to whether double-coated products can withstand prolonged steam exposure.

Inspection method Fill the pan with water and boil it to generate steam, place the molded product with double-sided coating and the uncoated molded product on the steamer with the inside facing down, cover the pan, and total Placed in a steam atmosphere for 200 hours. After 200 hours of exposure, a 0.1% rhodamine aqueous solution was applied to the surface of the sample, washed with water, and then the rough skin state was judged based on the degree of dyeing of the rhodamine aqueous solution.

Specimen double-sided coating product 1 Solid color product 1

A melamine resin molding material for commercial tableware (trade name “Nicaret MC” CT5720Z, manufactured by Nippon Carbide Industries Co., Ltd.) was used to mold a bowl, and the powder of the above-mentioned commercially available melamine resin molding coating composition for tableware (Japan) Carbide Kogyo Co., Ltd., trade name “Nika glaze C-6”) 1 sample coated on both sides and 1 uncoated sample The most of the surface of the molded product is stained with rhodamine on both the inside and outside Has been. In particular, remarkable results appear on the inside which has always been exposed to steam.
As for what is coated on both sides, there is almost no dyed part on both the inside and outside in the glaze-coated part.
By glaze coating, it seems that rough skin caused by steam can be reduced.

As described above, the present invention provides a double-sided glaze coating composition containing a melamine / guanamine cocondensation resin on both the inner and outer surfaces of a thermosetting melamine resin- molded container as needed. By coating, even when heated in a steam convection oven for cooked foods or for a long period of time in a steam atmosphere such as keeping warm in a steam atmosphere, deterioration due to contamination or loss of gloss during use is suppressed. A large number of hot meals can be served at a time, such as hospitals, elderly facilities, schools, employee cafeterias, etc., and dishes can be washed with an automatic washing machine. It is useful to use as a tableware for collective meals.

It is drawing explaining the shaping | molding process which manufactures the conventional thermosetting resin molded product. It is drawing explaining the shaping | molding process which manufactures the thermosetting resin molded product of this invention. It is explanatory drawing which shows the state outside the metal mold | die of the shaping | molding process which manufactures the thermosetting resin molded product of this invention. It is explanatory drawing which shows the moving mechanism of the semi-molded product of this invention. It is drawing which shows an example of the movement plate of this invention apparatus, and its fixing device.

1,11 Thermosetting resin 2,12 Convex mold 3,13 Concave mold 4,14 Molded article (base)
5,15 Glaze 6,16 Outer surface of molded product 7,17 Molded product after glaze coating 8,18 Inner surface of molded product 9,19 Foil 21 Fabrication burr 22 Moving plate 23 Moving plate fixing means (hook means)
24 Rod 25 Molded product

Claims (3)

A container for heating and eating a cooked food with a cooking tool that heats the cooked food under a steam atmosphere, or a container for keeping warm in a steam atmosphere, the container containing a melamine / guanamine cocondensation resin on the inner and outer surfaces a molded article of thermosetting melamine resin having a glaze coating layer coated with a molding coating composition comprising, heating or heat insulating containers are subjected under vapor atmosphere. In manufacturing a heating or heat retaining container provided in a steam atmosphere according to claim 1 using a mold comprising a concave mold and a convex mold, (a) the convex mold is closed by closing the mold Forming a thermosetting melamine resin substrate on top (or in a concave mold), and (b) forming at least one glaze coating of a molding coating composition containing a melamine / guanamine cocondensation resin on the surface of the substrate. (C) move the molding from the convex mold side to the concave mold side (or from the concave mold side to the convex mold side), and (d) to the concave mold side (or the convex mold side). Produced by continuously performing a series of steps of performing a glaze coating molding of a composition for molding coating containing at least one melamine / guanamine cocondensation resin on the surface of the adhered molded product, the gold in the step (c) From the convex mold side of the molded product when opening the mold, the concave mold side (or The movement of from concave mold side convex mold side) to, and performs the burr portion of the flowing out from the cavity during the molding of the green body, and diacetic mobile plate fixed to the mold, A method for producing a heating or warming container provided in a steam atmosphere. A container for heating or keeping warm under a steam atmosphere or a container for heating and cooking with a cooking utensil that heats the cooked food produced by the method of claim 2 under a steam atmosphere.

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