JP3003256U - Insulated tableware - Google Patents

Abstract

(57) [Summary] [Purpose] To provide a heat-insulating tableware made of plastic, which is capable of imparting a design effect while maintaining heat resistance. [Structure] Outer shell members 22 and 3 that form the outer shape of tableware
2 and the inner shell members 20 and 30 forming the inner surface shape are formed by injection molding, and the hollow chambers 26 and 36 formed by joining both members are filled with the heat insulating materials 24 and 34, and In a plastic heat-insulating tableware having thread bottoms 14 and 16 protruding from the outer surface of the tableware, the outer shell members 22 and 32 and the thread bottoms 28 and 38 forming the thread bottoms 14 and 16 are colored with each other. It is characterized in that it is formed of a different color resin different from each other and both members are fused and integrated.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to heat-insulating tableware, and more specifically, a hollow chamber formed by injection molding an outer shell member forming an outer surface shape and an inner shell member forming an inner surface shape of the tableware. It relates to a plastic heat-insulating tableware that is filled with heat insulating material.

[0002]

[Prior art]

 The tableware used for lunch at hospitals, etc. uses plastic heat-insulating tableware to prevent warm food from being cooled as much as possible or to prevent cold food from being heated as much as possible. There is. As such heat-insulating tableware, there are often used those in which a hollow chamber formed by joining an outer shell member forming the outer surface shape of the tableware and an inner shell member forming the inner surface shape is filled with a heat insulating material. There is.

[0003]

[Problems to be solved by the device]

 According to such heat-insulating tableware, it is possible to eat the dish on the tableware at a temperature close to that at the time of cooking, even after a certain amount of time has passed since the dish was prepared. Therefore, when a certain amount of time elapses between the time when a dish is served on a dish and the time when the dish is eaten, such as a lunch at a hospital, the heat-insulating tableware can be preferably used. However, in hospitals and the like, heat-insulating tableware is subjected to disinfection with hot water, so the outer shell member that forms the outer surface shape of the heat-insulating tableware and the inner shell member that forms the inner surface shape are made of heat-resistant resin. I have no choice but to do it. Furthermore, since the heat-insulating tableware is used for lunch at hospitals and the like, a large amount of tableware having the same shape is required. For this reason, generally, the outer shell member and the inner shell member constituting the heat-insulating tableware are molded by injection molding of a thermoplastic resin. Therefore, the outer shell member of the heat-insulating tableware is usually one color because it is difficult to give an elegant pattern to the outer surface like an eating device formed of a thermosetting melamine resin. Therefore, the conventional heat-retaining tableware has a poor design effect. In addition, some hospitals may require different meals from other patients, but it is convenient for the caterer serving each patient to be able to distinguish the meal content from the appearance of the tableware. Therefore, an object of the present invention is to provide a heat-insulating tableware made of plastic, which can impart a design effect and the like while maintaining heat resistance.

[0004]

[Means for Solving the Problems]

 In order to achieve the above-mentioned object, the inventors of the present invention first applied a pattern or the like to the heat-insulating tableware by printing or painting, and found that the heat or heat applied to the eating device in each step of washing, drying, and boiling water It has been found that the friction causes peeling of the paint, which makes it unusable for long-term use. For this reason, the inventors of the present invention have made heat resistance by welding to the outer shell member of the heat-insulating tableware a thread bottom member that is injection-molded with a resin of the same quality as the resin forming the outer shell member and different in color from each other. The inventors have found that it is possible to add a design effect to plastic heat-insulating tableware without impairing the temperature, and have reached the present invention.

That is, according to the present invention, the outer shell member forming the outer surface shape of the tableware and the inner shell member forming the inner surface shape are formed by injection molding, and both members are joined together. In a plastic heat-insulating tableware in which a hollow chamber is filled with a heat insulating material and a thread bottom is projected from the outer surface of the tableware, the outer shell member and the thread bottom member forming the thread bottom have different colors from each other. The heat-insulating tableware is characterized in that it is formed of a different color resin and that both members are fused and integrated. In the present invention having such a configuration, by forming the outer shell member and the thread bottom member with resins having compatibility with each other, it is possible to reliably fuse and integrate both members. At this time, by molding the yarn bottom member by injection molding using a resin of the same quality as the resin forming the outer shell member, it is possible to easily form a yarn bottom member having the same heat resistance and other characteristics as the outer shell member. By forming the undercut portion which can be fitted with a part of the thread bottom member on the outer shell member, it is possible to prevent the thread bottom member and the outer shell member from being separated from each other.

In addition, when the hollow chamber filled with the heat insulating material is depressurized at room temperature, when heat-insulating tableware is subjected to hot water sterilization, the air in the hollow chamber expands and the inner shell member It is possible to prevent separation from the shell member. By using such a heat insulating material as a mixture of organic synthetic fibers and inorganic fibers, it is possible to maintain a uniform filled state of the heat insulating material in the hollow chamber for a long period of time. In particular, when both organic synthetic fibers and inorganic fibers are short fibers, both fibers can be easily and uniformly mixed. By forming such a mixture ratio of the organic synthetic fiber and the inorganic fiber to be 2 to 150 parts by weight of the organic synthetic fiber per 100 parts by weight of the inorganic fiber, a molded article for a heat insulating material which is bulky and exhibits a good compression recovery property is formed. The hollow chamber can be uniformly filled with a heat insulating material. As the organic synthetic fiber, organic synthetic fiber having heat resistance against hot water disinfection temperature of tableware is used, and as the inorganic fiber, rock wool, glass fiber, or ceramic fiber is used. A heat insulating material having heat resistance can be obtained. In particular, when aramid fibers as organic synthetic fibers and aluminosilicate fibers as inorganic fibers are mixed, a heat insulating material having good heat resistance can be easily obtained.

Furthermore, by using the heat-retaining tableware according to the present invention as a tableware for lunch used for lunch in a hospital or the like, even if a certain amount of time has passed since the dish was cooked, the temperature close to that when the patient is cooking You can eat food at. Therefore, by forming the heat-insulating tableware from the bowl portion and the lid portion, it is possible to sufficiently maintain the heat of the served food. The "color" referred to in the present invention includes not only chromatic colors but also achromatic colors such as white and black.

[0008]

According to the heat-insulating tableware of the present invention, the outer shell member that forms the outer surface of the tableware and the thread-bottom member that forms the thread-bottom part, which are separately molded by different color resins having different colors, are fused together. It has been transformed. As a result, the outer surface of the heat-insulating tableware and the thread bottom can be made different in color, and a design effect can be imparted to the heat-insulating tableware. Since such a different color resin can be easily obtained by mixing pigments and dyes having different colors in the same resin, it is possible to form a different color thread bottom member with the same resin as the outer shell member, The thread bottom member is firmly fused and integrated, and the heat resistance of the thread bottom member can be made comparable to that of the outer shell member.

[0009]

【Example】

 The present invention will be described in more detail with reference to the drawings. FIG. 1 is a partial cross-sectional front view showing an embodiment of heat-insulating tableware according to the present invention. The tableware of FIG. 1 comprises a bowl portion 10 and a lid portion 12, and thread bottom portions 14 and 16 project from the outer surfaces of the bowl portion 10 and the lid portion 12, respectively. Each of the bowl portion 10 and the lid portion 12 is composed of the outer shell members 22 and 32 forming the outer shape of the tableware and the inner shell members 20 and 30 forming the inner shape of the tableware. The surfaces 23 and 33 are joined. The outer shell members 22 and 32 and the inner shell members 20 and 30 are formed by injection molding using a thermoplastic resin. Examples of the thermoplastic resin include polypropylene, polyethylene, ABS resin, polycarbonate, methacryl, polysulfone, saturated polyester, and a mixture thereof, and a polyester alloy in which a polyester resin is mixed with a polycarbonate resin is preferable.

In the present embodiment, the thread bottom portions 14 and 16 formed on the bowl portion 10 and the lid portion 12 have the thread bottom members 28 and 38 integrally fused to the outer shell members 22 and 32. Since the thread bottom members 28 and 38 are formed of a different color resin having a different color from the resin forming the fusion-integrated outer shell members 22 and 32, they are integrally fused to the outer shell members 22 and 32. The changed yarn bottom members 28 and 38 have different colors. By using resins having compatibility with each other as the resin forming the thread bottom members 28, 38 and the outer shell members 22, 32, it is possible to easily fuse both members. In particular, the thread bottom members 28 and 38 and the outer shell members 22 and 32 are made of the same resin having different colors, and the thread bottom members 28 and 38 are injection-molded, so that both members can be easily welded, In addition, the heat resistance of the thread bottom members 28, 38 can be made approximately the same as that of the outer shell members 22, 32. As described above, the outer shell members 22 and 32 that are fused and integrated with the thread bottom members 28 and 38 have a part of the thread bottom members 28 and 38 as shown in FIG. It is preferable to form the undercut portions 25 and 35 to be fitted with each other from the viewpoint of preventing separation of both members. The different color resin can be easily prepared by adding a pigment, a dye or the like to the resin, and a dispersant or the like may be added in order to improve the dispersion of the pigment or the like.

As shown in FIG. 1, the outer shell members 22 and 32 and the inner shell members 20 and 30 in which the thread bottom members 28 and 38 are fused and integrated are joined at joint surfaces 23 and 33 to form a hollow chamber. 26 and 36 are formed. The hollow chambers 26 and 36 are decompressed at room temperature and filled with heat insulating materials 24 and 34. Therefore, when heat-insulating tableware is subjected to disinfection with hot water, the air in the hollow chambers 26 and 36 expands, peeling the joint between the outer shell members 22 and 32 and the inner shell members 20 and 30, and deforming the tableware. Etc. can be prevented. In addition, the heat insulating materials 24 and 34 filled in the hollow chambers 26 and 36 prevent convection of air in the hollow chambers 26 and 36 and suppress heat transfer due to convection as much as possible to enhance the heat retention effect. it can.

The heat insulating materials 24 and 34 used in this embodiment are a mixture of organic synthetic fibers and inorganic fibers. In this way, by mixing both fibers, the uniformly mixed organic synthetic fibers absorb and alleviate the mechanical shock applied to the heat insulating materials 24 and 34 and prevent the inorganic fibers from being damaged. Even if it is used for a long period of time, it is difficult to cause deterioration of the physical properties and shape change of the heat insulating materials 24 and 34. By using short fibers as both the organic synthetic fiber and the inorganic fiber, both fibers can be easily and uniformly mixed. The short fibers used in this example are organic synthetic short fibers having a fiber length of about 0.5 to 20 mm (especially 0.8 to 5 mm) and fiber lengths of about 1 to 30 mm (preferably 1 to 30 mm). It is preferable to use 10 mm) of inorganic short fibers. By mixing such an organic synthetic fiber and an inorganic fiber with 2 to 150 parts by weight of the organic synthetic fiber per 100 parts by weight of the inorganic fiber, a molded article for a heat insulating material, which is bulky and exhibits a good compression recovery property, can be obtained. Molding is possible and the hollow chambers 26, 36 can be uniformly filled with the heat insulating materials 24, 34.

As the organic synthetic fibers constituting the heat insulating materials 24 and 34, organic synthetic fibers having heat resistance to the boiling sterilization temperature of tableware, such as polyvinyl alcohol fiber, polyester fiber, polypropylene fiber, polyamide fiber, Acrylic fibers, aramid fibers and the like can be mentioned, and aramid fibers are particularly preferable because they have excellent heat resistance. Here, since cellulose fibers, wool, and the like, which are typical organic fibers, have hygroscopicity, they may absorb moisture even if minute cracks are formed in the tableware body and cause bacterial contamination. Moreover, rock wool, glass fiber, and ceramic fiber can be mentioned as the inorganic fiber, and aluminosilicate fiber, alumina fiber, mullite fiber, silica fiber, magnesia fiber can be mentioned as the ceramic fiber. Of these inorganic fibers, aluminosilicate fibers are preferred because they are flexible and difficult to break. Therefore, in this example, the heat insulating material obtained by mixing the aramid fiber as the organic synthetic fiber and the aluminosilicate fiber as the inorganic fiber can be preferably used.

To manufacture the heat-insulating tableware shown in FIG. 1, first, the outer shell members 22, 32 and the inner shell members 20, 30 are molded by injection molding of a thermoplastic resin. The outer shell members 22 and 32 and the inner shell members 20 and 30 may be formed of the same color resin or different color resins. Next, for the injection-molded outer shell members 22 and 32, the thread bottom members 28 and 38 are molded by injection molding using a different color resin having a different color from the resin forming each of the outer shell members 22 and 32. After that, both members are fused and integrated. The different color resin used in this embodiment can be easily obtained by mixing the same resin as the resin forming each of the outer shell members 22 and 32 with a pigment, a dye or the like. It is preferable that the thread bottom members 28, 38 and the outer shell members 22, 32 are fused before the injection-molded outer shell members 22, 32 are cooled to a temperature below the part temperature. In particular, it is preferable to injection-mold the yarn bottom members 28 and 38 without taking out the outer shell members 22 and 32 from the injection-molded mold.

On the other hand, the heat insulating materials 24 and 34 are formed into a predetermined shape. As a method of molding the heat insulating materials 24 and 34, a wet molding method is suitable. In such a wet molding method, a predetermined amount of an organic synthetic fiber and an inorganic fiber are put into a dispersion liquid to which a predetermined amount of a binder is added, and the mixture is stirred to uniformly disperse both fibers, followed by dehydration molding. At this time, examples of the binder used include acrylic resin emulsion, vinyl acetate resin emulsion, and natural or synthetic rubber latex. In the dispersion liquid, a coagulant may be added to improve the dehydration moldability, or a water repellent may be added to impart water repellency to the heat insulating material.

The dehydration molding is performed using a mold having a cavity formed according to the shape of the hollow chambers 26 and 36 formed in the heat-insulating tableware, or is dehydrated into a sheet shape. In such dehydration molding, the thickness of the finally obtained heat insulating material molded body is equal to or greater than the distance between the hollow chambers 26 and 36 of the heat retaining device (the distance between the inner wall surfaces of the hollow chambers 26 and 36). To shape. Preferably, the obtained molded article for heat insulating material has a bulk density of about 0.1 to 0.2 g / cm ³ and a thickness of about 1 to 2.5 of the space between the hollow chambers 26, 36 of the tableware. Mold to double. The heat-insulating material molded article thus formed is compressed to a compression elastic recovery rate (weight in the thickness direction of the molded article and compressed to a compression rate of 60%, and that state is maintained for 5 minutes. The thickness of the molded body can be measured 5 minutes after the removal of, and the restoration ratio to the initial thickness of the molded body) can be made good.

The obtained molded body for heat insulating material is sandwiched between the outer shell members 22 and 32 and the inner shell members 20 and 30 in which the thread bottom members 28 and 38 molded previously are integrated, and the outer shell member is formed. 22 and 32 and the inner shell members 20 and 30 are welded at the joint surfaces 23 and 33 of both members. This welding can be performed by ultrasonic welding, hot plate welding, spin welding, vibration welding, etc., in which case the molded body for heat insulating material is formed following the shape of the hollow chambers 26, 36 of the heat insulating container. If it is thicker than the gap between the hollow chambers 26 and 36, the heat insulating material molded body is welded while being compressed. On the other hand, when the molded product for heat insulating material is in the form of a sheet, a cut piece obtained by cutting the molded product for heat insulating material into a predetermined size is provided along one inner wall surface of the outer shell member 22, 32 or the inner shell member 20, 30. Both members are welded while closely contacting each other, and the heat insulating materials 24 and 34 are filled in the hollow chambers 26 and 36. Further, when the outer shell members 22 and 32 are welded to the inner shell members 20 and 30 and the hollow chambers 26 and 36 are under normal pressure, the obtained heat-insulating dishes are served with hot dishes or hot water. When sterilization or the like is performed, the air in the hollow chambers 26 and 36 may expand, and the welding between the outer shell members 22 and 32 and the inner shell members 20 and 30 may be peeled off, or the heat-insulating tableware may be deformed. Therefore, by welding the outer shell members 22 and 32 and the inner shell members 20 and 30 under a reduced pressure of about 300 to 600 mmHg in the hollow chambers 26 and 36, the hollow chambers 26 and 36 are reduced in pressure at room temperature. It is possible to prevent the deformation of heat-insulating tableware when disinfecting with hot water.

The heat-insulating tableware of the present embodiment thus obtained can suppress the convective heat transfer in the hollow chambers 24 and 34 as much as possible, and reduce the heat radiation from the cooked dishes. Further, the heat-insulating tableware is composed of the bowl portion 10 and the lid portion 12, and it is possible to further suppress the heat radiation from the prepared dish. Therefore, even after a certain amount of time has passed since the food was served, the food can be eaten at a temperature close to that at the time of cooking. Moreover, since the thread bottoms 14 and 16 of the heat-insulating tableware of this embodiment are different from the outer shell members 22 and 32, the heat-insulating tableware can be given a design effect. In addition, the color of the thread bottoms 14 and 16 can display the difference in the content of the meal, so that the heat-insulating tableware of this embodiment is suitable as tableware for meals in hospitals and the like.

In the embodiment described above, the thread bottom portion 14 formed on the bowl portion 10 and the thread bottom portion 16 formed on the lid portion 12 may have different colors, and the thread bottom portion 14 or the thread bottom portion One of 16 may be different in color from the outer shell members 22 and 32. Further, it is possible to process a mold on the thread bottoms 14 and 16 to add a pattern, a pattern, characters, or the like, or to make a gradation by utilizing a change in wall thickness and a difference in color shade. it can. Further, the heat-retaining tableware of this embodiment can be applied to rice bowls, soup bowls, plates, bowls, cups, trays, etc., and of course, it can be applied to tableware only of the bowl section 10 without the lid section 12. is there.

[0020]

[Effect of device]

 According to the present invention, it is possible to impart a design effect to heat-insulating tableware while maintaining heat resistance, and it is possible to impart an interesting effect as compared with conventional heat-insulating tableware. In addition, it is possible to distinguish the contents of the food stored in the heat-insulating tableware from the appearance, and it can be suitably used for lunch at a hospital.

[Brief description of drawings]

FIG. 1 is a partial sectional front view showing an embodiment of the present invention.

FIG. 2 is an enlarged partial cross-sectional view of a portion A shown in FIG.

[Explanation of symbols]

 10 Bowl part 12 Lid part 14, 16 Thread bottom part 20, 30 Inner shell member 22, 32 Outer shell member 23, 33 Bonding surface 25, 35 Undercut part 24, 34 Insulating material 26, 36 Hollow chamber 28, 38 Thread bottom member

Claims (12)

[Scope of utility model registration request] 1. An outer shell member forming an outer surface shape of a tableware and an inner shell member forming an inner surface shape are formed by injection molding, and a heat insulating material is provided in a hollow chamber formed by joining both members. In a plastic heat-insulating tableware that is filled and has a thread bottom protruding from the outer surface of the tableware, each of the outer shell member and the thread bottom member that forms the thread bottom is formed of a different color resin. The heat-insulating tableware is characterized in that both members are fused and integrated. 2. The heat-insulating tableware according to claim 1, wherein the outer shell member and the thread bottom member are formed of resins having compatibility with each other. 3. The heat-insulating tableware according to claim 1, wherein the thread bottom member is formed by injection molding using a resin of the same quality as the resin forming the outer shell member. 4. The heat-insulating tableware according to claim 1, wherein an undercut portion that fits with a part of the thread bottom member is formed on the outer shell member. 5. The heat insulating tableware according to claim 1, wherein the hollow chamber filled with the heat insulating material is in a depressurized state at room temperature. 6. The heat insulating tableware according to claim 1, wherein the heat insulating material is a mixture of organic synthetic fibers and inorganic fibers. 7. The heat-insulating tableware according to claim 6, wherein both the organic synthetic fiber and the inorganic fiber are short fibers. 8. The mixing ratio of the organic synthetic fiber and the inorganic fiber is
2 to 150 organic synthetic fibers per 100 parts by weight of inorganic fibers
The heat-insulating tableware according to claim 6 or 7, which is parts by weight. 9. The organic synthetic fiber is an organic synthetic fiber having heat resistance against boiling sterilization temperature of tableware, and the inorganic fiber is rock wool, glass fiber, or ceramic fiber. Insulated tableware according to any one of claims. 10. The organic synthetic fiber is an aramid fiber,
10. The inorganic fiber is an aluminosilicate fiber.
Insulated tableware according to any one of claims. 11. The heat-insulating tableware according to claim 1, wherein the tableware is a tableware for lunch used for lunch in a hospital or the like. 12. The tableware according to claim 1, wherein the tableware includes a bowl portion and a lid portion, and a thread bottom member is formed in each of the bowl portion and the lid portion. Insulated tableware.