JPH0739729U - Vacuum insulation device - Google Patents

Abstract

(57) [Summary] [Purpose] Various types of heat insulation walls such as refrigerators, mobile coolers, bathtubs, building walls, and heat insulation pipes that can be used for hot water supply pipes, refrigerant transportation pipes, etc. To provide a new vacuum insulation device that can be applied to materials and instruments. [Structure] The air in the middle of the double wall is evacuated, and the inner wall of the double wall facing the vacuum is plated to prevent heat radiation. In the apparatus, at least one of the double walls forming the vacuum space is made of plastic or ceramic, and the inner wall is electroless copper-plated.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a vacuum heat insulating device that uses a high vacuum in a heat insulating container (a thermos bottle), a heat insulating wall, a heat insulating transport pipe, etc. for the purpose of keeping heat and cold.

[0002]

[Prior art]

 At present, vacuum-insulated containers called thermos, which have a double-walled inner surface plated with silver or copper to remove air in the middle to enhance heat insulation and cooling, are mainly made of metal such as stainless steel. . In the past, there were times when glass was the mainstream, but glass thermos bottles are vulnerable to shocks and are inconvenient to carry, so these days they are rarely used except in special cases.

The life of the thermos lies in its ability to keep warm and cool. It is the reduction of heat conduction from the mouth and the reduction of heat radiation through the double wall that determines performance. In the commercially available thermos, the mouth is narrowed down to reduce the heat conduction from the mouth, and in order to further reduce the heat emissivity, the vacuum layer is plated with metal such as silver or copper with a low heat emissivity. However, it is applied using electroplating or vacuum deposition.

At present, the reason why the thermos bottle is made of stainless steel and has the above-mentioned structure is that the characteristics of the stainless steel material are skillfully utilized. Among the various metals, the ones that belong to the category with the lowest thermal conductivity are stainless steel and titanium (recently, titanium-made thermos bottles are also commercial products), which are inexpensive and do not rust. Is used. That is, a stainless steel plate having poor heat conductivity is further added to 0.3 to 0. The thickness is reduced to about 4 mm, and the neck is made thinner so that the amount of heat lost from the mouth due to heat conduction is minimized. However, the emissivity of stainless steel is 0. Since it is as large as 3, the thermal radiant energy lost through the double wall is large and the heat insulation is poor. In order to prevent this, the inner surface of the double wall of stainless steel is plated with silver or copper having a heat radiation rate of 0.03 or less.

Techniques indispensable for manufacturing this stainless steel thermos are plastic working, welding, and vacuum sealing. Plastic working, so-called drawing, is mainly performed by repeating pressing and heat treatment. Since it is technically difficult to integrally process the entire thermos, it is plastically processed in several parts, and finally butt welded to form the shape of the bottle. Also, since stainless steel is heavy, it must be processed as thinly as possible, but the thinner the thickness, the worse the weldability. Since the gaps and pinholes that occur during welding are the biggest defects of products, it is essential to pay close attention and inspect them after manufacturing. In addition, the shape is limited because it is difficult to machine the whole body. Therefore, the ratio of the cost required for plastic working, welding, and inspection to the product cost is very large. Although it is a stainless steel thermos that is a product that is convenient because it does not break and is free to carry, it is still not sufficient in terms of weight, shape, heat and cold insulation, and cost for the above reasons. Absent.

[0006] On the other hand, plastic is a material which is by far the most advantageous in terms of weight, shape, heat retention / cooling property, and cost. Particularly recently, a composite plastic called an engineering plastic has been developed, and a material having a weight-specific strength three times that of stainless steel has also appeared. Furthermore, the thermal conductivity rate of plastic is smaller than that of stainless steel by one digit or more. Therefore, a magic bottle that does not use the vacuum heat insulation method, which positively utilizes the low thermal conductivity of plastic, has been commercialized. However, the heat insulation and cold insulation are far behind those of the vacuum insulation method.

[0007] Therefore, a plastic high-vacuum insulating thermos is conceivable. However, since plastics generally have high hygroscopicity, high gas permeability, and weakness against heat, even if plastic is used to form a double-layered vacuum insulation layer, a high-vacuum insulation thermos is manufactured. Even if it does, the high-vacuum state cannot be maintained due to the gas that permeates the plastic wall after vacuum sealing, and the vacuum heat insulating effect is lost.

Further, in order to prevent energy lost due to heat radiation, silver or copper having a low emissivity must be plated on the inner wall of the vacuum. Conventionally, a vacuum vapor deposition method has been used for plating plastic. Has been used. However, when plating on plastics by vacuum evaporation, unevenness occurs on the evaporation surface and no evaporation occurs at the shadow part from the evaporation source, so it has a barrier property against the gas generated from the plastic. I can't. For these reasons, plastic high-vacuum insulating thermos bottles have not been commercialized, and walls and heat-insulating transport tubes have not yet been commercialized.

Compared to glass, baked products (ceramics) have been used as a container for a long time because they are less likely to be broken than glass, are resistant to thermal shock, are highly heat-retaining, and can be manufactured at low cost. However, since it is porous, leakage will occur when water is added. In order to prevent this, the pottery is coated with a glass superior agent and sintered. However, even if the drug is applied, if the baked product is used as a vacuum container or a heat insulator, the barrier property against gas permeability is insufficient and it is difficult to maintain a high vacuum state. Moreover, even if a high-vacuum insulator for a baked product is manufactured, the heat-insulating effect cannot be exhibited without metal plating with a low emissivity to prevent heat radiation, but this was done by conventional vacuum evaporation. Then, not only does it not have a perfect barrier property, but it also becomes very expensive, and the low cost of ceramics is lost. For these reasons, vacuum insulation walls (brick) have not yet been developed.

Copper pipes are used as transport pipes for hot water and cooler refrigerants in industrial and general households. This is because copper has excellent heat resistance and corrosion resistance, good thermal conductivity, and low thermal emissivity. However, if it is left as it is, the heat lost from the outer wall or the heat entering it is large and the heat insulation is poor. Therefore, the outer wall is surrounded by a heat insulating material such as glass wool or Styrofoam. However, even if such measures are taken, they are still insufficient and improvement is desired.

[0011]

[Problems to be solved by the device]

 However, the present invention has been made in view of such a situation as described above, and its purpose is to eliminate the defects in vacuum of plastic and ceramics (ceramic) materials, and to reduce weight, shape, heat retention and cold insulation. From the standpoint of efficiency and cost, we provide plastic high vacuum insulation thermos, which goes beyond conventional stainless steel thermos, and further develop this principle to use insulation walls that can be used for refrigerators, mobile coolers, bathtubs, construction walls, etc. The company intends to provide a new vacuum insulation device that can be applied to various materials and appliances that require heat insulation and cold insulation, such as adiabatic transport pipes that can be used as hot water supply pipes and refrigerant transport pipes.

[0012]

[Means for Solving the Problems]

 In order to achieve the above-mentioned object, the air in the middle of the double wall is evacuated, and the inner wall of the double wall facing the sky is plated with heat radiation to prevent heat and cold, a heat insulating plate, a heat insulating plate, In a vacuum heat insulating device such as a heat insulating transport pipe, at least one of the double walls forming the vacuum space is made of plastic or ceramic, and the inner wall is electroless copper plated. Is.

[0013]

[Action]

 According to the present invention, the double wall forming the vacuum heat insulation is made of plastic, and the inner surface of the double wall is electroless copper plated, which is a dense metal film. This copper plating layer acts as a barrier layer against gas permeation and moisture absorption, and due to the low emissivity of copper, the heat lost by radiation can be minimized. For this reason, the electroless copper-plated plastic thermos bottle according to the present invention has a high vacuum heat insulation effect superior to that of the stainless steel thermos bottle in terms of weight, shape, heat / cold retention, and cost.

Further, according to the present invention, the copper plating layer functions as a barrier layer against gas permeation and moisture absorption, which are the biggest drawbacks of plastics and ceramics, and the low thermal emissivity of copper causes radiation. The heat lost by can be minimized. Therefore, the electroless copper-plated plastic or ceramic plate of the present invention can provide a new high-vacuum insulation wall, block, plate, etc. in terms of weight, shape, heat / cold retention, and cost. is there.

Furthermore, according to the present invention, at least one of the double walls forming the vacuum heat insulation is made of plastic or ceramic, and the inner surface of the vacuum is subjected to electroless copper plating which is a dense metal film. However, the copper plating layer acts as a barrier layer against gas permeation and moisture absorption, which are the main drawbacks of plastics and ceramics, and the low heat emissivity of copper minimizes the heat lost by radiation. can do. Therefore, the double pipe of the present invention, which is used with electroless copper-plated plastic or ceramic pipe, can obtain a new high-vacuum heat-insulated transport pipe in terms of weight, shape, heat and cold insulation, and cost. is there.

[0016] Although there are many advantages of electroless copper plating, first of all, since electricity is not required at all and plating can be performed simply by penetrating an object to be plated into the bath, it is very inexpensive and non-conductive. Moreover, even if a thermos, wall, or pipe with a complicated shape is immersed in the plating solution, all surfaces can be plated uniformly. Therefore, the electroless copper plating can be applied after the plastic or ceramic is integrally molded (after bonding or sintering), so that the plastic or ceramic is covered with the complete barrier layer of the electroless copper plating film. It is possible to completely block the gas release from the ceramics to the vacuum side. In addition, even if there is a slight leak in the plastic or ceramic container, the plating layer can block this leak during electroless copper plating. High vacuum insulation can be maintained for a long period of time if a vacuum is applied and vacuum sealed.

[0017]

【Example】

 Hereinafter, the present invention will be described with reference to the illustrated embodiments. In FIG. 1, reference numeral 1 is a high-vacuum heat-insulating thermos bottle made of polycarbonate plastic material. The container is composed of a cylindrical outer container 2 and an inner container 3, and has a continuous integral structure at the upper part 4. Alternatively, the outer container 2 and the inner container 3 may be manufactured separately and then bonded or welded at the upper portion 4. An exhaust port 5 is provided below the outer container 2.

After the container is manufactured, the container is turned upside down, and a chemical agent is injected into the space 6 formed by the double wall of the outer container 2 and the inner container 3 from the exhaust port 5 to perform pretreatment, and Electrolytic copper plating is applied to form a uniform copper thin film 7. At this time, the scratches on the bonding portion of the upper portion 4 and the pinholes 8 at other portions are covered with the electroless copper plating film and closed. A suitable plating thickness is 5 to 50 μm. After the electroless plating, the container is dried and heat-treated at a temperature of 100 ° C to 180 ° C in the air. After cooling, the lid 7 is bonded to the exhaust port 5 in a high vacuum and vacuum-sealed.

Since the portion of the plastic thermos which is in contact with the atmosphere is plastic, coloring and surface irregularities can be freely added. Therefore, it is possible to add animal motifs and design the shape freely.

It is also possible to metallize the non-vacuum side of the plastic by electroless plating. That is, in the embodiment of FIG. 1, if the surface 10 is electrolessly nickel-plated, it is possible to prevent the surface from being scratched or soiled.

In FIG. 1, reference numeral 11 denotes a stopper of a thermos bottle, the outer portion of which is covered with plastic 12. Then, an embodiment in the case where the present invention is applied to the plug 11 to manufacture it will be described. The lid that has been used so far is a plastic cap filled with Styrofoam, and is not insulated from the air. Therefore, the heat lost through this cap was very large. In the stopper 11 of the embodiment of FIG. 1, the radiant energy lost through the cap is the same as the side surface of the thermos, and the loss of conduction is only the plastic 12 portion. Since the thermal conductivity of plastic is about an order of magnitude lower than that of stainless steel, it is possible to provide a thermos bottle with excellent heat retention and cold retention. Here, 13 is a silicone rubber, which is used as a packing of the container.

FIG. 2 shows another embodiment of the present invention, which is a partial cutaway view of a block when the present invention is applied to a block of building material. The rectangular block 14 is manufactured by baking 16 of plastic or clay. In the embodiment of FIG. 2, electroless copper plating chemicals are put in through the holes 15 and a uniform copper plating 7 is applied to the inner surface of the block. After drying, the hole 15 is vacuum-sealed by vacuum baking. In particular, when the block is made of ceramic, high temperature baking at 300 to 400 ° C. is possible, so that the highest performance high vacuum heat insulating material can be obtained.

FIG. 3 shows still another embodiment of the present invention, in which the present invention is applied to a refrigerator or a plate material for building materials. Since the walls 17, 18 are under a pressure of about 1 kg / cm ^2, a large number of struts to withstand this are required between the two walls 17, 18. The embodiment shown in FIG. 3 shows a case where this support is reinforced by a wall 20 provided with a partially cut window 19. In the case of the present invention, since these columns are made of plastic or ceramic having low heat conductivity, heat escaping through this reinforcing wall (column) can be minimized. Further, even if there are many reinforcing walls (supports), electroless copper plating chemicals are put into the holes 21 and uniform copper plating is applied to the inner surfaces of the walls 17 and 18 and the reinforcing walls (supports) 20. .. Similarly, after drying, baking is performed in a vacuum, and the hole 21 is vacuum-sealed.

FIG. 4 is a side cross-sectional view of another embodiment of the present invention when the present invention is applied to an adiabatic transportation pipe. The outer tube 22 is made of porcelain ceramics and is joined to the copper pipe 23 at the joint 24. Reference numeral 25 is a hole for performing electroless copper plating and evacuating. Similarly, a pressure of about 1 kg / cm ² is applied to the pipe 24, but since the pipe 24 is a pipe, no reinforcement column is required. The copper pipe may be made of the same ceramic as the outer tube 22, or may be made of all plastic instead of the ceramic. If this transport pipe is manufactured to the same standard, the pipe tip 26 can be joined to the other end 27 of another transport pipe to provide a long-distance insulated transport pipe.

[0025]

[Effect of device]

 Since the present invention is configured as described in detail above, the following effects can be obtained.

(1) Since electroless copper plating is performed in the final step after assembling the thermos and the vacuum heat insulator, the fundamental performance as a vacuum container such as gas release and leak due to the difference in material and manufacturing method. Degrading fabrication defects can be repaired by the barrier properties of electroless copper plating, thus providing a very simple, inexpensive and reliable thermos or vacuum insulation.

(2) Electroless copper plating does not require electricity at all, and plating can be performed only by penetrating the object to be plated into the bath, so that even a complex-shaped object can be plated uniformly. Since it is possible to block the inflow of gas to the vacuum side with one thin and dense garment seamless barrier layer, it is possible to provide an ultralight vacuum insulation container or vacuum insulation.

[Brief description of drawings]

FIG. 1 is a side cross-sectional view of a vacuum heat insulating container (a thermos bottle) for heat insulation and cold insulation and a vacuum heat insulation stopper according to an embodiment of the present invention.

FIG. 2 is a partially cutaway perspective view of a vacuum heat insulating block according to an embodiment of the present invention.

FIG. 3 is a partially cutaway perspective view of a vacuum heat insulating wall according to an embodiment of the present invention.

FIG. 4 is a side sectional view of a vacuum heat insulating transport tube according to an embodiment of the present invention.

[Explanation of symbols]

 1 Vacuum Insulation Container (Vacuum Bottle) 2 Outer Cylinder 3 Inner Cylinder 4 Joint of Outer Cylinder and Inner Cylinder 5 Exhaust Port 6 High Vacuum Part 7 Electroless Copper Plating Coating 8 Pinhole 9 Vacuum Sealing Plug 10 Outer Wall 11 Vacuum Insulation Plug 12 Plastic 13 Silicon rubber 14 Vacuum insulation block 15 Block exhaust port 16 Ceramic 17 Upper panel 18 Lower panel 19 Cut-out window 20 Reinforcement wall 21 Panel exhaust port 22 Ceramic outer pipe 23 Copper inner pipe 24 Joint part 25 Double pipe exhaust port

Claims (1)

[Scope of utility model registration request] 1. The air in the middle of the double wall is evacuated.
In a vacuum heat insulation device such as a heat insulation / cold insulation vacuum container, a heat insulation plate, and a heat insulation transport pipe, in which the inner wall of the heavy wall facing the vacuum is plated with heat radiation, at least one of the double walls forming a vacuum space A vacuum heat insulating apparatus, characterized in that the wall is made of plastic or ceramic, and the inner wall is plated with electroless copper.