JPS62169980A - Vessel for cooling - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a cooling container that is flexible and can take any shape.

[Prior art]

Most conventional cooling containers are made of metal or plastic and contain a refrigerant such as ice or dry ice. These cooling containers are not flexible, so their uses are limited by their shape, and the outside surface of the container gets wet or sticky, making it difficult to wet objects placed on the container and wiping off the wet outside surface of the container.

[Purpose of the invention]

The present invention is not a container that is not flexible and has a fixed shape like the conventional metal or plastic cooling containers mentioned above, but can take any shape, and has an excellent cooling effect. The present invention provides a cooling container having:

[Structure of the invention]

The cooling container of the present invention that achieves the above object comprises a selectively permeable organic polymer base material that is liquid impermeable but gas permeable, and a reinforcing base material provided on at least one surface of the base material. a container having a water pressure resistance of at least 300
mm HzO/7.

The cooling container of the present invention is a composite sheet comprising a selectively permeable organic polymer base material that is liquid-impermeable but gas permeable, and a reinforcing base material provided on at least one surface of this base material. This container has a water pressure resistance of at least 300 mmH 0/cII!, and a liquid is stored in the container.

A container with water pressure resistance within the above range allows vapor, especially water vapor, to pass through, but liquid, especially water itself, does not pass through. Therefore, the liquid stored in the container made of this composite sheet-like material There is virtually no water leakage from inside the container.

What is important is that when the container is placed in the atmosphere, water vapor is transferred to the container through the permselective organic polymer base material, which is impermeable to liquids but permeable to gases. Evaporates and dissipates outside.

When the liquid changes from liquid to vapor, the temperature of the stored liquid decreases by absorbing the latent heat of vaporization, and becomes at least the temperature of the outside air.

Therefore, when an object to be cooled is placed in the container of the present invention, the object can be cooled to below the outside air temperature.

Furthermore, since the container of the present invention is flexible and has a fabric shape that can take any form, it can cool the object substantially regardless of the form of the object to be cooled.

The permselective organic polymer base material constituting the composite sheet in the present invention can be composed of any polymer, but the average pore size is 0.01 to 100μ, preferably 0.
．． It has continuous pores of 1 to 50μ, more preferably 0.3 to 5μ, and especially has a moisture permeability of at least 3000g/td,
Preferably 5000g/rr? Above, water pressure resistance is at least 300mm H2O/crA, preferably 500
mm H, O/co! or more, preferably 700 m
It is preferable to form a microporous structure having a performance of mH□O/cut or higher.

That is, when the average pore diameter becomes smaller than 0.01μ,
This is undesirable because the vapor permeability decreases and the cooling effect becomes small or slow.

Preferred examples of polymers that form such microporous membranes include polyurethane polymers, silicone polymers, fluoropolymers such as polytetrafluoroethylene and polytrifluoroethylene, and polyolefins represented by polyethylene. There are some types of polymers, but it is not limited to these.

Examples of the method for forming the microporous permselective organic polymer base material of the present invention using such a polymer include a dry coagulation method, a wet coagulation method, or a combination thereof.

For example, JP 60-47955 (wet type), JP 60-190393 (dry type), JP 59-1259
The microporous membrane forming method described in No. 74 (dry method, wet method) can be applied.

In addition, it is recommended to treat this microporous polymer membrane with a fluorine-based or silicone-based water repellent to make it hydrophobic. You can improve your sexual performance.

In addition, as a reinforcing base material that constitutes a composite sheet-like product,
It is not particularly limited as long as it is flexible and effective in reinforcing the membrane. For example, specific examples include various knitted fabrics, nonwoven fabrics, net fabrics, and cotton-like materials such as fleece.

The fineness of the fibers constituting such a base material is not particularly limited as long as it has a reinforcing effect, but usually there is no problem as long as it is about 0.01μ or more.

Generally, the greater the fineness, the greater the reinforcing effect, and it may be selected depending on the application, but usually about 10 d is sufficient.

In addition, when the permselective organic polymer base material or reinforcing base material is treated with a water repellent, the water repellency is improved and the average pore diameter is 1.
Even if the average pore diameter exceeds 00μ, the water pressure resistance may be satisfied, and it is also possible to apply a membrane with an even larger average pore diameter.

This point also applies when the permselective organic polymer base material is a fibrous structure.

As the fibrous structure, fabric strips such as non-woven fabrics and woven and knitted fabrics can be used, but it is important that these fabrics have a water pressure resistance of at least 300 mm H0/crA.

Such fabrics are usually obtained by making them denser by adjusting the fiber density and fineness, or by treating them with a water repellent.

The higher the water pressure resistance is, the better, and it is preferable to select it depending on the application.

However, in the composite sheet material constituting the container of the present invention, it is preferable that a microporous membrane forms the inner surface of the container, which improves the mechanical strength and durability of the container. There is no need to limit it to.

Furthermore, the liquid stored in the container is preferably a liquid with a large latent heat of vaporization, especially water, from the viewpoint of cooling effect, but in order to increase the cooling rate, a liquid miscible with water such as methanol or ethanol may be mixed. Optionally, a high boiling water miscible liquid such as glycerin or glycol can be mixed to slow the rate of evaporation of the reservoir liquid.

Hereinafter, one specific example of the cooling container according to the present invention will be explained with reference to the drawings.

The figure is a sectional view showing 1!3 types of cooling containers according to the present invention, in which 1 is a container, 2 is a composite sheet-like material, 3 is a permselective organic polymer base material, 4 is a reinforcing base material, 5 represents water, and 6 represents the object to be cooled.

As shown in the figure, a container 1 is composed of a composite sheet-like material 2, a permselective organic polymer base material 3 forming the sheet-like material 2 forms the inner surface of the container, and a reinforcing base material 4 forms the outer surface of the container. is forming.

Water 5 is stored inside the container 1, and an object to be cooled 6 is stored inside the container 1.

The object to be cooled 6 housed in the liquid cooling container 1 of the present invention having such a configuration generates water vapor when the water 5 stored in the container passes through the microporous organic polymer base material 3. At the same time, the latent heat of vaporization at this time lowers the temperature of the stored water 5, and as the temperature of this stored water decreases, the object to be cooled 6 is cooled. teyu (no deru)

〔Effect of the invention〕

As is clear from the above, the effects of the present invention are as follows:
It can effectively cool any type of object to be cooled, and since the outer surface of the container does not get wet or sticky like conventional metal or plastic containers, the objects around the cooling container will become wet. No problems at all.

Another advantage is that constant cooling is possible because liquids, such as water itself, which is extremely easily available, can be used as a cooling medium instead of a specially processed cooling medium such as ice or dry ice as in conventional cooling containers. has.

Examples of the present invention will be described below.

〔Example〕

Polyester filament plain weave with water pressure resistance of 1000m
m%O/ an! , moisture permeability 6000 g/rd
・A polyurethane polymer was coated on only one side and wet solidified for 24 hours.

Using this fabric, the volume of section 5 shown in the drawing is 500 m.
A flexible container having a volume of 10,100 O was prepared for the portion J and 6.

On the other hand, as a comparison product, the volume is 100100O made of aluminum.
I prepared a water bottle.

After pouring 450 mA water into part 5 of the flexible container, 6
Insert a fully curved tea caddy with a volume of 900 mj2 into the part, and 800 m1 inside! of water and made a hole in the lid of the tea caddy.

I also filled an aluminum water bottle with 800 m/m of water and made a hole in the lid of the water bottle's mouthpiece.

A copper-constantan thermocouple was inserted into each hole so that changes in the temperature of the water could be read.

These containers were placed in a room adjusted to a temperature of 35° C. and a relative humidity of 40%, and it was observed how the temperature of the water changed.

After about 2 hours, the temperature of the water in the tea caddy, which is inserted into a container made of a fabric coated with a polyurethane polymer, reaches about 29°C.
℃, and the temperature was maintained until 8 hours after the measurement was continued (measurement was discontinued after 8 hours).

On the other hand, the water temperature in the aluminum water bottle was approximately 35°C, which is similar to room temperature, throughout the 8-hour measurement period.

[Brief explanation of drawings]

The figure is a sectional view showing an example of the cooling container according to the present invention. 1... Fabric-like cooling container, 2... Composite sheet-like material, 3
...Microporous polymer film, 4. Reinforcing base material, 5.
・Water, 6...Object to be cooled.

Claims (1)

[Scope of Claims] 1. A container comprising a permselective organic polymer base material that is liquid impermeable but gas permeable, and a reinforcing base material provided on at least one surface of the base material. A cooling container, characterized in that the container has a water pressure resistance of at least 300 mm H_2O/cm^2. 2. The cooling container according to claim 1, wherein the permselective organic polymer base material is a continuous microporous synthetic polymer membrane. 3. The synthetic polymer continuous microporous membrane has an average pore diameter of about 0.01 to
The cooling container according to claim 2, which has a diameter of 100μ. 4. The cooling container according to claim 1, wherein the permselective organic polymer base material is a fibrous structure. 5. The cooling container according to claim 1, wherein the permselective organic polymer base material contains a water repellent.