JPS6212167B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a convenient dry ice maker. More specifically, the present invention relates to a dry ice manufacturing apparatus that utilizes the physical property of liquefied carbonic acid in a high pressure state being rapidly returned to a pressure below the triple point and cooled to solid carbonic acid.

Dry ice is a product that has a wide range of uses, including food freezing and medical use, and the demand for it is increasing year by year.

However, dry ice easily sublimates,
If the amount of dry ice used is large and constant, it is possible to install a storage warehouse to store the dry ice transported from the production area and take out the required amount for use, but even with this method, there is a considerable amount of loss. is unavoidable. Moreover, if the amount used is relatively small and non-regular, it would be wasteful to install a storage space for this purpose, and the loss due to sublimation would be too great to purchase and keep dry ice in case it is needed. It is uneconomical.

By keeping a liquefied carbon dioxide cylinder on hand, the dry ice production device of the present invention can not only supply the above-mentioned relatively small amount and irregular demand, but also instantly and easily produce the required amount of dry ice as needed. The purpose of this invention is to provide a lightweight device that can be supplied with

That is, the gist of the present invention is that the lower part of a cylindrical cylinder having an edge on the upper lid and the inner circumferential part of the lower end,
A perforated plate with a strainer on the top surface and a nozzle that penetrates the support frame and spouts out liquefied carbon dioxide are provided, and a relief plate is provided at the top of the cylinder top cover that penetrates the cylinder top cover that is screwed to a frame fixed to the cylinder support frame. The dry ice maker has a structure in which a valve is provided, a removable grip is attached to the side of the cylinder, and the nozzle is connected to a liquefied carbon dioxide inlet and a flow rate control valve to manufacture and fill dry ice into the cylinder. .

Hereinafter, in order to clarify the mechanism of the dry ice maker of the present invention, specific examples will be shown and explained in sequence with reference to the drawings.

FIG. 1 is a sectional view showing the structure of a dry ice manufacturing device according to the present invention.

Liquefied carbon dioxide sent from a cylinder (not shown) passes through a joint 1 and flows into a valve 2. The valve 2 is a type of valve that can finely adjust the pressure of liquefied carbon dioxide, and for example, a needle valve can be advantageously used. The high-pressure liquefied carbon dioxide whose flow rate is adjusted by the valve 2 is released and blown out from the nozzle 3, and at the same time forms snow (snowflake-like dry ice) and fills the cylinder 4. The shape of the nozzle 3 is such that in order to eject snow at an appropriate outflow speed into the cylinder 4, a square pin is installed inside a nozzle hole with an inner diameter of about 3 mm, and the gap between the holes, that is, 4
From experience, it is appropriate to have a structure in which the liquid is ejected from individual arcuate portions, but of course the shape is not limited to this.

A wire mesh 5 and cloth 6 are installed as strainers between the nozzle 3 and the lower part of the cylinder 4.
This wire mesh 5 serves to discharge snow into the cylinder 4 and carbon dioxide gas to the outside through the holes in the perforated plate 7 when liquefied carbon dioxide is ejected. For this reason, snow is accumulated in the cylinder 4 one after another and becomes a hard block of dry ice.

The lower part of the cylinder 4 has a packing groove 8, into which a packing 9 is attached, which fits into a protrusion 11 provided on a frame 10 equipped with a carbon dioxide gas hole for supporting the bottom of the cylinder, and a cover cup 12, which will be described later. The upper cover 13 is pressed together with the upper cover 13. The upper cover 13 has a packing groove 14 at the top of the cylinder 4.
The packing 15 is attached to the cylinder 4 and is fitted into the protrusion 16 of the cylinder 4.

A relief valve 17 is provided in the center of the upper lid 13.

The inside of the cylinder 4 is filled with snow, the internal gas resistance increases, and the snow is gradually pressurized.Finally, the blown carbon dioxide gas is discharged from the relief valve 17, and the desired dry ice is filled inside the cylinder 4. You can see what you have accomplished. It is also possible to adjust the hardness of the dry ice produced by changing the set pressure of this relief valve, and usually the gauge pressure is about 1 to 5 kg/ ^cm2 , preferably 4 kg/cm2.
Set around cm ² .

The above-mentioned upper lid 13 has an integral structure with the cover cup 12, and the cover cup 12 is connected to be able to move up and down by a screw shaft 18 provided with a handle 20, and the screw shaft 18 is screwed onto a U-shaped frame 19. This screw shaft 18 is rotated by a cross-shaped handle 20, which is rotated by hand to open the cover cup 12 and the top lid 1.
3, and to take out the finished dry ice, all you have to do is loosen the cross handle 20 and remove the cylinder 4.

The cover cup 12 not only has the function of pressing the upper lid 13, but also has a structure in which the relief valve 17 is wrapped around the relief valve 17 for the purpose of dispersing and discharging a small amount of carbon dioxide gas in the cylinder.

The cylinder 4 has an edge on the inner circumference of the lower end to prevent the dry ice from sliding down even when the cylinder 4 is removed after molding.

The dry ice formed in cylinder 4 is -70℃
Since it solidifies at a temperature below, the temperature of the outer wall of the cylinder also drops to around -50℃ through the cylinder wall. If you touch the cylinder 4 with bare hands in this state, there is a risk of instant frostbite. Therefore, in order to prevent this, a removable grip 21 is attached to the side of the cylinder. The grip 21 has a protrusion at the bottom with a spring 22, a hole is made in the wall of the cylinder 4 to accommodate this protrusion, and the upper part of the grip 21 is made such that a pin 23 fits snugly into a support 24 provided on the wall. So the cylinder can be held.

With such a structure, it can be easily attached to the cylinder 4 in which dry ice has been formed, and the dry ice in the cylinder can be safely taken out from the dry ice maker.

Producing dry ice with a dry ice maker,
A wire mesh cover may be attached to the entire dry ice maker as a measure against abnormal ejection of carbon dioxide gas from inside.

In the present invention, a method of forming distance pieces by inserting distance pieces of various shapes into a cylinder can be adopted for the purpose of producing dry ice of various sizes or shapes from one dry ice production machine. can.

2 and 3 are cross-sectional views showing examples of distance pieces inserted into the cylinder. Figure 2 shows an example in which a distance piece 27 with the same height but a smaller diameter is inserted into the cylinder 26, and Figure 3 shows a distance piece 28 with approximately the same diameter but with a lower height to obtain dry ice. This is an example of insertion.

The distance piece can be made of metal, but if you use one made of synthetic resin foam for the gap with the cylinder or for the entire body, it will not only have a better insulation effect but also be dangerous if it comes into contact with a cold cylinder. is preferable because it has less

In addition to the distance pieces shown in the figures, distance pieces that can be used in the present invention can be placed in a cylinder in various shapes depending on the desired shape of dry ice, thereby making it possible to obtain dry ice of different shapes.

The size of the dry ice maker of the present invention is not particularly limited, and the size of the cylinder may be determined as appropriate;
mm, height of 100 to 120 mm is conveniently used.

The cylinder and other materials of the dry ice maker may be made of stainless steel, mild steel, aluminum, brass, or other commonly used metals, and no special materials are required. It is also convenient to have the grip made of plastic as it has a heat insulating effect.

As mentioned above, the dry ice production device of the present invention can easily obtain dry ice at any time (about 2 to 3 minutes for about 600 g) as long as a cylinder of liquefied carbon dioxide is always on hand. It is extremely convenient when relatively small amounts are used irregularly, such as in the laboratory.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing the structure of a dry ice manufacturing device of the present invention, and FIGS. 2 and 3 are sectional views showing an example of a distance piece inserted into a cylinder.

Claims (1)

[Scope of Claims] 1. A cylindrical cylinder having an edge on the inner circumference of the upper lid and the lower end is provided with a perforated plate having a strainer on the upper surface and a nozzle for ejecting liquefied carbon dioxide through the support frame, and A relief valve is installed at the top of the cylinder top cover, which is screwed onto a frame fixed to the cylinder support frame, and a removable grip is installed on the side of the cylinder. A dry ice manufacturing device connected to a control valve to manufacture and fill dry ice into the cylinder. 2. The dry ice manufacturing device according to claim 1, wherein distance pieces of various shapes are provided in the cylinder. 3. The dry ice manufacturing device according to claim 2, wherein the distance piece is a synthetic resin foam.