JPS63231156A - Ice grain production unit - 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 (Industrial Field of Application) The present invention is utilized in the field of ice making technology, and particularly relates to an ice grain production device.

(Prior art and problems) Ice grains are often used when uniformly mixing powder and water, when performing ice blasting, when cooling gaps, etc., and when cooling drinks. used in

Several methods are conventionally known for producing such rice grains.

First, although ice grains are usually obtained by crushing or scraping ice blocks using mechanical methods, the yield is low and it is unsuitable for producing fine ice particles, and rice grains also become spherical. There are problems such as not being able to get things.

Another method is to make ice cubes directly from water. Three methods are known for this.

The first method is to spray water into cold air at temperatures below 0°C. In this method, the heat exchange between the water droplets and the surrounding cold air is
Since it is based on heat transfer between a liquid and a gas, it is less efficient than the heat exchange between liquids described below. In addition, although it is easy to produce fine particles, it is difficult to produce ice particles with a large diameter (for example, around 5 mm), frost tends to form on the heat exchanger of the cooling device due to cold air, and the cooling efficiency tends to decrease, and the device becomes larger. There are other problems.

Second, droplets of water are dropped on the surface of the cooled metal, etc.
This method involves freezing water droplets on a metal surface.

This method has problems such as poor ice production efficiency and the inability to produce spherical ice particles because water droplets adhere to the metal surface.

The third method is to produce ice grains by injecting water into a cold liquid in which water does not easily dissolve, and is extremely effective from the standpoint of heat exchange. This method can be further divided into two methods depending on the method of cooling the liquid. That is, there are two methods: cooling the liquid using another cold source (such as a refrigerator), and cooling the liquid using the latent heat of vaporization of the liquid.

In the former case, that is, when the liquid is cooled using a separate cold source, an organic solvent such as kerosene or hexane is used as the liquid. The performance required for this liquid is that it has a low assimilation point, is low in toxicity, and does not dissolve in water, and organic liquids such as kerosene, liquid paraffin, and hexane are used. These liquids generally have a lower specific gravity than water, and water droplets and ice particles sink through the solution and accumulate at the bottom of the container. Therefore, in order to take out the ice particles, it is necessary to take out the ice particles together with the liquid using a slurry pump or the like, and to separate the liquid and the ice particles using a centrifugal machine or the like. However, the liquid cannot be completely removed, and it is inevitable that some liquid will remain on the surface of the rice grains. Generally, these liquids are organic solvents and are toxic, which poses an extremely serious obstacle to the utilization of ice particles.

In addition, the latent heat generated when water droplets freeze in a liquid heats up the entire container or the liquid directly, so another cold source (for example, a refrigerator) is used to cool these to maintain a constant temperature of the liquid. Must be kept at low temperature.

In this ice-making method, in order to take out the ice grains from the top of the liquid, it is sufficient to use a liquid with a specific gravity heavier than water, but such a liquid is generally prepared using an organic chlorine solvent (
For example, carbon tetrachloride, trichlorethylene), etc., are extremely toxic and are not suitable for producing ice cubes.

Next, in the latter case of the third method above, that is,
When cooling a liquid using the latent heat of vaporization of the liquid, it is sufficient to use a liquid having an evaporation temperature of O'C or lower, and by using the liquid as iA, no particular refrigeration device is required. Generally, easily available liquid nitrogen or liquid oxygen is used. If these liquids are used, as in the previous example, toxic Ia? This eliminates the drawback that agent 6 remains on the surface of the ice grains. However, liquid oxygen has risks such as explosions, so safe liquid nitrogen (LN2) is often used, but it is expensive and difficult to handle due to its low temperature, and LN also has a specific gravity. Since ice is smaller than water, the ice particles accumulate at the bottom of the container, leaving the problem that a pump such as the one described above is required to continuously remove the ice particles.

(Means for Solving the Problems) The present invention solves the problems of the above-mentioned various ice grain production devices, and in particular effectively obtains ice grains directly from water by using the WI heat of liquid evaporation. The object of the present invention is to provide an improved device in a form that allows for.

In order to achieve the above object, the present invention provides a water inlet at the bottom of a container for storing liquid carbon dioxide gas, a branch pipe extending laterally is connected to the top of the container, and the branch pipe is located inside the container. is provided with a weir for preventing the liquid carbon dioxide from overflowing, and is also equipped with a release valve for the carbon dioxide generated within the container, and a level control means for maintaining the upper level of the liquid carbon dioxide near the weir. has, consists of.

(Function) According to the present invention, which consists of +11 yen, since the liquid carbon dioxide in the container has a higher specific gravity than water, the water supplied from the inlet is cooled as it rises in the liquid carbon dioxide. It turns into ice. At this time, water is spheroidized by surface tension and becomes ice.

The diameter of the ice particles can be adjusted by adjusting the amount of water supplied.

The ice grains that have risen reach the upper surface of the liquid carbon dioxide gas, but since the upper surface level of the liquid carbon dioxide gas is maintained near the weir in the branch pipe, only the rice grains will overflow over the weir. In this way, ice grains can be separated and obtained from liquid carbon dioxide.

Further, when the water turns into ice particles, the latent heat causes the liquid carbon dioxide to evaporate by that amount, which is released through a release valve provided in the branch pipe.

The amount of liquid carbon dioxide that has decreased due to evaporation is constantly replenished by the level control means, and the upper surface level of the liquid carbon dioxide is maintained near the weir to prevent the floating rice grains from overflowing over the weir. do not have.

(Example) Hereinafter, an example of the present invention will be described based on the accompanying drawings.

In FIG. 1, reference numeral 1 denotes a vertically long cylindrical container, the inside of which is filled with liquid carbon dioxide gas 2.

A water inlet 3 is provided at the bottom of the container 1 to which a nozzle (not shown) for supplying an appropriate amount of water W is connected. Note that the water W is injected while being pressurized by a pump (not shown) so that it enters the container against the pressure of liquid carbon dioxide inside the container 1. A heater (not shown) is also provided near the inlet 3 to prevent water from freezing there and blocking the inlet. Furthermore, a replenishment port 4 for liquid carbon dioxide is also provided at the bottom of the container 1 in order to maintain the upper surface of the liquid carbon dioxide in the container at a constant level, which will be described later.

On container l, 5ii1. The section is equipped with a pressure gauge 5 for monitoring internal pressure, a safety valve 6 for safety, and a rupture disc 7.

A branch pipe 8 extending laterally is connected to the upper part of the container 1. A weir 9 is provided in the branch pipe 8, and the liquid is supplied from the supply port 4 by a level control means (not shown) so that the upper surface level of the liquid carbon dioxide 2 is near the weir 9. Carbon dioxide gas is being replenished.

At the upper part of the branch pipe 8, beyond the weir 9, there is provided a release valve 10 for releasing evaporated carbon dioxide gas. The branch pipe 8 has a downward slope at its end, and after passing through a valve 11, it hangs down and is connected to a rice grain storage 12. The rice grain storage container 12 is equipped with a pressure release cock 13 at the top and a valve 14 at the bottom for removing ice grains.

Note that windows 15 provided at the middle and upper part of the container 1
．． 16 is for monitoring.

The procedure for producing ice grains using the apparatus according to the embodiment of the present invention described above will be described below.

(1) First, liquid carbon dioxide gas 2 is injected into the container 1 through the supply port 4 while being monitored through the window 16 so that its upper surface level is near the weir 9 of the branch pipe 8. At that time, for example, the pressure inside the liquid carbon dioxide container is set to 17.14 kg/afl, which corresponds to the evaporation temperature of -25° C., by 3 m 9M. In this case, the discharge pressure of the discharge valve 10 is also set to 17.14 kg/cIA.

(2) In this state, an appropriate amount of water pressurized above the above pressure is injected into the container 1 from the water inlet 3 through a nozzle or the like (not shown). The injected water becomes small droplets within the liquid carbon dioxide gas, and since the specific gravity of the liquid carbon dioxide gas is higher than that of water, the water droplets freeze while evaporating the surrounding liquid carbon dioxide gas and absorbing the latent heat of vaporization. The liquid carbon dioxide rises to the top of the liquid carbon dioxide.

■ Due to the action described in (■) above, many water droplets turn into ice particles one after another and accumulate on the upper surface of the liquid carbon dioxide gas. When the number of ice particles increases to a certain extent, they overflow over the weir 9 and accumulate in the space above the valve 11.

(2) On the other hand, carbon dioxide gas generated by evaporation is released to the outside through the release valve 10. This release lowers the pressure inside the container, and the liquid carbon dioxide can be fired in the kiln to a temperature corresponding to the lowered pressure, and its latent heat keeps the temperature constant. If the release valve 10 is provided at a position ahead of the weir 9, the ice particles will easily exceed N,9 due to the flow of the released gas.

(2) When the ice particles produced in this manner accumulate to a certain extent on the valve 11, the valve 11 is opened to store the ice particles in the ice particle storage device 12, and after the valve 11 is closed, the cock 13 is opened to release the pressure. Thereafter, the valve 14 is opened and the ice particles can be taken out as a product under normal pressure.

According to the present invention, as described above, spherical ice particles can be produced efficiently. !
! However, it is also possible to make rice grains that contain not only pure ice but also other substances.

Generally, when other substances (such as sugar) are dissolved in water and frozen, ice crystals have the property of eliminating impurities, so the other substances mentioned above are uniformly trapped in water at the same concentration as the solution. It's far away. This becomes more noticeable as the freezing rate becomes slower, and the faster the freezing rate becomes, the more uniformly the particles are likely to be trapped. According to the apparatus according to the ice grain manufacturing method of the present invention, water is instantly frozen, so that ice grains in which other substances such as sugar are uniformly mixed can be obtained.

Furthermore, it is possible to produce ice grains that contain other substances either inside or outside. For example, by first producing ice grains corresponding to the interior according to the present invention, and then mixing the above-mentioned ice grains with a solution of pond material serving as the exterior and injecting the mixture into the present device, double-structured rice grains can be produced. can be manufactured.

(Effects of the Invention) As described above, the present invention makes ice by directly and rapidly cooling water by injecting water into liquid carbon dioxide whose upper surface is controlled at a constant level near a weir. Since the floating ice particles are obtained by passing over the weir, the following effects can be obtained.

■ Extremely high productivity as ice can be made continuously.

■ Since the cooling liquid is liquid carbon dioxide, production costs can be reduced and ice grains can be obtained with no concerns about toxicity.

■ Since ice is made in liquid carbon dioxide gas, spherical ice particles can be easily obtained.

■ By changing the nozzle diameter of the water inlet, you can freely set the diameter of the ice particles.

■ Since ice is made by rapidly freezing, it can contain other substances and can have a uniform or multilayered structure.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view of an apparatus according to an embodiment of the present invention. l... Container 2... Liquid carbon dioxide gas 3... Water inlet 8... Branch pipe 9.・・・・・・・・・Weir patent applicant Nippon Kokan Co., Ltd. Agent Patent attorney Fujioka 1 deceased hand υε nail 11 positive awn;
: (Voluntary) June 16, 1985 Commissioner of the Patent Office Black 1) Mr. Akihiro ■, Indication of the case 1988 Patent side No. 062459 2, Name of the invention Ice grain manufacturing device 3, Person making the amendment Case and Relationship Patent Applicant Address 1-2 Marunouchi-chome, Chiyoda-ku, Tokyo Name (412) Nippon Kokan Co., Ltd. Representative Yamaguchi 4, Agent ■150 Telephone 03-770-9040
5. Subject of amendment 6. Contents of amendment As shown in the attached sheet (no changes to the content except for matters stated in the column of subject of amendment) Description ■ 1 Name of the invention Ice grain production device 2 Claims Liquid carbon dioxide A water inlet is provided at the bottom of the container that accommodates the water, and a branch pipe extending horizontally is connected to the top of the container, and the branch pipe is provided with a weir inside to prevent the liquid carbon dioxide from overflowing. A rice grain manufacturing apparatus, further comprising: a release valve for carbon dioxide gas generated in the container; and a level control means for maintaining the upper surface level of the liquid carbon dioxide near a weir. 3. Detailed Description of the Invention (Field of Industrial Application) The present invention is utilized in the field of ice-making technology, and particularly relates to an ice grain production device. (Prior art and problems) Ice grains are often used when uniformly mixing powder and a small amount of water, when performing ice blasting, when cooling gaps, etc., and when cooling drinks. used in Several methods are conventionally known for producing such rice grains. First, although ice grains are usually obtained by crushing or scraping ice blocks using mechanical methods, the yield is low and it is unsuitable for producing fine ice particles, and ice grains are also spherical. There are problems such as not being able to obtain the same. Another method is to make ice cubes directly from water. Three methods are known for this. The first method is to spray water into cold air at temperatures below 0°C. In this method, the heat exchange between the water droplets and the surrounding cold air is
Since it is based on heat transfer between a liquid and a gas, it is less efficient than the heat exchange between liquids described below. In addition, although it is easy to produce fine particles, it is difficult to produce ice particles with a large diameter (for example, after 5 mm), the heat exchanger of the cooling device is easily frosted by water spray, and the cooling efficiency is likely to decrease, and the device is large. There are problems such as compatibility. Second, droplets of water are dropped on the surface of the cooled metal, etc.
This method involves freezing water droplets on a metal surface. This method has problems such as poor ice production efficiency and the inability to produce spherical ice particles because water droplets adhere to the metal surface. Third, is a method of producing ice grains by injecting water into a cold liquid in which water does not easily dissolve, and is extremely effective from the viewpoint of heat exchange. This method can be further divided into two methods depending on the method of cooling the liquid. That is, there are two methods: a method in which the liquid is cooled by another cold heat FJ (such as a refrigerator), and a method in which the liquid is cooled by the latent heat of vaporization of the liquid. In the former case, where the liquid is cooled using a separate cold source,
The performance required for this liquid is that it has a low solidification point, is low in toxicity, and does not dissolve in water, and organic liquids such as kerosene, liquid paraffin, and hexane are used. These liquids generally have a lower specific gravity than water, and water droplets and ice particles sink through the solution and accumulate at the bottom of the container. Therefore, in order to avoid removing the rice grains, it is necessary to remove the ice grains along with the liquid using a slurry pump or the like, and then to separate the ice grains from the liquid using a centrifuge or the like. However, the liquid cannot be completely removed, and it is inevitable that some liquid will remain on the surface of the ice grains. Generally, these liquids are organic solvents and are toxic.
This poses an extremely large obstacle to the utilization of ice particles. In addition, the latent heat generated when water droplets freeze in the liquid causes the liquid to reach ambient temperature, so other cold sources (such as refrigerators)
Therefore, it is necessary to cool these to maintain the temperature of the liquid at a constant low temperature. In this ice-making method, in order to take out the rice grains from the top of the liquid, it is sufficient to use a liquid with a specific gravity heavier than water, but such a liquid is generally prepared using an organic chlorine solvent (
For example, carbon tetrachloride and trichlorethylene) are extremely toxic and are not suitable for producing ice cubes. Next, in the latter case of the third method above, that is,
When cooling a liquid using the latent heat of vaporization of the liquid, it is sufficient to use a liquid whose evaporation temperature is 0° C. or lower, and by purchasing the liquid, a freezing device is not required. Generally, liquid nitrogen or liquid oxygen, which is easy to handle, is used. The use of these liquids eliminates the drawback of toxic organic solvents remaining on the surface of the ice grains as in the previous example. However, liquid oxygen has risks such as explosion, so while safe liquid nitrogen (LN2) is often used, it is difficult to handle due to its low temperature.
LN also has a lower specific gravity than water, and ice particles accumulate at the bottom of the container, leaving the problem that a pump such as the one described above is required to continuously remove the ice particles. (Means for Solving the Problems) The present invention solves the problems of the various ice grain production devices described above, and in particular, it is possible to effectively obtain ice grains directly from water using the latent heat of vaporization of a liquid. The purpose of this invention is to provide an improved device in a manner that is possible. In order to achieve the above object, the present invention provides a water inlet at the bottom of a container that can contain liquid carbon dioxide, and connects a branch pipe extending in the yellow direction to the top of the container, and the branch pipe includes: Inside, there is a vine to prevent the overflow of the liquid carbon dioxide gas, and a release button ↑ for the carbon dioxide gas generated inside the container can be removed, allowing the upper level of the liquid carbon dioxide gas to be placed close to clothing. comprising level control means for maintaining the level. (Effect) It takes fi! According to the present invention, since the liquid carbon dioxide in the container has a higher specific gravity than water within a certain range of conditions, the water supplied from the bottom injection port rises in the liquid carbon dioxide and is cooled. It turns into ice. At this time, water is spheroidized by surface tension and becomes ice. The diameter of the ice particles can be adjusted by adjusting the diameter of the water injection port and the injection flow rate. The rising ice particles reach the upper surface of the liquid carbon dioxide gas, but since the upper surface level of the liquid carbon dioxide gas is maintained near the weir in the branch pipe, only the ice particles overflow beyond the force of the weir. . In this way, ice grains can be separated and obtained from liquid carbon dioxide. Further, when the water turns into ice particles, liquid carbon dioxide gas is emitted in a smaller amount due to its latent heat, and this is emitted through a release valve provided in a branch pipe. Then, the amount of liquid carbon dioxide that has decreased due to evaporation is constantly pulled down by the level control means, and the upper surface level of the liquid carbon dioxide is maintained near the weir so that the floating ice particles can overflow over the weir. There is no problem. (Example) Hereinafter, an example of the present invention will be described based on the accompanying drawings. In FIG. 1, reference numeral 1 denotes a vertically long cylindrical container, the inside of which is filled with liquid carbon dioxide gas 2. At the bottom of the container 1, a water inlet 3 is provided which serves as a nozzle (not shown) for appropriately supplying water W to the silkworms. Note that the water W is injected while being pressurized by a pump (not shown) so that it enters the container against the pressure of liquid carbon dioxide inside the container 1. Note that a heater (not shown) is also provided near the inlet 3 to prevent water from freezing there and blocking the water inlet. Furthermore, a replenishment port 4 for liquid carbon dioxide is provided at the bottom of the container 1 in order to maintain the upper surface of the liquid carbon dioxide in the container at a constant level, which will be described later. The upper end of the container 1 is provided with a pressure gauge 5 for monitoring internal pressure, a safety valve 6 for ensuring safety, and a rupture type safety valve 7. A branch pipe 8 extending laterally is connected to the upper part of the container 1. A weir 9 is provided in the branch pipe 8,
Liquid carbon dioxide gas is replenished from the replenishment port 4 by a level control means (not shown) so that the upper surface level of the liquid carbon dioxide gas 2 is near the weir 9. A discharge valve 10 for discharging evaporated carbon dioxide gas is provided at the upper part of the branch pipe 8 at a position beyond the weir 9. The branch pipe 8 has a downward slope at its end, and is connected to an ice storage device 12 through a valve 11. The ice storage device 12 is equipped with a pressure valve 13 at the top and a valve 14 for removing ice grains at the bottom. Note that the window 15 provided in the middle and upper part of the container l
．． 16 is for monitoring purposes, but this is not necessarily necessary. The procedure for producing rice grains using the apparatus according to the embodiment of the present invention as described above will be explained next. (1) First, liquid carbon dioxide gas 2 is injected into the container 1 through the supply port 4 while being monitored through the window 16 so that its upper surface level is near the weir 9 of the branch pipe 8. At that time, for example, the pressure inside the liquid carbon dioxide container is adjusted to 17.14 kg/ad, which corresponds to the temperature of -25°C. In this case, the discharge pressure of the discharge valve 10 is also set to approximately 17.14 8/cI11. (2) In this state, water pressurized above the above pressure is continuously injected into the container l from the water inlet 3 through a nozzle (not shown). The injected water becomes small droplets within the liquid carbon dioxide gas, and since the liquid carbon dioxide gas has a higher specific gravity than water at the above temperature and pressure, the water droplets emit the surrounding liquid carbon dioxide gas. It freezes while utilizing the latent heat of vaporization and rises to the top of the liquid carbon dioxide. ■ Due to the action described in (2) above, many water droplets turn into ice particles one after another and accumulate on the upper surface of the liquid carbon dioxide gas. When the number of ice particles increases to a certain extent, they overflow over the weir 9, pass through the valve 11, and accumulate in the ice particle storage device 12. (2) On the other hand, carbon dioxide gas produced by evaporation is released to the outside through the release valve 10. This release reduces the pressure inside the container, and the liquid carbon dioxide gas evaporates to a temperature corresponding to the reduced pressure, and its latent heat keeps the temperature constant. In addition, if the release valve 10 is provided at a position ahead of the weir 9, the rice grains will easily cross over the weir 9 due to the flow of the released gas. ■ When the ice grains produced in this way accumulate to a certain extent in the ice grain storage device 12, the valve 11 is closed, the valve 13 is opened to release the pressure, and then the valve 14 is opened to take out the ice grains as a product under normal pressure. Can be done. According to the present invention, spherical ice grains can be efficiently produced as described above, and in addition, ice grains containing not only pure ice but also other substances can be produced. Generally, when other substances (such as sugar) are dissolved in water and frozen, the ice crystals have the property of eliminating impurities, so the other substances are uniformly frozen in ice at the same concentration as the solution. It's difficult to squeeze in. This becomes more noticeable as the freezing rate becomes slower, and the faster the freezing rate becomes, the more uniformly the particles are likely to be trapped. According to the apparatus according to the ice grain manufacturing method of the present invention, water is instantly frozen, so that ice grains in which other substances such as sugar are uniformly mixed can be obtained. Furthermore, it is possible to produce ice grains that contain different substances inside and outside. For example, by first producing ice grains corresponding to the interior according to the present invention, and then mixing the above-mentioned rice grains with a solution of another substance that will become the exterior and injecting the mixture into this device, ice grains with a double structure can be produced. can be manufactured. (Effects of the Invention) As described above, the present invention makes ice by directly and rapidly cooling water by injecting water into liquid carbon dioxide whose upper surface is controlled at a constant level near a weir. Since the floating ice particles are obtained by passing over the weir, the following effects can be obtained. ■ Extremely high productivity as ice grains can be produced continuously. ■ Since the cooling liquid is liquid carbon dioxide, production costs can be reduced and ice grains can be obtained with no concerns about toxicity. ■ Since ice is made in liquid, spherical ice particles can be easily obtained. ■ By changing the nozzle diameter and injection flow rate of the water inlet,
The diameter of rice grains can be freely controlled. ■ Since ice is made by rapidly freezing, it is possible to uniformly contain other substances, and it is also possible to form ice grains with a multilayer structure. 4. Brief Description of the Drawings FIG. 1 is a longitudinal sectional view of an apparatus according to an embodiment of the present invention. 1... Container 2... Liquid carbon dioxide 3... Bone water outlet 8... Branch pipe 9.・・・・・・・・・Collection

Claims (1)

[Claims] A water inlet is provided at the bottom of a container for storing liquid carbon dioxide gas, and a branch pipe extending laterally is connected to the upper part of the container, and the branch pipe has an interior filled with the liquid carbon dioxide gas. A weir is provided to prevent flow, a release valve for the carbon dioxide gas generated within the container is installed, and a level control means is provided to maintain the upper surface level of the liquid carbon dioxide near the weir. An ice grain manufacturing device.