JP2015178076A - Blasting-type pulverization method and blasting-type pulverization device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a blasting-type pulverization method that can atomize a material which degrades or dissolves by touching to water vapor (water) and a raw material with cold shortness well while attempting reduction of equipment costs.SOLUTION: In a blasting-type pulverization method pulverizing by blasting a raw material for crushing which is a porous material, liquid inert gas permeates the raw material, the raw material permeated with the liquid inert gas is discharged to blasting processing room K where the liquid inert gas vaporizes suddenly, and the raw material is blasted and pulverized by sudden gasification of the liquid inert gas having permeated in the raw material.

Description

  The present invention relates to a blasting pulverization method for pulverizing and pulverizing a raw material to be pulverized which is a porous material, and a blasting pulverization apparatus for performing the blasting pulverization method.

  As a conventional example of such a pulverization type pulverization method, a raw material to be pulverized is impregnated with water, and the raw material in a water impregnated state is pressurized by being pumped by a pumping means and heated by a heating means to be in a high temperature and high pressure state. After that, the pressure on the raw material in a high temperature and high pressure state is rapidly reduced, and the raw material to be crushed is exploded by steam explosion of moisture in the raw material (for example, see Patent Document 1).

  As another conventional example of the explosion type pulverization method, the raw material to be pulverized and the supercritical gas are stored in the explosion container, and the supercritical gas is swollen into the raw material, and then the internal pressure of the explosion container is rapidly increased. There is one in which the raw material is exploded by rapidly evaporating and expanding the supercritical gas inside the raw material (see, for example, Patent Document 2).

  Incidentally, Patent Document 2 describes that carbon dioxide having a critical temperature of 31 ° C. and a refrigerant (Suva: registered trademark) having a critical temperature of less than 120 ° C. are used as suitable supercritical gases. Yes.

Japanese Patent No. 5034011 JP 2002-126562 A

  The explosion-type pulverization method of Patent Document 1 is equipped with a pressure feeding means for pressurizing a raw material in a water-impregnated state and a heating means for heating the raw material in a pressurized state, thereby bringing the raw material in a moisture-impregnated state into a high-temperature and high-pressure state. Therefore, a large-scale apparatus is required to bring the raw material in a water-impregnated state into a high-temperature and high-pressure state, and there is a disadvantage that the equipment cost for carrying out the explosion-type pulverization method becomes expensive.

  Moreover, since the explosion-type pulverization method of Patent Document 1 impregnates the raw material to be pulverized with water, it cannot be used for materials that deteriorate or dissolve when exposed to water vapor (water) (for example, biomaterials). Furthermore, since it cannot be pulverized using low-temperature brittleness, there is a disadvantage that atomization becomes difficult when the raw material to be pulverized is a low-temperature brittle material (for example, organic matter).

In the explosion-type pulverization method of Patent Document 2, it is necessary to configure a container for explosion that stores the raw material to be pulverized and the supercritical gas so that the supercritical gas can be stored at high pressure and can withstand high pressure. There is a disadvantage that the equipment cost is high due to the provision of an expensive blasting container that can withstand high pressure.
Incidentally, for example, when carbon dioxide is used as the supercritical gas, the critical pressure of carbon dioxide is 72.8 atm. Therefore, it is necessary to configure the container for explosion so that it can withstand this critical pressure. is there.

The present invention has been made in view of the above circumstances, and its purpose is to improve materials that deteriorate or dissolve when exposed to water vapor (water) and raw materials that are low-temperature brittle while reducing the equipment cost. The present invention provides a method for pulverizing fine particles that can be atomized.
In addition, another object of the present invention is to provide a pulverization type pulverization capable of satisfactorily atomizing a material that degrades or dissolves by touching water vapor (water) or a raw material having low temperature brittleness while reducing the equipment cost. The point is to provide a device.

The explosion-type pulverization method of the present invention is a pulverization-type pulverization method for pulverizing and pulverizing a raw material to be pulverized which is a porous material.
The raw material infiltrated with the liquefied inert gas into the raw material, the liquefied inert gas infiltrated with the liquefied inert gas discharged into the explosion treatment space where the liquefied inert gas rapidly vaporizes, The raw material is explosively pulverized by rapid vaporization of gas.

  Incidentally, the rapid vaporization of the inert gas means that the inert gas is vaporized so rapidly that the raw material can be pulverized and pulverized.

  In other words, the liquefied inert gas is infiltrated into the raw material to be crushed, which is a porous material, and the raw material infiltrated with the liquefied inert gas is discharged into the explosion treatment space where the liquefied inert gas is rapidly vaporized. The infiltrated liquefied inert gas is rapidly vaporized, and the raw material is crushed and pulverized by the rapid vaporization of the liquefied inert gas.

In order to infiltrate the liquefied inert gas into the raw material to be crushed, the raw material and the liquefied inert gas are stored in the infiltration container. For example, when the liquid nitrogen is at a pressure of 0.1 MPaN / mm ² In addition, since the pressure of the liquefied inert gas is lower than the pressure of the supercritical gas, such as the boiling point is -195.8 ° C., the pressure resistance of the infiltration container storing the liquefied inert gas is Compared with the case of storing critical gas, it can be made considerably smaller, so that the infiltration container becomes an inexpensive container having a small pressure resistance, and the equipment cost can be reduced.

In addition, even a material that deteriorates or dissolves by contact with water vapor (water) can be finely pulverized because it does not deteriorate or dissolve by contact with a liquefied inert gas.
Furthermore, by infiltrating the raw material to be pulverized with a low-temperature liquefied inert gas, the raw material can be finely pulverized satisfactorily using low-temperature brittleness.

  In short, according to the first characteristic configuration of the explosion-type pulverization method of the present invention, the material that deteriorates or dissolves by touching water vapor (water) or the raw material having low-temperature brittleness is finely granulated while reducing the equipment cost. Can be

In addition to the first feature configuration described above, the second feature configuration of the explosion-type pulverization method of the present invention includes:
The liquefied inert gas is liquid nitrogen.

  That is, since liquid nitrogen is used as the liquefied inert gas, the raw material to be pulverized can be pulverized while reducing the running cost.

  That is, as the liquefied inert gas, liquid helium, liquid argon, liquid carbon dioxide, or the like can be used in addition to liquid nitrogen, but liquid nitrogen is less expensive than other liquefied inert gases. Therefore, the raw material to be pulverized can be pulverized while reducing the running cost.

  In short, according to the second characteristic configuration of the explosion-type pulverization method of the present invention, in addition to the operational effects of the first characteristic configuration of the above-described explosion-type pulverization method, the running cost can be reduced.

In addition to the first or second feature configuration described above, the third feature configuration of the explosion-type pulverization method of the present invention includes:
The blasting treatment space is a space opened to the atmosphere.

  That is, since the blasting space is a space that is open to the atmosphere, it is not necessary to equip equipment for adjusting the temperature and pressure of the blasting space, so that the equipment cost can be further reduced. .

  In other words, it is possible to adjust the explosion treatment space to a temperature higher than the atmospheric temperature or to a pressure lower than the atmospheric pressure, but the liquefied inert gas vaporizes sufficiently rapidly in the atmosphere. Therefore, it is possible to further reduce the equipment cost by making the explosion treatment space open to the atmosphere.

  In short, according to the third feature configuration of the explosion-type pulverization method of the present invention, in addition to the operational effects of the first or second feature configuration of the above-described explosion-type pulverization method, the facility cost can be further reduced. Can do.

The explosion-type pulverization apparatus of the present invention is an explosion-type pulverization apparatus that pulverizes and pulverizes a raw material to be pulverized which is a porous material.
The infiltration container for storing the raw material and the liquefied inert gas and infiltrating the liquefied inert gas into the raw material, and the liquefied inert gas for the raw material and the liquefied inert gas stored in the infiltration container The present invention is characterized in that an infiltration raw material supply path for supplying gas to the blasting treatment space at a temperature at which gas is vaporized and an opening / closing portion for opening and closing the infiltration raw material supply path are provided.

  That is, the characteristic configuration of the explosion-type pulverization apparatus of the present invention includes a configuration for implementing the first characteristic configuration of the above-described explosion-type pulverization method, and thus the first of the above-described explosion-type pulverization method. The same operational effects as the operational effects described in the column of the characteristic configuration are obtained.

  That is, in a state where the opening and closing part that opens and closes the infiltration raw material supply path is in a closed state, the raw material to be pulverized and the liquefied inert gas are stored in the infiltration container, and the raw material to be pulverized and the liquefied inert gas are infiltrated, After infiltrating the liquefied inert gas into the raw material to be crushed, by opening the opening / closing part that opens and closes the infiltrating raw material supply path, the raw material infiltrated with the liquefied inert gas is passed through the infiltrating raw material supply path. By releasing the activated gas into the blasting space where it is rapidly vaporized, the liquefied inert gas infiltrating the raw material is rapidly vaporized, and the raw material is blasted and pulverized by the rapid vaporization of the liquefied inert gas. become.

  And, since the pressure resistance of the infiltration container for storing the liquefied inert gas can be considerably reduced compared with the case of storing the supercritical gas, the infiltration container is an inexpensive container with low pressure resistance. Can be reduced.

In addition, even a material that deteriorates or dissolves by contact with water vapor (water) can be finely pulverized because it does not deteriorate or dissolve by contact with a liquefied inert gas.
Furthermore, by infiltrating the raw material to be pulverized with a low-temperature liquefied inert gas, the raw material can be finely pulverized satisfactorily using low-temperature brittleness.

  In short, according to the characteristic configuration of the explosion-type pulverization apparatus of the present invention, the material that deteriorates or dissolves and the raw material having low temperature brittleness are finely atomized by touching water vapor (water) while reducing the equipment cost. be able to.

The figure which shows the structure of the explosion type pulverization apparatus of 1st Embodiment. The figure which shows the structure of the explosion type pulverization apparatus of 2nd Embodiment.

[First Embodiment]
DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, a first embodiment of the invention will be described with reference to the drawings.
(Overall configuration of explosive pulverization equipment)
As shown in FIG. 1, the explosion-type pulverization apparatus explosively pulverizes a raw material to be crushed which is a porous material, and stores liquid nitrogen as a raw material and a liquefied inert gas, An infiltrating container 1 for infiltrating the raw material with liquid nitrogen, an infiltrating raw material supply path 2 for supplying the raw material and liquid nitrogen stored in the infiltrating container 1 to the explosion treatment space K where the liquid nitrogen rapidly vaporizes, An infiltration raw material supply valve 3 is provided as an opening / closing part for opening and closing the infiltration raw material supply path 2.

  That is, the explosion-type pulverization apparatus infiltrates liquid nitrogen into the material to be crushed, which is a porous material, and discharges the material infiltrated with liquid nitrogen into the explosion treatment space K where liquid nitrogen is rapidly vaporized. An explosion-type pulverization method is carried out in which the raw material is blasted and pulverized by rapid vaporization of liquid nitrogen infiltrated into the slag.

In the present embodiment, the raw material to be crushed is a material having a property of embrittlement at a low temperature, for example, a biomaterial, a synthetic resin, an organic material, and the like so that the raw material is cooled below the embrittlement point by liquid nitrogen. It is configured.
Moreover, the raw material to be pulverized is in a granular form, and such a granular raw material is pulverized to be pulverized.

  In the present embodiment, the blasting treatment space K is a space opened to the atmosphere, and the liquid nitrogen infiltrating the raw material is rapidly vaporized in the blasting treatment space K opened to the atmosphere to explode the raw material. And is configured to be pulverized.

(Details of infiltration container)
As shown in FIG. 1, the infiltration container 1 is configured such that a raw material can be input through an openable / closable upper wall 1 u and liquid nitrogen is supplied through a nitrogen supply path 4.
A stirring blade 5 for stirring the charged raw material and liquid nitrogen is provided inside the infiltration container 1, and nitrogen gas vaporized inside the infiltration container 1 is placed above the infiltration container 1. An outside air communication cylinder portion 6 for discharging to the outside is provided.

The nitrogen supply path 4 introduces liquid nitrogen sent from a liquid nitrogen supply source such as a liquid nitrogen cylinder, and in this embodiment, for example, a liquid of −200 ° C. and 1 MPa (N / mm ² ). Nitrogen is introduced into the infiltration container 1 through the nitrogen supply path 4.
Further, the nitrogen supply path 4 is provided with a nitrogen supply valve 4 </ b> A so that the supply of nitrogen to the infiltration container 1 can be interrupted.

(Details of operation procedure)
With the infiltration raw material supply valve 3 closed, the raw material is introduced into the infiltration container 1 and the nitrogen supply valve 4A is opened to supply liquid nitrogen through the nitrogen supply passage 4.
At that time, the charged raw material and liquid nitrogen are stirred by the stirring blade 5.
The raw material charged into the infiltration container 1 is cooled below the embrittlement point by liquid nitrogen, and liquid nitrogen is infiltrated into the raw material.

Incidentally, the nitrogen supply valve 4 </ b> A is closed when an appropriate amount of liquid nitrogen is supplied to the infiltration container 1.
The stirring blade 5 is operated only immediately after the raw material and liquid nitrogen are introduced into the infiltration container 1 and then stopped. However, the stirring blade 5 is continuously operated while liquid nitrogen is infiltrated into the raw material. It may be.

  Then, when liquid nitrogen is infiltrated into the raw material, the infiltrating raw material supply valve 3 is opened, the raw material infiltrated with liquid nitrogen is discharged into the explosion treatment space K, and the raw material is removed by rapid vaporization of the liquid nitrogen infiltrated into the raw material. Blast and pulverize.

[Second Embodiment]
Next, the second embodiment will be described. This second embodiment shows another embodiment of the infiltration container 1, and the other configuration is the same as that of the first embodiment. Only parts different from the embodiment will be described, and the same configurations as those of the first embodiment will be denoted by the same reference numerals as those of the first embodiment, and detailed description thereof will be omitted.

(Details of infiltration container)
As shown in FIG. 2, a pulverization target material supply path 10 for supplying a pulverization target raw material to the infiltration container 1 is provided in a state of penetrating the upper wall 1 u of the infiltration container 1. Is provided with a raw material supply valve 10A to be crushed so that the supply of the raw material to the infiltration container 1 can be interrupted.
The infiltration container 1 is configured to be sealed by closing the nitrogen supply valve 4A provided in the nitrogen supply path 4 and the pulverization target raw material supply valve 10A provided in the pulverization target raw material supply path 10.

  The infiltration container 1 includes a container pressure gauge 11 that measures the internal pressure of the infiltration container 1, and a container pressure adjustment valve 12 whose opening degree is automatically adjusted based on the detection result of the container pressure gauge 11. And the opening of the container pressure regulating valve 12 is automatically adjusted based on the detection result of the container pressure gauge 11 to maintain the internal pressure of the infiltration container 1 at a set pressure. Yes.

The set pressure of the infiltration container 1 is a pressure for suppressing vaporization of liquid nitrogen supplied from the nitrogen supply path 4, and is set to a pressure of about 0.2 to 0.3 MPa (N / mm ² ), for example. Will be.

(Details of operation procedure)
With the infiltration raw material supply valve 3 closed, the pulverization target raw material supply valve 10A is opened, the raw material is introduced into the infiltration container 1 through the pulverization target raw material supply path 10, and the nitrogen supply valve 4A is opened to open the nitrogen supply path 4 Through which liquid nitrogen is supplied.
At that time, the charged raw material and liquid nitrogen are stirred by the stirring blade 5.
The raw material charged into the infiltration container 1 is cooled below the embrittlement point by liquid nitrogen, and liquid nitrogen is infiltrated into the raw material.

By the way, when the appropriate amount of raw material to be crushed is supplied to the infiltration container 1, the raw material supply valve 10A for pulverization is closed, and when the appropriate amount of liquid nitrogen is supplied to the infiltration container 1, the nitrogen supply valve 4A is closed. .
The stirring blade 5 is operated only immediately after the raw material and liquid nitrogen are introduced into the infiltration container 1 and then stopped. However, the stirring blade 5 is continuously operated while liquid nitrogen is infiltrated into the raw material. It may be.

  When liquid nitrogen is infiltrated into the raw material, the infiltrating raw material supply valve 3 is opened, the raw material infiltrated with liquid nitrogen is discharged into the blasting treatment space, and the raw material is blasted by rapid vaporization of the liquid nitrogen infiltrated into the raw material. And then pulverized.

[Another embodiment]
Next, another embodiment is listed.
(1) In the first and second embodiments, the case where liquid nitrogen is used as the liquefied inert gas is exemplified. However, for example, other liquefied inert gases such as liquid helium, liquid argon, and liquid carbon dioxide are used. It may be used.

(2) In the first and second embodiments, the powdery raw material to be pulverized is exemplified as a powder of a material having a property of embrittlement at a low temperature. As a raw material, a material such as rubber having a property of undergoing glass transition at a low temperature can be used as a raw material to be crushed as long as it is a porous material.

(3) In the said 1st and 2nd embodiment, although the case where the explosion processing space K was the space open | released to air | atmosphere was illustrated, as the explosion processing space K, the space which reduced the internal pressure rather than the air | atmosphere. Alternatively, a space in which the internal temperature is higher than the atmospheric temperature may be used.

(4) In the first and second embodiments described above, the case where the infiltration container 1 stirs and mixes the charged raw material and liquid nitrogen with the stirring blade 5, but the liquid nitrogen flows, for example. The raw material may be introduced into the flow path to generate a mixed liquid of the raw material and liquid nitrogen, and the mixed liquid may be supplied to the infiltration container 1.

1 Infiltration container 2 Infiltration raw material supply path 3 Opening and closing part K

Claims (4)

An explosion-type pulverization method for pulverizing and pulverizing a raw material to be crushed which is a porous material,
The raw material infiltrated with the liquefied inert gas is infiltrated into the raw material, the raw material infiltrated with the liquefied inert gas is discharged into the explosion treatment space where the liquefied inert gas is vaporized, and the liquefied inert gas infiltrated into the raw material An explosion type pulverization method, wherein the raw material is pulverized by vaporization to be pulverized.   2. The explosion type pulverization method according to claim 1, wherein the liquefied inert gas is liquid nitrogen.   3. The explosion type pulverization method according to claim 1 or 2, wherein the explosion treatment space is a space opened to the atmosphere. A pulverization type pulverization device that pulverizes and pulverizes a material to be pulverized which is a porous material,
The infiltration container for storing the raw material and the liquefied inert gas and infiltrating the liquefied inert gas into the raw material, and the liquefied inert gas for the raw material and the liquefied inert gas stored in the infiltration container A pulverization type pulverization apparatus provided with an infiltration raw material supply path that supplies a blasting treatment space having a temperature at which gas is vaporized, and an opening / closing portion that opens and closes the infiltration raw material supply path.

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