JP6862759B2 - Particle generator - Google Patents

Description

The present invention relates to a particle generator that supplies particles having extremely finely limited particle sizes.

A spray dryer (spray dryer) is known as one of the devices for obtaining fine particles. For example, Patent Document 1 discloses a spray dryer. The spray dryer described in Patent Document 1 is a blow-down method in which a mist in which a material is dissolved is sprayed downward in a drying chamber and dried while dropping the mist to obtain particles.

Further, it is known that the particles as a product are recovered by a cyclone as in Patent Document 1 or by a bug filter as in Patent Document 2. When a cyclone and a bag filter are used in combination, heavy particles having a large particle size are collected by the cyclone, and light particles having a small particle size are collected by the bag filter. Also, the bug filter may be installed simply to clean the exhaust.

JP 2000-154015 JP-A-2005-089251

However, in the conventional apparatus as described above, it is difficult to obtain particles having an extremely fine particle size (mainly 1 μm or less). According to the device of the prior art, the particles having a small particle size are the particles recovered by the bag filter, that is, the particles not recovered by the cyclone. It is difficult to control the particle size of the particles collected by the cyclone, and inevitably, a large number of particles having a large particle size are mixed in the particles collected by the bag filter.

In addition, when collecting particles that are products with a bug filter, it is necessary to replace the bug filter as appropriate, and the spray dryer must be stopped when the bug filter is replaced. It also requires work to separate the particles from the bug filter. That is, there is a lot of work and it is difficult to continuously supply particles.

Therefore, an object of the present invention is to provide a particle generating apparatus capable of stably and continuously supplying particles having an extremely fine particle size (mainly 1 μm or less).

In order to solve the above problems, a typical configuration of the particle generator according to the present invention is to spray a mist in which a material is dissolved downward in a drying chamber and dry the mist while dropping it to obtain particles. A blow-down type spray dryer, a drying tower through which the air flow passes from the bottom to the top, a connecting pipe connecting the lower part of the spray dryer and the lower part of the drying tower, and an air flow containing particles from the upper part of the drying tower It is characterized by having a discharge pipe.

According to the above configuration, only the particles floating in the drying tower and rising can be supplied as a product. That is, since it is possible to supply only particles having a size that does not precipitate in a colloidal state in the air flow, it is possible to stably supply particles having an extremely fine particle size (mainly 1 μm or less). it can. It is preferable that the airflow rising through the drying tower is gentle.

Further, the line for suspending and supplying the particles can be directly connected to the device in the next process. Therefore, it is not necessary to stop the spray dryer for filter replacement, and the particles can be continuously supplied.

It is preferable that the connecting pipe is provided with a bent portion. The bend acts as an eliminator to remove undried droplets. As a result, the amount of liquid in the drying column can be reduced, and the drying of small-diameter droplets can be promoted.

The spray dryer preferably swirls the dry air in the drying chamber. By placing the particles in a swirling stream and drying them for a long time, particles having a desired particle size can be obtained with high efficiency.

It is preferable that the drying tower is equipped with a heater that heats the air flow passing through the drying tower. By heating the "air containing particles" generated by this device, it is possible to suppress the occurrence of condensation as much as possible when the "water vapor" generated separately in the boiler is mixed later.

According to the particle generation apparatus according to the present invention, particles having an extremely fine particle size (mainly 1 μm or less) can be stably and continuously supplied.

It is a figure explaining the structure of the particle generation apparatus. It is a figure explaining the effect of the particle generation apparatus. It is a figure explaining another structure of the particle generation apparatus.

Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The dimensions, materials, and other specific numerical values shown in such an embodiment are merely examples for facilitating the understanding of the invention, and do not limit the present invention unless otherwise specified. In the present specification and drawings, elements having substantially the same function and configuration are designated by the same reference numerals to omit duplicate description, and elements not directly related to the present invention are not shown. To do.

FIG. 1 is a diagram illustrating a configuration of a particle generation device according to an embodiment. The particle generation device 100 shown in FIG. 1 is roughly classified into a spray dryer 120, a connecting pipe 130, and a drying tower 140.

The spray dryer 120 is a blow-down type. A nozzle 124 for injecting mist and a blow nozzle 126 for supplying dry air are installed in the drying chamber 122. The outside air is compressed by the compressor 110, dried by the air dryer 112, and then the dust in the air is removed by the filter 114 (for example, a HEPA filter). The dry air thus generated is mixed with the aqueous solution supplied from the aqueous solution supply line 118 and supplied to the nozzle 124, and mist is injected downward from the nozzle 124.

Further, the dry air generated by the filter 114 is supplied to the blow nozzle 126. The injection direction of the blow nozzle 126 is angled and the dry air creates a swirling flow inside the drying chamber 122. Therefore, the mist injected from the nozzle 124 also swirls in the drying chamber 122.

As the mist swirls in the drying chamber 122, drying is performed over a longer period of time than when the mist is orthogonal to the connecting pipe 130 from the nozzle 124. As a result, particles having a desired particle size can be obtained with high efficiency.

The connecting pipe 130 connects the lower part of the spray dryer 120 and the lower part of the drying tower 140. The connecting pipe 130 includes a horizontal pipe 132 extending from below the spray dryer 120 to below the drying tower 140, and a vertical pipe 134 rising from the horizontal pipe 132 to the drying tower 140. A bent portion 136 is formed at the connecting portion between the horizontal pipe 132 and the vertical pipe 134.

The bent portion 136 acts as an eliminator for removing undried droplets. As a result, the amount of liquid in the drying tower 140 can be reduced, and the drying of small-diameter droplets can be promoted.

The drying tower 140 is a pipeline installed vertically, and the air flow passes from the bottom to the top. The mist is dried in the drying chamber 122, but the drying is not completed only in the drying chamber 122, and the mist is also dried in the drying tower 140. Then, a discharge pipe 142 is attached to the upper part of the drying tower 140, and the air flow mixed with the dried particles is discharged from the discharge pipe 142.

Here, the particles having a large mass cannot rise in the drying tower 140 and fall downward. Only particles of a size that does not settle in a colloidal state in the air can float and rise in the drying column 140. Therefore, particles having an extremely fine particle size (mainly 1 μm or less) can be stably supplied as a product. The airflow rising through the drying tower is preferably gentle (slow flow velocity). This is because if the flow velocity is high, particles that cannot normally rise may be carried upward.

Further, the line for suspending and supplying particles such as the discharge pipe 142 can be directly connected to the device in the next process. That is, it is not necessary to collect the particles using a cyclone or a bug filter. Therefore, it is not necessary to stop the spray dryer 120 for filter replacement, and the particles can be continuously supplied.

FIG. 2 is a diagram for explaining the effect of the particle generating apparatus 100 according to the present embodiment, and is a graph showing the relationship between the ^{particle size [μm] and the particle number concentration [pieces / cm 3].} As shown in FIG. 2, when the CsI aqueous solution (cesium iodide aqueous solution) is sprayed, a sharp peak is generated in the vicinity of the particle size of 0.1 μm. On the other hand, when pure is sprayed, the particle number concentration is extremely low, and most of the water droplets do not remain. Therefore, it can be seen that the particles when the CsI aqueous solution is sprayed are not water droplets but CsI particles. As described above, it was confirmed that the particle generating apparatus according to the present invention can stably and continuously supply particles having an extremely fine particle size (mainly 1 μm or less).

FIG. 3 is a diagram illustrating another configuration of the particle generator. Compared with the particle generation device shown in FIG. 1, an air heater 116 for heating the dry air generated by the filter 114 is provided. Further, the spray dryer 120, the connecting pipe 130, and the drying tower 140 are equipped with a heater 144 for heating the air flow passing through the inside.

By heating the "air containing particles" generated by this device in this way, it is possible to suppress the occurrence of condensation as much as possible when the "water vapor" generated separately in the boiler is mixed later. it can.

Although preferred embodiments of the present invention have been described above with reference to the accompanying drawings, it goes without saying that the present invention is not limited to such examples. It is clear that a person skilled in the art can come up with various modifications or modifications within the scope of the claims, which naturally belong to the technical scope of the present invention. Understood.

The present invention can be used as a particle generation device that supplies particles having extremely finely limited particle sizes.

100 ... particle generator, 110 ... compressor, 112 ... air dryer, 114 ... filter, 116 ... air heater, 118 ... aqueous solution supply line, 120 ... spray dryer, 122 ... drying chamber, 124 ... nozzle, 126 ... blow nozzle, 130 ... connected Pipe, 132 ... horizontal pipe, 134 ... vertical pipe, 134a ... wall surface, 136 ... bent part, 140 ... drying tower, 142 ... discharge pipe, 144 ... heater

Claims (3)

A blow-down type spray dryer that sprays the mist in which the material is dissolved downward in the drying chamber and dries the mist while dropping it to obtain particles.
A drying tower through which airflow passes from bottom to top,
A connecting pipe connecting the lower part of the spray dryer and the lower part of the drying tower,
A discharge pipe for discharging an air flow mixed with particles from the upper part of the drying tower is provided .
The spray dryer is a particle generation device characterized in that heated and dried air is swirled in a drying chamber. The particle generation device according to claim 1, wherein the connecting pipe is provided with a bent portion. The particle generation device according to claim 1 or 2 , wherein the drying tower is provided with a heater for heating an air flow passing through the drying tower.

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