JP2018180000A - Cesium adsorption apparatus and adsorption method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cesium adsorption apparatus and a cesium adsorption method capable of adsorbing and disposing most radioactive cesium dissolved in water and reducing exposure risk of installation workers.SOLUTION: A cesium adsorption apparatus comprises an adsorption unit 5 including a filter for adsorbing cesium dissolved in water and a floating member 6, a plurality of the adsorption units 5 being coupled to the floating member 6. The adsorption units 5 each preferably have the filters stacked and contained in a net-like container 4.SELECTED DRAWING: Figure 5

Description

  The present invention reduces the concentration of radioactive materials in water and reduces environmental impact by adsorbing most of all types of cesium including radioactive cesium dissolved in water such as harbors, rivers, and lakes. The present invention relates to a cesium adsorption apparatus and an adsorption method.

  It has been reported that radioactive cesium is dissolved in the waters of ports, rivers and lakes due to the accident at the Tokyo Electric Power Company's Fukushima Daiichi Nuclear Power Station. In addition, it is presumed that radioactive cesium is accumulated at high concentration in fishery resources such as fish and shellfish due to this.

  Various adsorbents have been devised and used to adsorb and remove these radioactive cesium. For example, Patent Document 1 discloses a water purification filter cartridge for efficiently collecting harmful metals, particularly radioactive cesium contained in groundwater, clean water, industrial water, agricultural water industry water, or washing water of contaminated soil. The water purification filter cartridge of Patent Document 1 is efficiently and efficiently incorporated by sequentially winding and laminating specific three types of functional non-woven fabrics as filter media into a compact cartridge unit and incorporating it as a replacement filter into a conventional water treatment apparatus. It states that water can be purified economically (paragraph 0007, etc.).

JP, 2013-88411, A

  However, there is no adsorbent capable of adsorbing and removing only radioactive cesium from the water of wide area ports, rivers, and lakes, and the conventional adsorbent adsorbs not only radioactive cesium but also stable cesium and other ions. Therefore, even if the conventional adsorbent is used in the water, the adsorption capacity is reduced in a relatively short time, and as a result, radioactive cesium remains in the water.

  Therefore, it is conceivable to use a large amount of adsorbent in the above-mentioned water, but the problem that the risk of exposure to workers increases if the number of human operations at the site increases due to the installation and recovery of a large amount of adsorbent. Will occur.

  The present invention has been made in view of the above problems, and its object is to absorb and discard most radioactive cesium dissolved in water, and to reduce the risk of exposure to installation workers. It is providing the adsorption apparatus and adsorption method of cesium which can be

  The cesium adsorption apparatus according to the present invention includes an adsorption unit including a filter for adsorbing cesium dissolved in water, and a floating member, and a plurality of the adsorption units are connected to the floating member. It features.

  In the cesium adsorbing device, it is preferable that the filters be stacked on each of the plurality of adsorbing units and be stored in a net-like container.

  In the cesium adsorbing device, it is preferable that in each of the plurality of adsorption units, the filter is stacked in a roll shape.

  In the cesium adsorption apparatus, the net-like container is made of a yarn of high molecular weight polyethylene in which the repeating unit is substantially ethylene, and the yarn preferably has a tensile strength of 27 g / d or more.

In the cesium adsorption device, it is preferable that the area of the filter included in each of the plurality of adsorption units is 50 to ²⁰⁰ m ² .

  The cesium adsorbing apparatus further includes a weight member having a specific gravity larger than that of water, and each of the plurality of adsorption units has one end connected to the floating member and the other end connected to the weight member. Is preferred.

  Preferably, in the cesium adsorption apparatus, the plurality of adsorption units are arranged close to each other in the longitudinal direction of the floating member.

  In the cesium adsorbing device, the filter is preferably one in which Prussian blue is impregnated or coated in a polyester continuous fiber non-woven fabric.

  In the method for adsorbing cesium according to the present invention, a filter for adsorbing cesium dissolved in water is laminated, and a unitization step of producing an adsorption unit stored in a net-like container; And an installation step of

  The method for adsorbing cesium further includes a connecting step of connecting the plurality of adsorption units to the floating member, and the installing step may install the plurality of adsorption units connected to the floating member in water. preferable.

  In the adsorption device for dissolved cesium according to the present invention, a plurality of adsorption units are connected to the floating member. According to the adsorption method of dissolved cesium of the present invention, it has a unitization step of producing an adsorption unit in which filters are stacked, and an installation step of installing the adsorption unit in water.

  Since a large area filter can be efficiently installed in water by these, most radioactive cesiums dissolved in water can be adsorbed and discarded. In addition, since the preparation of the adsorption unit can be performed at a place where there is little radiation other than the site, the possibility of the exposure of the installation worker can be reduced by reducing the human work in water. In addition, since the adsorption unit can be replaced, it becomes possible to continuously and efficiently adsorb most of all types of cesium in water containing radioactive cesium.

FIGS. 1A and 1B are cross-sectional views of an adsorption filter that adsorbs cesium dissolved in water. Fig.2 (a), (b) is a side view of a roll-shaped filter. FIGS. 3A and 3B are front views of the circular laminated filter. FIG. 4 is an external view of a suction unit. FIG. 5 is an external view of the case where each of the plurality of suction units is continuously connected to the floating member and the weight member.

In the adsorption apparatus according to the present invention, the adsorption filter capable of selectively adsorbing cesium is housed in a net-like container having high strength, low elongation and high abrasion resistance, whereby a large-area adsorption filter can be provided with a predetermined water area. It can be installed efficiently inside.

  In the adsorption device according to the present invention, a large-area adsorption filter is installed to adsorb most of all types of cesium in a predetermined water area. By installing a large-area adsorption filter in a predetermined water area, it is possible to adsorb most of all types of cesium in water containing radioactive cesium, and to reduce the activity concentration in the predetermined water area.

The adsorption filter is a polyester long fiber non-woven fabric impregnated or coated with Prussian blue. Due to the property that Prussian blue selectively adsorbs cesium ions in the prescribed water area by concentration gradient, both vertical permeability coefficient and in-plane permeability coefficient are 1.0 × in order to make water in the prescribed inner water zone easy to contact with Prussian blue. It is preferable that it is 10 ^<-1 > cm / sec or more.

Fig.1 (a), (b) is sectional drawing of the adsorption | suction filter which adsorb | sucks the cesium currently melt | dissolved in water. An adsorption filter 1a shown in FIG. 1 (a) is a long fiber spunbonded nonwoven fabric impregnated with Prussian blue. An adsorption filter 1b shown in FIG. 1 (b) is obtained by applying Prussian blue 1d to one side of a long fiber spunbond nonwoven fabric 1c. The cesium adsorption capacity of the adsorption filters 1a and 1b is preferably 6 mg / m ² or more regardless of fresh water or seawater, and the desorption rate of cesium once adsorbed is preferably 10% or less . Further, it is preferable that Prussian blue itself impregnated or applied to the adsorption filter is hardly desorbed by rubbing or immersion in an aqueous solution.

  Fig.2 (a), (b) is a side view of a roll-shaped filter. The roll filter 2a shown in FIG. 2 (a) is formed by winding the suction filter 1a in a roll and laminating it into a cylindrical shape, and the roll filter 2b shown in FIG. 2 (b) rolls the suction filter 1b. It is wound in the shape of a circle, laminated and made into a cylindrical shape. Here, although the suction filter is wound into a cylindrical shape, it does not have to be necessarily cylindrical, and for example, the suction filter may be wound into a polygonal pillar shape.

  FIGS. 3A and 3B are front views of the circular laminated filter. The circular laminated filter 3a shown in FIG. 3 (a) is formed by laminating a plurality of circular adsorption filters 1a vertically to form a cylindrical shape, and the circular laminated filter 3b shown in FIG. 3 (b) is circular. A plurality of the suction filters 1b are vertically stacked to form a cylindrical shape. In addition, although the circular adsorption filter was laminated | stacked here, it does not necessarily need to be circular, for example, a polygon adsorption filter may be laminated | stacked and it may be made into a polygon pillar shape.

In addition, when the water permeability coefficient of the adsorption filter is lower than 1.0 × 10 ⁻¹ cm / sec, both of the roll-shaped filters 2 a and 2 b and the circular laminated filters 3 a and 3 b are 1.0 between the adjacent adsorption filters. It is preferable to make it easy for water in a predetermined inner water area to come in contact with Prussian blue by securing a water permeability coefficient of × 10 ⁻¹ cm / sec or more.

The adsorption | suction filter 1a or 1b can be laminated | stacked, it can accommodate in the net-like container 4, and the adsorption | suction unit 5 can be produced. FIG. 4 is an external view of a suction unit. In the suction unit 5 shown in FIG. 4, the roll filters 2 a and 2 b or the circular laminated filters 3 a and 3 b are housed in a net container 4. The area of the suction filter included in the roll filters 2a and 2b or the circular laminated filters 3a and 3b is preferably 50 to ²⁰⁰ m ² . Moreover, since unitization work which produces an adsorption unit can be performed at a place with few radiations, the possibility of exposure of an installation worker can be reduced by being able to reduce human work in water.

  The net-like container 4 preferably has high strength and low elongation, is flexible, and is excellent in abrasion resistance. The yarn used for the net portion of the net-like container 4 is preferably a synthetic fiber filament having a tensile strength of 15 g / d or more and a tensile elongation at break of 10% or less. For example, the above yarns include aramid fibers (trade name "Kevlar" manufactured by Toray Industries, Inc., trade name "Technola" manufactured by Teijin Ltd.), liquid crystal polyester fibers (trade name "Bectran" manufactured by Kuraray Co., Ltd.) and ultra-high strength polyethylene fibers (Trade name "Dyneema" made by Toyobo Co., Ltd.) can be used. In particular, the net-like container 4 is made of a yarn of high molecular weight polyethylene in which the repeating unit is substantially ethylene, and the yarn preferably has a tensile strength of 27 g / d or more. Incidentally, the multifilament yarn of "Dyneema" is a yarn of high molecular weight polyethylene and has a denier of 1600, a filament of 1560, a tensile strength of 30 g / d, and an elongation at break of 4%.

  In order to install the adsorption unit 5 in water, a method of directly fixing to a revetment etc., and a method of suspending it in a floating member such as a float and floating in the sea can be considered.

  When the water flow or waves such as waves are large, it is preferable that one end of the adsorption unit 5 be suspended on the floating member 6 and suspended in water in a dense state. In this case, it is necessary to be firmly moored to a revetment or the like so that the floating member 6 does not flow. In addition, it is preferable to connect a weight member 7 such as a weight chain having a specific gravity larger than that of water to the other end of the adsorption unit 5 because the posture of each adsorption unit 5 is stabilized in water.

  FIG. 5 is an external view of the case where each of the plurality of suction units is connected to the floating member 6 and the weight member 7 continuously. As shown in FIG. 5, one end A of each of the plurality of suction units 5 is connected to the floating member 6, and the other end B of each of the plurality of suction units 5 is connected to the weight member 7. Preferably, the plurality of suction units 5 are arranged close to each other in the longitudinal direction of the floating member 6 and the weight member 7. By arranging the adsorption units 5 close to each other, not only the installation density can be increased, but also, if marine organisms such as shellfish adhere to the outside of the adsorption units 5, the adjacent matter is collided to remove the attached matter. Can be expected to

  Moreover, unlike the unitization work, the installation work for installing the adsorption unit 5 needs to be performed on the site, but since the adsorption filter is compactly condensed in the adsorption unit 5, the installation work can be performed efficiently. It can be carried out. Furthermore, in the case where the connecting step of connecting the suction unit 5 to the floating member 6 is performed in a place with a small amount of radiation as in the unitization work, the plurality of suction units 5 connected to the floating member 6 are submerged in the installation work By installing it, the possibility of exposure to the installation worker can be further reduced.

  On the other hand, in the case where the adsorption unit 5 is fixed to a revetment or the like, it is preferable to store the plurality of adsorption units 5 in a large casing and install and replace from the land or the water.

  As described above, in the cesium adsorption apparatus according to the present invention, a large-area adsorption filter can be efficiently installed in water, so that most of the radioactive cesium dissolved in water is adsorbed and discarded. Can. In addition, since the preparation of the adsorption unit can be performed at a place where there is little radiation other than the site, the possibility of the exposure of the installation worker can be reduced by reducing the human work in water. Moreover, since it is possible to replace the adsorption unit, it becomes possible to continuously and efficiently adsorb cesium of all types in the water containing radioactive cesium.

DESCRIPTION OF SYMBOLS 1a, 1b Suction filter 2a, 2b Roll-like filter 3a, 3b Circular laminated filter 4 Net-like container 5 Suction unit 6 Floating member 7 Weight member

Claims (10)

An adsorption unit comprising a filter for adsorbing cesium dissolved in water;
And a floating member,
A cesium adsorption apparatus, wherein a plurality of the adsorption units are connected to the floating member. Each of the plurality of adsorption units is
The cesium adsorption device according to claim 1, wherein the filters are stacked and stored in a net-like container. Each of the plurality of adsorption units is
The cesium adsorption device according to claim 2, wherein the filter is stacked in a roll shape. The net-like container is
The cesium adsorption apparatus according to claim 2 or 3, which is made of a yarn of high molecular weight polyethylene in which the repeating unit is substantially ethylene, and the yarn has a tensile strength of 27 g / d or more. Each of the plurality of adsorption units is
The cesium adsorption apparatus according to any one of claims 1 to 4, wherein the area of the filter included is 50 to ²⁰⁰ m2. further,
It has a weight member with a specific gravity greater than that of water,
Each of the plurality of adsorption units is
The cesium adsorption apparatus according to any one of claims 1 to 5, wherein one end is connected to the floating member and the other end is connected to the weight member. The plurality of suction units are
The cesium adsorbing device according to claim 6, wherein the adsorbing device according to claim 6, which is adjacently arranged in the longitudinal direction of the floating member. The filter is
The cesium adsorption apparatus according to any one of claims 1 to 7, wherein the continuous fiber non-woven fabric made of polyester is impregnated or coated with Prussian blue. A unitization step of producing an adsorption unit in which filters for adsorbing cesium dissolved in water are stacked and housed in a net-like container;
And D. installing the adsorption unit in water. further,
Including a connecting step of connecting a plurality of the suction units to the floating member;
The installation step is
10. The cesium adsorption method according to claim 9, wherein the plurality of adsorption units connected to the floating member are installed in water.