JP2007130626A - Method for treating asbestos - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for treating asbestos capable of preventing asbestos from splashing in the air and conveniently treating a removed asbestos-containing substance, when the asbestos-containing substance is removed from the surface of a base body. <P>SOLUTION: The method for treating the asbestos that removes the asbestos-containing substance from the surface of the base body after an anti-splashing liquid is beforehand coated on the asbestos-containing substance, having (a) a spraying step that entraps the asbestos-containing substance in the anti-splashing liquid by spraying the anti-splashing liquid onto the asbestos-containing substance from a low pressure-spraying nozzle, (b) an exfoliating step that exfoliates the asbestos-containing substance from the surface of the base body by jetting a high-pressure water to the asbestos-containing substance in which the anti-splashing liquid is impregnated, and (c) a coagulating step that sprays a coagulant over the exfoliated asbestos-containing substance to make it a gel. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a method for treating asbestos used for ceilings, walls, and the like of buildings.

  In the past, asbestos was often used for the ceiling and walls of buildings because there was no legal restriction on asbestos and it was excellent in soundproofing and fireproofing.

  However, at present, asbestos has been found to cause lung cancer and mesothelioma, and its treatment is a problem.

  Thus, attempts have been made to remove asbestos used in buildings. However, in the process of removing asbestos, asbestos used on the ceiling and walls of buildings is scattered in the air, and causes inhalation by workers and nearby residents, causing lung cancer and mesothelioma There is concern about becoming.

  Therefore, conventionally, a method of removing asbestos after enclosing a portion where asbestos is used with a sheet or the like is used (see Patent Document 1).

In addition, asbestos is prevented from scattering in the air by removing asbestos after wetting with a water retention agent or the like (see Patent Document 2).
JP-A-8-28026 JP-A-10-323614

  However, in the method of Patent Document 1, a large amount of asbestos is scattered in the enclosure, and workers are exposed to danger, and a small amount of asbestos may be scattered outside the enclosure.

  Further, in the method of Patent Document 2, the post-treatment of the removed asbestos has not been improved.

  The present invention has been made to solve the above-described problems. When removing asbestos-containing materials from the surface of the foundation body, the asbestos is prevented from scattering in the air, and from the ceiling or wall of the building. An object of the present invention is to provide an asbestos treatment method that can easily perform post-treatment of removed asbestos.

  In order to solve the above-mentioned problems, the asbestos treatment method of the present invention includes the following (a) to (a) to the asbestos treatment method for removing the asbestos-containing material from the surface of the basic body after applying the anti-scattering liquid to the asbestos-containing material (C) It has each process, It is characterized by the above-mentioned. (A) A spraying step of spraying the anti-scattering liquid onto the asbestos-containing material from a low-pressure spray nozzle using the anti-scattering liquid made of water glass, and encapsulating the asbestos-containing material in the anti-scattering liquid; (b) A separation step of separating the asbestos-containing material from the surface of the base body by spraying high-pressure water from a high-pressure spray nozzle onto the asbestos-containing material impregnated with the anti-scattering liquid; and (c) removing the asbestos-containing material. The agglomeration step of sprinkling a flocculant to form a gel.

  Moreover, the asbestos processing method of this invention is the asbestos processing method which removes an asbestos containing material from the base body surface, after apply | coating a scattering prevention liquid to an asbestos containing material previously, each process of the following (a)-(c). It is characterized by having. (A) a spraying step of spraying the anti-scattering liquid onto the asbestos-containing material from a low-pressure spray nozzle using the anti-scattering solution comprising a polyacrylamide solution, and encapsulating the asbestos-containing material in the anti-scattering liquid; ) A peeling step in which high-pressure water is sprayed from a high-pressure spray nozzle onto the asbestos-containing material impregnated with the scattering prevention liquid, and the asbestos-containing material is peeled off from the surface of the base body; and (c) the peeled asbestos-containing material. And an agglomeration step in which a flocculant is sprinkled to form a gel.

  In such an asbestos treatment method, the asbestos-containing material is sprayed into the asbestos-containing material by spraying the anti-scattering solution composed of a polyacrylamide solution or water glass into the asbestos-containing material. Is reliably prevented.

  In addition, by spraying high-pressure water from the high-pressure spray nozzle and peeling the asbestos-containing material from the surface of the base body, the operator can work at a position away from the place where the asbestos-containing material is peeled off. Therefore, even if a small amount of asbestos is scattered in the air, the possibility that the worker sucks asbestos is reduced.

  Further, the asbestos-containing material thus peeled is sprinkled with a flocculant to form a gel, so that the asbestos accumulates on the floor or the like without being scattered on the floor or the like.

  Here, the present inventors have found that the polyacrylamide solution has a property that once the peeled asbestos-containing material is taken in, the asbestos-containing material is never released.

  In addition, the present inventors have discovered that water glass is an inorganic substance solution and asbestos is also an inorganic substance, so that the adsorption power of asbestos-containing materials by water glass is increased.

  In the asbestos treatment method of the present invention, in the spraying step, a scattering prevention liquid made of a polyacrylamide solution to which static electricity is applied may be used.

  With such a configuration, even when fine asbestos is scattered in the air in the process of spraying the polyacrylamide solution, the polyacrylamide solution to which static electricity has been applied is also affected by electrostatic attraction. Can be captured. Therefore, the asbestos inclusion capacity of the polyacrylamide solution is further improved.

  In the asbestos treatment method of the present invention, after the aggregation step, the asbestos-containing material formed into a gel is further provided with a mesh having a roughness that does not allow at least the gel-like asbestos-containing material to escape. It has the 1st bagging process accommodated in this mesh bag, It is characterized by the above-mentioned.

  With such a configuration, it becomes easy to handle the asbestos-containing material thereafter, and excess water can be removed while the gel-like asbestos-containing material is stored in the first mesh bag. It becomes like this.

  Here, as a method of storing the gel-like asbestos-containing material accumulated on the floor or the like in the first mesh bag, for example, the gel-like asbestos-containing material accumulated on the floor or the like is scooped with a scoop to form the first mesh. The method of storing in a bag is mentioned. Moreover, the method of attracting | sucking the gel-like asbestos containing material which accumulated on the floor etc. with the air vacuum apparatus, and accommodate | stores in a 1st mesh bag can also be used.

  In the asbestos treatment method of the present invention, after the first bagging step, the first mesh bag is packed into a second mesh bag having a finer mesh than the first mesh bag, It has the dehydration process which throws a dehydrating agent between the 1st mesh bag and the 2nd mesh bag.

  With this configuration, the moisture retained in the flocculant by the dehydrating agent is removed from the first mesh bag, and the volume of the peeled gel-like asbestos-containing material in the first mesh bag is reduced. Will be able to. Therefore, it becomes easy to post-process the peeled asbestos.

  In the asbestos treatment method of the present invention, the concentration of the polyacrylamide solution is preferably 500 ppm or more and 5000 ppm or less. Furthermore, it is more preferable that it is 2000 ppm or more and 3000 ppm or less.

  With such a configuration, the asbestos-containing material is well contained in the polyacrylamide solution, and the asbestos is further prevented from scattering into the air. Here, when the concentration is less than 500 ppm, the asbestos-containing material is hardly contained in the polyacrylamide solution, whereas when the concentration exceeds 5000 ppm, the viscosity of the polyacrylamide solution becomes too high and the asbestos-containing material becomes difficult to be contained.

  Moreover, in the asbestos processing method of this invention, it is preferable that the said water glass is a liquid state at normal temperature.

  With such a configuration, the asbestos-containing material is well contained in the water glass, and asbestos is prevented from scattering into the air. Moreover, it becomes easy to spray water glass on the base-body surface by using such water glass.

In the asbestos treatment method of the present invention, the pressure of the high-pressure water is preferably 50 kg / cm ² or more and 1000 kg / cm ² or less. The pressure of the high-pressure water is preferably 100 kg / cm ² or more and 500 kg / cm ² or less, and more preferably 200 kg / cm ² or more and 400 kg / cm ² .

  With such a configuration, the asbestos-containing material is peeled off favorably from the surface of the base body, and the asbestos-containing material is peeled off in a state of being contained in a scattering prevention liquid made of a polyacrylamide solution or water glass. Become.

  In the asbestos treatment method of the present invention, an aluminum-based flocculant may be used as the flocculant in the aggregation step.

  With such a configuration, by adding an aluminum-based flocculant, the asbestos-containing material that has been peeled off and contained in the polyacrylamide solution becomes a flock-like precipitate while being contained in the polyacrylamide solution. Can be separated.

  The asbestos treatment method of the present invention includes, after the aggregation step, a separation step of separating the precipitate containing the asbestos-containing material and water, and a reprocessing step of adding an anionic surfactant to the water separated in the separation step. You may have.

  If it is set as such a structure, the water processed by the reprocessing process can be used in order to prepare a polyacrylamide solution again. Therefore, since water resources can be used effectively, the transportation of water can be reduced, and for example, work on a higher floor of a building becomes easier.

  According to the asbestos treatment method of the present invention, when asbestos-containing material is peeled from the surface of the basic body, scattering of asbestos into the air is prevented. Moreover, it becomes easy to post-process the asbestos-containing material peeled from the base body surface.

Embodiments of the present invention will be described below with reference to the drawings.
(First embodiment)
FIG. 1 is a flowchart showing a processing flow of the asbestos processing method according to the first embodiment of the present invention. FIG. 2 is a schematic view showing some steps in the asbestos treatment method of FIG. Hereinafter, the asbestos processing method according to the present embodiment will be described with reference to FIGS. 1 and 2.

  As shown in FIG. 1, the asbestos treatment method according to this embodiment includes a spraying process A, a peeling process B, an aggregating process C, a first bagging process D, a second bagging process E, and a dehydrating process. F, a third bagging process G, and a final processing process H.

In the spraying step A, a polyacrylamide solution, which is a scattering prevention liquid, is sprayed at a low pressure (for example, a discharge pressure of about 1 kg / cm ² ) on the asbestos-containing material on the surface of the basic body. Here, the surface of the building material used for the ceiling or pillar of a building is mentioned as the foundation body surface. When the polyacrylamide solution is sprayed on the asbestos-containing material on the surface of the basic body, the asbestos-containing material is included in the polyacrylamide solution, so that asbestos hardly scatters in the air. The polyacrylamide solution is preferably prepared at a concentration of 500 ppm to 5000 ppm. Furthermore, it is more preferable to adjust the concentration to 2000 ppm or more and 3000 ppm or less. By setting it as such a concentration range, the asbestos-containing material is more reliably included in the polyacrylamide solution.

In the peeling process B, the asbestos-containing material enclosed by the polyacrylamide solution is peeled from the surface of the base body. Here, once the peeled asbestos-containing material is included in the polyacrylamide solution, the polyacrylamide solution never releases the peeled asbestos-containing material. As a means for peeling off the asbestos-containing material, a means for jetting water pressurized to a high pressure can be used. Further, as other means for peeling off the asbestos-containing material, a means for peeling off using a scraper can be used. Here, the water to be sprayed is preferably pressurized to 50 kg / cm ² or more and 1000 kg / cm ² or less, more preferably 100 kg / cm ² or more and 500 kg / cm ² or less, and even more preferably 200 kg / cm 2. More preferably, it is ² or more and 400 kg / cm ² . By spraying water at such a pressure, the asbestos-containing material is peeled well from the surface of the base body, and the asbestos-containing material is peeled in a state of being contained in the polyacrylamide solution.

  In addition, it is preferable to perform the spraying process A and the peeling process B in a substantially sealed space in order to prevent leakage to the outside even if a small amount of asbestos is scattered. Or even if it is not a substantially sealed space, in order to prevent the worker from sucking asbestos, for example, the air is blown along the surface of the base body, and the spraying process A and the peeling process B are performed while collecting the asbestos in the direction where there is no worker. May be performed.

  In the coagulation step C, the coagulant is sprinkled on the asbestos-containing material that has been contained in the polyacrylamide solution and peeled as described above. When the flocculant is sprinkled onto the peeled asbestos-containing material, a gel-like lump 1 is obtained. Here, as the flocculant, for example, a water-absorbing polymer material (water-absorbing polymer) can be used. As this water-absorbing polymer material, for example, starch-based, carboxymethylcellulose-based, polyacrylic acid-based, and poval-based materials can be used.

  In the first bag filling process D, as shown in FIG. 2A, the gel-like lump 1 of the asbestos-containing material aggregated by the flocculant is put into the first mesh bag 2. Here, as a method of storing the gel-like lump 1 of the asbestos-containing material aggregated by the flocculant in the first mesh bag 2, for example, the gel-like lump 1 is scooped with a scoop and the first mesh bag. The method of storing in 2 is mentioned. Moreover, the method of attracting | sucking the gel-like lump 1 with an air vacuum apparatus, and accommodating in the 1st mesh bag 2 can also be used. As said 1st mesh bag 2, the thing of the coarseness which the gel-like lump 1 of the asbestos containing material aggregated with the coagulant does not leak outside is used. Here, as the first mesh bag 2, for example, a sandbag bag can be used.

  In the second bag filling process E, as shown in FIG. 2 (b), the first mesh bag 2 bagged in the first bag filling process D is put into the second mesh bag 3. Here, the mesh of the second mesh bag 3 is finer than the mesh of the first mesh bag 2. For example, as the roughness of the second mesh bag 3, it is preferable to use a mesh having a size of 0.1 μm to 0.2 μm. Here, by using a material having such a coarse mesh, the fibrous asbestos of the asbestos-containing material is prevented from flowing out of the second mesh bag 3. In this case, it is more preferable that a flocculant (water-absorbing polymer) is also placed in the bottom of the second mesh bag 3. This is because even if asbestos taken into the gel-like lump 1 flows out of the first mesh bag 2, it is taken in again by the flocculant at the bottom of the second mesh bag 3. .

  In the dehydration step F, the dehydrating agent 4 is put in the gap between the first mesh bag 2 and the second mesh bag 3 as shown in FIG. If it does in this way, water will be taken out by the dehydrating agent 4 from the water-absorbing polymer material in the state which absorbed water in the 1st mesh bag 2, and it will dehydrate. However, as explained in the second bagging step E, fibrous asbestos out of the asbestos-containing material does not flow out from the second mesh bag 3. And the volume of the gel-like lump 1 incorporating the asbestos-containing material is about 1/10 of the volume when water is absorbed. By reducing the volume of the gel-like lump 1 in this way, processing in the final processing step H described later becomes easy. Here, the dehydrating agent 4 can be used without particular limitation as long as it dehydrates water from the first mesh bag 2. For example, an inorganic salt such as sodium chloride, potassium chloride, calcium chloride, or magnesium chloride, which is a salt that dehydrates water from the first mesh bag 2 by the osmotic pressure effect, or an organic salt can be used.

  In the third bag filling process G, as shown in FIG. 2 (d), the second mesh bag 3 dehydrated in the dehydration process F is wrapped in a third bag 5. Here, wrapping in the third bag 5 prevents further leakage of water from the sufficiently drained second mesh bag 3 and prevents asbestos from jumping out of the second mesh bag 3. Because. Therefore, when the second mesh bag 3 dehydrated in the dehydration step F is wrapped in a double or triple manner by the third bag 5, this effect becomes greater. Here, the third bag 5 can be used without particular limitation as long as it is made of a material that does not leak water to the outside. For example, a bag made of a material such as polyethylene or polypropylene can be used.

In the final processing step H, the third bag 5 in which the second mesh bag 3 is packed in the third bagging step G is finally processed. For example, the third bag 5 in which the second mesh bag 3 is packed is incinerated or landfilled.
(Second Embodiment)
FIG. 3 is a flowchart showing a processing flow of the asbestos processing method according to the second embodiment of the present invention.

  As shown in FIG. 3, the asbestos treatment method according to this embodiment includes a spraying process A, a peeling process B, an aggregating process C, a separating process S, a reprocessing process T, and a final processing process H. . In the asbestos treatment method of this embodiment, the steps up to the peeling step B are the same as those in the first embodiment, and the steps after the aggregation step C are changed.

  First, the mixture of the asbestos-containing material and water peeled in the state of being encapsulated in the polyacrylamide solution in the peeling step B is collected by means such as an air vacuum device.

  In the aggregation step C, an aluminum-based aggregating agent is added to the collected mixture of the asbestos-containing material and water. When an aluminum flocculant is added to the mixture of the asbestos-containing material and water, a floc-like precipitate is generated. Here, as the aluminum-based flocculant, for example, aluminum sulfate or polyaluminum chloride can be used.

  Next, in the separation step S, the floc-like precipitate generated in the aggregation step C and water are separated. As a method for separating the flock-like precipitate and water, a known method such as filtration can be used. The separated floc-like precipitate contains polyacrylamide containing asbestos-containing material. The separated floc-like precipitate is processed in the final processing step H. Examples of the final processing step H include incineration processing and landfill processing.

  On the other hand, the separated water contains aluminum ions derived from the aluminum-based flocculant. Therefore, the following reprocessing step T is performed on the separated water.

  In the reprocessing step T, an anionic surfactant is added to the separated water. Then, the aluminum ion in water is electrically neutralized by the anionic surfactant. The electrically neutralized water can again be used to prepare a polyacrylamide solution. Therefore, water resources can be used effectively. Here, as the anionic surfactant, for example, a polycarboxylic acid surfactant can be used.

The reuse of the water separated as described above into the polyacrylamide solution will be described in the section of the polyacrylamide solution spraying apparatus.
(Third embodiment)
In the asbestos treatment method of the third embodiment, water glass is used in place of the polyacrylamide solution as the anti-scattering solution, and other treatments are the same as in the first embodiment.

That is, in the spraying step A, sprayed at low pressure water glass is shatterproof liquid to asbestos compounds basal surface (e.g., the discharge pressure is 1 kg / cm ² or so). When water glass is sprayed on the asbestos-containing material on the surface of the basic body, the asbestos-containing material is contained in the water glass, so that asbestos hardly scatters in the air. Here, the water glass is prepared by, for example, dissolving sodium silicate in water. In this embodiment, the water glass is in a liquid state at room temperature. By using such a water glass, the asbestos-containing material is well contained in the water glass, and asbestos is prevented from scattering into the air. Easy to spray.

Next, in the peeling process B, the asbestos-containing material enclosed by the water glass is peeled from the surface of the base body. Here, once the peeled asbestos-containing material is contained in the water glass, the water glass never releases the peeled asbestos-containing material. As a means for peeling off the asbestos-containing material, a means for jetting water pressurized to a high pressure can be used. Further, as other means for peeling off the asbestos-containing material, a means for peeling off using a scraper can be used. Here, the water to be sprayed is preferably pressurized to 50 kg / cm ² or more and 1000 kg / cm ² or less, more preferably 100 kg / cm ² or more and 500 kg / cm ² or less, and even more preferably 200 kg / cm 2. More preferably, it is ² or more and 400 kg / cm ² . By injecting water at such a pressure, the asbestos-containing material is exfoliated well from the surface of the base body, and the asbestos-containing material is exfoliated while being encapsulated in water glass.

  In the agglomeration step C, the aggregating agent is sprinkled on the asbestos-containing material that has been contained in the water glass and peeled off as described above. When the flocculant is sprinkled onto the peeled asbestos-containing material, a gel-like lump 1 is obtained. Here, as the flocculant, for example, a water-absorbing polymer material (water-absorbing polymer) can be used. As this water-absorbing polymer material, for example, starch-based, carboxymethylcellulose-based, polyacrylic acid-based, and poval-based materials can be used.

  And about the 1st bagging process D, the 2nd bagging process E, the dehydration process F, the 3rd bagging process G, and the final process process H which are the processes after the above, it is the same as that of the said 1st Embodiment. .

  Also in the asbestos processing method of this embodiment, there exists an effect that removal of asbestos can be performed, preventing scattering of asbestos.

  Moreover, since water glass is an inorganic substance and asbestos is also an inorganic substance, the adsorption power of the asbestos containing material by water glass becomes high.

Furthermore, no harmful substances such as dioxins are generated even when landfilled or incinerated (low temperature incineration) at the time of final disposal.
[Polyacrylamide solution spraying equipment]
Next, the polyacrylamide solution spraying apparatus used in the spraying step A in the asbestos treatment method of the first embodiment of the present invention will be described.

  FIG. 4 is a schematic view showing a polyacrylamide solution spraying apparatus used in the asbestos treatment method of the present invention.

  The polyacrylamide solution spraying apparatus includes a polyacrylamide tank 11, a water tank 12, a pump 14 connected to the polyacrylamide tank 11 and the water tank 12, a mixing tank 15 connected to the pump 14, and the mixing A spray nozzle 17 connected to the tank 15 is included.

  The polyacrylamide tank 11 stores a polyacrylamide solution in which polyacrylamide is dissolved. Here, the concentration of the polyacrylamide solution is provisionally prepared and is higher than the concentration when actually spraying on the asbestos-containing material.

  The water tank 12 stores water for finally preparing the concentration of the polyacrylamide solution stored in the polyacrylamide tank 11.

  The pump 14 is connected to the polyacrylamide tank 11 and the water tank 12 through a pipe 13. Here, the pump 14 sucks a predetermined amount of polyacrylamide solution from the polyacrylamide tank 11 and also sucks a predetermined amount of water from the water tank 12 and sends it to the mixing tank 15 described later.

  The mixing tank 15 is connected to the pump 14 via the pipe 13. The mixing tank 15 adjusts a polyacrylamide solution having a desired concentration by mixing the polyacrylamide solution sucked by the pump 14 from the polyacrylamide tank 11 and the water sucked by the pump 14 from the water tank 12. Here, the desired concentration of the polyacrylamide solution is a concentration of 500 ppm or more and 5000 ppm or less as described above. More preferably, the concentration is 2000 ppm or more and 3000 ppm or less. By setting it as such a concentration range, an asbestos-containing material comes to be fully included in a polyacrylamide solution.

The spray nozzle 17 is connected to the mixing tank 15 via a hose 16. Here, the asbestos-containing material is contained by the polyacrylamide solution sprayed by the spray nozzle 17. For the spray nozzle 17, in order to make the polyacrylamide solution into a mist, for example, a spray nozzle having a large number of holes is used. Here, when the polyacrylamide solution is sprayed on the asbestos-containing material, it is sprayed at a low pressure as much as possible. This is because if the polyacrylamide solution is sprayed onto the asbestos-containing material at a high pressure, asbestos may be scattered in the air.
(Modification 1)
FIG. 5 is a schematic view showing a modification of the polyacrylamide solution spraying apparatus used in the asbestos treatment method of the present invention.

  As shown in FIG. 5, in the polyacrylamide solution spraying apparatus of this modification, a static electricity applying device 30 is attached to the spray nozzle 17. As the static electricity applying device 30, a known device can be used. About another structure, it is the same as that of the polyacrylamide solution spraying apparatus shown in FIG.

With such a configuration, static electricity can be applied to the sprayed polyacrylamide solution. Therefore, even when there is asbestos scattered in the air in the process of spraying the polyacrylamide solution in the spraying step A, the polyacrylamide solution can take in this asbestos by electrostatic attraction.
(Modification 2)
FIG. 6 is a schematic view showing a polyacrylamide solution spraying apparatus used in the second embodiment.

  In the polyacrylamide solution spraying apparatus of this modification, a second treatment tank 40 and a first treatment tank 50 are provided in the previous stage of the water tank 12. The water tank 12 and the second treatment tank 40 are connected via a pipe 13. The second treatment tank 40 and the first treatment tank 50 are connected via the pipe 13.

  In the first treatment tank 50, the mixture of the asbestos-containing material and water peeled in the state of being encapsulated in the polyacrylamide solution in the peeling step B is collected and put by means such as an air vacuum device. Next, in the first treatment tank 50, an aluminum-based flocculant is added to the mixture of the asbestos-containing material and water. As a result, the mixture of asbestos-containing material and water produces a floc-like precipitate 100. Of these, water is separated by known means (for example, filtration). The water treated in the first treatment tank 50 in this way is called primary treated water. The primary treated water is moved to the second treatment tank 40 through the pipe 13. Here, the primary treated water contains aluminum ions derived from the aluminum-based flocculant. Therefore, the following reprocessing is performed.

  In the second treatment tank 40, an anionic surfactant is added to the primary treated water (reprocessing). In this way, aluminum ions in the primary treated water are electrically neutralized. The water treated in the second treatment tank 40 in this way is called secondary treated water. The secondary treated water can dissolve polyacrylamide again.

The secondary treated water is moved to the water tank 12 through the pipe 13. In this way, the water from which the asbestos-containing material has been removed becomes secondary treated water, and is used again to prepare a polyacrylamide solution. Therefore, water resources can be used effectively. Moreover, since it is sufficient to add new water to the water tank 12 by the amount of water that has been reduced by filtration or the like, it is possible to reduce the amount of water transport, for example, work on a high floor of a building becomes easier.
[Water glass spraying equipment]
Next, the water glass spraying apparatus used in the spraying process A in the asbestos treatment method of the third embodiment of the present invention will be described.

  In the above description, the polyacrylamide solution spraying apparatus that sprays the polyacrylamide solution used as the anti-scattering liquid in the first embodiment and the second embodiment has been described. However, by replacing a part of the configuration of this spraying apparatus, It can also be used as a water glass spraying device for spraying the water glass used as the anti-scattering liquid in the third embodiment.

  Specifically, a water glass tank is used instead of the polyacrylamide tank 11 and water glass in which water glass is dissolved is stored. About the structure of the other water glass spraying apparatus, it is the same as that of a polyacrylamide solution spraying apparatus.

Here, the water glass is in a liquid state at room temperature. By using such a water glass, the asbestos-containing material is sufficiently contained in the water glass, and the water glass is easily sprayed on the surface of the base body.
[High pressure water injection device]
Next, the high-pressure water injection device used in the peeling step B in the asbestos treatment method of the first to third embodiments of the present invention will be described with reference to FIG. FIG. 7 is a schematic view showing a high-pressure water injection device used in the asbestos treatment method of the present invention.

  The high-pressure water injection device includes a water tank 21, a high-pressure pump 23 connected to the water tank 21, an accumulator 24 connected to the high-pressure pump 23, and a high-pressure water injection gun 26 connected to the accumulator 24. Consists of including.

  The water tank 21 stores water sprayed by a high-pressure water spray gun 26 described later.

  The high pressure pump 23 is connected to the water tank 21 via the pipe 22. The high-pressure pump 23 pressurizes and supplies the water sent from the water tank 21 through the pipe 22 to an accumulator 24 described later.

  The accumulator 24 is connected to the high pressure pump 23 via the pipe 22. The accumulator 24 is for stabilizing the injection pressure of high-pressure water sprayed from a high-pressure water injection gun 26 described later.

The high-pressure water spray gun 26 is connected to the accumulator 24 through a hose 25. By jetting high-pressure water from the high-pressure water spray gun 26, the asbestos-containing material is peeled off from the base body surface. Here, the water to be sprayed is preferably pressurized to 50 kg / cm ² or more and 1000 kg / cm ² or less, more preferably 100 kg / cm ² or more and 500 kg / cm ² or less, and further 200 kg / cm 2. More preferably, it is ² or more and 400 kg / cm ² . By spraying water at such a pressure, the asbestos-containing material is peeled well from the surface of the base body, and the asbestos-containing material remains encapsulated in the anti-scattering solution comprising a polyacrylamide solution or water glass. It will come off.

  The asbestos treatment method according to the present invention is useful as a method capable of preventing the asbestos from being scattered in the air when removing the asbestos-containing material from the surface of the basic body and easily treating the removed asbestos-containing material.

It is a flowchart which shows the processing flow of the asbestos processing method of 1st Embodiment of this invention. It is the schematic which shows a one part process among the asbestos processing methods of FIG. It is a flowchart which shows the processing flow of the asbestos processing method of 2nd Embodiment of this invention. It is the schematic which shows the polyacrylamide solution spraying apparatus used for the asbestos processing method of 1st Embodiment of this invention. It is the schematic which shows the modification of the polyacrylamide solution spraying apparatus used in the asbestos processing method of this invention. It is the modification of the polyacrylamide solution spraying apparatus used in the asbestos processing method of this invention, Comprising: It is the schematic which shows the polyacrylamide solution spraying apparatus used for the asbestos processing method of 2nd Embodiment. It is the schematic which shows the high pressure water injection apparatus used for the asbestos processing method of 1st Embodiment of this invention thru | or 3rd Embodiment.

Explanation of symbols

A Spraying process B Peeling process C Aggregation process D First bagging process E Second bagging process F Dehydration process G Third bagging process H Final processing process S Separation process T Reprocessing process 1 Gel-like mass 2 First Mesh bag 3 Second mesh bag 4 Dehydrating agent 5 Third bag 11 Polyacrylamide tank 12, 21 Water tank 13, 22 Pipe 14 Pump 15 Mixing tank 16, 25 Hose 17 Spray nozzle 23 High pressure pump 24 Accumulator 26 High pressure water injection Gun 30 Static electricity application device 40 Second treatment tank 50 First treatment tank 100 Flock-shaped precipitation

Claims (10)

The asbestos treatment method for removing the asbestos-containing material from the surface of the basic body after applying the anti-scattering solution to the asbestos-containing material in advance, has the following steps (a) to (c).
(A) a spraying step of spraying the anti-scattering liquid onto the asbestos-containing material from the low-pressure spray nozzle using the anti-scattering liquid made of water glass, and including the asbestos-containing material in the anti-scattering liquid;
(B) a peeling step of spraying high-pressure water from a high-pressure spray nozzle onto the asbestos-containing material impregnated with the anti-scattering liquid, and peeling the asbestos-containing material from the surface of the basic body;
(C) A coagulation step in which a flocculant is sprinkled on the peeled asbestos-containing material to form a gel. The asbestos treatment method for removing the asbestos-containing material from the surface of the basic body after applying the anti-scattering solution to the asbestos-containing material in advance, has the following steps (a) to (c).
(A) using the anti-scattering liquid comprising a polyacrylamide solution, spraying the anti-scattering liquid onto the asbestos-containing material from a low-pressure spray nozzle, and enclosing the asbestos-containing material in the anti-scattering liquid;
(B) a peeling step of spraying high-pressure water from a high-pressure spray nozzle onto the asbestos-containing material impregnated with the anti-scattering liquid, and peeling the asbestos-containing material from the surface of the basic body;
(C) A coagulation step in which a flocculant is sprinkled on the peeled asbestos-containing material to form a gel.   The asbestos treatment method according to claim 2, wherein in the spraying step, an anti-scattering solution comprising a polyacrylamide solution to which static electricity is applied is used.    After the agglomeration step, the first bag for storing the gelled asbestos-containing material in a first mesh bag having a mesh with a roughness that does not allow at least the gelled asbestos-containing material to escape. The asbestos treatment method according to claim 1, further comprising a stuffing step.   After the first bagging step, the first mesh bag is packed into a second mesh bag having a finer mesh than the first mesh bag, and the first mesh bag and the second mesh bag. The asbestos treatment method according to claim 4, further comprising a dehydration step of adding a dehydrating agent between the two.   The asbestos treatment method according to any one of claims 2 to 5, wherein the concentration of the polyacrylamide solution is 500 ppm or more and 5000 ppm or less.   The asbestos treatment method according to claim 1, wherein the water glass is in a liquid state at room temperature. The asbestos treatment method according to claim 1, wherein the pressure of the high-pressure water is 50 kg / cm ² or more and 1000 kg / cm ² or less.   The asbestos treatment method according to claim 2, wherein an aluminum-based flocculant is used as the flocculant in the aggregation step.   After the coagulation step, the method includes a separation step of separating the precipitate containing asbestos-containing material and water, and a reprocessing step of adding an anionic surfactant to the water separated in the separation step. The asbestos processing method of Claim 9.

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