JP5151377B2 - Deposit processing apparatus and deposit processing method - Google Patents

Description

  The present invention relates to a deposit processing apparatus and a deposit processing method, and more particularly, to a deposit processing apparatus installed in a structure having a longitudinal direction along a vertical direction, and a longitudinal space defined by the structure. The present invention relates to a deposit processing method for performing processing related to deposits adhering to the surface of an object in space (hereinafter referred to as “attachment related processing”).

  An elevator shaft is a structure having a longitudinal direction along the vertical direction. In the internal space defined by the elevator shaft, a cage (cage) for carrying people and things moves up and down.

In order to prevent dust and the like from adhering to the cage, the wall surface of the elevator shaft, and the like, dust is collected by providing a duct and a dust collector in the elevator shaft (see, for example, Patent Document 1). In the technique described in Patent Document 1, a plurality of air intakes are provided in a duct, and the air intakes are arranged at intervals in the vertical direction in the elevator shaft. As a result, the dust collector sucks the air at every position in the elevator shaft together with dust such as dust floating in the air via a plurality of air intakes of the duct, and collects the dust when exhausting it. (Dust collection). As a result, the amount of dust in the elevator shaft is reduced.
JP 07-228446 A

  However, although the above-described technique can reduce the amount of dust in the elevator shaft, cleaning in the elevator shaft (attachment related processing) is not completely unnecessary.

  Here, the cleaning work is normally performed in the order from the high place to the low place in the elevator shaft. Dust such as dust generated at this time is scattered around the place where the cleaning work is performed. That is, dust is locally generated in the elevator shaft. However, in the above-described technology, as a result of the intake ports at every position in the elevator shaft, the exhaust capacity of the dust collector (the number of ventilations per unit time) is distributed to each intake port. In this case, the dust generated locally cannot be collected efficiently.

  The local generation of dust is not limited to the cleaning work, and for example, asbestos adhering to the object surface (ceiling surface, wall surface, elevator door surface, etc.) in the elevator shaft. It also occurs when taking measures (for example, removing) against harmful substances such as (asbestos).

  An object of the present invention is to provide a deposit processing apparatus capable of selecting to improve exhaust efficiency locally in a longitudinal space in which a structure is defined, and the structure is defined by using the deposit processing apparatus. An object of the present invention is to provide a deposit processing method for performing deposit related processing in a longitudinal space.

In order to achieve the above object, the deposit treatment apparatus of the present invention is an deposit treatment apparatus installed in a structure having a longitudinal direction along the vertical direction,
A duct having a first inlet, a second inlet, and an exhaust;
A first shielding member capable of shielding the first air inlet;
A second shielding member capable of shielding the second air inlet;
An exhaust device that takes in air through an intake port opened by the first shielding member or the second shielding member, and exhausts the captured air by moving the air toward the exhaust port;
With
The exhaust device is a dust collector connected to the exhaust port;
The dust collector is provided with a first filter,
The duct is installed in the structure such that the first air inlet and the second air inlet are aligned vertically in the longitudinal direction in a longitudinal space defined by the structure,
The deposit processing apparatus is used when processing related to deposits attached to the surface of an object in the longitudinal space,
Each of the ducts is provided with a second filter at a position corresponding to the first air inlet and the second air inlet, and the second filter is a filter having a coarser mesh than the first filter. Yes,
By partitioning the longitudinal space in a direction intersecting the longitudinal direction, an upper space including the first shielding member and the first air inlet, and a lower space below the upper space, the second shielding member. And a partition member that partitions the lower space including the second air inlet,
When the processing is performed in the upper space,
The first air inlet is opened by the first shielding member, and the second air inlet is shielded by the second shielding member;
When the processing is performed in the lower space,
The second air inlet is opened by the second shielding member, and the first air inlet is shielded by the first shielding member;
The first air inlet is at a lower portion of the upper space;
The second air inlet is in the lower part of the lower space;
In order to drop the deposit from the surface of the object, a spray device capable of spraying granular dry ice to the object,
In the upper space, the duct has a third air inlet different from the first air inlet and the second air inlet,
The third air inlet is located in the vicinity of a scaffold installed in the upper space;
A third shielding member capable of shielding the third air inlet;
When the processing is performed in the upper space, the third intake port is opened by the third shielding member .

  Furthermore, in the deposit processing apparatus, it is further preferable that a gas supply device for supplying a gas containing oxygen from an upper portion of the space in which the spraying device is used among the upper space and the lower space is provided. Thereby, oxygen can be supplied to the worker who performs work using dry ice in the space.

  Moreover, the deposit processing method which performs the deposit | attachment related process regarding the deposit | attachment adhering to the surface of the object in the said longitudinal space in said longitudinal space using said deposit | attachment processing apparatus may be sufficient. .

  In the deposit treatment method, the deposit-related process includes a removal process for removing the deposit from the surface of the object by applying an external force to the deposit, and a method using the chemical solution. It is preferable that the at least one process selected from a process group consisting of a containment process for containing a kimono and an enclosing process surrounding the deposit. Thereby, in the case of a removal process, a deposit | attachment can be dropped, and in the case of a containment process or an enclosure process, the fall of a deposit | attachment can be prevented.

  According to the deposit processing apparatus and the deposit processing method of the present invention, the first intake port arranged vertically in the longitudinal direction in the longitudinal space defined by the structure using the first shielding member and the second shielding member. It is possible to select shielding of the second intake port. When both openings of the first intake port and the second intake port are selected, the exhaust device can disperse its exhaust capability to both intake ports. On the other hand, when one opening of the first intake port and the second intake port is selected, the exhaust device can concentrate the exhaust capability on the intake port in the open state, and locally in the vicinity of the intake port. The exhaust efficiency increases. Therefore, according to the present invention, by using the first shielding member and the second shielding member, it is possible to select to improve the exhaust efficiency locally in the longitudinal space defined by the structure.

  Embodiments of the present invention will be described below with reference to the drawings. In the following embodiments (first embodiment and second embodiment), deposit-related processing (cleaning work and asbestos removal work described later) is performed in the longitudinal space defined by the elevator shaft. The elevator shaft is an example of a structure having a longitudinal direction along the vertical direction.

  FIG. 1 is a longitudinal sectional view showing a schematic configuration of a building in which a cleaning device as an attached matter processing device according to the first embodiment is installed.

  A building 10 shown in FIG. 1 is a building having a multilayer structure including a first-floor portion to a fifth-floor portion, and an elevator 50 is further installed. Each floor of the building 10 functions as an elevator hall. The floor of the first floor portion of the building 10 is at the same height as the ground surface 1.

  The elevator 50 includes a cage 51 for carrying a person or an object and an elevator shaft 52 that performs a guide for the cage 51 to move up and down in the vertical direction. The cage 51 can be stopped on each floor of the building 10. The elevator shaft 52 is a structure erected in the vertical direction and defines a long space that is long in the vertical direction. A pit 53 is formed at the bottom of the longitudinal space. The pit 53 is for storing the cage 51 at a position lower than the ground surface 1.

  Moreover, as shown in FIG. 1, the building 10 is provided with a duct 110 which is a hollow member, and a dust collector 120 having an exhaust function and a dust collection function. As the duct 110, for example, a flexible duct or a telescopic duct can be used. The flexible duct is a hollow member surrounded by a flexible member having flexibility and airtightness. Since the flexible duct is flexible, the flexible duct can be arbitrarily bent along, for example, a corner portion in the building 10. It is also stretchable. The telescoping duct is formed so that it can be expanded and contracted stepwise in the length direction. By using such a flexible duct or a telescope type duct, it becomes easy to install the duct 110 in the indoor space 20 having any size and any shape. Furthermore, since the volume occupied by the outer shape of the duct 110 is reduced by making the flexible duct or the telescopic duct into a contracted state, it is easy to carry.

  The duct 110 has a plurality of intake ports and one exhaust port 119. An exhaust port 119 of the duct 110 is connected to the dust collector 120. The plurality of air inlets of the duct 110 are arranged vertically in the elevator shaft 52 in the longitudinal direction of the elevator shaft 52. In addition, on the outer side surface of the duct 110, an intake selection unit (reference numerals 111 to 116 shown in FIG. 1) capable of shielding each intake port of the duct 110 is provided. The portion of the duct 110 where the intake selection unit is provided is preferably formed of a member different from the flexible duct or the telescopic duct, and the intake selection unit can be easily configured by using a rigid housing as the member. Can be provided. In addition, by making the shape of the casing in which the intake selection unit is provided rectangular, it is easy to install the intake selection unit so that it does not face the wall surface 52a of the elevator shaft 52, for example.

  The duct 110 is installed such that a plurality of intake air selection units are arranged vertically in the vertical direction as shown in FIG. The interval between two adjacent intake selection units is equal to the height dimension of each floor of the building 10, for example. Therefore, the plurality of intake selection units are arranged at equal intervals. By setting the interval in this way, the intake selection unit can be easily positioned when the duct 110 is installed in the elevator shaft 52. The configuration of the intake air selection unit will be described later with reference to FIG.

  For example, the dust collector 120 is installed on the first floor portion of the building 10 and, when activated, exhausts air in the direction of arrow A shown in FIG. 1 (exhaust function). When exhausting, the dust collector 120 takes in the air in the elevator shaft 52 (see arrow B) via the intake port that is not shielded by the intake selection unit, and moves the intake air toward the exhaust port 119. become. The dust collector 120 includes a thin film filter (not shown) that is fine enough to allow ventilation. When the air in the elevator shaft 52 is sucked in, the dust collector 120 also sucks dust such as dust floating in the air, and collects the dust with the thin film filter during exhaust (dust collecting function). Thereby, the air exhausted by the exhaust function of the dust collector 120 is dedusted, and as a result, is cleaned.

  As described above, since the duct 110 having the air inlet is installed in the elevator shaft 52, the dust collector 120 connected to the duct 110 is operated during normal operation of the elevator 50 or during a cleaning operation described later. As a result, the amount of dust in the elevator shaft 52 can be reduced.

  FIG. 2 is a partially enlarged side view of the duct 110 shown in FIG. As described above, a plurality of intake air selection units are provided on the side surface of the duct 110. Two intake selection units 114 and 115 are shown in the partially enlarged view of FIG.

  In FIG. 2, the intake selection unit 115 is provided at a position corresponding to an intake port 115 a that is one of a plurality of intake ports of the duct 110. The intake selection unit 115 includes a door 115b as a shielding member that shields the intake port 115a, and a lock mechanism (not shown) that controls opening and closing of the door 115b. The other intake selection units are also configured in the same manner as the intake selection unit 115. For example, the intake selection unit 114 includes a door 114b as a shielding member that shields a corresponding intake port.

  In the example shown in FIG. 2, the intake selection unit 115 out of the two intake selection units 114 and 115 is in a state where the lock of the door 115 b is released (door open state). As a result, the intake port 115a is opened and the inflow of air into the duct 110 is allowed. Therefore, by setting the intake selection unit to the door open state, the corresponding intake port and the exhaust port 119 communicate with each other, whereby the exhaust path from the arrow B to the arrow A shown in FIG. Secured. On the other hand, the intake selection unit 114 is in a state where the door 114b is locked (door closed state), and thereby the corresponding intake port is shielded.

  Further, in the example shown in FIG. 2, a filter 115c is installed in the duct 110 at a position corresponding to the intake port 115a. The filter 115c is a filter having a coarser mesh than that of the thin film filter included in the dust collector 120, and functions as a prefilter that makes the thin film filter less likely to be clogged. Thereby, the exchange frequency of the thin film filter with which the dust collector 120 is provided can be suppressed. A filter such as the filter 115c is also installed at a position corresponding to each of the intake ports other than the intake port 115a.

  As described with reference to FIG. 2, the duct 110 is provided with the intake selection units 114 and 115, so that one of the door open state and the door closed state can be selected for each intake selection unit. Yes, according to the selection result, shielding / opening of the corresponding intake port is determined. In practice, since a plurality (three or more) of intake selection units are provided in the duct 110, the number of intake ports that can select shielding or opening is not limited to two. Accordingly, the duct 110 has a high degree of freedom when selecting the shielding or opening of the intake port.

  Here, during normal operation of the elevator 50, the door open state is selected for all the intake selection units of the duct 110. For this reason, all the air inlets which the elevator shaft 52 has are in an open state, and the dust collector 120 can take in air through all the air inlets (intake). In this state, the exhaust function of the dust collector 120 is distributed to all the intake ports.

  Therefore, during normal operation of the elevator 50, the dust collector 120 can collect dust floating in the elevator shaft 52 from any location in the elevator shaft 52. Here, since the dust is generated during the normal operation of the elevator 50 as the cage 51 is moved up and down and a person gets on and off, the location where the dust is generated is not specified. For this reason, as described above, the amount of dust in the elevator shaft 52 can be efficiently reduced by collecting the dust from every location.

  However, since the amount of dust in the elevator shaft 52 is not completely eliminated, a part of the generated dust is caused by the surface of the object in the elevator shaft 52 (the surface of the cage 51, the ceiling surface, the wall surface 52a, the door of the elevator 50). Adhere to partial surfaces. Therefore, it is necessary to periodically perform a cleaning operation for cleaning the inside of the elevator shaft 52. The cleaning operation is mainly performed by removing dust and other attached substances from the object surface in the elevator shaft 52. Therefore, the cleaning work is an example of the deposit related process. Hereinafter, the procedure of the cleaning work and the like will be described in detail.

  In order to perform the cleaning work, first, as shown in FIG. 1, a cleaning device 100 used when performing the cleaning work is installed in the building 10. The cleaning device 100 includes a vertical partition member 140 and an air blast machine 150 that can inject air in a compressed state, and further includes the duct 110 and the dust collector 120. That is, in the present embodiment, an existing duct and a dust collector are used during the cleaning operation. In other words, it can be said that the existing duct and dust collector form part of the cleaning device 100.

  Specifically, the air blast machine 150 is placed on the housing of the cage 51, and the vertical partition member 140 is installed so as to be vertical in the elevator hall on each floor of the building 10. Here, the vertical partition member 140 is configured by a highly airtight sheet-like member, and is, for example, a sheet made of PET (polyethylene terephthalate). By installing the vertical partition member 140, the elevator hall is partitioned. Thereby, the space on the elevator shaft 52 side is isolated from the space in the building 10 as a cleaning work place. Each vertical partition member 140 is provided with a door (not shown) that can be opened and closed so that a worker can directly enter the cleaning work place.

  Subsequently, the worker gets into the housing of the cage 51 from the elevator hall on the first floor. That is, the housing of the cage 51 is used as a scaffold for cleaning work. Therefore, it can be said that the cage 51 forms a part of the cleaning device 100. Then, the worker moves to the uppermost part (high place) in the elevator shaft 52 using the cage 51. During this movement, the worker places the intake selection unit in the low place (in the example shown in FIG. 1, the intake selection units 111, 112, 113,...) In the door closed state and is in the high place (near the cage 51). The intake selection unit maintains the door open state. In addition, you may perform selection of the door open state or door closed state of an intake selection unit by remote control.

  Subsequently, the worker starts a cleaning operation using the air blast machine 150 while the dust collector 120 is in operation. Specifically, the worker blows compressed air jetted by the air blast machine 150 onto an object on the elevator shaft 52. Due to the collision energy generated at the time of spraying, adhering substances such as dust adhering to the object in the elevator shaft 52 fall off from the object surface.

  As described above, when the air blast machine 150 is used, a large amount of dust such as dust is locally generated in the space on the elevator shaft 52 side centering on the place where the cleaning operation is performed. However, the generated dust is collected by a filter provided at an intake port not shielded by the intake selection unit or a thin film filter of the dust collector 120. In this way, the cleaning work at the uppermost part of the elevator shaft 52 is completed. In addition, since the vertical partition member 140 is installed, dust does not scatter to the elevator hall.

  When the cleaning work at the uppermost part of the elevator shaft 52 is completed, it moves downward from the uppermost part and performs the same cleaning work at the moved position, for example, the position of the cage 51 shown in FIG. In the example shown in FIG. 1, during movement, the worker places the intake selection units 116 and 115 near the cage 51 in the door open state, and maintains the door open state during the cleaning work at the top ( The intake selection unit 116 above the intake selection unit 116) is set to the door closed state.

  Then, the above-described operation is repeated, and finally the cleaning operation at the lowermost part (pit 53) of the elevator shaft 52 is performed. The cleaning work in the pit 53 does not use the cage 51 as a scaffold, and the worker performs the cleaning work on the bottom surface 53a of the pit 53. In this way, the cleaning work in the elevator shaft 52 is completed.

  According to the cleaning operation as described above, even if the position of the cage 51 (cleaning position) changes, the intake selection unit in the vicinity of the cage 51 is in the door open state (intake port open state) and not in the vicinity of the cage 51. The air intake selection unit is in the door closed state (air inlet shielding state). At this time, since the exhaust function of the dust collector 120 is concentrated only on the intake port in the open state, in the dust collector 120, the exhaust efficiency of the exhaust through each intake port is greater than when all the intake ports are in the open state. Will increase. That is, in the present embodiment, the dust generated locally is quickly and efficiently collected by increasing the exhaust efficiency of the exhaust through the intake port near the cleaning position where dust is likely to be generated. For this reason, dust does not stay in a state of floating in the elevator shaft 52 for a long time, and the dust collection efficiency by the dust collector 120 is very high. Thereby, it is suppressed that dust adheres to the object in the elevator shaft 52 as a result of not being collected.

  After the cleaning operation is completed, all the intake selection units are opened, and the vertical partition member 140 and the air blast machine 150 are removed. By doing in this way, it becomes possible to restart the collection of the dust at the time of the normal operation of the elevator 50.

  In the first embodiment described above, the cage 51 is used as a scaffold during cleaning work. However, a gondola (wall maintenance lift) that replaces the cage 51 may be installed and used as a scaffold. You may build a foothold from the elevator hall on each floor without installing.

  In the above-described embodiment, the air blast machine 150 is used in the cleaning operation. However, instead of the air blast machine 150, a dry ice blast machine capable of spraying granular dry ice may be used. When a dry ice blasting machine is used, carbon dioxide gas is generated as a result of sublimation (vaporization) of dry ice (solid). Therefore, during the cleaning operation, the intake selection unit 111 in the pit 53 is always in the door open state. It is preferable to do. This is because carbon dioxide gas has a specific gravity greater than that of air, and thus tends to stay in the pit 53 at the bottom of the elevator shaft 52. Thereby, carbon dioxide gas can be exhausted quickly and efficiently, and the safety of workers can be ensured reliably.

  Further, in the above-described embodiment, the existing duct is used for the cleaning operation. However, for example, when the intake selection unit is not provided in the existing duct, the intake selection unit is provided. Moreover, instead of using the existing duct and dust collector during the cleaning work, a duct and dust collector dedicated to the cleaning work may be prepared.

  Next, a second embodiment of the present invention will be described. In the first embodiment described above, the cleaning operation is performed in the elevator shaft 52. In the present embodiment, the asbestos removal operation is performed in the elevator shaft 52. For this reason, in the present embodiment, the same or similar configurations and components of the building and the apparatus as those in the first embodiment described above are denoted by the same or similar reference numerals, and description thereof is omitted. .

  In the asbestos removal work, there is a work of peeling / dropping off asbestos, which is a harmful substance attached to these objects, from the object surface (the ceiling surface, the wall surface 52a, the door part surface of the elevator 50, etc.) in the elevator shaft 52. Become the center. Therefore, the asbestos removal operation is an example of the deposit related process. The asbestos removal operation is preferably performed when replacement is performed as a result of aging of the elevator 50. This is because the existing cage 51 is removed from the elevator shaft 52 during the update, so that the entire wall surface 52a of the elevator shaft 52 is exposed.

  FIG. 3 is a flowchart showing the steps of asbestos removal work using the asbestos removal apparatus as the deposit processing apparatus according to the second embodiment.

  In FIG. 3, first, in the first step (step S1: asbestos removal device installation step), the asbestos removal device 100 ′ used when performing asbestos removal work is installed in the elevator shaft 52 in the building 10 and in the vicinity thereof ( (See FIG. 4).

  As shown in FIG. 4, the asbestos removal apparatus 100 ′ includes a duct 110 ′ and a dust collector 120 ′ prepared exclusively for asbestos removal work, and a dry ice blast machine 160 described later. The configuration of the duct 110 'is the same as that of the duct 110 described above. However, the length of the portion arranged in the vertical direction of the duct 110 ′ can be appropriately selected according to the area of the work place for asbestos removal work. In the example shown in FIG. The length is equivalent to the height of the minute. The dust collector 120 ′ is configured in the same manner as the dust collector 120 described above, but includes a high efficiency particle air filter (HEPA filter) with high dust collection efficiency. In addition, the dust collector 120 ′ has an exhaust capacity that is high enough to allow the workplace to be set to a negative pressure in order to realize ventilation of the workplace.

  The asbestos removal apparatus 100 ′ includes a vertical partition member 140, an upper horizontal partition member 141, and a lower horizontal partition member 142. Furthermore, the asbestos removal apparatus 100 ′ includes a blower 130. Here, in the first step, among the components of the asbestos removal device 100 ′, components other than the horizontal partition members 141 and 142 and the blower 130 are installed.

  In the first step, a gondola 210 and a security zone 220 are installed as incidental facilities for the asbestos removal apparatus 100 ′. The gondola 210 is installed in place of the removed cage 51. The gondola 210 includes a scaffold 211 for asbestos removal work, a wire 212 for suspending the scaffold 211 from above, and a winding device (not shown) that winds the wire 212. As with the cage 51, the scaffold 211 can move up and down in the elevator shaft 52. Accordingly, the gondola 210 is installed to facilitate the use of the asbestos removal apparatus 100 '. The security zone 220 is installed on the first floor portion of the building 10 and includes a front room and an air shower room. The front room of the security zone 220 serves as an entrance for workers to enter and exit the workplace. Therefore, the security zone 220 is installed to prevent leakage of asbestos to the outside due to the worker handling asbestos going out of the workplace.

  Subsequently, in the second step (step S2: workplace curing step), the workplace that performs asbestos removal work is covered. Here, the term “curing” is also referred to as an isolated hermetic curing, and the surroundings of the work place are surrounded and covered with a highly air-tight sheet (for example, a sheet made of PET) to make the space inside the work place a sealed space. Isolation from space (outside the workplace). By curing the workplace, asbestos in the workplace is prevented from leaking outside. In the example shown in FIG. 4, an operator who has entered the scaffold 211 of the gondola 210 installs the lower horizontal partition member 142 below the scaffold 211 and installs the upper horizontal partition member 141 above the scaffold 211. Curing is completed. As shown in FIG. 4, the installation location of the horizontal partition members 141 and 142 is a portion excluding the opening of the door portion of the elevator 50, that is, a boundary between the floors of the building 10.

  At this time, another worker installs the blower 130. The blower device 130 includes a blower 131 and a pipe 132 connected to the blower 131. The blower 131 is installed above the upper horizontal partition member 141, in the example shown in FIG. The pipe 132 is installed so as to penetrate the upper horizontal partition member 141.

  Thereafter, in the third step (step S3: negative pressure setting step), the dust collector 120 'is operated, thereby exhausting the workplace and setting the atmospheric pressure in the workplace to a negative pressure lower than the atmospheric pressure. Moreover, by operating the air blower 130, air moves in the direction of arrow C shown in FIG. Thereby, fresh air (gas containing oxygen) is supplied into the work place. As a result, replacement of the air in the workplace (ventilation) is achieved, so that the worker can easily secure oxygen. The supply amount (supply volume) per unit time of the air supplied by the blower 130 is controlled to be smaller than the exhaust amount (supply volume) per unit time of the air exhausted by the dust collector 120 ′. Thereby, the state where the internal pressure of the work place does not become too low is maintained, and the negative pressure set in the work place is maintained. In this way, by maintaining the negative pressure of the work place, it is possible to prevent dust containing asbestos from moving outside the exhaust path, that is, exposure of asbestos to the outside of the work place.

  In the fourth step (step S4: asbestos removal step), asbestos removal work is performed. Asbestos removal work is carried out in the order from the upper part (high place) to the lower part (low place) of the cured work place. Therefore, the scaffold 211 of the gondola 210 is moved to a high place, and the intake selection unit (the intake selection unit 115 in the example shown in FIG. 4) in the vicinity of the scaffold 211 is brought into the door open state. On the other hand, the other intake selection units are brought into the door closed state. In addition, you may perform selection of the door open state or door closed state of an intake selection unit by remote control.

  Subsequently, in order to remove asbestos from the building 10, the worker applies an external force to the asbestos adhering to an object (such as the wall surface 52a) in the elevator shaft 52. As a result, asbestos peels off from the surface of the object. In the present embodiment, in order to drop off asbestos, first, manual work is performed using a spatula, leather skin, brush, or the like. Subsequently, the worker performs a dry ice blasting method using the dry ice blasting machine 160. In the dry ice blasting method, granular dry ice sprayed by the dry ice blasting machine 160 is sprayed onto an object, and asbestos adhering to the object is dropped from the object surface by collision energy generated at the time of the spraying. If there is a possibility that asbestos may remain without dropping even by these operations, an operation of making the asbestos harmless by applying a chemical to asbestos is also performed.

  Here, the dust containing asbestos that has fallen from the object in the elevator shaft 52 is scattered in the work place, but is collected (collected) by the dust collecting function of the dust collector 120 ′. At this time, since the intake port near the scaffold 211 of the gondola 210 is opened by the intake selection unit, the exhaust capacity of the dust collector 120 ′ is opened as in the first embodiment. Since the exhaust gas is concentrated at the intake port, the exhaust efficiency is increased, so that the dust collection efficiency in the vicinity of the scaffold 211 can be improved.

  When the asbestos removal work proceeds and the asbestos removal work at the lower part of the work place is completed, the asbestos deposited on the lower horizontal partition member 142 is collected manually and stored temporarily.

  Next, it is determined whether there is another section where asbestos removal work should be performed (step S5). In the example shown in FIG. 4, since there is a space below the work place (lower horizontal partition member 142) in the elevator shaft 52, it is determined that there is another section. And when there exists another division (it is YES at step S5), the asbestos removal operation | work is performed by implementing the 2nd process-4th process mentioned above in the division. In the case of the example shown in FIG. 4, first, the horizontal section members 141 and 142 are removed, and then the scaffold 211 of the gondola 210 is moved downward as shown in FIG. This is completed by installing the upper horizontal partition member 141 ′ at the top. In addition, in the example shown in FIG. 5, since it becomes the lowest division of the elevator shaft 52, a lower horizontal division member is unnecessary.

  On the other hand, when there is no other section, that is, when the asbestos removal work at the work place including the pit 53 of the elevator shaft 52 is completed as shown in FIG. 5 (NO in step S5), the asbestos removal work is completed. The asbestos collected and temporarily stored in a plurality of sections (workplaces) is transported to the final disposal site. In addition, the asbestos removal apparatus 100 ′ and its associated equipment installed for carrying out the asbestos removal work are removed.

  According to the process of FIG. 3, since the curing of the workplace is performed by the horizontal partition members 141, 142, etc., a long space that is long in the vertical direction can be divided. As a result, the exhaust capacity (the number of ventilations per unit time) of the dust collector 120 ′ can be increased, and the dust collection efficiency of the dust collector 120 ′ is increased.

  Further, when the asbestos removal work is performed in the cured work space, the air intake near the scaffold 211 in the work place is in an open state and the air intake that is not in the vicinity of the scaffold 211 (the air intake outside the work place). (Including the mouth) is in a shielded state, so the exhaust efficiency of the exhaust through the intake port in the open state is high. Thereby, the dust collection efficiency of the dust containing the asbestos generated locally can be improved. This applies similarly when asbestos removal work is performed in the space in the next work place.

  In addition, the dust collector 120 'has a high exhaust capacity to the extent that the workplace can be set to a negative pressure, so it is possible to exhaust the carbon dioxide gas generated by the implementation of the dry ice blasting method as well as collecting dust containing asbestos. It becomes.

  By the way, in the above description, when the fourth step is performed, the intake selection unit in the vicinity of the scaffold 211 is set to the door open state and the other intake selection unit is set to the door closed state. Thus, when using dry ice, it is preferable that the intake selection unit at the lower part of the work place is also in the door open state. This is to efficiently exclude carbon dioxide gas generated by the implementation of the dry ice blasting method. This will be described in detail below.

  First, when installing the duct 110 ′ in the first step, the intake port and the corresponding intake selection unit are arranged at a position that can be a lower portion of the space formed by the partitioning by the horizontal partitioning members 141 and 142. Here, since the place where the horizontal partition members 141, 142, etc. are installed is the boundary between the floors of the building 10, the position of the intake air selection unit is in the vicinity of the upper side of the installation place of the horizontal partition member, or the pit. This is near the bottom surface 53 a of 53.

  When the horizontal partition members 141 and 142 are arranged in the second step, the space above the lower horizontal partition member 142 and below the space below the upper horizontal partition member 141 (upper space) is 1 One intake port and the corresponding intake selection unit 113 are arranged. In addition, one intake port and an intake selection unit 111 corresponding to the intake port 111 are also arranged below the space (lower space) below the lower horizontal partition member 142 (in the vicinity of the bottom surface 53a of the pit 53).

  After that, before carrying out the dry ice blasting method as an asbestos removal operation, the intake selection unit installed at the lower part of the work place is set in the door open state. During the asbestos removal work (when dry ice is being used), the air inlet at the lower part of the work area is kept open. Here, the intake selection unit in the door open state corresponds to the intake selection unit 113 in the example shown in FIG. 4, and corresponds to the intake selection unit 111 in the example shown in FIG. As described above, during the asbestos removal work, the intake selection unit (the intake selection unit 115 in FIG. 4 and the intake selection unit 112 in FIG. 5) in the vicinity of the scaffold 211 is also opened. For this reason, when the asbestos removal work is performed at the lower part of the work area, the intake selection unit at the lower part of the work area may coincide with the intake selection unit near the scaffold 211.

  When the dry ice blasting method is performed, a large amount of carbon dioxide gas is generated in the work place as a result of sublimation (vaporization) of the used dry ice (solid). Part of the generated carbon dioxide gas is exhausted from the intake port near the scaffold 211. However, since carbon dioxide gas has a higher specific gravity than air, carbon dioxide gas tends to fill the lower part of the workplace. Therefore, the remaining carbon dioxide gas that has not been exhausted from the intake port near the scaffold 211 moves below the intake port near the scaffold 211. Here, as described above, the carbon dioxide gas to be filled in the lower portion of the work place can be exhausted through the air intake port by maintaining the intake port in the lower portion of the work place in an open state in advance (see FIG. 4, see arrow B ′ shown in FIG.

  In this way, in the work place, not only the intake port in the vicinity of the scaffold 211 is opened, but also the intake port in the lower part of the work site is opened, so that carbon dioxide gas generated when dry ice is used fills the lower part of the work site. It can be quickly evacuated before. That is, carbon dioxide gas can be efficiently excluded.

  In the case of asbestos removal work, laws and regulations require that the workplace be ventilated (replacement of the air in the entire workplace) at least four times per hour. If the exhaustion of carbon dioxide gas is sufficiently performed by this ventilation, the intake selection unit at the lower part of the work area does not have to be in the door open state. However, when asbestos removal work is performed in the elevator shaft 52, particularly when a horizontal partition member is installed, the work space tends to be narrow, and in the pit 53, air containing carbon dioxide gas tends to stay (airflow). Is less likely to occur). For this reason, when a large amount of carbon dioxide gas is generated, the worker is exposed to the danger of oxygen deficiency. Therefore, in order to ensure the safety of workers, as described above, it is preferable to quickly and efficiently exhaust carbon dioxide gas by setting the intake selection unit at the lower part of the workplace to the door open state. . In other words, when using dry ice, opening the intake selection unit at the bottom of the work area to open the door and exhausting the carbon dioxide gas reliably is effective when the work area is small or air is likely to stay in the lower part of the work area. It can be said that there is.

  In the above-described second embodiment, the duct 110 ′ dedicated for asbestos removal work is prepared, but an existing duct may be used instead. However, since asbestos is harmful, it is preferable to prepare a duct 110 ′ dedicated to asbestos removal work.

  In the above-described second embodiment, as an asbestos removal operation, an example has been described in which asbestos is positively peeled off and dropped by manual operation and dry ice blasting. Thus, positively removing harmful substances such as asbestos from the building 10 is very effective as a measure against harmful substances (attachment-related treatment). However, in situations where the harmful substances cannot be positively removed from the building 10, containment or enclosure may be performed as measures against the harmful substances. Containment is a measure for preventing the falling off (scattering) of harmful substances by coating the surface of the harmful substances with the chemical liquid by spraying the chemical liquid toward the wall surface 52a or the like. Enclosure is a measure to prevent the harmful substance from falling off by surrounding the entire wall surface 52a to which the harmful substance is attached, that is, surrounding the harmful substance with another member. In addition, the containment and the enclosure may be performed as a measure against harmful substances that may remain after positively removing the harmful substances. In the case of containment or enclosure, dry ice is not used, so there is no need to open the air inlet at the bottom of the work area.

  In the second embodiment, the main removal target is asbestos, but may be harmful substances other than asbestos (for example, dioxins and radioactive substances). Further, the removal target is not limited to harmful substances, and may be dust or the like as described in the first embodiment.

  Further, in the second embodiment, the horizontal partition members 141, 141 ', 142 are installed horizontally, but may not be completely horizontal. That is, the horizontal partition member may be any member that partitions the longitudinal space defined by the elevator shaft 52 in a direction intersecting the longitudinal direction. Thereby, the working space can be narrowed and the exhaust capacity of the dust collector 120 ′ can be increased.

  In the first and second embodiments described above, the dust collectors 120 and 120 ′ have both an exhaust function and a dust collection function, but may be a blower (exhaust device) having only an exhaust function. . In this case, a filter that realizes a dust collecting function is installed in the ducts 110, 110 'and the like.

  In the first and second embodiments described above, the elevator shaft 52 is exemplified as a structure having a longitudinal direction along the vertical direction. However, the structure is not limited thereto. Examples of such a structure include an incinerator for a garbage incineration facility and a tower type multi-story parking lot. This is because such a structure is generally performed sequentially from a high place to a low place when processing such as cleaning work and harmful substance removal work is performed.

It is a longitudinal cross-sectional view which shows the schematic structure of the building in which the cleaning apparatus as a deposit | attachment processing apparatus which concerns on the 1st Embodiment of this invention was installed. It is a partial expanded side view of the duct shown in FIG. It is a flowchart which shows the process of the asbestos removal operation | work using the asbestos removal apparatus as a deposit | attachment processing apparatus which concerns on the 2nd Embodiment of this invention. It is a longitudinal cross-sectional view which illustrates a certain workplace cured in step S2 of FIG. It is a longitudinal cross-sectional view which illustrates another work place cured in step S2 of FIG.

Explanation of symbols

1 Ground surface 10 Building 51 Cage (car)
52 Elevator shaft 52a Wall surface 100 Cleaning device 100 ′ Asbestos removal device 110, 110 ′ Duct 111-116 Intake selection unit 115a Intake port 114b, 115b Door 119 Exhaust port 120, 120 ′ Dust collector 130 Blower 140, 141 ′ Vertical partition member 141 Upper horizontal partition member 142 Lower horizontal partition member 150 Air blast machine 160 Dry ice blast machine 210 Gondola

Claims (4)

A deposit processing apparatus installed in a structure having a longitudinal direction along the vertical direction,
A duct having a first inlet, a second inlet, and an exhaust;
A first shielding member capable of shielding the first air inlet;
A second shielding member capable of shielding the second air inlet;
An exhaust device that takes in air through an intake port opened by the first shielding member or the second shielding member, and exhausts the captured air by moving the air toward the exhaust port;
With
The exhaust device is a dust collector connected to the exhaust port;
The dust collector is provided with a first filter,
The duct is installed in the structure such that the first air inlet and the second air inlet are aligned vertically in the longitudinal direction in a longitudinal space defined by the structure,
The deposit processing apparatus is used when processing related to deposits attached to the surface of an object in the longitudinal space,
Each of the ducts is provided with a second filter at a position corresponding to the first air inlet and the second air inlet, and the second filter is a filter having a coarser mesh than the first filter. Yes,
By partitioning the longitudinal space in a direction intersecting the longitudinal direction, an upper space including the first shielding member and the first air inlet, and a lower space below the upper space, the second shielding member. And a partition member that partitions the lower space including the second air inlet,
When the processing is performed in the upper space,
The first air inlet is opened by the first shielding member, and the second air inlet is shielded by the second shielding member;
When the processing is performed in the lower space,
The second air inlet is opened by the second shielding member, and the first air inlet is shielded by the first shielding member;
The first air inlet is at a lower portion of the upper space;
The second air inlet is in the lower part of the lower space;
In order to drop the deposit from the surface of the object, a spray device capable of spraying granular dry ice to the object,
In the upper space, the duct has a third air inlet different from the first air inlet and the second air inlet,
The third air inlet is located in the vicinity of a scaffold installed in the upper space;
A third shielding member capable of shielding the third air inlet;
When the processing is performed in the upper space, the third intake port is opened by the third shielding member .   2. The deposit processing apparatus according to claim 1, further comprising a gas supply device that supplies a gas containing oxygen from an upper portion of a space in which the spraying device is used in the upper space and the lower space. The deposit processing apparatus according to claim 1 or 2 , wherein deposit-related processing relating to deposits attached to the surface of an object in the longitudinal space is performed in the longitudinal space. Deposit treatment method. The deposit related process is:
A removal process for removing the deposit from the surface of the object by applying an external force to the deposit;
A containment process for containing the deposit using a chemical solution;
A surrounding process surrounding the deposit;
The deposit treatment method according to claim 3 , wherein the deposit treatment method is at least one treatment selected from a treatment group consisting of:

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