JP3223742U - Air conditioning system for explosives handling equipment - Google Patents

Abstract

An air conditioning system for explosives handling equipment capable of efficiently adjusting the room temperature of the explosives handling equipment. An explosives handling equipment air-conditioning system 3 for adjusting the room temperature of an explosives handling equipment 1 installed in the vicinity of an explosives consumption site, comprising a frame main body 31 and an explosives handling equipment wall surface. The air supply duct 31A connected to the provided air supply duct opening, the air supply duct 31A connected to the frame main body, and the heat insulating material 45 is provided on the inner surface of the internal space of the frame main body, and is installed in the internal space. And an air path guiding unit 63 that increases the dynamic pressure of the cool air or the warm air blown from the air outlet of the air conditioner and sends the cool air or the warm air to the air supply duct. [Selection] Figure 7

Description

  This invention relates to an air conditioning system for explosives handling equipment.

  For example, when constructing a tunnel or a dam, foundation excavation using an explosive (for example, slurry explosive, dynamite, etc.) is performed to form a foundation ground.

  Explosives containing dynamite (explosives, explosives, pyrotechnics) have the risk of explosion and combustion, so the Explosives Control Law regulates the handling, handling, and consumption of explosives. .

  For example, the Explosives Control Law establishes a “powder storage” to store and manage explosives near the site. When the amount of explosives per day exceeds the standard amount, a “powder handling center” separate from the explosives storage. In order to prepare for explosives explosives, such as installing a detonator in a medicine package or removing a detonator from a medicine package, set up a pyrotechnics in a location away from the explosives store or explosives handling center. Provision is made. Strict standards have also been established for the structures of explosives storage, explosives handling stations, and pyrotechnic buildings. In addition, here, the buildings related to the explosives warehouse, explosives handling station, and pyrotechnics are also collectively referred to as “explosives handling equipment”.

  Conventional explosives handling facilities include those disclosed in Patent Document 1 and Non-Patent Document 1, for example. Patent Document 1 discloses an explosive cabinet formed with a cellular concrete panel. Non-Patent Document 1 discloses explosives handling equipment, and also discloses simple heating equipment that blows warm air into the interior of the explosives handling equipment.

JP 50-49841 A

Nikki Kogyo Co., Ltd. product catalog, “powder storage system”, [online], [October 16, 2018 search], Internet <http://www.nikkikogyo.jp/storage/index.html>

  In general, explosives handling facilities are installed in mountainous areas, cold regions, etc., and in summer, the trend toward higher temperatures is progressing with recent warming, and in winter, it is extremely cold and snowfall is deep. For this reason, an operator who handles explosives in the room of the explosives handling facility works in intense heat or extremely cold, and the working environment is not sufficient.

  Conventionally, only explosives handling equipment has been provided with heating equipment, but there is no cooling equipment. Since the melting point of dynamite is about 60 ° C., when working in a high temperature environment in summer, dynamite may be melted, and it cannot be said that the working environment is favorable from such a viewpoint.

  In addition, since the conventional heating equipment only allows warm air to flow into the room of the explosives handling equipment, it cannot be said that the heating effect is functioning sufficiently. In addition, there are cases where conventional heating equipment is buried in snow due to snowfall, and in that case, there is also a problem that heating is not effective.

  Therefore, there is a demand for an air conditioning system for explosives handling equipment that can efficiently adjust the room temperature of the explosives handling equipment.

  In order to solve such problems, the air conditioning system for explosives handling equipment according to the present invention is an air conditioning system for explosives handling equipment that adjusts the indoor temperature of explosives handling equipment installed near the explosives consumption site. (1) a frame main body, (2) an air supply duct opening provided on the wall surface of the explosives handling facility, an air supply duct connected to the frame main body, and (3) a frame main body Heat insulating material is provided on the inner surface of the internal space of the part, and (4) increase the dynamic pressure of the cold air or warm air blown from the air outlet of the air conditioner, And an air path guiding section for feeding cool air or warm air into the air supply duct.

  According to the present invention, the room temperature of the explosives handling facility can be adjusted efficiently.

It is a front view of the explosives handling equipment concerning an embodiment. It is a side view of the explosives handling equipment concerning an embodiment. It is a top view of explosives handling equipment concerning an embodiment. It is sectional drawing of the explosives handling equipment which concerns on embodiment. It is a front view which shows the external appearance structure of the air-conditioning equipment which concerns on embodiment. It is an internal block diagram which shows the internal structure of the air conditioning equipment of the state which removed the board | plate material of the back lower part of the frame main-body part of embodiment. In embodiment, it is explanatory drawing explaining the mode of the air supply from which the cold air or warm air from an air conditioner flows into the room | chamber interior of explosives handling equipment. In embodiment, it is explanatory drawing explaining the mode of the exhaust_gas | exhaustion by which the air in the room | chamber interior of explosives handling facilities is exhausted with an exhaust fan. It is a block diagram which shows the structure of the air supply / exhaust unit which concerns on embodiment. It is explanatory drawing explaining the whole structure of the installation which concerns on the explosives management which concerns on embodiment.

(A) Main Embodiment Hereinafter, an embodiment of an air conditioning system for explosives handling equipment according to the present invention will be described in detail with reference to the drawings.

(A-1) Configuration of Embodiment (A-1-1) Overall Configuration FIG. 10 is an explanatory diagram for explaining the overall configuration of equipment related to explosives management according to this embodiment.

  In FIG. 10, the explosives management facility 10 according to this embodiment is generally provided with an explosive cabinet 1-1, an explosives handling place 1-2, and a pyrotechnic 1-3.

  The explosive storage 1-1 is a storage for storing and managing explosives. An operator stores explosives in the explosive depot 1-1 and manages the type, quantity, purpose, and the like of the stored explosives. Therefore, the gunpowder depot 1-1 has a role as a base for the operator to manage the explosives, together with a role as a storage for storing the explosives. The explosive depot 1-1 is installed at a location more than a predetermined distance away from the explosives handling facility 1-2 and the pyrotechnic plant 1-3 provided at the consumption location.

  The explosives handling station 1-2 is installed at the explosives consumption place, and the operator manages the explosives and makes preparations other than the blasting preparation that must be performed at the pyrotechnic 1-3. It is a building or place. In this embodiment, the building installed in the consumption place is called explosives handling place 1-2. In the unlikely event that an explosive explodes in the explosives handling facility 1-2, the types and amounts of explosives that can be brought into the explosives handling facility 1-2 are limited. For example, the Explosives Control Law stipulates that there is one explosives handling place 1-2 installed at a consumption place. In addition, the amount of explosives that can be handled by an operator in a day at the explosives handling station 1-2 is determined. Therefore, when an operator handles explosives at the explosives handling station 1-2, an amount of explosives that can be handled per day from the explosive depot 1-1 is transported to the explosives handling place 1-2 for management. To do. Moreover, when an operator does not consume the amount of all explosives and an explosive remains, an operator conveys the remaining explosive amount to the explosives warehouse 1-1, and stores it.

  Pyrotechnic 1-3 is installed in a place where explosives are consumed, and a worker handles the installation of a detonator on a medicine package or a medicine package (also called a parent die) with a detonator attached. Or a place. In this embodiment, the building installed in the consumption place is referred to as a pyrotechnic 1-3. When the amount of explosives handled in one day is small, the worker carries explosives from the explosive depot 1-1 to the pyrotechnic 1-3, and when the explosives handling place 1-2 is installed, The worker works by transporting explosives from the explosives handling station 1-2 to the pyrotechnic 1-3.

  An outer fence 5 is provided around each of the explosive storage 1-1, the explosives handling place 1-2, and the pyrotechnics 1-3 to prevent intrusion of persons other than those concerned.

  As the outer fence 5, for example, a steel outer fence formed of a member obtained by subjecting stainless steel to hot dip galvanizing finish can be applied. Moreover, the outer fence 5 is provided so that each of the explosive cabinet 1-1, the explosives handling place 1-2, and the pyrotechnic 1-3 may be surrounded. The fence part of the outer fence 5 can use what is mesh shape, for example, in order to suppress a wind pressure. The outer fence 5 is provided with a door (not shown) for an operator to enter and exit. Although the door body of the outer fence 5 is desirably provided on the side facing the door body provided in each of the explosive storage 1-1, the explosives handling place 1-2, and the pyrotechnic 1-3. However, the present invention is not limited to this.

(A-1-2) Configuration of explosives handling equipment Next, the explosives container 1-1, explosives handling place 1-2, pyrotechnics plant to be air-conditioned by the air conditioning system for explosives handling equipment according to this embodiment The configuration 1-3 will be described in detail with reference to the drawings.

  The structure of the building related to the explosive storage 1-1, the explosives handling station 1-2, and the pyrotechnics 1-3 can be basically the same structure. Therefore, here, the buildings related to the explosive depot 1-1, the explosives handling place 1-2, and the pyrotechnic 1-3 are collectively expressed as “explosive handling equipment 1”.

  FIG. 1 is a front view of the explosives handling facility 1 according to this embodiment, FIG. 2 is a side view of the explosives handling facility 1, and FIG. 3 is a plan view of the explosives handling facility 1. FIG. 4 is a cross-sectional view of the explosives handling facility 1 according to this embodiment.

  The explosives handling facility 1 is a box-shaped structure, and is disposed above the frame portion 11 composed of a base, a column, and a beam, a plurality of wall portions 12 arranged in four directions, and the column of the frame portion 11. It has the roof part 13 and the floor part 14 arrange | positioned under the frame part 11. FIG.

  Of the four wall portions 12 of the explosives handling facility 1, one wall (front wall) has a door 15, and the side wall of the explosives handling facility 1 has a window, an underfloor ventilation port 18 </ b> A, a ceiling. There is a vent 18B. The installation positions of the windows, the underfloor ventilation openings 18A, and the ceiling ventilation openings 18B are not particularly limited.

  The interior of the explosives handling facility 1 (inner wall, ceiling, floor, etc.) is formed so that the explosives are not exposed due to static electricity so as not to be exposed. In addition, the outside of the explosives handling facility 1 (outer wall, etc.) is formed of iron plates to prevent the explosive damage from expanding when explosives explode, and bolts etc. to prevent static electricity from being generated. It is formed so that the protruding part of the irons does not come out.

  The explosives handling facility 1 is connected to the air conditioning facility 3 disposed outside the outer fence 5 via an air supply duct 31A and an exhaust duct 31B. Cold air or warm air from the air conditioning equipment 3 is sent into the room of the explosives handling equipment 1 through the air supply duct 31A, and the room air of the explosives handling equipment 1 is discharged to the air conditioning equipment 3 side through the exhaust duct 31B. The Thereby, the room | chamber interior of the explosives handling equipment 1 can be made into comfortable temperature. In this embodiment, the air supply duct 31A and the exhaust duct 31B are exemplified by circular cylindrical pipes, but the shapes thereof are not particularly limited, and may be rectangular pipes or the like.

[Foundation foundation 9]
The explosives handling facility 1 is provided near the explosives consumption place. Therefore, since the soil may not be leveled, a foundation base (concrete base) 9 is formed at a place where the explosives handling facility 1 is installed so as to have a flat upper surface, for example, with concrete. The explosives handling facility 1 is installed on the upper surface of the base 9. The foundation base 9 may be a cloth foundation or a solid foundation as long as it can support the load of the explosives handling facility 1.

[Frame part 11, foundation part 111]
The skeleton part 11 is a frame part that becomes a base, a pillar, a beam, or the like of the explosives handling facility 1. The skeleton part 11 is formed, for example, by fixing a lightweight steel member using a fixing member such as a bolt or a screw.

  The base 111 is provided at each corner of the lower part of the explosives handling facility 1. The base part 111 has a role as a base pillar that raises the position of the explosives handling facility 1 relative to the base base 9. Although the height of the base part 111 can be suitably determined according to the environment where the explosives handling equipment 1 is installed, it can be set to, for example, about 100 mm to 200 mm.

  Here, in this embodiment, the case where the height of the base part 111 is about 150 mm is illustrated. The reason is that when the explosives handling facility 1 is loaded on the loading platform of a vehicle and transported to the site, it passes through many tunnels. At that time, if the height of the base portion 111 becomes too high, it may be difficult to pass due to the height restriction of the tunnel. For example, the vehicle height is determined to be 3800 mm or less by the road law or the like. Therefore, considering the height of the loading platform of the vehicle and the raised height of the explosives handling facility 1 provided with the base portion 111, the height of the base portion 111 is preferably about 150 mm or less. Therefore, in this embodiment, the case where the height of the base part 111 is about 150 mm is illustrated. Of course, the height of the base portion 111 is not limited to this. In addition, for example, base portions 111 having different heights such as 100 mm, 150 mm, and 200 mm are prepared, and the type of the base portion 111 to be fixed to the lower part of the explosives handling facility 1 is determined according to the site environment. It may be.

  The base 111 can be a quadrangular pillar member in plan view. In addition, in this embodiment, although the case where the shape of the base part 111 is a square pillar member is illustrated, it is not limited to this, For example, it is good also as a round shape, L shape, a hollow square, etc. Moreover, the base part 111 is being fixed with respect to the pillar member (for example, L-shaped member) of the frame part 11 with fixing members, such as a volt | bolt and a screw. For example, there is a metal plate-like plate on the lower surface of the base portion 111 provided at the lower part of the explosives handling facility 1 for fixing to the foundation base 9, and the plate is fixed using a fixing member such as an anchor. The base part 111 may be fixed to the foundation base 9.

  In addition, since the base part 111 has the role which raises the height of the explosives handling equipment 1, the bottom raising space 2 is formed between the bottom face of the floor part 14 of the explosives handling equipment 1 and the foundation base 9. The Thus, by raising the height of the explosives handling equipment 1 at the base portion 111, the ventilation becomes good and the humidity in the room of the explosives handling equipment 1 can be prevented. As a result, it is possible to prevent the explosives and the detonator from corroding (or the explosives of the explosives).

  In addition, for example, it is conceivable that submergence or earth and sand flows in due to heavy rain, etc., but by raising the height of the explosives handling facility 1, damage due to inundation or earth and sand can be avoided. Furthermore, since the bottom raising space 2 is formed, when installing the explosives handling equipment 1 on the foundation base 9, the explosives handling equipment 1 can be lifted and installed by a forklift or the like.

[Wall 12]
The outer wall of each wall portion 12 is formed of, for example, an iron plate panel, and the iron plate panel is fixed to the frame portion 11 with bolts, nuts, or the like. Further, a heat insulating member 122 such as a heat insulating material or a heat insulating plate is attached to the inside of the outer wall 121 of each wall portion 12. Thereby, the heat insulation effect can be acquired. A wooden board is attached to the inner wall 123 of each wall portion 12. This is because, when the operator handles the explosives in the explosives handling facility 1, static electricity is generated to prevent the explosives from exploding. As described above, iron is prevented from being exposed on the inner wall, floor, etc. of the room for the explosives handling facility 1 for countermeasures against static electricity.

  A thermal barrier paint (high solar reflectance paint) is applied to the surface of the outer wall 121 of each wall portion 12. For example, in the summer, when sunlight falls directly on the outer surface of the explosives handling facility 1, the surface temperature of the outer wall 121 of the wall portion 12 may increase and the indoor temperature may also increase. Conventionally, explosives may explode, so there are restrictions on the installation of electrical equipment such as air conditioners (for example, the Explosives Control Law prohibits the installation of air conditioners in buildings). Therefore, the worker is working in a room with a high temperature. On the other hand, as in this embodiment, by applying a thermal barrier paint to the surface of the outer wall 121 of the wall portion 12, direct sunlight can be reflected with high efficiency, and the increase in the indoor temperature can be reduced. . As a result, the working environment of the worker who works indoors can be improved. In addition, you may make it apply | coat a thermal barrier coating also to the surface of the roof part 13. FIG.

  Further, as shown in FIG. 2, the wall portion 12 of the explosives handling facility 1 has an air supply duct port 17A that can be connected to the air supply duct 31A and an air exhaust duct port 17B that can be connected to the exhaust duct 31B. There is.

[Door 15, locks 152a and 152b]
The door 15 is an opening / closing body for an operator to enter and exit the room. The outside of the door portion 15 is formed of, for example, an iron plate panel, and the inside of the door portion 15 is formed of, for example, a wood panel. The door portion 15 is attached to the frame portion 11 so as to be openable and closable with, for example, a plurality of hinges. Further, the door portion 15 includes a handle portion 151 and a plurality (two in this embodiment) of locks 152a and 152b.

  A lock called a so-called Saga lock (Saga-type crime prevention lock) is generally used for the door of conventional explosives handling equipment. Saga is a lock used in warehouses and warehouses a long time ago.

  Since the explosives handling facility 1 is a place for handling explosives and a place for storing explosives, it is necessary to firmly prevent the intrusion of objects other than those concerned. Therefore, in this embodiment, two cylinder locks 152 a and 152 b are provided on the door portion 15. Thereby, this embodiment has the following effects. For example, the conventional Saga lock is heavy and difficult to handle, but the cylinder locks 152a and 152b are lighter in weight and easier to handle than the Saga lock. The key for opening and closing the traditional Saga lock is difficult to create a spare key. If the key is lost, the lock cannot be opened and closed, making it difficult to handle, but the cylinder locks 152a and 152b are used. As a result, the creation of a spare key is relatively easy and the management of the key is facilitated.

[Roof 13]
The roof portion 13 forms the framework of the roof portion 13 by fixing the rafter 131 and the field plate 132 to the pillars of the framework portion 11 and the like. An iron plate 133 is stretched on the upper portion of the roof portion 13 and the surrounding portion (that is, the outside of the roof portion 13). Further, a wooden plate-like ceiling portion 134 is stretched under the roof portion 13 to form an indoor ceiling.

[Floor 14]
The floor portion 14 is a portion arranged below the skeleton portion 11. A conductive underfloor member such as an iron plate panel is attached to the lower portion of the skeleton portion 11, and a wooden board or the like is also attached to the upper surface of the underfloor member. Formed with floor members attached. In order to suppress the generation of static electricity, antistatic equipment (static electricity prevention equipment) may be provided on all or part of the surface of the floor portion 14.

(A-1-3) Explosives handling facility air conditioning system Hereinafter, the configuration of the explosives handling facility air conditioning system according to the present embodiment will be described in detail with reference to the drawings. The air conditioning system for explosives handling equipment adjusts the room temperature of the explosives handling equipment installed near the explosives consumption site, and has each component of the air conditioning equipment 3 described later. Furthermore, the air-conditioning system for explosives handling equipment may include a supply / exhaust unit 47, which will be described later, installed in the room of the explosives handling equipment 1 as necessary.
[Appearance structure of air conditioning equipment]
FIG. 5 is a front view showing an external configuration of the air conditioning equipment 3 according to the embodiment.

  In FIG. 5, the air conditioning equipment 3 according to the embodiment includes a frame main body 31 assembled as a box-shaped (cubic or rectangular parallelepiped) structure using a metal frame member or a metal plate material. The height of the frame main body 31 can be about 1800 mm to 2500 mm. The heating equipment for conventional explosives handling equipment is low in height, and when snow falls, the heating equipment itself is buried in snow, and the heating effect is not sufficiently functioning. On the other hand, the air conditioning equipment 3 of this embodiment has a sufficient height, and the outdoor unit 41 is placed in the snow by placing the outdoor unit 41 on the upper stage (upper part) of the frame main body 31 as will be described later. Is prevented. Therefore, even when there is snow, the heating effect can function effectively. In the frame main body 31, a partition plate material 311 formed using a metal frame member or a metal plate material is provided at a substantially central portion in the height direction, and the internal space of the frame main body portion 31 is divided into two vertically. ing.

<Upper part of frame body>
An outdoor unit 41 is fixed to the upper part of the frame main body 31 partitioned by the partition plate material 311 (that is, the upper surface 311a of the partition plate material 311). That is, in order to fix the outdoor unit 41 to the upper surface 311a of the partition plate material 311, for example, a metal installation member 61 is provided, and the outdoor unit 41 is fixed to the installation member 61 using screws, screws, or the like. Yes. In addition, although the outdoor unit 41 and the air conditioner (indoor unit 43) are connected by piping, illustration is abbreviate | omitted here.

  In the upper part of the frame main body 31, a partition plate material 312 is provided from the front side to the back side in order to further divide the upper space into two spaces, and one surface (outer surface) 312a of the partition plate material 312 is provided. Are equipped with control panels 42a and 42b for controlling operations of an air conditioner 43 and an exhaust fan 44 described later.

  The control panel 42 a is provided with a power button for turning on the air conditioner 43 and the exhaust fan 44. The control panel 42b includes, for example, an operation mode selection button for the air conditioner 43 such as cooling, heating, drying, and air blowing, a temperature setting button, and the like. Note that a remote control receiver connected to the air conditioner 43 may be provided in the control panel 42b, and the operation of the air conditioner 43 may be controlled through a remote control transmitter. In this embodiment, the control panel 42a for controlling the power supply and the control panel 42b for controlling the operation of the air conditioner 43 are physically separated from each other, but may be physically one control panel.

  A plate material is stretched on the ceiling of the upper space of the frame main body 31, and the partition plate material 311 described above is provided on the bottom of the upper portion. And the four directions (a front surface, a back surface, a right side surface, and a left side surface) of the upper space formed with the frame main-body part 31 are shown. However, for example, in order to protect the air conditioner 3 during periods when the explosives handling facility 1 is not working, when the air conditioner 3 is not used, during snowfall or during rain, etc., You may make it cover with a board | plate material on all sides.

  Specifically, a plate material (not shown) may be attached to the frame body 31 using screws, screws, or the like on the front, back, right side, and left side of the upper part of the frame body 31. . By protecting the upper space of the frame main body 31 with a plate material in this way, it is possible to prevent the outdoor unit 41, the control panel 42, etc. from being stolen or mischiefed when the work is not performed or when the air conditioning equipment 3 is not used. In addition, it is possible to prevent damage to the outdoor unit 41 and the control panels 42a and 42b due to snow or rain when it snows or rains.

  In other words, when the air conditioning equipment 3 is used, the four plate members on the upper part of the frame main body 31 may be removed from the frame main body 31. In this embodiment, the upper part of the frame main body 31 is easy to explain. The air conditioning equipment 3 in a state where the plate material is removed will be described.

<Bottom of the frame body>
The lower part of the frame main body portion 31 partitioned by the partition plate material 311 is covered with a metal plate material 32 on its four sides (front, back, right side, left side). That is, the front, back, right side, and left side of the lower part of the frame body are provided with the plate 32 fixed to the frame body 31 with screws, screws, or the like.

  As will be described later, an air conditioner 43, an exhaust fan 44, and the like are provided in the internal space below the frame body 31. Then, the lower four sides of the frame main body 31 are surrounded by a metal plate 32 to improve the airtightness of the internal space below the frame main body 31 where the air conditioner 43, the exhaust fan 44, etc. are provided. The air conditioning effect in the room of the explosives handling facility 1 by the machine 43 can be improved, and further, condensation in the lower space of the frame body 31 can be prevented in winter.

  The plate member 32 on the front surface of the frame main body 31 is provided with an air supply duct port 321 connected to the air supply duct 31A and an exhaust duct port 322 connected to the exhaust duct 31B.

[Internal configuration of air conditioning equipment]
FIG. 6 is an internal configuration diagram illustrating an internal configuration of the air conditioning equipment 3 in a state in which the plate material at the lower back of the frame main body 31 of the embodiment is removed.

  FIG. 7 is an explanatory diagram for explaining a state of air supply in which cool air or warm air from the air conditioner 43 flows into the room of the explosives handling facility 1 in the embodiment.

  FIG. 8 is an explanatory diagram for explaining the state of exhaust in which air in the room of the explosives handling facility 1 is exhausted by the exhaust fan 44 in the embodiment.

<Insulation material>
In FIG. 6, a heat insulating material 45 is stretched in a lower space partitioned by the partition plate material 311 in the frame main body portion 31 in order to improve airtightness. Specifically, a heat insulating material 45 is provided on the lower surface 311 b of the partition plate material 311 that is the ceiling of the lower space of the frame main body 31, the four side wall surfaces of the lower portion of the frame main body 31, and the bottom surface of the frame main body 31. ing.

  As described above, by providing the heat insulating material 45 on the ceiling, the four side wall surfaces, and the bottom surface of the lower internal space of the frame main body 31, the airtightness of the lower space can be improved. The air conditioning effect in the room of the handling facility 1 can be improved.

  Since the installation site of the explosives handling facility 1 is a consumption site such as dynamite (for example, a site such as a mountainous area), it is particularly cold in the winter. In such a state, even if it is attempted to operate the air conditioner 43 in order to warm the interior of the explosives handling facility 1, the airtightness is low, the temperature of the internal space below the frame body 31 is extremely low, and the heating effect is sufficient. Does not work. On the other hand, according to this embodiment, the internal space of the frame main body 31 containing the air conditioner 43 is covered with the heat insulating material 45 to improve the airtightness, thereby suppressing the temperature drop of the internal space. And the heating effect can be improved. In addition, condensation in the internal space can be prevented.

  Note that the material of the heat insulating material 45 is not particularly limited as long as the airtightness of the lower space of the frame main body 31 and the prevention of condensation are possible. For example, a synthetic resin such as polyurethane can be used. Moreover, it does not specifically limit about the thickness of the heat insulating material 45, According to the condition of the installation site of the explosives handling equipment 1, it can determine suitably. Further, by providing the heat insulating material 45 on the inner wall or the like at the lower part of the frame main body 31, the air conditioner 43 can be soundproofed and vibration-proof.

<Air conditioner>
As shown in FIGS. 6 to 8, an air conditioner installation portion 62 suspended from the lower surface 311 b of the partition plate material 311 is provided at the lower portion of the frame main body portion 31.

  The air conditioner 43 is provided on the upper surface of the installation plate material 621 of the air conditioner installation unit 62. As the air conditioner 43, for example, either a ceiling-embedded type or a wall-mounted type air conditioner (air conditioner: indoor unit) can be used, and the air outlet 43 is arranged so that the air outlet 431 faces downward as shown in FIG. Is done. Thereby, the cold air or warm air from the outlet 431 of the air conditioner 43 flows downward and is sent to the inside of the air passage guiding portion 63, and the cold air or warm air sent to the air passage guiding portion 63 is supplied to the air supply duct 31A. Sent. As described above, a detailed description of the fact that the air outlet 43 431 of the air conditioner 43 is directed downward and that the air path guiding unit 63 is provided will be described later.

<Air conditioner installation section>
The air conditioner installation unit 62 includes an installation plate unit 621 for installing the air conditioner 43, a support plate unit 622, and a plurality of support units 623 that are fixed to the lower surface 311 b of the partition plate material 311 and support the support plate unit 622. Have. In FIG. 6, a heat insulating material 45 is provided between the installation plate portion 621 and the support plate portion 622 in order to improve airtightness.

  Each of the plurality of support portions 623 can be a rod-shaped member, one end of each support portion 623 is fixed to the lower surface 311b of the partition plate material 311, and the other end is each of a plurality of end portions of the support plate portion 622. By fixing the air conditioner, the air conditioner installation part 62 is formed in a hanging plate shape. In addition, when each support part 623 fixes and supports the edge part of the support plate part 622, it penetrates the edge part of the heat insulating material 45, and fixes and supports the heat insulating material 45 and the support plate part 622 together. You may make it do.

  The support plate portion 622 is formed of, for example, a metal plate, and the end portion of the support plate portion 622 is supported by the plurality of support portions 623 as described above. Thereby, even when the air conditioner 43 is placed, the support plate 622 can be in a stable state. The installation plate portion 621 is a plate-like member that installs the air conditioner 43 on the upper surface thereof.

  As illustrated in FIGS. 6 to 7, the installation plate portion 621, the heat insulating material 45, and the support plate portion 622 are provided with openings (not shown) at positions corresponding to the positions of the air outlets 431 of the air conditioner 43. ing. Specifically, the opening portions of the installation plate portion 621, the heat insulating material 45, and the support plate portion 622 can have a rectangular shape that is long in the left-right direction in a plan view of FIG. Thereby, the cold air or the warm air from the outlet 431 of the air conditioner 43 is sent to the inside of the air path guiding portion 63 through these openings (not shown).

<Air guide unit>
The air path guidance | induction part 63 sends out the cold air or warm air which was blown off from the blower outlet 431 of the air conditioner 43 to the duct 31A for air supply connected with the explosives handling equipment 1 side.

  As illustrated in FIG. 6 to FIG. 7, the air passage guiding portion 63 has, for example, a hollow triangular prism shape, and the upper portion thereof is an opening portion of the installation plate portion 621, the heat insulating material 45, and the support plate portion 622 ( The lower part is on the bottom surface side of the lower part of the frame main body part 31 and the lower part of the air passage guiding part 63 is connected to the air supply duct 31A. ing.

  In other words, the inside of the air passage guiding portion 63 is hollow, and has a structure that allows the flow of cool air or warm air blown out from the air conditioner 43. Further, the air passage guiding portion 63 has a tapered structure in which the inner area (the area of the horizontal plane) increases toward the upper side and the inner area decreases toward the lower side.

  As described above, the cool air or the warm air blown out from the air outlet 431 of the air conditioner 43 is sent to the lower inside of the taper-shaped air passage guiding portion 63, so that the speed is increased (that is, the dynamic pressure is increased). Then, the cold air or the warm air whose dynamic pressure is increased is vigorously sent into the air supply duct 31A. Thereby, even from the air conditioner 43 located away from the explosives handling facility 1, cold air or warm air can be sent to the explosives handling facility 1 through the air supply duct 31 </ b> A. That is, cold air or warm air can be sent into the room through the air supply duct 31A having a length of several meters, so that the room of the explosives handling facility 1 can be adjusted to a more comfortable temperature than before.

  In this embodiment, when the cool air or warm air of the air conditioner 43 is sent into the room of the explosives handling facility 1 through the air supply duct 31A, the dynamic pressure of the cool air or warm air is increased (the speed is increased). In addition, the air passage guiding portion 63 shown in FIGS. 6 and 7 is provided. Therefore, as long as the dynamic pressure of the cold air or the warm air blown downward from the air conditioner 43 can be increased, the structure of the air path guiding unit 63 is not limited to the structure illustrated in FIGS. 6 and 7.

  Further, the air passage guiding portion 63 may be formed of, for example, a metal plate material, and further, the heat insulating material 45 is provided around the air passage guiding portion 63 in order to maintain the temperature of cold air or warm air inside and prevent condensation. You may make it cover with.

<Exhaust fan>
Next, the exhaust fan 44 will be described with reference to FIGS. The exhaust fan 44 exhausts the interior of the explosives handling facility 1 through the exhaust duct 31B, and for example, a turbo fan can be used. In addition, a turbo fan is what the direction of the blade of a centrifugal blower inclines in the reverse direction with respect to a rotation direction.

  By operating the exhaust fan 44, the indoor air of the explosives handling facility 1 flows into the exhaust duct 31B, and the indoor air is exhausted from the exhaust fan 44 through the exhaust duct 31B. Although the air conditioner 43 of this embodiment simply sends cool air or cold air or warm air having a relatively high pressure into the room of the explosives handling facility 1, the air conditioning effect is effective, but together with the air conditioner 43, the exhaust fan 44. By operating the air, the cool air or warm air is sent into the room, and at the same time the room air of the explosives handling facility 1 is exhausted, so the room air circulates, so that the air conditioning effect is more effective. .

  Further, the lower space of the frame main body 31 is covered with a heat insulating material 45, and airtightness is maintained. Therefore, the air exhausted by the exhaust fan 44 is discharged into the lower space of the frame main body 31, and the air conditioner 43 exchanges heat with the air in the lower space of the frame main body 31, so that the air conditioning effect is improved. That is, as the room temperature of the explosives handling equipment 1 is lowered or raised by the air conditioner 43, the temperature of the lower space of the frame body 31 is also lowered or raised by the exhaust of the exhaust fan 44. The effect will go up.

  In this embodiment, the exhaust fan 44 is operated together with the air conditioner 43. However, only the air conditioner 43 or only the exhaust fan 44 may be operated.

<Air supply / exhaust unit>
Next, the air supply / exhaust unit provided in the room of the explosives handling facility 1 will be described with reference to the drawings.

  FIG. 9 is a configuration diagram showing the configuration of the air supply / exhaust unit 47 according to the embodiment.

  In FIG. 9, a supply / exhaust unit 47 includes a box-shaped main body portion 471 formed of a plate member, and a partition plate portion that divides an internal space of the main body portion 471 into two portions for supplying and exhausting air. 479, an air supply attachment port 472, an air supply port 473, an exhaust attachment port 474, an exhaust port 475, a first air supply dustproof net 476, a second air supply dustproof net 477, and an exhaust dustproof net 478. .

  The air supply / exhaust unit 47 attaches the air supply attachment port 472 and the exhaust attachment port 474 of the air supply / exhaust unit 47 to the air supply duct port 17A and the exhaust duct port 17B on the wall surface of the explosives handling facility 1 to supply air. The cool air or warm air from the duct 31A is sent into the room, and the indoor air is sent into the exhaust duct 31B.

  The main body portion 471 of the air supply / exhaust unit 47 has a rectangular parallelepiped box shape, and the inside thereof is divided into two by a partition plate portion 479 to form an air supply section and an exhaust section. As described above, the internal space of the main body 471 is divided into the air supply section and the exhaust section, so that mixing of the air supply and the exhaust air can be prevented.

  Since the air supply / exhaust unit 47 is placed in the room of the explosives handling facility 1, it is necessary to prevent static electricity from being generated. Therefore, for example, when the main body 471 is formed of a metal plate material, the entire surface of the main body 471 may be covered with a heat insulating material. Thereby, generation | occurrence | production of static electricity can be prevented and the temperature of the air supplied and / or exhausted can be hold | maintained. Further, for example, the main body portion 471 may be formed of a wooden plate material. Even in this case, in order to maintain the temperature of the supplied and / or exhausted air, the entire surface of the main body portion 471 is made of a heat insulating material. You may make it cover.

  The air supply attachment port 472 and the exhaust attachment port 474 are provided on the same side surface of the box-shaped main body 471, and the air supply attachment port 472 and the exhaust attachment port 474 are for supplying air to the wall surface of the explosives handling facility 1. They are arranged at positions corresponding to the positions of the duct port 17A and the exhaust duct port 17B.

  The air supply attachment port 472 and the exhaust attachment port 474 may be made of, for example, a pipe material made of synthetic resin. The diameters of the air supply attachment port 472 and the exhaust attachment port 474 are slightly larger than the diameters of the air supply duct port 17A and the air exhaust duct port 17B on the wall surface of the explosives handling facility 1, so that the air supply / exhaust unit When attaching 47, the air supply attachment port 472 and the exhaust attachment port 474 are fitted and attached to the air supply duct port 17A and the air exhaust duct port 17B.

  Here, when the air conditioner 43 and / or the exhaust fan 44 are operated, an air supply sound or an exhaust sound sounds from the air supply duct port 17A and the air exhaust duct port 17B, or the air supply duct port 17A and the air exhaust duct are exhausted. The mouth 17B vibrates slightly. However, by attaching the air supply attachment port 472 and the exhaust attachment port 474 of the air supply / exhaust unit 47 according to this embodiment to the air supply duct port 17A and the air exhaust duct port 17B, the air supply sound or the exhaust sound and vibration Can be suppressed. In other words, by attaching the air supply / exhaust unit 47 to the air supply duct port 17A and the air exhaust duct port 17B, quietness and vibration isolation can be obtained.

  The air supply port 473 and the exhaust port 475 are provided on the upper surface of the box-shaped main body 471. By providing the air supply port 473 and the exhaust port 475 on the upper surface of the main body 471, the supplied cool air or warm air can be sent upward, and the air existing below the room can be exhausted.

  Therefore, in winter, warm air (relatively light air) that is supplied can be sent upward into the room, and the cold vacant space (relatively heavy air) that exists below the room can be exhausted. The room can be warmed while circulating. In the summer, cool air (relatively heavy air) supplied to the room is sent upward into the room, and the air below the room is exhausted to circulate the room air and lower the room temperature. be able to. In this way, the room temperature can be adjusted to a comfortable temperature.

  In this embodiment, the case where both the air supply port 473 and the exhaust port 475 are provided on the upper surface of the box-shaped main body portion 471 is illustrated, but the air supply port 473 is the upper surface of the main body portion 471. The exhaust port 475 may be provided on the side surface of the main body 471 (that is, the surface facing the installation surface of the exhaust attachment port 474). As a result, the indoor lower air can be exhausted, so that the same effect as the above-described indoor circulation can be obtained.

  Here, a first dust-proof net 476 for air supply is provided at the upper end portion of the air supply port 473, and further, a second portion is provided at the end portion of the air supply attachment port 472 (the end portion on the side inside the main body portion 471). A dust-proof net 477 for supplying air is provided. This is because foreign substances such as dust are sent into the room by supplying air, which may cause static electricity. Therefore, on the air supply side, a second air supply dustproof net 477 is provided at the end of the air supply attachment port 472, and a first air supply dustproof net 476 is provided at the upper end of the air supply port 473. ing.

  FIG. 9 illustrates the case where two air supply dustproof nets (first air supply dustproof net 476 and second air supply dustproof net 477) are provided. You may make it provide three or more dust-proof nets for supply of air, such as providing also in the lower end part of. Increasing the number of dust-proof nets for air supply may weaken the amount of air supplied, so the number of dust-proof nets for air supply and the diameter of the mesh holes, etc. Can be determined in consideration of

  An exhaust dust proof net 478 is provided at the upper end of the exhaust port 475. This is also for preventing foreign matter from being exhausted. Here, the exhaust dust-proof net is not attached to the end of the exhaust attachment port 474 (the end on the side inside the main body 471). The reason for this is that if the number of dust screens for exhaust is increased, the amount of exhaust becomes weak, which may affect the indoor air circulation efficiency. On the other hand, there is a possibility that static electricity may be generated due to the exhaust of foreign matter, but since it is exhausted, the possibility of static electricity generation in the room is low. Therefore, in this embodiment, in order to give priority to the improvement of the exhaust amount and the improvement of the indoor circulation efficiency, the case where the exhaust dustproof net is not provided at the end of the exhaust attachment port 474 is illustrated. Of course, when priority is given to preventing the generation of static electricity, two or more exhaust dust nets may be provided.

(A-2) Effects of the Embodiment As described above, according to this embodiment, the explosives handling equipment is provided with the air conditioning equipment connected to the explosives handling equipment by the air supply duct and the exhaust duct. The room temperature can be adjusted.

  The air-conditioning equipment can improve the airtightness by placing a heat insulating material in the lower space of the frame main body provided with the air conditioner as an indoor unit.

  In addition, the cool air or warm air from the air conditioner is sent downward, and the cool air or warm air flows through the inside of the airway guide section below the air conditioner, so that the cool air or warm air speed is increased. Sent to the room through the duct. Thereby, the air conditioning effect improves.

  Further, since the exhaust fan in the lower space of the frame main body exhausts indoor air, the indoor air circulates, so that an efficient cooling / heating effect can be obtained.

  In addition, by installing an air supply / exhaust unit in the room of the explosives handling facility with an air supply duct port and an exhaust duct port, an air supply sound or exhaust sound that rings at the indoor air supply duct port and the exhaust duct port, Vibration can be suppressed.

  Furthermore, since the air supply port and the exhaust port of the air supply / exhaust unit are on the upper surface of the main body, air can be circulated efficiently in the room.

(B) Other Embodiments (B-1) In the above-described embodiment, the air conditioner 43 is installed in the lower space of the frame main body portion 31 so that the air outlet 431 faces downward, and the air passage guide portion is provided below the air conditioner 43. The case where 63 arrange | positions was illustrated. However, the present invention is not limited to this, and the blowout port 431 of the air conditioner 43 blows out cold air or warm air in the horizontal direction from the back side to the front side of the frame main body 3 and sends it to the air path guiding unit 63. You may do it. In this case, the triangular plane of the triangular prism-shaped air passage guiding portion 63 of FIG. 6 is placed on the bottom surface of the frame main body portion 31 so that the air supply duct is connected to the distal end side with the smaller internal area. By doing in this way, the cold air or the warm air is sent to the air passage guiding portion 63 in a substantially horizontal direction, and the dynamic pressure of the cold air or the warm air is increased in the air passage guiding portion 63, and then the air passage guiding portion 63 Cold air or warm air is sent to the air supply duct 31A in a substantially horizontal direction.

  (B-2) Further, in the embodiment described above or in the embodiment of (B-1), air is sent to the explosives handling equipment 1 side in the vicinity of the inlet of the air supply duct 31A or in the air supply duct 31A. An air supply fan may be provided. Thereby, the cold air or warm air flowing in the air supply duct 31 can be strongly sent to the explosives handling equipment 1 side, and the room temperature can be adjusted efficiently.

DESCRIPTION OF SYMBOLS 1 ... Explosives handling equipment, 1-1 ... Explosives storage, 1-2 ... Explosives handling place, 1-3 ... Pyrotechnics plant, 17A ... Duct opening for supply air, 17B ... Duct opening for exhaust,
DESCRIPTION OF SYMBOLS 3 ... Air conditioning equipment, 31 ... Frame main-body part, 311 ... Partition board material, 41 ... Outdoor unit, 42a and 42b ... Control panel, 321 ... Duct for supply air, 322 ... Duct for exhaust, 43 ... Air conditioner (indoor unit) 431 ... outlet, 44 ... exhaust fan, 45 ... insulation,
62 ... Air conditioner installation unit, 621 ... Installation plate material, 622 ... Support plate unit, 623 ... Support unit, 63 ... Airway guide unit,
47 ... Supply / exhaust unit, 471 ... Main body part, 479 ... Partition plate part, 472 ... Supply air installation port, 473 ... Supply air port, 474 ... Exhaust installation port, 475 ... Exhaust port, 476 ... First dust-proof for air supply Net, 477... Second air supply dust proof net, 478.

Claims (6)

An explosives handling equipment air conditioning system that adjusts the indoor temperature of the explosives handling equipment installed near the explosives consumption site,
The frame body,
An air supply duct opening provided on a wall surface of the explosives handling facility, and an air supply duct connected to the frame main body,
A heat insulating material is provided on the inner surface of the internal space of the frame main body, and an air conditioner installed in the internal space;
An explosives handling facility comprising: an air passage guiding unit that increases a dynamic pressure of cold air or warm air blown out from an air outlet of the air conditioner and sends the cold air or warm air into the air supply duct Air conditioning system. An exhaust duct opening provided on a wall surface of the explosives handling facility, and an exhaust duct connected to the frame main body,
The explosives handling facility according to claim 1, further comprising: an exhaust fan provided in the internal space of the frame main body and exhausting room air of the explosives handling facility through the exhaust duct. Air conditioning system. A hanging plate-like air conditioner installation part fixed to the upper surface of the internal space of the frame body part,
The air conditioner is installed in the air conditioner installation section so that the air outlet is directed downward, and in the air conditioner installation section, the position corresponding to the position of the air outlet of the air conditioner is an opening,
The explosives handling equipment according to claim 1 or 2, wherein the cold air or the warm air from the air conditioner installed in the air conditioner installation unit is sent to the airflow guide unit through the opening. Air conditioning system. The air supply duct is connected to the lower side of the air passage guiding portion,
The interior of the air passage guide section has a relatively large internal area on the air conditioner side, and the internal area becomes smaller toward the air supply duct side. An air conditioning system for explosives handling equipment as described in 1. The frame main body is divided into an upper space and a lower space at a substantially central portion in the height direction,
The internal space of the frame body is the lower space;
The explosives handling facility air conditioning system according to any one of claims 1 to 4, wherein an outdoor unit connected to the air conditioner by piping is provided in the upper space. The explosives handling facility is provided in a room, and includes a supply / exhaust unit attached to the air supply duct port and the exhaust duct port on the wall surface of the explosives handling facility,
The air supply / exhaust unit is
A hollow box-shaped body section partitioned into an intake space and an exhaust space;
An air supply attachment port provided on a side surface of the main body that communicates with the air supply space and attached to the air supply duct port;
An exhaust attachment port provided on a side surface of the main body portion that communicates with the exhaust space, and attached to the exhaust duct port;
An air supply port that is provided on the upper surface of the main body, and supplies the cold air or the warm air from the air supply attachment port to the room through the air supply space;
The explosives according to any one of claims 2 to 5, further comprising: an exhaust port provided on an upper surface of the main body portion and exhausting indoor air to the exhaust mounting port side through the exhaust space. Air conditioning system for handling equipment.

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