KR102572741B1 - Cleaning Device for Air Breathing Type Fire Detection Device - Google Patents

Abstract

The present invention relates to a cleaning device for an air suction type fire detector, and more particularly, to a cleaning device for an air suction type fire detector having a dust collector connected to a plurality of air sampling pipes.
According to the cleaning device for an air suction type fire detector according to an embodiment of the present invention, since a dust collection unit sequentially connected to the air sampling pipes of all channels is provided, the configuration is completed with a single cleaner and a dust collection unit, reducing the number of parts.

Description

Cleaning Device for Air Breathing Type Fire Detection Device}

The present invention relates to a cleaning device for an air suction type fire detector, and more particularly, to a cleaning device for an air suction type fire detector having a dust collector sequentially connected to a plurality of air sampling pipes.

In general, a fire detector detects a fire at an early stage and informs the disaster prevention system to quickly extinguish the fire to minimize damage to valuable property and human life. It is installed in places where it is difficult to monitor or manage a lot of property and human damage in the event of a fire, such as large-area buildings such as apartments and small-area buildings such as detached houses and row houses.

These fire detectors can be classified according to their purpose or operation method. For example, fire detectors are mainly used in large-area buildings such as buildings or apartments depending on the installation location or monitoring area, as well as interlocking structured fire detectors that operate in conjunction with centrally controlled disaster prevention systems and detached houses or townhouses. It is classified as a single-type fire detector that operates individually in a small-area building. In addition, fire detectors include a heat detection method using heat generated in the event of a fire, a smoke detection method using smoke, and a flame detection method using flames according to fire detection methods.

Here, the heat detection method or the flame detection method is a passive detection method in which a detection sensor for temperature detection or flame detection is separately installed on the ceiling or wall of the room, and the heat or flame generated in the event of a fire is detected when it reaches the detection sensor. Therefore, it is difficult to quickly detect the fire because the time from the initial stage of fire to the fire detection is long, and it is difficult to uniformly detect the fire depending on the location where the sensor is installed and where the fire occurs.

On the other hand, the smoke detection method detects the smoke that first occurs at the beginning of a fire and spreads to the surroundings, so the time from the beginning of a fire to detection is short, so the fire can be detected quickly and as uniformly as possible regardless of the installation location. It is possible to detect one, and it is widely used recently.

In particular, among the smoke detection methods, the air intake detection device is a method of detecting a fire by actively inhaling air from various places through a pipe network composed of air sampling pipes, so that a fire over a large area can be quickly detected. It has an advantage, and since the sensing area can be expanded only by additional installation of the air sampling pipe piping network, it is very efficient when trying to further expand the existing sensing area.

The air intake type fire detector includes a smoke detector installed on an indoor wall to detect whether there is a fire using smoke sucked in, and an air sampling system installed on the ceiling or a place where fire detection is required to configure an air intake passage. made of pipes

The smoke detector controls a vacuum pump for sucking air through an air sampling pipe, a smoke detector that analyzes smoke or gas from the sucked air, and controls the vacuum pump and the smoke detector based on data detected from the smoke detector. It is equipped with a controller that determines whether there is a fire and controls it to sound an alarm or transmits a fire signal in connection with a disaster prevention system.

In addition, the air sampling pipe is connected to the smoke detector and is disposed long to the place where the fire is to be detected to form a pipe network. It is designed to suck air from various places in the room.

Therefore, when the vacuum pump of the smoke detector is driven, air in various places in the room is sucked through the air inlet of the air sampling pipe and supplied to the smoke detector of the smoke detector, so that the air condition in various places in the room can be continuously sensed. And, if smoke or gas is included in the inhaled air, the smoke detection unit detects it and the control unit determines whether there is a fire based on the detection data. It can be suppressed to minimize the damage to valuable lives and property.

As a prior art of the air suction type fire detector, Korean Patent Registration No. 10-1188094 'Air sampling pipe for an air suction type fire detection device that is easy to remove dust' may be referred to.

In addition, reference may be made to Korean Registered Patent No. 10-2477850 air suction type fire detector, filed and registered by the present applicant.

Since this air suction type fire detector analyzes the air sucked through the air sampling pipe to determine whether there is a fire, if the air contains a lot of dust such as dust or fine foreign substances, the smoke detector cannot accurately detect it. Therefore, there is a concern that prompt detection may not be made in the early stage in the event of a fire, and even if a fire does not occur, there is a concern that a fire is misjudged and the disaster prevention system is operated. Therefore, the inside of the air sampling pipe must be periodically cleaned to remove dust.

That is, the air intake type fire detector requires a cleaning device to remove dust inside the air sampling pipe.

As a prior art of such an air suction type fire detector cleaning device, reference may be made to No. 10-2023-0027141 'cleaning device for an air suction type fire detector' filed by the present applicant.

Figure 1 shows the internal structure of the air suction type fire detector cleaning device according to the prior art.

An air sampling pipe 11 and a fire detector 60 connected thereto are provided, and a cleaning device 10 is provided in the air sampling pipe 11. A plurality of air inlets 12 are formed in the air sampling pipe 11 .

The air sampling pipe 11 is branched into the fire detector 60 and the cleaner 50 through the flow path connection part 19 inside the cleaning device 10 .

The flow path connection part 19 is branched in three directions. For example, the first flow path 91 connected to the air sampling pipe 11 is coupled to the side of the flow path connection part 19, and the second flow path 92 connected to the fire detector 60 is connected to the flow path connection part 19. ), and the third flow path 93 connected to the cleaner 50 is coupled to the upper side of the flow path connection part 19.

The first flow path 91 connects the air sampling pipe 11 and the passage connection part 19, so that the air sucked from the air sampling pipe 11 passes through the passage connection part 19 to the fire detector 60 or the cleaner 50. ) is sent to

The second flow path 92 connects the fire detector 60 and the flow path connection part 19, and the first valve 20 is installed adjacent to the flow path connection part 19 in the second flow path 92, and the air sampling pipe The air introduced through (11) flows into the fire detector (60) through the first valve (20).

The third flow path 93 connects the cleaner 50 and the flow path connection part 19, and the second valve 30 is installed adjacent to the flow path connection part 19 in the third flow path 93, and the air sampling pipe ( The air introduced through 11) flows into the cleaner 30 through the second valve 30.

The first valve 20 remains open unless an external force acts. In a normal state in which the cleaner 50 does not operate and only the fire detector 60 operates, air introduced from the air sampling pipe 11 passes through the first valve 20 and enters the fire detector 60.

The second valve 30 remains closed unless an external force acts on it.

When the cleaner 50 operates and the suction force acts on the third flow path 93, the first valve 20 is closed to block air movement through the second flow path 92, and the second valve 30 is opened and the air moves to the third flow path (93).

The dust sucked by the cleaner 50 is collected in the dust collection unit 40 . Meanwhile, a manipulation unit 15 for manipulating the cleaner 50 is provided.

In the air suction type fire detector cleaning device according to the prior art, two dust collecting parts 40 and two cleaners 50 are provided, and two air sampling pipes 11 are connected to each dust collecting part 40.

However, the cleaner 50 is a fairly expensive product, and generates a lot of noise. If the number of cleaners and dust collectors can be reduced, the cost can be reduced and the noise can be reduced.

The present invention was conceived to solve the above problems, and its object is to provide a cleaning device for air suction type fire detectors in which the number of cleaners and dust collection units is reduced.

Another object of the present invention is to provide a cleaning device for an air suction type fire detector in which noise generation is reduced.

Another object of the present invention is to provide a cleaning device for an air suction type fire detector that reduces costs due to reduced parts.

A cleaning device for an air suction type fire detector according to an embodiment of the present invention includes a plurality of branch pipes respectively connected to a plurality of air sampling pipes for sucking indoor air and a dust collection unit connected to the plurality of branch pipes, Each of the plurality of branch pipes includes a first flow path connected to the air sampling pipe, a second flow path connected to a fire detector that analyzes components of the sucked air, and a third flow path connected to a cleaner that removes dust from the sucked air. Is coupled, the dust collecting unit, an external chamber connected to the plurality of branch pipes; and an inner chamber sequentially communicating with the plurality of branch pipes while rotating within the outer chamber.

Here, a plurality of channel connectors connected to the outside are provided in the middle of the external chamber.

In addition, the plurality of channel connectors are arranged at equal intervals along the circumferential surface.

In addition, the plurality of channel connectors protrude from the outer chamber, are inclined upward with respect to the horizontal direction, and inclined in a circumferential direction with respect to the radial direction.

In addition, a lower portion of the outer chamber is formed with an inclined portion narrowing downward.

In addition, a first discharge hole is formed at a lower end of the outer chamber.

In addition, a stepped portion to which a packing member is installed is formed on an inner circumferential surface of the outer chamber.

In addition, an upper cover is provided between the outer chamber and the cleaner.

In addition, the upper cover has an upper surface formed of a flat plate and a coupling surface formed of a circumferential surface and connected to a lower portion of the upper surface.

In addition, a guide rail part supporting the inner chamber is provided on the coupling surface.

In addition, a rail groove is formed in the guide rail unit, and the inner chamber is moved up and down by an elevating member moving along the rail groove.

In addition, the guide rail part has a guide surface formed of a flat plate and a circumferential surface connected to a lower portion of the guide upper surface and having the rail groove formed therein.

In addition, the rail groove has a curved rising portion that rises gently and a curved descending portion that rapidly descends.

In addition, a stop portion protruding to the right of the lower portion is formed at a right end of the rising portion.

In addition, a backflow prevention part is formed at the right end of the descending part, the upper and lower points being formed to the left of the lower and lower points.

In addition, the elevating member is composed of a vertical part disposed above and coupled to the guide rail and a horizontal part disposed below and coupled to the inner chamber.

In addition, a shaft member is installed through the vertical portion, and a rotating member inserted into the rail groove is provided on the shaft member.

In addition, a second inclined portion narrowing downward is formed at a lower portion of the inner chamber, and a second discharge hole is formed at a lower portion of the inner chamber.

In addition, a suction part communicating with any one of the plurality of channel connectors is formed in the middle of the inner chamber.

In addition, the packing member, a packing rim formed of a rigid material and having a plurality of rim holes are formed; and a packing seal formed of a soft material and having a plurality of seal holes.

And, the suction part is provided with an O-ring.

According to the cleaning device for an air suction type fire detector according to an embodiment of the present invention, a dust collecting unit sequentially connected to the air sampling pipe of all channels is provided, and the configuration is completed with a single cleaner and a dust collecting unit, so that the number of parts is reduced.

Accordingly, parts costs for the dust collector and the cleaner are reduced.

In addition, since the number of cleaners is reduced, noise generation is reduced.

In addition, since the plurality of sampling pipes are sequentially connected to the cleaner one by one, the suction force of the cleaner increases.

1 is an internal structure diagram of a cleaning device for an air suction type fire detector according to the prior art.
2 is an internal structure diagram of a cleaning device for an air suction type fire detector according to an embodiment of the present invention.
3 and 4 are operational diagrams of an air intake type fire detector to which a cleaning device according to an embodiment of the present invention is applied.
5 is a perspective view of a dust collector applied to a cleaning device for an air suction type fire detector according to an embodiment of the present invention.
6a and 6b are exploded perspective views of the dust collector of FIG. 5 .
7 is a longitudinal sectional view of a dust collector.
8 and 9 are longitudinal cross-sectional and top views of the outer chamber.
10 is a partial side view of a guide rail part.
11 is a side view of the elevating member.
12 is a side view of the inner chamber.
13 is a working diagram of a dust collection unit applied to a cleaning device for an air suction type fire detector according to an embodiment of the present invention, showing a state when the cleaner operates.
14 is a plan view of an inner chamber according to another embodiment of the present invention.
15 is a side view of an inner chamber according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, this is to explain in detail enough for those skilled in the art to easily practice the invention, which means that the technical spirit and scope of the present invention are limited by these drawings. It is not.

The term "member" or "part" used to refer to a component in the present invention is not used for any limiting purpose, and may be omitted.

An air intake type fire detector according to each embodiment of the present invention will be described in detail with reference to the drawings.

2 shows an internal structure diagram of a cleaning device for an air suction type fire detector according to an embodiment of the present invention, and FIGS. 3 and 4 show an air suction type fire detector to which the cleaning device according to an embodiment of the present invention is applied. A functional diagram of the sensor is shown.

The cleaning device 100 for an air suction type fire detector according to an embodiment of the present invention includes a plurality of branch pipes 190 connected to a plurality of air sampling pipes 110 sucking indoor air, and the plurality of branch pipes 190, respectively. It includes a dust collector 400 connected to the engine 190, and the plurality of branch pipes 190 include a first flow path 910 connected to the air sampling pipe 110, respectively, to analyze the components of the sucked air. A second flow path 920 connected to the fire detector and a third flow path 930 connected to a cleaner for removing dust from sucked air are coupled, and the dust collector 400 is connected to the plurality of branch pipes 190. It includes an external chamber 410 that is connected and an internal chamber 440 that sequentially communicates with the plurality of branch pipes 190 while rotating within the external chamber 410 .

First, an overview of the basic configuration and operation of the cleaning device for an air suction type fire detector according to an embodiment of the present invention is as follows.

An air suction type fire detector cleaning device 100 according to an embodiment of the present invention includes an air sampling pipe 110 for sucking air, a first flow path 910 connected to the air sampling pipe 110, and a fire detector A flow path connection part (branch pipe) 190 to which the second flow path 920 connected to the 600 and the third flow path 930 connected to the cleaner 500 is connected, and is provided in the branch pipe 190 to detect a fire detector 600 or non-powered valve assemblies 200 and 300 selectively connected to the cleaner 500, and a dust collector 400 provided between the cleaner 500 and the third flow path 930 of the branch pipe 190.

The action of the cleaning device 100 for an air suction type fire detector according to an embodiment of the present invention is that the first non-powered valve assembly 200 connected to the second flow path 920 is opened and introduced through the air sampling pipe. When the cleaner 500 is operated, the second non-powered valve assembly 300 connected to the third flow path 930 is opened to clean the inside of the air sampling pipe 110. , the introduced air is switched to the cleaner 500 (see FIG. 4).

Let's take a closer look at the cleaning device 100 for an air suction type fire detector according to an embodiment of the present invention.

The enclosure 101 will be described first. An enclosure 101 forming the outer shape of the cleaning device 100 for an air suction type fire detector is provided. The enclosure 101 may be made of a material such as steel or synthetic resin. In the enclosure 101, devices or parts such as the non-powered valve assemblies 200 and 300, the dust collecting unit 400, and the cleaner 500 are embedded or installed.

In addition, one end of the first flow path 910 , the second flow path 920 , and the third flow path 930 are respectively installed in the enclosure 101 . On the other hand, a flow path connection portion (branch pipe) 190 connecting the first flow path 910 , the second flow path 920 , and the third flow path 930 is provided.

A fire detector 600 may be built into the enclosure 101 or a fire detector 600 installed outside may be connected. The enclosure 101 must be manufactured with sufficient strength to support the installed devices or parts and to maintain stable operation.

Inside the enclosure 101, a mount 130 is provided in the middle, and each flow path or component can be installed.

An air sampling pipe 110 is provided. The air sampling pipe 110 is provided to suck in indoor air, which is a space to be detected by fire, and provide the air to the fire detector 600 . A plurality of air sampling pipes 110 may be provided. For example, four air sampling pipes 110 may be configured as one set. In the case where the plurality of air sampling pipes 110 are configured as described above, each air sampling pipe 110 is divided into a channel or a way. That is, when it is composed of 4 air sampling pipes 110, it is composed of 1 channel to 4 channels. In order to distinguish these channels, subscripts of lowercase alphabet letters a, b, c, and d are used. That is, the code of the 1-channel air sampling pipe is indicated as 110a.

The air sampling pipe 110 is disposed with an appropriate length in the space to be sensed. When a plurality of air sampling pipes 110 are divided into each floor or compartment (room) inside a building, the space to be sensed (monitored) reaches a significant portion. That is, since the air sampling pipe 110 can be properly extended and disposed in a necessary space, the space to be monitored is easily expandable.

The air sampling pipe 110 may be associated with a network system. For example, it may be combined with a network line such as TCP/IP or USB, or provide an auxiliary function of a network line.

A filter (not shown) may be provided in the air sampling pipe 110 . Indoor air contains a small amount of dust, moisture, and salt, so when these foreign substances accumulate in the air sampling pipe 110, normal operation is prevented. Accordingly, a filter for removing these foreign substances may be provided.

Although not shown separately, a fan or a suction mechanism for sucking air may be provided at an end of the air sampling pipe 110 . In this case, indoor air may be forcibly introduced into the air sampling pipe 110 by a fan or the like.

An intake hole 112 is formed in the air sampling pipe 110 . A plurality of intake holes 112 are formed in the air sampling pipe 110 . Indoor air is drawn into the air sampling pipe 110 through the intake hole 112 and moves to the fire detector 600 . A plurality of intake holes 112 are formed in the longitudinal direction along the air sampling pipe 110 . The intake holes 112 may be arranged in one row or multiple rows in the longitudinal direction along the air sampling pipe 110 .

An intake valve may be provided in the intake hole 112 of the air sampling pipe 110 to smoothly perform the intake operation. An intake valve may be provided for each air sampling pipe 110 .

To connect the air sampling pipe 110 to the fire detector 600 and the cleaner 500, a first flow path 910, a second flow path 920, and a third flow path 930 are provided. Each flow path may be composed of a pipe (tube). A T-shaped flow path connection portion 190 is provided at a portion where the three flow paths converge. The flow path connection part 190 may be formed as a T-shaped tube. The flow path connection unit 190 may also be referred to as a branch pipe.

The first flow path 910 connects the air sampling pipe 110 and the flow path connection unit 190 . The air sucked from the air sampling pipe 110 is sent to the fire detector 600 or the cleaner 500 via the flow path connection 190 .

The second flow path 920 connects the fire detector 600 and the flow path connection unit 190 . The first non-powered valve assembly 200 is installed in the second flow path 920 adjacent to the flow path connection part 190 . Air introduced through the air sampling pipe 110 is introduced into the fire detector 600 through the first non-powered valve assembly 200 .

The third flow path 930 connects the cleaner 500 and the flow path connection part 190 . The second non-powered valve assembly 300 is installed adjacent to the flow path connection part 190 in the third flow path 930 . Air introduced through the air sampling pipe 110 is introduced into the cleaner 300 through the second non-powered valve assembly 300 .

The flow path connection part 190 branches in three directions. Here, the three directions may include upward, downward, and lateral directions. Here, the first flow path 910 connected to the air sampling pipe 110 is coupled to the side of the flow path connection unit 190, and the second flow path 920 of the flow path connection unit 190 connected to the fire detector 600 is The third flow path 930 coupled to the lower side and connected to the cleaner 500 is coupled to the upper side of the flow path connection unit 190 .

The non-powered valve assemblies 200 and 300 will be described.

Unpowered valve assemblies 200 and 300 are provided. The non-powered valve assemblies 200 and 300 are provided to adjust the movement path of air sucked from the air sampling pipe 110 according to circumstances.

The non-powered valve assemblies 200 and 300 include a first non-powered valve assembly 200 connected to the fire detector 600 and a second non-powered valve assembly 300 connected to the cleaner 500.

First, the first non-powered valve assembly 200 will be described with reference mainly to the operational views of FIGS. 3 and 4 . 3 shows a state in which the first non-powered valve assembly 200 is opened and the second non-powered valve assembly 300 is closed so that the sucked air flows to the fire detector 600, and FIG. 4 shows the first non-powered valve assembly 200 ) is closed and the second non-powered valve assembly 300 is opened to indicate a state in which the sucked air flows to the cleaner 500 .

The first non-powered valve assembly 200 includes a first housing 210, a first cover 230, and a first opening/closing valve 250.

The first housing 210 may be made of a synthetic resin material or a metal material. The first housing 210 is formed in a cylindrical shape.

The first housing 210 is stepped and has a first expansion part 211 and a first contraction part 220 . A plurality of first inclined surfaces 215 are formed between the first expansion part 211 and the first contraction part 220 .

The first contraction part 220 is connected to the second flow path 920 .

The first cover 230 may include a first flange portion 231 and a first pipe portion 240 .

The first pipe part 240 is coupled to the flow path connection part 190 . The first pipe part 240 is connected to the first flow path 910 , the third flow path 930 and the second non-powered valve assembly 300 through the flow path connection part 190 .

A first opening/closing valve 250 is provided. The first opening/closing valve 250 is inserted into the first housing 210 . The first opening/closing valve 250 is rotatably installed in the first housing 210 and placed in an open state. In a state in which there is no external force or the suction force of the fire detector 600 is applied, the first opening/closing valve 250 maintains this state.

As the first opening/closing valve 250 rotates downward, a passage from the flow path connection part 190 to the second flow path 920 is opened, and air can move. Air moves through the space inside the first housing 210 .

When the cleaner 500 operates and the suction force acts on the first pipe part 240, the first opening/closing valve 250 rotates upward and contacts the first cover 230 to block the first pipe part 240. .

The upper part of the first non-powered valve assembly 200, that is, the first pipe part 240 of the first cover 230 is connected to the flow path connection part 190, and is connected to the first flow path 910 and the second non-powered valve assembly 300. Subsequently, the lower part of the first non-powered valve assembly 200, that is, the first contraction part 220 of the first housing 210 is connected to the second flow path 920. Here, the first flow path 910 is connected to the air sampling pipe 110 and the second flow path 920 is connected to the fire detector 600 as described above.

In the first non-powered valve assembly 200, the first opening/closing valve 250 is in an open state by gravity unless an external force acts. Even when suction force is applied from the fire detector 600, the first opening/closing valve 250 maintains this state. Air introduced from the air sampling pipe 110 flows through the space in the first housing 210 to the second flow path 920 and enters the fire detector 600 .

When a suction force acts on the first non-powered valve assembly 200 from the side of the third flow path 930, the first opening/closing valve 250 rises and comes into contact with the first flange portion 231, and the first non-powered valve assembly 200 is closed so that air movement through the second flow path 920 is blocked.

Next, the second non-powered valve assembly 300 will be described.

The second powerless valve assembly 300 is formed similarly to the first powerless valve assembly 200 . However, the installation direction of the second non-powered valve assembly 300 is opposite to that of the first non-powered valve assembly 200 . That is, the second housing 310 is disposed on the upper side, and the second cover 330 coupled thereto is disposed on the lower side.

The second non-powered valve assembly 300 includes a second housing 310, a second cover 330, and a second opening/closing valve 350.

The second housing 310 may be made of a synthetic resin material or a metal material. The second housing 310 is formed in a cylindrical shape.

The second housing 310 is stepped and has a second expansion part 311 and a second contraction part 320 . Here, the diameter (outer diameter) of the second expansion part 311 is larger than the diameter (outer diameter) of the second contraction part 320 .

A second inclined surface 315 is provided between the second expansion part 311 and the second contraction part 320 .

The second contraction part 320 is connected to the third flow path 930 .

The second cover 330 may include a second flange portion 331 and a second pipe portion 340 .

The second pipe part 340 is coupled to the flow path connection part 190 . The second pipe part 340 is connected to the first flow path 910 , the second flow path 920 and the first non-powered valve assembly 200 through the flow path connection part 190 .

A second opening/closing valve 350 is provided. The second opening/closing valve 350 is inserted into the second housing 310 . The second opening/closing valve 350 rests on the second flange portion 331 . In a state in which there is no external force or in a state in which suction force is applied from the side of the fire detector 600, the second opening/closing valve 350 maintains a posture placed on the second flange portion 331 as described above.

When the cleaner 500 operates and a suction force acts on the second pipe part 340, the second opening/closing valve 350 rotates upward. In this state, air moves through the space within the second housing 331 .

The upper part of the second non-powered valve assembly 300, that is, the second contraction part 320 of the second housing 310 is connected to the third flow path 930, and the lower part of the second non-powered valve assembly 300, that is, the The second pipe part 340 of the second cover 330 is coupled to the flow path connection part 190 and connected to the first flow path 910 and the first non-powered valve assembly 200 . Here, the first flow path 910 is connected to the air sampling pipe 110 and the third flow path 930 is connected to the cleaner 500 as described above.

In the second non-powered valve assembly 300, the second opening/closing valve 350 is placed on the second flange portion 331 by gravity unless an external force acts. Even when suction force is applied from the fire detector 600, the second open/close valve 350 maintains this state. Thus, the third flow path 930 is closed.

When a suction force acts on the second non-powered valve assembly 300 in the direction of the third flow path 930, the second opening/closing valve 350 rises, the second non-powered valve assembly 300 is opened, and air flows into the third flow path. Go to (930).

A fire detector 600 is provided. Of the air sucked in through the air sampling pipe 110, the air that has passed through the flow path connector 190 and the first non-powered valve assembly 200 is introduced into the fire detector 600 through the second flow path 920.

The fire detector 600 analyzes the components of the air sucked through the air sampling pipe 110 to detect whether there is a fire and notify it.

A cleaner 500 is provided. Of the air sucked in through the air sampling pipe 110 , air that has passed through the flow path connection unit 190 and the second non-powered valve assembly 300 is introduced into the cleaner 500 through the third flow path 930 .

When the motor 510 in the cleaner 500 operates, a suction force that sucks air toward the cleaner 500 acts, and accordingly, the pressure in the third flow passage 930 connected to the second non-powered valve assembly 300 decreases. Thus, the second opening/closing valve 250 rises. Accordingly, the second non-powered valve assembly 300 is opened and air movement through the third flow path 930 is permitted.

At this time, when the suction force is strong, the first opening/closing valve 250 also rises, the first non-powered valve assembly 200 is closed, and the movement of air through the second flow path 920 is blocked. (See Fig. 4)

The cleaner 500 removes dust in the air sampling pipe 110 so that the air flowing to the fire detector 600 can be delivered as indoor air. That is, dust adhering to or stacked on the inside of the air sampling pipe 110 or around the intake hole 112 is sucked by the suction force of the cleaner 500 .

The cleaner 500 is operated by the control panel 150 . The control panel 150 controls the operation of the cleaner 500 . For example, in the control panel 150, operating conditions such as operating time, operating cycle, operating intensity, and operating channel of the cleaner 500 may be set. Since the cleaner 500 is usually operated by the motor 510, the control panel 150 controls driving of the motor 510.

A dust collection unit 400 is provided to collect dust or moisture from the air sucked by the cleaner 500 . The dust collecting unit 400 may be provided between the second flow path 920 and the cleaner 500 . Alternatively, the dust collecting unit 400 may be built into the cleaner 500 .

A dust collection unit 400 is provided. The dust collector 400 separates and discharges dust and impurities contained in the dust air by generating centrifugal force on dusty air introduced into the inside through a mechanical or physical action to remove dust or impurities accumulated on the air sampling pipe 110 and , It is a device that minimizes dust and impurities flowing into the fire detector 600.

5 is a perspective view of a dust collector according to an embodiment of the present invention, FIGS. 6A and 6B are an exploded perspective view of the dust collector according to an embodiment of the present invention, and FIG. 7 is an embodiment of the present invention. A longitudinal cross-sectional view of the dust collector according to the example is shown.

The dust collection unit 400 applied to an embodiment of the present invention is designed to improve dust collection efficiency.

The dust collector 400 is configured to connect a plurality of passages (channels) (at least three or more). For example, the dust collector 400 is configured in a 4-way (or 4-channel) format. That is, it is designed to sequentially introduce the dusty air of the four air sampling pipes 110.

The air sampling pipe 110 is provided in plurality. For example, the air sampling pipe 110 is composed of four (110a, 110b, 110c, 110d). This will be referred to as 4-way or 4-channel. They are classified into a first channel sampling pipe 110a, a second channel sampling pipe 110b, a third channel sampling pipe 110c, and a fourth channel sampling pipe 110d.

When classifying the passages connected to the air sampling pipe 110 of each channel by channel, lowercase letters of the alphabet are applied. For example, the first flow path 910a of the first channel is denoted as 910a.

The dust collecting unit 400 includes an outer chamber 410, an inner chamber 440, and a guide rail 430. Here, the outer chamber 410 is connected to all four air sampling pipes 110 (specifically, connected through the third flow path for each channel), and the inner chamber 440 is connected to the guide rail within the outer chamber 410. Circling along the portion 430, it is sequentially connected to four air sampling pipes 110a, 110b, 110c, and 110d.

Further reference is made to a longitudinal cross-sectional view of the outer chamber shown in FIG. 8 and a top view of the outer chamber shown in FIG. 9 .

An upper cover 420 is coupled to the upper surface of the outer chamber 410 . The outer chamber 410 and the guide rail unit 430 are coupled to the upper cover 420 .

A plurality of channel connectors 416 are provided in the external chamber 410 . The air sampling pipe 110 is connected to the connection unit through each of the four channels. For example, the first channel sampling pipe 110a is connected to the first channel connector 416a via the first channel first flow path 910a and the first channel third flow path 930a (see FIG. 2 ).

The outer chamber 410 is formed in a cylindrical shape. That is, the first opening 411 is formed on the upper surface of the external chamber 410 .

The upper end 412 of the wall of the outer chamber 410 is coupled to the upper cover 420 . The upper end of the wall 412 may be coupled to the upper cover 420 by screwing. To this end, a thread may be formed on the inner circumferential surface 412a of the upper end portion 412 of the wall.

A first inclined portion 414 narrowing downward is formed at a lower portion of the outer chamber 410 .

A first discharge hole 415 is formed at the lower end of the outer chamber 410 . Dust or moisture accumulated in the lower part of the chamber is discharged to the outside through the first discharge hole 415 . Here, although not separately shown, a check valve may be connected to the first discharge hole 415 . Dust or moisture accumulates in the check valve, and the user can discharge the dust by opening the check valve at an appropriate time.

A plurality of channel connectors 416 connected to the outside are provided in the middle of the external chamber 410 . Channel connectors 416 are provided corresponding to the number of channels. For example, in the case of a system having a 4-channel air sampling pipe 110, 4 channel connectors 416 may be provided. Each channel connector can be divided into 416a, 416b, 416c, and 416d.

At this time, it is preferable that each channel connector 416 is provided at equal intervals along the circumferential surface of the external chamber 410 . That is, in the case of four channels, the channel connectors 416 adjacent to each other are provided at intervals of 90 degrees.

Channel connector 416 is formed of a tube. That is, a connection hole 417 is formed inside the channel connector 416 . The third flow path 930 of the flow path connection part 190 connected to the air sampling pipe 110 of each channel is connected to each channel connector 416 so that the dust of the air sampling pipe 110 is absorbed when the motor operates.

The channel connector 416 protrudes obliquely from the outer chamber 410 . The channel connector 416 protrudes from the outer chamber 410 in a horizontal direction and a radial direction, respectively, in an oblique direction. For example, the channel connector 416 is inclined upward by 45 degrees with respect to the horizontal direction from the external chamber 410, and protrudes in an inclined direction by 45 degrees in the circumferential direction with respect to the radial direction (see FIGS. 8 and 9). . Accordingly, the air sucked in through the third flow path 930 moves downward while rotating along the inner circumferential surface of the chamber, then rises along the center and moves to the cleaner 500 through the central holes 422 and 432 . At this time, dust or moisture in the sucked air descends and is discharged to the lower part through the discharge holes 415 and 445 . That is, a cyclone effect in which dust and air are separated occurs in the dust collector.

In addition, the space occupied by the channel connector 416 and the third flow path 930 in the inner space of the enclosure 101 is reduced, so that the cleaning device has a compact configuration.

A stepped portion 418 in which the packing members 460 and 470 are installed is formed on the inner circumferential surface of the outer chamber 410 . The stepped portion 418 is formed at a lower portion adjacent to the portion where the channel connector 416 is formed. This is because the packing members 460 and 470 are in contact with the circumference of the connection hole 417 of the channel connector 416 .

An upper cover 420 is coupled to the upper surface of the outer chamber 410 .

The upper cover 420 has an upper surface 421 formed of a flat plate and a coupling surface 425 formed of a circumferential surface and connected to a lower portion of the upper surface 421 .

A first central hole 422 is formed in the upper surface 421 . The inside of the dust collecting unit 400 communicates with the cleaner 500 through the first central hole 422 .

A first fastening hole 424 into which a fastening member capable of coupling the guide rail unit 430 is inserted is formed on the upper surface 421 .

A plurality of protrusions 423 protruding toward the periphery may be formed on the upper surface 421 . The protrusion 423 also serves as a handle that can be grasped by the user.

The outer chamber 410 and the guide rail unit 430 are coupled to the coupling surface 425 .

Threads are formed along the outer circumferential surface of the coupling surface 425 so that the external chamber 410 can be screwed together.

The guide rail unit 430 may be fitted to the coupling surface 425 along the inner circumferential surface.

A guide rail unit 430 is provided. A cam line is formed on the guide rail unit 430 to move the inner chamber 440 up and down by the elevating member 450 .

The guide rail unit 430 is formed in an inverted cylindrical shape.

The guide rail unit 430 has a guide upper surface 431 formed as a flat plate and a guide surface 435 formed as a circumferential surface and connected to a lower portion of the guide upper surface 431 .

A second central hole 432 is formed in the upper surface 431 . The second central hole 432 communicates with the first central hole 422 and is connected to the cleaner 500 from the dust collecting part 400 through the second central hole 432 and the first central hole 422 .

A second fastening hole 434 communicating with the first fastening hole 424 is formed on the upper surface of the guide 431 . The fastening member is coupled to the first fastening hole 424 and the second fastening hole 434 so that the guide rail unit 430 is fixed to the upper cover 420 .

A fitting groove 433 is formed along the circumferential direction at the outer portion of the portion where the upper guide surface 431 and the guide surface 435 come into contact. The fitting groove 433 of the guide rail part 430 is fitted into the coupling surface 425 of the upper cover 420 .

A rail groove 436 formed as a wave-shaped cam groove is provided on the outer circumferential surface of the guide surface 435 . 10 shows a specific form of the rail groove 436.

The rail groove 436 has a rising portion 436a formed of a curve that rises gently and a descending portion 436c formed of a curve that rapidly descends.

A stop portion 436b protruding to the right from the lower portion 436c is formed at the right end of the rising portion 436a. When the motor of the cleaner 500 operates to raise the internal chamber 440 and the rotating member 457 of the elevating member 450 rises, it is placed in a temporarily stopped state at the stop portion 436b.

At the right end of the descending portion 436c, a backflow prevention portion 436d is formed with an upper and lower point 436e on the left side of the lower and lower point 436f. When the operation of the motor of the cleaner 500 stops, the internal chamber 440 descends, and the rotating member 457 of the elevating member 450 is positioned at the backflow preventing part 436d. Thereafter, when the motor is operated again, the rotating member 457 is caught at the upper and lower points 436e and fails to move in the left direction, and rises along the rising part 436a in the right direction.

The rail groove 436 may have an ascending part and a descending part according to the number of channels. For example, in the case of 4 channels, four rising parts 436a and four falling parts 436c are formed. Here, the ascending part 436a and the descending part 436c are alternately formed and connected to each other to create a single path that goes up and down. At this time, since each rising portion 436a and lowering portion 436c are repeatedly formed in the same size, they form an angle of 90 degrees with respect to adjacent portions. For example, a gap between one stopper 436b and an adjacent stopper 436b is 90 degrees.

In a system having a 4-channel air sampling pipe 110, when four ascending parts 436a and four descending parts 436c of the rail groove 436 are formed along the circumferential surface, one cycle of the inner chamber 440 The air sampling pipes 110 of each channel are communicated with each other once. This is related to the rotational speed, and is not necessarily limited by the number of the ascending portion 436a and the descending portion 436c. For example, when four rail grooves 436 of the guide rail unit 430 are formed on one circumferential surface, each of four raised portions 436a and four lowered portions 436c are formed, each rotation of the inner chamber 440 Each air sampling pipe 110 is communicated once.

An elevating member 450 is provided. The elevating member 450 ascends while rotating along the guide rail unit 430 . 11 shows a side view of the elevating member 450 .

The elevating member 450 is formed in an inverted 'T' shape. That is, the elevating member 450 is composed of a vertical portion 451 disposed above and a horizontal portion 452 disposed below.

In the vertical portion 451, a shaft member 455 is installed through the through hole 453, and a rotating member 457 is provided in the shaft member 455. The rotating member 457 is inserted into the rail groove 436 of the guide rail unit 430 and is movable along the rail groove 436 . Here, the rotating member 457 may be composed of a roller.

A fastening hole 454 is formed in the horizontal portion 452 , and a fastening member 458 is coupled to be fixed to the inner chamber 440 .

The horizontal portion 452 may be bent in an arc shape along the outer circumferential surface of the inner chamber 440 .

When the motor of the cleaner 500 operates, a pressure drop is formed on the upper part of the dust collector 400, and an upward force acts to suck the inner chamber 440 upward. At this time, the rotating member 457 of the elevating member 450 moves along the rail groove 436 of the guide rail unit 430 . Accordingly, the elevating member 450 rotates around the longitudinal axis V of the external chamber 410 and moves upward and downward. Here, since the inner chamber 440 is coupled to the lifting member 450, the inner chamber 440 also rotates and moves up and down. While the rotating member 457 of the elevating member 450 moves along the ascending portion 436a of the rail groove 436, the inner chamber 440 moves upward, and the rotating member 457 of the elevating member 450 moves upward. While moving along the descending portion 436c of the rail groove 436, the inner chamber 440 moves downward.

The vertical movement distance of the elevating member 450 and the internal chamber 440 corresponds to the height between the stopper 436b and the backflow preventer 436d.

An inner chamber 440 is provided. The inner chamber 440 rotates and ascends and descends according to the operation of the motor 510 of the cleaner 500 .

The inner chamber 440 is formed in a cylindrical shape. An opening 441 is formed on an upper surface of the inner chamber 440 . 12 shows a side view of the inner chamber.

A fastening hole 443 is formed in the rim of the upper end 442 of the inner chamber 440 to couple the elevating member 450 thereto.

The lower part of the inner chamber 440 is formed with a second inclined portion 444 in an up-and-down shape. The air sucked through the channel connector 416 rotates along the second inclined portion 444 like a whirlwind while descending, and moves upward while the power is weakened at the center.

A second discharge hole 445 is formed at the lower end of the inner chamber 440 . The second discharge hole 445 communicates with the first discharge hole 415 of the external chamber 410 .

A suction part 446 is formed in the middle of the inner chamber 440 . The suction part 446 is composed of a periphery 447 protruding to the outside and an intake hole 448 surrounded by the periphery 447 .

When the suction part 446 of the inner chamber 440 communicates with the channel connector 416 of the outer chamber 410, air from the sampling pipe 110 of the channel connected to the corresponding channel connector 416 flows through the inner chamber 440. is sucked into the interior of (see Fig. 13). The channel connector 416 is formed to communicate when reaching one of the stop portions 436b of the rail groove 436.

Packing members 460 and 470 are provided between the outer chamber 410 and the inner chamber 440 .

The packing members 460 and 470 may include a packing rim 460 and a packing seal 470 .

Packing rim 460 is formed in the shape of a disk ring. The packing rim 460 is made of a material that is relatively harder than the packing seal 470, such as steel or synthetic resin.

In the packing rim 460, rim holes 462 are formed according to the number of channels along the circumferential direction.

The packing rim 460 is fitted and coupled to the stepped portion 418 of the outer chamber 410 as if to rest on it.

The packing seal 470 is formed in the shape of a disc ring. The packing seal 470 is formed of a material that is relatively soft compared to the packing rim 460, such as silicone or rubber. The packing seal 470 is formed of a material capable of being temporarily deformed.

A packing seal 470 is provided between the packing rim 460 and the outer chamber 410 .

Seal holes 472 are formed in the packing seal 470 according to the number of channels. The seal hole 472 is smaller than the rim hole 462 . The packing seal 470 is formed of a material capable of being temporarily deformed. Therefore, as shown in FIG. 13 , when pressure is generated through the intake hole 448 of the inner chamber 440 , the area around the seal hole 472 is sucked in and comes into contact with the area 447 to create airtightness.

When the packing members 460 and 470 are installed on the stepped portion 418 of the external chamber 410, the rim hole 462 and the seal hole 472 communicate with the channel connector 416.

The packing members 460 and 470 are provided between the outer chamber 410 and the inner chamber 440 to connect the channel connector 416 and the suction part 446 and maintain airtightness from the surroundings.

The inner chamber 440 rises by the suction force when the motor operates, and descends when the motor stops.

The operation of the cleaning device 100 for an air suction type fire detector according to an embodiment of the present invention will be described.

The flow path connection part 190 branches in three directions. Here, the first flow path 910 connected to the air sampling pipe 110 is coupled to the side of the flow path connection unit 190, and the second flow path 920 of the flow path connection unit 190 connected to the fire detector 600 is The third flow path 930 coupled to the lower side and connected to the cleaner 500 is coupled to the upper side of the flow path connection unit 190 .

The first flow path 910 connects the air sampling pipe 110 and the flow path connection part 190, so that the air sucked from the air sampling pipe 110 passes through the flow path connection part 190 to the fire detector 600 or the cleaner 500. ) is sent to

The second flow path 920 connects the fire detector 600 and the flow path connection part 190, and the first non-powered valve assembly 200 is installed adjacent to the flow path connection part 190 in the second flow path 920, Air introduced through the sampling pipe 110 is introduced into the fire detector 600 through the first non-powered valve assembly 200 .

The third flow path 930 connects the cleaner 500 and the flow path connection unit 190, and the second non-powered valve assembly 300 is installed adjacent to the flow path connection unit 190 in the third flow path 930 to sample air. Air introduced through the pipe 110 is introduced into the cleaner 300 through the second non-powered valve assembly 300 .

In the first non-powered valve assembly 200, the first opening/closing valve 250 is in an open state by gravity unless an external force acts. Even when suction force is applied from the fire detector 600, the first opening/closing valve 250 maintains this state. In a normal state in which the cleaner 500 does not operate and only the fire detector 600 operates, the air introduced from the air sampling pipe 110 passes through the space inside the first non-powered valve assembly 200 to the second flow path 920. Flows into the fire detector 600.

In the second non-powered valve assembly 300, the second opening/closing valve 350 is placed on the second flange 331 by gravity unless an external force acts. Even when suction force is applied from the fire detector 600, the second open/close valve 350 maintains this state. Thus, the third flow path 930 is closed.

When the cleaner 500 operates and a suction force acts on the first non-powered valve assembly 200 from the side of the third flow path 930, the first opening/closing valve 250 rotates in the opposite direction and the first flange portion 231 , and the first non-powered valve assembly 200 is closed so that air movement through the second flow path 920 is blocked.

When the cleaner 500 operates and a suction force acts on the second non-powered valve assembly 300 in the direction of the third flow path 930, the second opening/closing valve 350 rotates upward so that the second non-powered valve assembly 300 ) is opened and the air moves to the third flow passage 930.

When the motor 510 of the cleaner 500 operates, a pressure drop is formed on the upper part of the dust collector 400 and an upward force acts to suck the inner chamber 440 upward. At this time, the rotating member 457 of the elevating member 450 moves along the rail groove 436 of the guide rail unit 430 . Accordingly, the elevating member 450 rotates around the longitudinal axis V of the external chamber 410 and moves upward and downward. Here, since the elevating member 450 is coupled to the inner chamber 440, the inner chamber 440 also rotates and moves upward and downward. While the rotating member 457 of the elevating member 450 moves along the ascending portion 436a of the rail groove 436, the inner chamber 440 moves upward, and the rotating member 457 of the elevating member 450 moves upward. While moving along the descending portion 436c of the rail groove 436, the inner chamber 440 moves downward.

When the cleaner 500 is operated and the rotating member 457 of the elevating member 450 moves along the elevated portion 436a of the rail groove 436 and is at the stationary portion 436b, intake air from the inner chamber 440 The hole 448 communicates with the connection hole 417 of the external chamber 410 . First, it is assumed that the intake hole 448 of the inner chamber 440 is located in the first channel connector 416a. Thereafter, when the cleaner 500 stops, the rotating member 457 moves along the descending portion 436c of the rail groove 436 and comes to the backflow preventing portion 436d.

Thereafter, when the cleaner 500 is operated again, the inner chamber 440 rotates and rises, so that the intake hole 448 of the inner chamber 440 communicates with the connection hole 417 of the outer chamber 410. This time, the intake hole 448 of the inner chamber 440 is located at the second channel connector 416b.

In this way, whenever the operation of the cleaner 500 is turned on or off, the internal chamber 440 rotates and ascends and descends along the ascending portion 436a and the descending portion 436c of the rail groove 436 . A moving distance along one ascending part 436a and one descending part 436c may be referred to as one cycle. The intake hole 448 of the inner chamber 440 is sequentially connected to each channel connector 416 of the outer chamber 410 at every cycle.

Accordingly, the air sampling pipes 110a, 110b, 110c, and 110d of each channel are sequentially connected to the cleaner to remove dust.

Here, control of the operation of the cleaner 500 is possible through the control panel 150 . In the control panel 150, the time or period connected to each channel may be set by adjusting the on/off cycle, operating time, and operating intensity of the cleaner 500.

14 is a plan view of an inner chamber according to another embodiment of the present invention.

A fastening hole 443 is formed in the rim of the upper end 442 of the inner chamber 440 to couple the elevating member 450 thereto. An insertion groove 443a may be formed around the fastening hole 443 along the circumferential surface so that the horizontal portion 452 of the elevating member 450 is inserted and coupled thereto.

15 is a side view of an inner chamber according to another embodiment of the present invention.

An inner chamber 440A and a second discharge hole 445A are shown. The suction part 446 is composed of a peripheral part 447A formed in a ring shape and an intake hole 448A surrounded by the peripheral part 447A.

An O-ring 490 is fitted around the peripheral portion 447A. The O-ring 490 is composed of a ring portion 491 and a hole portion 492. The O-ring 490 acts as a seal between the suction part 446 and the channel connector 416 of the outer chamber 410 . In this case, the packing members 460 and 470 of the previous embodiment may be omitted.

According to the cleaning device for an air suction type fire detector according to an embodiment of the present invention, since the dust collection unit is sequentially connected to the air sampling pipes of all channels, the configuration is completed with a single cleaner and dust collection unit.

Accordingly, the cost of the dust collection unit and cleaner parts is reduced.

In addition, since the number of cleaners is reduced, noise generation is reduced.

In addition, since the plurality of sampling pipes are sequentially connected one by one, there is an effect of increasing the suction force of the cleaner.

The embodiments described above are examples of the best practice for implementing the present invention, and those skilled in the art can make various modifications and modifications without departing from the essential characteristics of the present invention. transformation will be possible. Therefore, these embodiments are only intended to explain and not to limit the technical idea of the present invention. Therefore, it should be understood that the scope of the technical idea of the present invention is not limited by these embodiments. That is, the protection scope of the present invention should be construed according to the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

101 enclosure
110 air sampling pipe
112 intake hole
150 control panel
190 Euro connection
200,300 unpowered valve assemblies
210,310 housing
211,311 extension
215,315 slope
220,320 shrinkage
230,330 cover
231,331 Flange
240,340 government
250,350 open/close valve
400 dust collector
410 outer chamber
416 channel connector
420 top cover
430 guide rail part
436 Rail Home
440 inner chamber
450 lifting member
460,470 packing member
500 cleaner
600 fire detector
910 1st Euro
920 2nd Euro
930 3rd Euro

Claims (21)

It includes a plurality of branch pipes respectively connected to a plurality of air sampling pipes for sucking indoor air and a dust collector connected to the plurality of branch pipes,
Each of the plurality of branch pipes includes a first flow path connected to the air sampling pipe, a second flow path connected to a fire detector that analyzes components of the sucked air, and a third flow path connected to a cleaner that removes dust from the sucked air. is combined,
The dust collector,
an external chamber connected to the plurality of branch pipes; and
A cleaning device for an air suction type fire detector comprising an inner chamber sequentially communicating with the plurality of branch pipes while rotating in the outer chamber. The air suction type fire detector cleaning device according to claim 1, wherein a plurality of channel connectors connected to the outside are provided in the middle of the external chamber. According to claim 2, The plurality of channel connectors are arranged at equal intervals along the circumferential surface of the air suction type fire detector cleaning device. The air suction type fire detector cleaning device according to claim 3, wherein the plurality of channel connectors protrude from the outer chamber, are inclined upward with respect to the horizontal direction, and inclined in a circumferential direction with respect to the radial direction. . The air suction type fire detector cleaning device according to claim 1, wherein a lower portion of the outer chamber is formed with an inclined portion narrowing downward. The cleaning device of claim 1, wherein a first discharge hole is formed at a lower end of the outer chamber. According to claim 1, Air suction type fire detector cleaning device is formed on the inner circumferential surface of the outer chamber has a stepped portion to which the packing member is installed. The cleaning device of claim 1, wherein an upper cover is provided between the outer chamber and the cleaner. The cleaning device of claim 8, wherein the upper cover has an upper surface formed of a flat plate and a coupling surface formed of a circumferential surface and connected to a lower portion of the upper surface. [10] The cleaning device of claim 9, wherein a guide rail portion for supporting the inner chamber is provided on the coupling surface. [Claim 11] The cleaning device of claim 10, wherein a rail groove is formed on the guide rail, and the inner chamber is moved up and down by an elevating member moving along the rail groove. [Claim 12] The cleaning device of claim 11, wherein the guide rail part has a guide surface formed of a guide upper surface formed of a flat plate and a circumferential surface, connected to a lower portion of the guide upper surface, and having the rail groove formed therein. . [Claim 12] The cleaning device of claim 11, wherein the rail groove has a gently rising curved rising part and a rapidly falling curved descending part. [Claim 14] The air suction type fire detector cleaning device according to claim 13, wherein a stop portion protruding to the right side of the lower portion is formed at a right end of the rising portion. [Claim 14] The air suction type fire detector cleaning device according to claim 13, wherein an upper and lower point is formed on the left side of a lower and lower point at a right end of the descending part. The air suction type fire detector cleaning device according to claim 11, wherein the elevating member is composed of a vertical part disposed above and coupled to the guide rail part and a horizontal part disposed below and coupled to the internal chamber. [Claim 17] The air suction type fire detector cleaning device according to claim 16, wherein a shaft member is installed through the vertical part, and a rotating member inserted into the rail groove is provided on the shaft member. The air suction type fire detector cleaning device according to claim 1, wherein a second inclined portion narrowing downward is formed at a lower portion of the inner chamber, and a second discharge hole is formed at a lower portion of the inner chamber. [Claim 3] The cleaning device of claim 2, wherein a suction part communicating with any one of the plurality of channel connection holes is formed in the middle of the inner chamber. The method of claim 7, wherein the packing member,
A packing rim made of a rigid material and having a plurality of rim holes formed therein; and
A cleaning device for an air suction type fire detector comprising a packing seal formed of a soft material and having a plurality of seal holes. [Claim 20] The cleaning device of claim 19, wherein an O-ring is provided on the suction part.

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