KR102173830B1 - A fire rescue system that uses 3d mapping signals from an air purifying device to detect and locate fires - Google Patents

Abstract

The present invention relates to a fire and rescue system using a 3D mapped rescue signal from an air purification device and, more specifically, to a fire and rescue system which safely protects a user from toxic gas in case of fire, allows the user to easily replace a filter when the life of the filter expires during the use of the device, can continuously and hermetically protect the user′s respiratory system from external harmful substances and fine dust even while the filter is being replaced, detects whether the user is wearing the air purification device normally, and determines whether or not airtightness is maintained and generates a notification so that the user can recognize the determination. Therefore, the fire and rescue system can maximize the effect of wearing and, in case of fire, can quickly rescue the user by accurately grasping the location of the user waiting for rescue. The fire and rescue system comprises a main body, a purification unit, a discharge unit, a face cover, a binding member, and a sensing means.

Description

A fire rescue system using 3D mapped rescue signals from an air purification device {A FIRE RESCUE SYSTEM THAT USES 3D MAPPING SIGNALS FROM AN AIR PURIFYING DEVICE TO DETECT AND LOCATE FIRES}

The present invention relates to a fire rescue system using a three-dimensional mapped rescue signal from an air purification device, and more particularly, to safely protect a user from toxic gases in the event of a fire, and when the life of the filter expires during use, the user can easily The filter can be replaced and the user's respiratory system can be continuously confidentially protected from external harmful substances and fine dust even while the filter is being replaced, and it is possible to detect whether the user is wearing the air purification device normally, and whether or not it is kept confidential. A fire rescue system that can determine whether or not and generate a notification so that the user can recognize it, thereby maximizing the effect of wearing it, and in addition, when a fire occurs, a fire rescue system that can accurately identify the location of a user waiting for rescue and rescue quickly. It is about.

As the population density in the city center continues, the skyscrapers of buildings such as apartments and high-rise buildings continue to occur.

For this reason, in the case of high-rise buildings, when a fire occurs, a lot of damage to property and serious human damage occurs.

This is because people located in the upper floors are not easy to evacuate to the ground because people are distributed up to the high number of floors due to the characteristics of high-rise buildings, and when a fire occurs, the fire rapidly spreads to the upper floors.

Therefore, in the event of a fire in a high-rise building, it is impossible to evacuate without the help of fire ladders or rescue equipment such as helicopters provided outside for fire suppression.

Therefore, the requestor finds a place where they can wait for the rescue relatively safely, moves quickly, provides accurate information on the requestor, and waits for the rescue as safely as possible until rescue. You are confronted with it.

However, conventionally, in a fire situation, it is very difficult for the requestor to inhale toxic gas while waiting for rescue and lose consciousness, or when confronted with a disaster situation, it is very difficult to provide accurate request information. Since it is impossible to determine the exact location of the requestor, there is a problem in that smooth life-saving activities cannot be performed when a fire occurs.

In addition, in the event of a fire, the requestor must wear a gas mask quickly in order not to inhale toxic gas, but in the event of a fire, it is recommended to quickly move to the place where the gas mask is installed, find and wear the gas mask, and evacuate to a safe place again. Since it is virtually impossible, it is also very difficult to be rescued safely in a fire situation.

Therefore, in the event of a fire, there is a demand for a technology capable of smooth lifesaving by preventing the requestor from inhaling toxic gas and accurately transmitting rescue request information including the requestor's location information to the rescuer.

On the other hand, the urgency of the golden time that determines life and death is required for the rescue of life at the fire site, and the rescue plan is decided at the fire site in response to the structure and use of the building and the fire situation.

However, in the past, it was unreasonable for rescuers to recognize the situation inside the fire building, and even if firefighters or first aid personnel arrived at the fire site, the number and location of the requestors in the fire zone could not be confirmed, thus responding to the fire situation. It is not always possible to determine an optimal fire suppression and lifesaving plan, which often leads to a missed golden time for lifesaving.

Accordingly, there is a need for a method of maximizing lifesaving by securing a golden time for making accurate decisions as well as extinguishing fires by providing status information of requesters to the outside when a fire occurs.

In addition, in some commercial facilities, fire detectors are sometimes turned off in order to prevent material damage caused by driving an emergency bell due to malfunctions such as sensors for fire detection.

If an actual fire occurs in such a state, the fire management system does not operate. Therefore, it is more difficult to quickly identify the situation of the fire and evacuate to the ground. Therefore, it is more difficult to protect the requestor from the toxic gas caused by the fire, and active rescue activities are carried out. There is a need for a technology to make it happen.

Korean Patent Application Publication No. 10-2013-0083224 (2013.07.22.)

The above-described conventional problems can be solved through the objects, configurations and effects proposed by the present invention, and the present invention devised for this purpose,

Its purpose is to provide a fire rescue system that can safely protect users from toxic gases in case of fire.

In addition, when the life of the filter is over during use, the user can easily replace the filter, and even while the filter is being replaced, a fire rescue system is provided that can continuously and confidentially protect the user's respiratory system from external harmful substances and fine dust. Has a purpose.

In addition, it provides a fire rescue system capable of maximizing the effect of wearing by detecting whether the user normally wears the air purification device, determining whether or not confidentiality is maintained, and generating a notification so that the user can recognize it. Has a purpose.

In addition, it is an object to provide a fire rescue system that can quickly rescue by accurately grasping the location of a user waiting for rescue in the event of a fire.

The present invention conceived to achieve the above object,

In the fire rescue system,

The main body 100 is configured such that a space part is formed therein, and the purification part 110 and the discharge part 120 are respectively airtightly partitioned through one or more vertical partition walls formed in the space part,

It is configured to penetrate the air in the longitudinal direction, and is configured to be able to insert the filter frame 130 in the transverse direction, and the external air introduced from the bottom by the user's inhalation passes through the filter frame 130 and is purified. At least one purification unit 110 comprising a filter frame 130 to be discharged toward the inner space of the face cover 200,

At least one discharge unit 120 configured to discharge the user's exhalation from the inner space of the face cover 200 to the bottom,

It is configured to be coupled to the upper outer periphery of at least one selected from the purification unit 110 and the discharge unit 120, and when worn on the user's face, the inner space sealed from the external air is formed at a position below the user's nose Face cover (200),

A binding member 300 configured to be worn on the user's neck,

A sensing means 400 included in the main body 100 and configured to generate a notification when an event occurs from the air purification device 10,

Measurement means 500 configured to acquire at least one or more information of the user's breathing status information, the user's heart rate information, ambient temperature information, and air pollution level information,

At least one air purification device (10) comprising a processing means (600) configured to transmit the information obtained from the measurement means (500) to at least one of the server (700) or the rescuer terminal (800). )Wow;

A server 700;

It characterized in that it comprises a rescuer terminal 800;

Therefore, through the present invention, it is possible to remarkably solve the conventional problems, and the present invention is also remarkable in the accompanying effects,

It can provide a fire rescue system that can safely protect users from toxic gases in case of fire.

In addition, when the life of the filter is reached during use, the user can easily replace the filter and provide a fire rescue system that allows the user's respiratory system to be continuously and confidentially protected from external harmful substances and fine dust even while the filter is being replaced. I can.

In addition, it provides a fire rescue system capable of maximizing the effect of wearing by detecting whether the user normally wears the air purification device, determining whether or not confidentiality is maintained, and generating a notification so that the user can recognize it. I can.

In addition, in the event of a fire, it is possible to provide a fire rescue system that can quickly rescue by accurately identifying the location of a user waiting for rescue.

1 to 2 are perspective views of the present invention according to an embodiment.
3 is a side view showing an example operation of the present invention according to an embodiment.
4 is a plan view of the present invention according to an embodiment.
5 to 6 are views showing an example of wearing the present invention according to an embodiment.
7 to 9 are diagrams showing examples of filter frame replacement according to an embodiment of the present invention, and are views illustrating an example of an operation when a user replaces the filter frame in section AA' of FIG.
10 to 11 are diagrams illustrating various configuration examples for replacing the filter frame of the present invention in a section taken along section AA' of FIG. 4.
12 to 16 are views showing examples of various detachable configurations of the filter frame and filter of the present invention.
17 is a diagram showing a configuration example of the present invention according to an embodiment.
18 is a block diagram showing a configuration example of an air purification device according to an embodiment of the present invention.
19 is a block diagram showing a configuration example of a sensing means of an air purification device according to an embodiment of the present invention.
Fig. 20 is a block diagram showing a configuration example of measuring means of the air purification device of the present invention according to an embodiment.
Fig. 21 is a block diagram showing a configuration example of processing means of the air purification device of the present invention according to an embodiment.
22 is a block diagram showing a configuration example of a server of the present invention according to an embodiment.
23 is a block diagram showing a configuration example of a rescuer terminal of the present invention according to an embodiment.

Hereinafter, since the present invention can apply various transformations and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail.

However, this is not intended to limit the present invention to a specific embodiment, it is to be understood to include all conversions, equivalents, and substitutes included in the spirit and scope of the present invention.

The present embodiments are provided to describe the present invention in more detail to those of ordinary skill in the art to which the present invention pertains. Therefore, the shape of each element shown in the drawings may be exaggerated to emphasize a more clear description, and in describing the present invention, when it is determined that a detailed description of a related known technology may obscure the gist of the present invention, the detailed description thereof Is omitted.

Terms such as first and second may be used to describe various components, but the components should not be limited by terms. The terms are only used for the purpose of distinguishing one component from another component.

The terms used in the present invention are used only to describe specific embodiments, and are not intended to limit the present invention, and expressions in the singular include plural expressions unless the context clearly indicates otherwise.

In the present invention, terms such as "comprises" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 to 6 and 17,

The present invention according to an embodiment,

In the fire rescue system,

The main body 100 is configured such that a space part is formed therein, and the purification part 110 and the discharge part 120 are respectively airtightly partitioned through one or more vertical partition walls formed in the space part,

It is configured to penetrate the air in the longitudinal direction, and is configured to be able to insert the filter frame 130 in the transverse direction, and the external air introduced from the bottom by the user's inhalation passes through the filter frame 130 and is purified. At least one purification unit 110 comprising a filter frame 130 to be discharged toward the inner space of the face cover 200,

At least one discharge unit 120 configured to discharge the user's exhalation from the inner space of the face cover 200 to the bottom,

It is configured to be coupled to the upper outer periphery of at least one selected from the purification unit 110 and the discharge unit 120, and when worn on the user's face, the inner space sealed from the external air is formed at a position below the user's nose Face cover (200),

A binding member 300 configured to be worn on the user's neck,

A sensing means 400 included in the main body 100 and configured to generate a notification when an event occurs from the air purification device 10,

Measurement means 500 configured to acquire at least one or more information of the user's breathing status information, the user's heart rate information, ambient temperature information, and air pollution level information,

At least one air purification device (10) comprising a processing means (600) configured to transmit the information obtained from the measurement means (500) to at least one of the server (700) or the rescuer terminal (800). )Wow,

Server 700,

It is configured to include a rescuer terminal 800.

Referring to Figure 20,

The measuring means 500,

A breathing information measuring unit 510 for acquiring user's breathing information,

A heart rate information measuring unit 520 for acquiring user's heart rate information.

It is configured to include at least one or more of the environmental information measuring unit 530 for acquiring ambient temperature information or air pollution level information around the user.

Referring to Figure 21,

The processing means 600,

A location information processing unit 610 that acquires GPS information,

) 건물에 층별로 m개 설치된 노드(

) 중 가장 근접한 노드를 통해 서버에 접속하고, 접속한 노드에 대하여 서버로부터 각각 층별, 노드별로 부여된 층별노드매트릭스정보(

)를 획득하는 1차맵핑처리부(620)와,k floor (

) M nodes installed per floor in the building (

), the server is connected to the server through the nearest node, and the node matrix information for each floor given by the server and each node for the connected node (

The primary mapping processing unit 620 to obtain ), and

) 합산하여 위치정보를 산출하고, 산출된 위치정보와 상기 측정수단(500)으로부터 측정된 정보 중 적어도 어느 하나 이상을 패킷정보를 생성하여 서버(700) 또는 구조자 단말기(800) 중 적어도 어느 하나 이상으로 송출하는 패킷생성처리부(630) 중 적어도 어느 하나 이상을 포함하여 구성된다.GPS information and node matrix information for each floor (

) Calculate location information by summing, and generate packet information from at least any one or more of the calculated location information and the information measured by the measurement means 500 to generate at least one of the server 700 or the rescuer terminal 800 It is configured to include at least one or more of the packet generation processing unit 630 transmitted to the.

Referring to Figure 22,

The server 700,

) 건물에 층별로 m개 설치된 노드(

)에 대하여 층별노드매트릭스정보(

)를 생성하고, 노드로부터 상기 공기 정화 디바이스(10)가 접속되면, 생성된 층별노드매트릭스정보(

)를 노드를 통해 상기 공기 정화 디바이스(10)로 송출하며, 상기 처리수단(600)의 상기 패킷생성처리부(630)로부터 송출된 패킷정보를 수신받는 패킷분석처리부(710)와,k floor (

) M nodes installed per floor in the building (

Information about the node matrix by floor (

), and when the air purification device 10 is connected from a node, the generated layer-by-floor node matrix information (

) To the air purification device 10 through a node and receiving packet information transmitted from the packet generation processing unit 630 of the processing means 600; and

A 3D mapping processing unit 720 for 3D mapping the location of the air purification device 10 worn by the user based on the packet information received by the packet analysis processing unit 710;

When a plurality of packet information is received from a plurality of air purification devices 10, the user's breathing information and heart rate information included in the packet information. A priority analysis unit 730 for generating structure priority information by analyzing the structure priority based on the ambient temperature information and air pollution level information around the user,

At least one of the analysis information processing units 740 receiving location information from the rescuer terminal 800, generating request group information by collating and analyzing the rescue priority information, and transmitting the generated request group information to the rescuer terminal. It consists of including.

23,

The rescuer terminal 800,

A location information transmission unit 810 for transmitting location information to the server 700,

When receiving request group information from the server 700 or packet information from the packet generation processing unit 630 of the air purification device 10, a structure information notification unit 830 that generates a structure information notification,

When receiving request group information from the server 700 or receiving packet information from the packet generation processing unit 630 of the air purification device 10, a structure information processing unit configured to check the location of a user who needs a rescue It is configured to include at least one or more of (820).

19,

At this time, the detection means 400 is configured to further include a notification unit 440 for generating a notification when an event occurs from the air purification device 10.

At this time, the sensing means 400 detects whether the main body 100 is properly worn by contacting the user's body, and controls the notification unit 440 to generate a notification according to whether or not the body is normally worn. It is configured to further include a wear sensing unit 410.

At this time, the detection means 400 detects the remaining life of the filter F, and when the life of the filter F reaches the replacement cycle, the notification unit 440 is controlled to control the filter F replacement cycle. It is configured to further include a filter state detection unit 410 for generating a notification upon arrival.

At this time, the detection means 400, after the body 100 is detected that the body 100 is normally worn in close contact with the user's body by the normal wear detection unit 430, the inside and outside of the air purification device 10 A comparison value is calculated by measuring the density of each, and the notification unit 440 is controlled through the calculated comparison value to generate a notification according to whether the inside of the air purification device 10 maintains airtightness from outside air. It is configured to further include a confidentiality detection unit 430.

At this time, the purification unit 110 is configured to further include a filter insertion unit 111 formed with an opening formed on the outside so that the filter frame 130 can be inserted from the outside to the inside,

When the filter frame 130 is inserted, the filter insertion portion 111 and the outer sidewall portion of the filter frame 130 are airtightly contacted and fitted together.

At this time, the filter frame 130 is provided in at least two or more,

In this case, the purification unit 110 is configured such that at least two or more of the filter frames 130 can be airtightly stacked on the inside of the purification unit 110.

At this time, at the side of the filter frame 130, when the filter frame 130 is inserted into the filter insertion part 111, a downward removal induction part 131 for inducing the previously inserted filter frame 130 to descend is provided. It is configured to include more.

In this case, the purifying unit 110 has an opening formed in the lower part so that the filter frame 130 lowered by the downward stripping guide unit 131 is removed from the purifying unit 110 and discharged to the outside.

In this case, the filter frame 130 is configured to further include a filter (F) configured to be detachable and replaceable from the filter frame 130.

At this time, the filter (F) is composed of at least one of a dust filter and a gas filter.

At this time, the periphery of the face cover 200, when the face cover 200 is worn on the user's face, further includes a contact portion 210 for enhancing adhesion with the user's face so that external air does not flow into the inside. It is composed by

At this time, the inner surface of the face cover 200, the face cover 200 is configured to further include an auxiliary contact portion 220 configured to have a multiple contact structure in order to increase the adhesion to the user's face,

The auxiliary contact part 220 is configured to form an inverted'Y' shape together with the contact part 210.

The body has a space portion formed therein.

The main body is configured such that the purification unit 110 and the discharge unit 120 are each hermetically partitioned through at least one vertical partition formed in the space of the main body.

The purification unit 110 is configured to allow air to penetrate in the longitudinal direction.

The purification unit 110 is configured to be able to insert the filter frame 130 in the transverse direction.

At this time, the purification unit 110 is configured to further include a filter insertion unit 111 having an opening formed on the outside so that the filter frame 130 can be transversely inserted from the outside to the inside.

The purification unit 110 is configured such that external air introduced from the bottom by the user's inhalation passes through the filter frame 130 and is purified and then discharged toward the inner space of the upper face cover 200.

The purification unit 110 is configured to include a filter frame 130.

The purification unit 110 is composed of at least one or more.

In this case, the purifying unit 110 has an opening formed in the lower part so that the filter frame 130 lowered by the downward stripping induction unit 131 is removed from the purifying unit 110 and discharged from the bottom.

At this time, the purification unit 110 is configured such that when the filter frame 130 is inserted, the filter insertion unit 111 and the outer sidewall portion of the filter frame 130 are in tight contact with each other and are fitted.

In this case, the purification unit 110 may be configured to be airtightly stacked on the inside of two or more filter frames 130.

7 to 9,

In this case, the purification unit 110 may further include a removal guide part 112 guiding downward removal of the filter frame 130.

In this case, the purification unit 110 may be configured to accommodate a single filter frame 130 therein, or may be configured to accommodate two or more filter frames 130 therein.

At this time, the filter frame 130 inserted into the purifying unit 110 is fitted and fixed inside the purifying unit 110, and then, as shown in FIGS. 7 to 8, the user selects the new filter frame 130. When it is pushed back into the filter insertion part 111, the previously inserted filter frame 130 moves downward under the guidance of the removal guide part 112, and a new filter frame 130 is inserted into the filter frame 130. It is stacked on top of ).

At this time, when the purification unit 110 is configured to accommodate the single filter frame 130 therein, the previously inserted filter frame 130 is dropped to the bottom of the purification unit 110 and removed, and a newly inserted filter Only the frame 130 remains.

In addition, when the purification unit 110 is configured to accommodate two or more filter frames 130 therein, the previously inserted filter frame 130 moves downward, and the new filter frame 130 is previously inserted. It is stacked on the upper portion of the frame 130, and when the acceptance value of the filter frame 130 of the purification unit 110 is exceeded while repeating this operation, the filter frame 130 stacked on the lowermost end of the purification unit 110 It falls to the bottom and is removed.

Referring to Figure 10,

In this case, the inside of the purification unit 110 may further include a separation preventing member 113 that prevents the filter frame 130 from indiscriminately falling downward.

At this time, the separation preventing member 113 is configured by coupling an elastic portion 114 to one side, and may be configured to be elastically drawn in and protruded from the inside of the purification portion 110 by the elastic portion 114 have.

At this time, the inside of the purification unit 110, the elastic portion 114 and the separation prevention member 113 may be configured to further include a recessed inlet 115 formed so as to be completely retractable.

Therefore, when the filter frame 130 is not dropped and removed by the separation preventing member 113 to the lower portion of the purification unit 110, and the separation preventing member 113 is inserted into the inlet 115 Only the filter frame 130 can move downward.

11,

At this time, a "L"-shaped rotating support 116 may be coupled to one side of the purification part 110 adjacent to the filter insertion part 111.

In this case, the pivoting support 116 may be configured to be hingedly coupled to the purification unit 110 by a pivoting member 118, and may be configured to pivot the pivoting member 118.

At this time, a locking protrusion 117 is formed at a lower side of the pivoting support 116, and the locking protrusion is configured to pass through the purification unit 110 and to be inserted into the inner side, thereby supporting the filter frame 130. Can be configured.

In this case, the upper portion of the pivoting support 116 may be configured to protrude toward the filter insertion part 111 to a predetermined height.

Therefore, when the filter frame 130 is inserted into the filter insertion part 111, the upper part of the rotating support 116 is pushed together with the filter, and accordingly, the locking protrusion 117 is formed in the purification part 110 ), the previously inserted filter frame 130 is able to move downward.

10 to 11,

At this time, an airtight member coupling portion 150 for coupling the airtight member 160 may be formed at one side of the purification unit 110.

In this case, an airtight member 160 configured to be coupled to the airtight member coupling portion 150 may be configured.

At this time, the airtight member coupling portion 150 is formed on a contact surface in contact with the user's neck, so that when the user wears the air purification device 10, the body and the user's neck may be in close contact.

The discharge unit 120 is configured to discharge the user's exhalation from the inner space of the face cover 200 to the bottom.

At this time, referring to the invention filed by the present applicant on June 26, 2019 (registered patent publication No. 10-2036025, hereinafter referred to as a prior invention),

In this case, the discharge unit 120 may be configured by referring to the configuration of the second space unit disclosed in the prior invention.

In this case, the second space may be configured to include an external air inflow blocking part.

In this case, the second space portion is configured to include a plurality of second air inlet holes formed in the body portion above the second space portion so that air discharged from the human body by exhalation may be introduced into the second space portion. I can.

At this time, the second space portion, a plurality of formed in the body portion under the second space portion so that the air discharged from the human body by the exhalation introduced into the second space portion is discharged from the second space portion to the outside. It may be configured to include a second air outlet hole.

At this time, the external air inlet blocking portion divides the second space into two regions, and is formed under the partition plate in which the air inlet hole is formed in the center and the partition plate in the position where the air inlet hole is formed, and is initially closed. It may be configured to include an opening/closing membrane that opens with pressure by exhalation to open the air inlet hole.

1 to 3,

At this time, the filter frame 130 is configured to be inserted into the filter insertion part 111 of the purification part 110.

At this time, at the side of the filter frame 130, when the filter frame 130 is inserted into the filter insertion part 111, a downward removal induction part 131 for inducing the previously inserted filter frame 130 to descend is provided. It is configured to include more.

In this case, the filter frame 130 is configured to further include a filter (F) configured to be detachable and replaceable from the filter frame 130.

At this time, the filter frame 130 is provided in at least two or more.

At this time, the filter (F) is composed of at least one of a dust filter and a gas filter.

In this case, the filter frame 130 may be composed of a plurality, and each filter frame composed of a plurality of filters (F) composed of a dust filter or a gas filter is configured, so that the user is suitable according to the situation. It may be configured to selectively use the filter (F).

In this case, the downward departure induction part 131 may be configured to have at least one inclined surface.

12 to 16,

At this time, the filter frame 130 may be configured to be replaceable by detaching the filter (F).

In this case, when the filter frame 130 is coupled to the purification unit 110, the upper and lower portions may be opened so that the air penetrates in the longitudinal direction.

12,

The filter frame 130 of the present invention according to an embodiment may further include a stepped portion 132.

Therefore, as shown in FIG. 12, one side of the filter frame 130 is configured in an open shape, so that the filter F can be inserted or separated from the opened side, and the filter F is It may be configured to be locked and fixed by the stepped portion 132.

13,

At this time, the filter frame 130 of the present invention according to an embodiment may be configured to insert or remove the filter F from the opened top, and the filter F is at the center of the filter frame 130. It may be configured to be fitted.

14,

In this case, the filter frame 130 of the present invention according to an exemplary embodiment may be configured to insert or detach the filter frame 130 into the inside of the filter F configured to have only one side open.

15,

At this time, the filter frame 130 of the present invention according to an embodiment is configured to form a pair by being cut in a transverse direction and divided into an upper frame and a lower frame, and the upper frame and the lower frame are configured to be combined and separated vertically. It is configured in a fitting groove 133 in any one of a pair of frames, and a fitting protrusion 134 may be configured on a contact surface at a position corresponding to the fitting groove 133 of the other frame. By combining and separating the upper frame and the lower frame with the filter F disposed between the frame and the lower frame, the filter F may be combined or separated.

16,

At this time, the filter frame 130 of the present invention according to an embodiment is configured to include a hinge 135 at one end, and is configured to be cut in the transverse direction so as to be unfolded and folded by the hinge, and the filter at the top It may be configured to couple or separate the filter (F) by folding operation by the hinge 135 in the state where (F) is disposed.

Referring to Figure 1,

At this time, the face cover storage unit 140 is configured on an upper portion of at least one of the purification unit 110 and the discharge unit 120 and is configured to receive and store the face cover 200.

The face cover 200 is configured to be coupled to an upper outer periphery of at least one selected from among the purification unit 110 and the discharge unit 120.

The face cover 200 is configured such that when worn on the user's face, an internal space sealed from external air is formed at a position below the user's nose.

At this time, the periphery of the face cover 200, when the face cover 200 is worn on the user's face, further includes a contact portion 210 for enhancing adhesion with the user's face so that external air does not flow into the inside. It is composed by

At this time, the inner surface of the face cover 200 is configured to further include an auxiliary contact portion 220 configured to have a multiple contact structure in order to increase the adhesion of the face cover 200 to the user's face.

At this time, the auxiliary contact portion 220 is configured to form an inverted'Y' shape together with the contact portion 210.

The binding member 300 is configured to be worn on the user's neck.

Therefore, the present invention,

It can provide a fire rescue system that can safely protect users from toxic gases in case of fire.

In addition, when the life of the filter is reached during use, the user can easily replace the filter and provide a fire rescue system that allows the user's respiratory system to be continuously and confidentially protected from external harmful substances and fine dust even while the filter is being replaced. I can.

In addition, it provides a fire rescue system capable of maximizing the effect of wearing by detecting whether the user normally wears the air purification device, determining whether or not confidentiality is maintained, and generating a notification so that the user can recognize it. I can.

In addition, in the event of a fire, it is possible to provide a fire rescue system that can quickly rescue by accurately identifying the location of a user waiting for rescue.

In the above, the present invention has been described based on what is shown in the drawings, but this is only illustrative, and various substitutions, modifications, and changes are possible within the scope of the technical spirit of the present invention, so limited to the above-described embodiments and drawings. It does not become.

100: main body
110: purification unit
111: filter insertion part 112: removal guide part
113: separation preventing member 114: elastic portion
115: inlet 116: rotating support
117: stopping protrusion 118: rotating member
120: discharge unit
130: filter frame
131: downward departure induction part 132: step part
133: fitting groove 134: fitting protrusion
135: hinge
140: face cover storage unit
150: airtight member coupling part
160: airtight member
200: face cover
210: contact portion 220: auxiliary contact portion
300: binding member
400: detection means
410: normal wear detection unit 420: filter condition detection unit
430: confidentiality detection unit 440: notification unit
500: measuring means
510: respiration information measurement unit 520: heart rate information measurement unit
530: Environmental Information Measurement Department
600: treatment means
610: location information processing unit 620: primary mapping processing unit
630: packet generation processing unit
700: server
710: packet analysis processing unit 720: 3D mapping processing unit
730: priority analysis unit 740: analysis information processing unit
800: rescuer terminal
810: location information transmission unit 820: structure information processing unit
830: Structure information notification unit
F: filter

Claims (5)

In the fire rescue system,
The main body 100 is configured such that a space part is formed therein, and the purification part 110 and the discharge part 120 are respectively airtightly partitioned through one or more vertical partition walls formed in the space part,
It is configured to penetrate the air in the longitudinal direction, and is configured to be able to insert the filter frame 130 in the transverse direction, and the external air introduced from the bottom by the user's inhalation passes through the filter frame 130 and is purified. At least one purification unit 110 comprising a filter frame 130 to be discharged toward the inner space of the face cover 200,
At least one discharge unit 120 configured to discharge the user's exhalation from the inner space of the face cover 200 to the bottom,
It is configured to be coupled to the upper outer periphery of at least one selected from the purification unit 110 and the discharge unit 120, and when worn on the user's face, the inner space sealed from the external air is formed at a position below the user's nose Face cover (200),
A binding member 300 configured to be worn on the user's neck,
A sensing means 400 included in the main body 100 and configured to generate a notification when an event occurs from the air purification device 10,
Measurement means 500 configured to acquire at least one or more information of the user's breathing status information, the user's heart rate information, ambient temperature information, and air pollution level information,
At least one air purification device (10) comprising a processing means (600) configured to transmit the information obtained from the measurement means (500) to at least one of the server (700) or the rescuer terminal (800). )Wow;
A server 700;
Rescuer terminal 800; is configured to include,
The server 700,
k floor (

) M nodes installed per floor in the building (

Information about the node matrix by floor (

), and when the air purification device 10 is connected from a node, the generated layer-by-floor node matrix information (

) To the air purification device 10 through a node, and receiving packet information transmitted from the packet generation processing unit 630 of the processing means 600;
A 3D mapping processing unit 720 for 3D mapping the location of the air purification device 10 worn by the user based on the packet information received by the packet analysis processing unit 710;
When a plurality of packet information is received from a plurality of air purification devices 10, the user's breathing information and heart rate information included in the packet information. A priority analysis unit 730 for generating structure priority information by analyzing the structure priority based on the ambient temperature information and air pollution level information around the user,
At least one of the analysis information processing units 740 receiving location information from the rescuer terminal 800, generating request group information by collating and analyzing the rescue priority information, and transmitting the generated request group information to the rescuer terminal. A fire rescue system using a three-dimensional mapped rescue signal from an air purification device, comprising:
The method of claim 1,
The measuring means 500,
A breathing information measuring unit 510 for acquiring the user's breathing information,
A heart rate information measuring unit 520 for acquiring user's heart rate information.
A fire rescue system using a three-dimensional mapped rescue signal from an air purification device, comprising at least one or more of an environmental information measuring unit 530 that acquires ambient temperature information or air pollution level information around a user.
The method of claim 2,
The processing means 600,
A location information processing unit 610 that acquires GPS information,
k floor (

) M nodes installed per floor in the building (

), the server is connected to the server through the nearest node, and the node matrix information for each floor given by the server and each node for the connected node (

The primary mapping processing unit 620 to obtain ), and
GPS information and node matrix information for each floor (

) Calculate location information by summing, and generate packet information from at least any one or more of the calculated location information and the information measured by the measurement means 500 to generate at least one of the server 700 or the rescuer terminal 800 A fire rescue system using a three-dimensional mapped rescue signal from an air purification device, characterized in that it comprises at least one or more of the packet generation processing unit 630 transmitted to the air.
delete The method of claim 1,
The rescuer terminal 800,
A location information transmission unit 810 for transmitting location information to the server 700,
When receiving request group information from the server 700 or packet information from the packet generation processing unit 630 of the air purification device 10, a structure information notification unit 830 that generates a structure information notification,
When receiving request group information from the server 700 or receiving packet information from the packet generation processing unit 630 of the air purification device 10, a structure information processing unit configured to check the location of a user who needs a rescue A fire rescue system using a three-dimensional mapped rescue signal from an air purification device, comprising at least one or more of (820).

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