KR20210029922A - Real-time laboratory monitoring system - Google Patents

Abstract

The present invention relates to a real-time laboratory monitoring system, which can quickly respond to an emergency situation such as a fire in a laboratory, and provide information to researchers about an emergency situation quickly. More specifically, the real-time laboratoy monitoring system includes: a plurality of sensors which sense whether the fire has occurred in the laboratory; and a control server which is connected to a sensor unit by a wired/wireless communication network, which controls firefighting facilities in response to a fire occurring in the laboratory, and which transmits the laboratory situation to a mobile terminal of a researcher (C-P) in real time, wherein the sensor unit includes: a gas sensor which senses smoke caused by the fire by scattering light, but allows firefighting water to be discharged through a control signal from a control unit depending on the sensing of the smoke; a temperature and humidity sensor which senses changes in the temperature and humidity in the laboratory and transmits sensing information to the control unit; and a camera which allows image information photographed inside and outside the laboratory to be transmitted to the control server through the control unit.

Description

Real-time laboratory monitoring system

The present invention relates to a real-time laboratory monitoring system capable of promptly responding to an emergency situation such as a fire in a laboratory and quickly providing information to a researcher about the emergency situation.

In general, since the conventional safety management system has a configuration for preventing one specific accident, it is not suitable for a space where various accidents may occur, such as in a laboratory.

That is, since the conventional safety management system has a configuration capable of identifying a specific accident and responding quickly to it, like the conventional fire management system shown in FIG. 1, it is possible to efficiently cope with a specific accident. However, when applied to a space where various accidents such as fire accidents, toxic substance leakage accidents, and theft accidents can occur, such as in a laboratory, there is a problem that the effectiveness is poor.

In other words, when the conventional safety management system is applied to the laboratory, for safety management such as fire accident, toxic substance leakage accident, and theft accident, there are multiple fire management systems, toxic substances safety management system, and theft accident safety management system. Since dog safety management systems must be individually installed and managed in the laboratory, the system system becomes complicated and difficult to manage, and the installation cost of the system is also largely consumed. Currently, most schools have simply introduced fire management systems. , As such a fire management system cannot prevent or cope with hazardous substance leakage accidents such as formalin leakage accidents that occurred in Pohang on December 15, 2017, and laboratory explosion accidents that are difficult to determine the cause, the laboratory can manage safety more efficiently. There is a need for a new laboratory safety management system that can be used.

Korean Patent Publication No. 10-2019-68995 (Publication date: 2019.06.19.) Korean Patent Publication No. 10-2010-9348 (Publication date: 2010.01.27.)

In order to solve the above-described conventional problem, an object of the present invention is to provide a system capable of quickly responding to a fire in a laboratory, but transmitting the situation in real time to a researcher who is involved in the laboratory.

In order to solve the above technical problem, the real-time laboratory monitoring system according to the present invention is connected to a plurality of sensor units for detecting whether or not a fire occurs in the laboratory, and the sensor unit and the wired/wireless communication network. And a control server that transmits the situation of the laboratory to the researcher's mobile terminal in real time, wherein the sensor unit detects smoke caused by a fire by scattering light, but through a control signal of the control unit according to whether or not it is detected. A gas detection sensor that enables fire prevention water to be discharged, a temperature/humidity sensor that senses temperature and humidity changes in the laboratory and transmits the detection information to the control unit, and image information photographed inside and outside the laboratory through the control unit. It characterized in that it comprises a camera to be transmitted to the control server.

In addition, the gas detection sensor is connected to a smoke inflow body in which smoke from a fire is introduced and the temperature and humidity detection sensor is installed, a light emitting device that irradiates lighting by a control signal from the control unit, and the control unit to be irradiated from the light emitting device. A smoke detection unit including a light-receiving element that detects whether or not a fire is detected depending on whether or not lighting is received, the lower part is detachably coupled to the upper part of the smoke inflow body, but the discharge body having a supply path inside, and a stopper for opening and closing the supply path And a lower part is inserted into the discharge body, and the upper part is inserted into the stopper and is damaged according to the degree of heat caused by a fire to separate the stopper so that the supply path can be opened. It is connected to the discharge body to communicate with the discharge body, but the upper part is connected to the fire prevention pipe, and is opened and closed through a control signal of the control unit according to the presence or absence of the detection information of the smoke detection unit so that the fire water in the fire prevention pipe can be supplied to the supply path. It is preferable to include a solenoid valve.

In addition, the smoke inflow body includes an extension plate that can be installed so that the temperature and humidity sensor does not interfere with the discharge of fire extinguishing water, the temperature and humidity sensor is detachably installed under the extension plate, but the end of the extension plate is lengthwise It is preferable that a blocking plate protruding downward along the direction is further formed to prevent the temperature/humidity sensor installed under the extension plate from directly contacting fire water by the blocking plate.

In addition, it is preferable that the control server allow the researcher to check the situation of the laboratory checked through the sensor unit with the mobile terminal through an application provided by the control server so that the researcher can check the situation of the laboratory through the mobile terminal of the researcher.

According to the present invention, differently from the prior art, it has the effect of promptly responding to a fire in a laboratory through a sensor unit, but transmitting the situation to a mobile terminal possessed by a researcher involved in the laboratory in real time through a control server. .

1 is a block diagram showing a conventional safety management system.
2 is a conceptual diagram of a real-time laboratory monitoring system according to the present invention.
Figure 3 is a block diagram of Figure 2;
4 and 5 are views showing a gas detection sensor and a temperature and humidity detection sensor for a real-time laboratory monitoring system according to the present invention.
6 is a view showing the inside of the smoke detection unit for the real-time laboratory monitoring system according to the present invention.
7 is an operational relationship diagram showing the direction of discharge of fire extinguishing water with respect to FIG. 4.

Hereinafter, other objects and features of the present invention in addition to the above objects will be clearly revealed through the description of the embodiments with reference to the accompanying drawings, and unless otherwise defined, all terms used herein including technical or scientific terms are the present invention. It has the same meaning as commonly understood by those of ordinary skill in the art to which the invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in the present application. Does not.

Hereinafter, a real-time laboratory monitoring system according to the present invention (hereinafter, simply referred to as a'monitoring system') according to the present invention will be described in detail with reference to the accompanying drawings.

First, as shown in FIGS. 2 and 3, the monitoring system 1 according to the present invention largely includes a plurality of sensor units 10, a control server 60, and a control server 70.

When described in more detail with reference to FIGS. 4 to 7, a plurality of the sensor units 10 are installed in the laboratory (L), and the air pollution degree, temperature change, humidity change, and the inside of the laboratory (L) It is a configuration for providing the external image information, etc., to the control server 70 managed by the administrator or the researcher's mobile terminal (CP), which will be described later, and is a gas sensor 11, a temperature and humidity sensor 40, and a camera ( 50).

When a fire occurs in the laboratory (L), the gas detection sensor 11 senses the smoke caused by the fire and at the same time extinguishes the fire. Solenoid valve 12, fire prevention water discharge member 13, smoke detection It includes a unit 20 and a control unit 30.

As shown, the solenoid valve 12 refers to a valve that can be opened and closed through a control signal from the control unit 30, and is connected to a fire prevention pipe (FW) provided in the ceiling of the laboratory (L), so that the control unit 30 ) So that the fire prevention water supplied to the fire prevention pipe (FW) can be discharged to the laboratory (L).

The solenoid valve 12 has a structure that is embedded in the ceiling of the laboratory (L) in consideration of the aesthetics, and the lower part of the solenoid valve 12 is connected to the discharge body 14, which is a component of the fire prevention water discharge member 13, so that the solenoid valve 12 is It has a structure in which fireproof water can be discharged into the laboratory L through the supply path 16 formed in the discharge body 14 when opened.

A number of solenoid valves 12 may be installed on the ceiling depending on the area of the laboratory (L), and if necessary, a conventional sprinkler head directly connected to a fire prevention pipe (FW) in addition to the gas detection sensor 11 in the present invention. Although (not shown) may be installed separately, it is possible to maximize the effect of fire detection and fire suppression for the detection by preferably installing a general sprinkler head and a smoke detection sensor integrally formed.

The fire extinguishing water discharge member 13 is discharged to the area where the fire occurred in the laboratory (L) by the heat caused by the fire while the solenoid valve 12 described above is open. It includes a discharge body 14, a stopper 17, and a support glass 18 in a configuration to be able to.

The discharge body 14 has an upper part connected to the lower part of the solenoid valve 12 and the lower part is screwed detachably with the smoke detection part 20 to be described later.

On the upper cross section of the discharge body 14 connected to the solenoid valve 12, a supply path 16 through which the fire extinguishing water of the fire extinguishing pipe (FW) can move due to the opening of the solenoid valve 12 is formed in the longitudinal direction, The supply path 16 is maintained in a closed state by the stopper 17, but when the support glass 18 is damaged by heat due to fire, the stopper 17 is separated from the supply path 16 and the supply path (16) has a structure in which fireproof water can be discharged into the laboratory (L) by opening it.

At this time, the fire extinguishing water discharged at a predetermined discharge pressure through the supply path 16 is hit by the upper surface of the smoke inlet 21 or the assembly 15, and is radially centered on the smoke inlet 21 by the impact. It spreads in a circle so that the fire can be quickly extinguished, and for this purpose, it is preferable that a plurality of discharge holes are formed on the outer surface of the discharge body 14.

In addition, in the present invention, a plurality of discharge holes formed in the discharge body 14 may be formed on the side of the support glass 18.

The stopper 17 is inserted into the output end of the supply channel 16 and is supported by being inserted into the upper end of the support glass 18 formed in a column shape so that the supply channel 16 can be closed by the support of the support glass 18. do.

When the pressure of the fire extinguishing water is directly transmitted through the supply path 16 due to the opening of the solenoid valve 12 at the same time as the temperature of the stopper 17 is increased due to the heat from the fire, the support glass 18 is damaged. It is separated (detached) from the supply path 16 by means of which fire extinguishing water can be discharged.

The support glass 18 is made of a glass material having a length in the vertical direction as a whole, but there is a heat-sensitive body 19, that is, the support glass 18 can be damaged by the expansion force by expanding by the external temperature. The heat-sensitive material 19 in the form of a liquid such as alcohol is injected.

The heat-sensitive body 19 expands so that the support glass 18 can be damaged when heat caused by a fire directly affects its outer surface, and the stopper 17 supported by the breakage is transferred to the supply path 16 It is separated from and allows the fire protection water to be discharged, and for this purpose, the lower portion of the support glass 18 has a structure that can be inserted and supported in the assembly 15.

In addition, the smoke detection unit 20 is configured to detect the smoke by the dispersion of light and transmit it to the control unit 30 when smoke due to a fire occurs. (25) and a light receiving element (26).

The smoke inflow body 21 is formed in the shape of a hollow enclosure as a whole, but a plurality of through holes 22 are perforated to communicate with the inside so that smoke lighter than air can be easily introduced and discharged when a fire occurs. A thread capable of being screwed with the above-described fire prevention water discharge member 13 is formed.

The light-emitting element 25 is provided on one side inside the smoke inlet 21, and irradiates lighting (light) to the inner center of the smoke inlet 21 by a battery (not shown), which is not shown, and the smoke inlet ( 21) to be able to detect the smoke that has flowed into it.

The light-receiving element 26 is installed on the other side of the smoke inflow body 21 so as not to face each other or to face each other, and when the light irradiated from the light-emitting element 25 causes a scattering effect by smoke, the scattering A light is sensed to detect that smoke has been introduced, and the detection information is transmitted to the control unit 30.

To this end, the light-receiving element 26 has a state in which it is electrically connected to the control unit 30 and is supplied with power by a battery to operate.

At this time, the control unit 30 is connected to the control server 60 by a wired/wireless communication network to transmit the detection information to the control server when smoke is detected through the smoke detection unit 20 as well as whether the solenoid valve 12 is operated or not. It is desirable to be able to determine whether a fire has occurred in (70).

The temperature/humidity sensor 40 outputs a current in proportion to the temperature and humidity measured in the laboratory L, and then transmits the output current to the control server 60 through the control server 60. It converts into a digital signal that can be transmitted with 70).

The temperature-humidity sensor 40 is installed on the wall of the laboratory (L) or experimental equipment (not shown), etc. to detect the changing temperature and humidity in the laboratory (L) to check whether there is a fire.

On the other hand, the temperature and humidity sensor 40, as shown, can be installed under the extension plate 23 that is detachably provided on the outer surface of the smoke inlet 21, the end of the extension plate 23 downward in the longitudinal direction. The blocking plate 24 that protrudes is further formed so that the temperature-humidity sensor 40 provided under the extension plate 23 has the advantage that it can be used continuously without interfering with the discharged fireproof water.

The camera 50 photographs the inside or outside of the laboratory (L), but transmits the photographed image information to the control server 60, and is controlled by the control server 70 connected to the control server 60 by a wired or wireless communication network. Make the video information available to the manager or researcher.

In particular, the camera 50 in the present invention may use a thermal imaging camera, and a number of the thermal imaging cameras are installed inside the laboratory (L) to detect heat through the captured image to generate a fire in the control server 70 Allows you to judge whether or not.

And the control server 70 is connected through the above-described control server 60 and a wired/wireless communication network (eg, CDMA, WCDMA and GSM modem), as shown in Figs. 2 and 3, in the laboratory (L). When an emergency situation occurs due to a fire, it is transmitted through a mobile terminal (CP) possessed by the researcher to enable rapid response.

The control server 70 checks the presence or absence of an abnormality in the laboratory L through a monitoring PC controlled by the administrator, and the monitoring PC is used as a means to check the image information photographed by the above-described camera 50 in real time. .

The control server 70 provides an application (APP) that can be installed on a mobile terminal (CP) possessed by the researcher to transmit the presence or absence of an abnormality in the laboratory (L) to the researcher, and the information transmitted to the app is the above-described sensor. Provides information on the operation of the unit 10.

In addition, the control server 70 is a firefighting facility (FP) such as an exhaust means or a firewall for exhausting the smoke inside the laboratory (L) according to the progress of the fire generated in the laboratory (L), as well as an external organization server such as a fire station. By sending (80) that an emergency situation has occurred, it is possible to quickly respond to the fire.

The monitoring system 1 according to the present invention having such a configuration is differentiated from the prior art, and responds quickly through the sensor unit 10 to the fire in the laboratory (L), but the situation is controlled through the control server 70. It has the effect of being able to transmit in real time to a mobile terminal (CP) possessed by a researcher related to the laboratory (L).

As described above, in the present invention, specific matters such as specific components, etc., and limited embodiments and drawings have been described, but this is provided only to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , If a person of ordinary skill in the field to which the present invention belongs, various modifications and variations are possible from these descriptions.

Therefore, the spirit of the present invention is limited to the described embodiments and should not be defined, and all those having variations equivalent or equivalent to the claims, as well as the claims to be described later, will be said to belong to the scope of the spirit of the present invention. .

1: Real-time laboratory monitoring system according to the present invention
10: sensor unit
11: gas detection sensor 12: solenoid valve
13: fire prevention water discharge member 14: discharge body
15: assembly 16: supply path
17: stopper 18: support glass
19: thermal element
20: smoke detection unit
21: smoke influx 22: through hole
23: extension plate 24: blocking plate
25: light-emitting element 26: light-receiving element
30: control unit
40: temperature and humidity sensor
50: camera
60: control server
70: control server

Claims (4)

A plurality of sensor units 10 for detecting whether or not a fire occurs in the laboratory (L); And
The sensor unit 10 is connected to the wired/wireless communication network, and controls the firefighting facility (FP) in response to the fire generated in the laboratory (L), and the situation of the laboratory (L) is monitored in real time by the researcher's mobile terminal (CP). Including; control server 70 to transmit to,
The sensor unit 10 is
Gas detection sensor 11 that detects smoke caused by fire by scattering light, but allows fire extinguishing water to be discharged through a control signal of the control unit 30 according to whether or not it is detected, temperature and humidity changes in the laboratory (L) The temperature and humidity sensor 40 that senses and transmits the detection information to the control unit 30 and image information photographed inside and outside the laboratory (L) are transferred to the control server 70 through the control unit 30. Real-time laboratory monitoring system, characterized in that it comprises a camera (50) that allows it to be transmitted.
The method of claim 1,
The gas detection sensor 11
The smoke from the fire is introduced into the smoke inlet 21 to which the temperature and humidity sensor 40 is installed, the light emitting element 25 and the control unit 30 for irradiating lighting by a control signal of the control unit 30, and A smoke detection unit 20 including a light-receiving element 26 that is connected to the light-emitting element 25 and detects whether or not a fire is received depending on whether or not the light emitted from the light-emitting element 25 is received;
The lower part is detachably coupled to the upper part of the smoke inlet 21, but the discharge body 14 having a supply passage 16 formed therein, a stopper 17 for opening and closing the supply passage 16, and the lower part of the discharge body A fire prevention water discharge member provided to be inserted and supported in (14), but the upper part is inserted into the stopper (17) and is damaged according to the degree of heat caused by fire to separate the stopper (17) to open the supply passage (16) (13); And
The lower part is connected to the discharge body 14 so that the lower part is in communication with the supply path 16, and the upper part is connected to the fire prevention pipe (FW), so that the control part 30 A real-time laboratory monitoring system comprising: a solenoid valve (12) that is opened and closed through a control signal of the fire prevention pipe (FW) so that the fire water in the fire prevention pipe (FW) can be supplied to the supply path (16).
The method of claim 2,
The smoke inflow body 21 includes an extension plate 23 that can be installed so that the temperature and humidity sensor 40 does not interfere with the discharge of fire water.
The temperature/humidity sensor 40 is detachably installed under the extension plate 23, and the end of the extension plate 23 is further formed with a blocking plate 24 protruding downward along the length direction. 23) A real-time laboratory monitoring system, characterized in that the temperature-humidity sensor (40) installed at the lower part is prevented from directly contacting fire water by the barrier plate (24).
The method of claim 1,
The control server 70 is
The mobile terminal (CP) through an application provided by the control server 70 by the researcher so that the situation of the laboratory (L) checked through the sensor unit 10 can be confirmed through the researcher's mobile terminal (CP). ) Real-time laboratory monitoring system, characterized in that to be confirmed.

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