KR102168651B1 - Body temperature measuring device with thermal sensor and monitoring system therewith - Google Patents

Abstract

The present invention relates to a body temperature measuring device with a heat-detection sensor and a heat-detection monitoring system using the same. The number of people is counted and a person with a high fever is detected by using a body temperature measuring device consisting of inexpensive heat-detection sensors without using an expensive thermal imaging camera to reduce purchase and operating costs to reduce an economic burden of a manager or a company. In an unexpected situation where a person with a high fever among visitors and occupants exits, unexpected information including unexpected content, time, location, and body temperature (T) information of the person with a high fever is outputted to a manager terminal to allow the manager to immediately deal with the unexpected situation to minimize damage spread and maximize heat radiation efficiency.

Description

Body temperature measuring device with thermal sensor and monitoring system therewith, and body temperature measuring device with thermal sensor and monitoring system using the same

The present invention relates to a body temperature measuring device equipped with a heat-sensing sensor, and a heat-sensing monitoring system using the same, and in detail, a predetermined management target (D) using a body temperature measuring device consisting of low-cost heat-sensing sensors. By counting the number of people entering and exiting the site and the number of occupants in the management area, and real-time detection of the high-heater among accessors and occupants, installation and operation costs are reduced, and the current real-time status can be viewed and monitored through the administrator terminal. , In case of occurrence of a high fever, a body temperature measuring device having a heat-sensing sensor capable of quick follow-up measures, and a heat-sensing monitoring system using the same.

Recently, Corona 19, Middle East Respiratory Syndrome (Mers), Severe Acute Respiratory Syndrome (SARS), and avian influenza (AI) are transmitted through humans or livestock. As infectious diseases appear variously, various studies on quarantine systems to prevent the spread of infectious diseases are being conducted.

These infectious diseases are manifested in various ways depending on the type, but since it causes high fever as the most common infection symptom, thermal imaging cameras are installed at the entrances of places such as airports, buildings, government offices, hospitals, etc. The introduction of a method of separately detecting a high fever among those entering through the thermal image obtained by the method is increasing.

However, since such thermal imaging cameras are expensive, they are not effective in large companies, large buildings, and government offices, but in small businesses, small daycare centers, and churches.

In addition, the conventional method has a structural limitation in that accuracy and reliability are degraded, and control is performed only in the corresponding section because the operator or manager visually checks the thermal image acquired by the thermal imaging camera to determine the person with high fever.

In addition, even if a high fever person is detected, the conventional method has a disadvantage that not only does the time required for the follow-up measures be delayed but also the quarantine efficiency is significantly lowered because the follow-up measures are not collectively performed, but individually performed by the manager.

1 is a block diagram showing a disease risk detection system for a group facility for infants and children disclosed in Korean Patent Registration No. 10-1932379 (name of the invention: disease risk detection system and method for group facilities for infants and children).

The disease risk detection system (hereinafter referred to as the prior art) 100 for a group facility for infants and children of FIG. 1 includes a manager server 140, an ID card 110, a first disease risk detection device 120, and a second disease risk. It consists of a sensing device 130 and a monitoring portable terminal 150.

The manager server 140 is provided to communicate with the external terminal 150 using a communication means.

The ID card 110 inputs personal identification information, and is a RIFD card held by an infant or child.

The first disease risk detection device 120 is installed around the entrance of the indoor space, and in detail, the ID card check unit 121 for checking personal identification information by checking the ID card 110 entering the indoor space , Consisting of a body temperature measuring unit 122 that measures the body temperature of the owner of the ID card 110 entering and exiting.

The second disease risk detection device 130 includes a body temperature change monitoring unit 131 that monitors changes in body temperature of owners who are worthy of an indoor space, and a field situation monitoring unit 132 that monitors the site situation of the indoor space.

At this time, the second disease risk detection device 130 is a thermal imaging camera.

This prior art 100 is provided in a group facility for infants and young children, and has the advantage of being able to check the change in body temperature of infants and children at an early stage, thereby preventing the risk of disease occurrence and spread of infants and children.

However, the conventional technology 100 has a problem that the installation and operation cost increases as the second disease risk detection device 130 uses an expensive thermal imaging camera, and accordingly, it is used in small-scale churches, day care centers, offices, etc. It has a limit that is difficult to become

In addition, in the prior art 100, when a heating element is detected, the follow-up procedure is performed simply by transmitting such information to the guardian's portable terminal and the monitoring portable terminal 150, so that the guardian or manager moves to the corresponding place to perform the follow-up procedure. It has a disadvantage that the efficiency of quarantine is inferior because it takes time to perform it.

However, since these thermal imaging cameras are expensive, they are not effective in large companies, large buildings, government offices, etc., but in small and medium-sized businesses, small churches, and the like, which are expensive to purchase and operate, and thus are less effective.

In addition, the conventional method has a structural limitation in that accuracy and reliability are degraded, and control is performed only in the corresponding section because the operator or manager visually checks the thermal image acquired by the thermal imaging camera to determine the person with high fever. That is, even if a heating element is detected, the conventional method has a disadvantage that not only the time required for the follow-up treatment is delayed but also the quarantine efficiency is remarkably deteriorated because the follow-up measures are not performed collectively, but individually performed by the manager.

The present invention is to solve such a problem, and the problem of the present invention is configured to perform counting of personnel and detection of high fever by using a thermometer consisting of inexpensive heat-sensing sensors without using an expensive thermal imaging camera. As a result, it is intended to provide a temperature measuring instrument equipped with a heat-sensing sensor and a heat-sensing monitoring system using the same, which can reduce the economic burden of a manager or a company by reducing purchase and operation costs.

In addition, another problem of the present invention is that when an unexpected situation occurs in which a person with high fever exists among visitors and occupants, the accidental situation is configured to output the accidental information, including the contents of the accident, time, location, and body temperature (T) information of the high fever person to the administrator terminal. It is to provide a body temperature measuring instrument equipped with a heat-sensing sensor that can maximize the heat dissipation efficiency as well as minimize the spread of damage through immediate response of the manager, and a heat-sensing monitoring system using the same.

In addition, another problem of the present invention is that the management server includes access number (N) and body temperature information of the person entering the management target, and current occupancy number (N1) and body temperature information of each management area at the request of the administrator terminal. It is configured to provide the current status, so that the manager can immediately monitor the current status through the manager terminal regardless of time and location, and to provide a body temperature measuring device equipped with a heat-sensing sensor, and a heat-sensing monitoring system using the same. will be.

In addition, another problem of the present invention is that when an unexpected situation occurs, the local server is configured to display pre-made announcements and announcements through speakers and monitors installed in the management target and each management area. It is intended to provide a body temperature measuring device equipped with a heat-sensing sensor that can further improve heat dissipation efficiency by making a response, and a heat-sensing monitoring system using the same.

In addition, another problem of the present invention is that the body temperature meter is composed of a plurality of heat-sensing sensors, and the detection area (S) is divided into a plurality of N×N blocks so that temperature detection is performed. Depending on the direction of heat detection), the temperature meter can be used separately for counting purposes and for body temperature purposes.Therefore, a temperature meter equipped with a heat-sensing sensor that can further improve ease of use and cost burden, and heat-sensing monitoring using the same It is to provide a system.

The solution means of the present invention for solving the above problem includes at least one body temperature measurement unit for a person who is installed at the entrance of a predetermined management target (D) to measure the body temperature of the person; At least one occupant body temperature measuring unit for the occupant for measuring the body temperature of the occupant of the management target (D); By analyzing the body temperature information installed on the management target (D) and transmitted from the body temperature measurement unit for the visitor and the body temperature measurement unit for occupants, the body temperature of the visitor or the body temperature of the occupant is higher than a preset set value (TH, Threshold). At least one local server for generating sudden information including contents, time, and body temperature after determining that the sudden situation has occurred when detected; When receiving the unexpected information from the local server, it includes a management server that transmits the accidental information to the administrator terminal preset as the manager of the management target (D), and the body temperature measurement unit for the visitor counts the number of people (N) of the visitor. A body temperature measuring device for the first visitor; A body temperature measuring device for a second person to measure the body temperature of a person; The number of people entering (N) is counted by analyzing the sensing information input from the first visitor's body temperature meter, and the body temperature of the visitor is detected by analyzing the detection information inputted from the second visitor's body temperature meter, and the detection time, access After generating access information including personnel (N) and body temperature information, it includes a first controller that transmits to the local server, and the local server transmits the access information received from the first controller to the management server, , The management server stores the access information transmitted from the local server and provides the stored access information according to the request of the manager terminal, and the management object consists of a plurality of management areas, and the body temperature measurement unit for the occupant A first occupant temperature measuring unit installed in each of the management areas, and the body temperature measuring unit for occupants is installed on a door of the corresponding management area to count the number of occupants N1 in the management area; A second occupant body temperature measuring device for measuring the body temperature of the occupant in the corresponding management area; By analyzing the sensing information input from the first occupant body temperature measuring device, the number of occupants (N) in the corresponding management area is counted, and the body temperature of the occupant in the corresponding management area by analyzing the sensing information input from the second occupant body temperature measuring device. And a second controller configured to generate occupancy information and transmit the sensing time, occupant number (N1), and body temperature information to the local server, and the local server includes second controllers of body temperature measuring units for occupants The occupancy information received from the server is transmitted to the management server, and the management server stores occupancy information received from the local server and provides the occupancy information stored at the request of the administrator terminal, and the body temperature meter for the first visitor Is divided into N×N blocks including a plurality of heat-sensing sensors to measure the temperature value for each block, and is installed on the upper structure of the entrance to be managed in a direction from top to bottom. It is installed to detect heat, and the first controller calculates the difference values for each block, which is a difference value between the preset reference value C and the temperature values for each block input from the first visitor's body temperature meter, and then the calculated The maximum difference value, which is the maximum value among the difference values for each block, is detected, the block having the maximum difference value is determined as an entry block, and the trajectory of the entry block is tracked, and the trajectory of the entry block is the detection area (S). When passing the preset reference line (L) above, the number of persons entering (N) is increased or subtracted by '1' according to the passing direction, and the first occupant body temperature measuring instrument includes a plurality of heat-sensing sensors. (S) is divided into N×N blocks to measure the temperature value for each block, installed on the upper structure of the door of the corresponding management area, and installed so as to sense heat in a direction from the top to the bottom, and the second controller Is the maximum difference value, which is the maximum value among the calculated difference values for each block, after calculating the difference values for each block, which is the difference value between the temperature values for each block input from the preset reference value C and the first occupant body temperature meter. Is detected, the block with the maximum difference value is determined as the entry block, and the entry block It tracks the trajectory of the lock, and when the trajectory of the entry block passes the preset reference line L on the detection area S, the number of occupants N1 is increased or subtracted by '1' according to the passing direction. .

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In addition, in the present invention, the heat-sensing monitoring system further includes speakers installed in each of the management areas and monitors installed in each of the management areas, and the local server includes the speakers and It is preferable to control the speakers and the monitors so that pre-made announcements and announcements are output to the monitors.

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According to the present invention having the above problems and solutions, purchase and operation costs are reduced by counting personnel and detecting high fever by using a thermometer made of low-cost thermal-sensing sensors without using an expensive thermal imaging camera. As a result, it is possible to reduce the economic burden on managers or companies.

In addition, according to the present invention, when an emergency situation occurs in which a person with high fever exists among visitors and occupants, the administrator terminal is configured to output unexpected information including information about the accident, time, location, and body temperature (T) of the person with high fever. It is possible to minimize the spread of damage and maximize heat dissipation efficiency through immediate response.

In addition, according to the present invention, the management server provides the current status including the number of access persons (N) and body temperature information of the person entering the management target, and the current number of occupants (N1) and body temperature information of each management area at the request of the administrator terminal. It is configured so that the manager can immediately monitor the current status through the manager terminal regardless of time and location.

In addition, according to the present invention, when an unexpected situation occurs, the local server is configured to display pre-manufactured announcements and announcements through speakers and monitors installed in the management target and each management area, thereby providing a quick response to an unexpected situation. Efficiency can be further improved.

In addition, according to the present invention, the body temperature measuring device is composed of a plurality of heat-sensing sensors, and the detection area (S) is divided into a plurality of N×N blocks to detect the temperature, so that the installation direction of the body temperature measuring device (heat detection direction) Accordingly, it is possible to further improve the convenience of use and cost burden as the temperature meter can be used separately for counting and body temperature purposes.

1 is a block diagram showing a disease risk detection system for a group facility for infants and children disclosed in Korean Patent Registration No. 10-1932379 (name of the invention: disease risk detection system and method for group facilities for infants and children).
2 is a block diagram showing a heat-sensing monitoring system according to an embodiment of the present invention.
3 is an exemplary view for explaining FIG. 2.
FIG. 4 is a block diagram showing the body temperature measuring device of FIG. 2.
5 is a block diagram showing the temperature measuring device for occupants of FIG. 2.
6 is an exemplary diagram for explaining a management server, a management platform, and a manager terminal of FIG. 2.
7 is a block diagram illustrating a local server of FIG. 2.
8 is a block diagram illustrating a first occurrence determining unit of FIG. 7.
9 is a block diagram illustrating a second occurrence determining unit of FIG. 7.
10 is an exemplary view showing a body temperature measuring unit applied to the present invention.
11 is a block diagram illustrating a controller when the body temperature measurement unit of FIG. 10 is used for counting purposes.
12 is a block diagram showing the counting module of FIG. 11.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

2 is a block diagram showing a heat-sensing monitoring system according to an embodiment of the present invention, and FIG. 3 is an exemplary view for explaining FIG. 2.

The heat-sensing monitoring system (1), which is an embodiment of the present invention, uses a body temperature measuring unit consisting of 1) a heat-sensing sensor to count access objects passing through the entrance and simultaneously measure whether there is a high temperature, and 2) management target (D) In the event of a suspected high temperature by monitoring the temperature of a visitor's body, a pre-set isolation algorithm is used to induce rapid isolation of the suspected high temperature, thereby reducing installation and operation costs, as well as increasing heat dissipation efficiency. .

In addition, the heat-sensing monitoring system 1 of the present invention is installed at the entrance of the management target (D) consisting of a plurality of management areas (D1), ..., (Dn), as shown in FIGS. 2 and 3 It is installed in each of the accessor's body temperature measurement unit (4) and the management area (D1), ..., (Dn), which counts the accessor at the same time, and measures the body temperature of the occupant in the management area. Body temperature measurement units (5-1), ..., (5-N) for occupants, and guides pre-made under the control of the local server (3) in the event of an unexpected situation installed in the management target (D) Speakers 11 for outputting broadcasts, monitors 12 that are installed on the management target D and display pre-manufactured guide texts under the control of the local server 3 when an unexpected situation occurs, and a management area It is installed in each of (D1), ..., (Dn) and analyzes the data transmitted from the body temperature measuring unit (4), (5-1), ..., (5-N), Local servers (3-1), ..., (3-N), and local servers (3-1), ..., (3-N) that determine whether a high fever person exists or not Stores and monitors the access information and body temperature information received from the device, and provides a management platform service (8) to the connected administrator terminal (9), and transmits the information on the occurrence of the unexpected situation to the administrator terminal (9) when an unexpected situation occurs. It consists of a management server (7) and a communication network (10) that provides a data movement path between the management and local servers (3-1), ..., (3-N).

At this time, in the present invention, for convenience of explanation, it has been described for example that the body temperature measurement unit 4 for accessors is a single configuration, but the body temperature measurement unit 4 for accessors is the number of entrances 20 of the corresponding management target (D) Depending on the configuration of a plurality or a plurality may be installed in a single entrance (20).

In addition, in the present invention, for convenience of explanation, the local server 3 has been described as an example of determining whether an unexpected situation has occurred, but the operation processing for determining whether an unexpected situation has occurred is performed by the controller 201 of the body temperature measuring unit of FIG. 11 to be described later. ) Can be configured to run on its own.

The communication network 10 supports data communication between the management server 7 and the local server 3-1, ..., (3-N), and in detail, a wide area network (WAN), a mobile communication network, Various well-known communication methods such as wired communication network and 4G/5G/LTE can be applied.

The client 9 is a terminal that provides services such as monitoring, reading, and requesting information of access information and occupancy information by interlocking with the management platform 8 provided by the management server 7, and in detail, a desktop PC (Desktop PC). -top PC), notebook (Note-book), smart phone (Smart-phone), can be composed of a tablet PC (Tablet PC).

The subject of management (D) refers to a building having a closed space such as a public health center, daycare center, office, and government office.

In addition, the management target (D) includes pre-set management areas (D1), ..., (Dn) inside.

In addition, a body temperature measurement unit 4 for accessors is installed at the entrance 20 of the management target (D), and a body temperature measurement unit 5 for occupants inside each management area (D1), ..., (Dn), A speaker 11 and a monitor 12 are installed.

In addition, the body temperature measuring unit (4), (5-1), ..., (5-N), speakers (11) and monitor (12) installed in the management target (D) are the local server (3) and It is connected to a wired/wireless communication network (not shown) and operates according to the management and control of the local server 3.

4 is a block diagram illustrating a body temperature measuring unit for a person in FIG. 2.

The body temperature measuring unit 4 for accessors is installed at the entrance 20 of the management target (D).

In addition, as shown in FIG. 4, the body temperature measuring unit 4 for visitors includes a first controller 41, a first visitor body temperature measuring device 43 that detects the visitor and counts the number of people entering (N), and It consists of a second body temperature measuring device 45 for measuring the body temperature of.

At this time, temperature information for each block measured by the heat-sensing sensors of the first and second body temperature measuring devices 43 and 45 are output to the first controller 41.

The first controller 41 analyzes the temperature information for each block input from the first visitor's body temperature measuring device 43 to detect entry or exit details, time, and entry number (N) information, and the second visitor's body temperature meter ( 45), detects body temperature information by analyzing the detection signal inputted from), generates access information including entry or exit details, time, number of people entering (N), and body temperature information, and then sends the generated access information to the local server (3). ).

At this time, a process in which the first controller 41 of the body temperature measuring unit 4 for accessors performs calculation processing such as detection of accessors, counting access personnel (N), and measurement of body temperature will be described in detail in FIGS. 10 to 12 to be described later. .

In addition, the first and second body temperature measuring devices 43 and 45 have the same configuration and shape as the body temperature measuring unit 203 of the body temperature measuring unit 200 of FIGS. 10 to 12 described later, but the body temperature for the first visitor The measuring device 43 is installed on the upper ceiling or structure of the entrance 20 and installed to sense heat in a direction from the top to the bottom, and the body temperature measuring device 45 for the second entrance is in a horizontal direction toward the entrance 20. It is installed to detect heat. At this time, it is preferable that the second body temperature measuring device 45 is installed so that the upper end of the detection area faces a height corresponding to the height of a person.

5 is a block diagram showing a body temperature measuring unit for occupants of FIG. 2.

The body temperature measuring unit 5 for occupants is installed in each of the management areas D1, ..., Dn.

In addition, as shown in FIG. 5, the body temperature measurement unit 5 for occupants includes a second controller 51 and a first occupant body temperature measuring device 53 installed on the door of the corresponding management area to count the occupant number N1. ), and a second occupant body temperature measuring device 55 that measures the body temperature of the occupant in the corresponding management area.

At this time, temperature information for each block detected by the heat-sensing sensors of the first and second occupant body temperature measuring devices 53 and 55 is output to the second controller 51.

The second controller 51 analyzes the temperature information for each block input from the second occupant body temperature measuring device 53 to detect entry or exit details, time, and number of occupants (N1) information into the corresponding management area, and the second When body temperature information is detected by analyzing the temperature information for each block input from the body temperature measuring device 55 for occupants, after generating occupancy information including the detected entry or exit details, time, occupancy number (N2) and body temperature information, The generated occupancy information is output to the local server 3.

The second temperature measuring device 53 for occupants is installed on the door of the corresponding management area to detect heat in a direction from top to bottom, and the body temperature measuring device for second occupants 55 is also installed in a direction from top to bottom. Is installed to detect.

Speakers 11 are installed in each of the management areas (D1), ..., (Dn), and when it is determined that an unexpected situation has occurred by the local server 3, it is controlled by the local server 3 The previously produced announcement is output.

The monitors 12 are installed in each of the management areas (D1), ..., (Dn), and when it is determined that an unexpected situation has occurred by the local server 3, it is controlled by the local server 3 The pre-made guide text is displayed.

The local server 3 temporarily stores the access information received from the body temperature measuring unit 4 for accessors and transmits it to the management server 7 at the same time, and the body temperature (T) of the entered access information is set to a preset value (TH). Compared with, when the body temperature (T) is greater than or equal to the set value (TH), the person in question is determined to be a high fever, and it is determined that a first sudden situation has occurred, indicating that a high fever person exists among the visitors.

In addition, when the first unexpected situation occurs, the local server 3 generates first sudden information including the contents of the accident, location, time, and body temperature (T), and then transmits the generated first accident information to the management server 7. At the same time as the transmission to the speakers 11 and the display means (12).

At this time, the speakers 11 and the monitor 12, when receiving the first unexpected information from the local server 3, outputs the previously produced announcement and announcement, and the management server 7 from the local server 3 Upon receiving the first breakthrough information, the first breakthrough information is transmitted to the preset management target manager terminal 9. In addition, the management platform 8 allows the manager to immediately recognize that the first unexpected situation has occurred by exposing the first unexpected information to the manager terminal 9 in a pop-up manner when the first unexpected situation occurs, so that quick follow-up measures are possible. Can be achieved.

In addition, when the local server 3 receives occupancy information from the second controller 51 of the occupancy body temperature measuring unit 5, the entered occupancy information is temporarily stored and transmitted to the management server 7 at the same time. The body temperature (T) of the information is compared with a preset set value (TH), and when the body temperature (T) is greater than or equal to the set value (TH), it is determined that a second sudden situation that a high fever person exists among the occupants has occurred.

In addition, when a second unexpected situation occurs, the local server 3 generates second accidental information including the contents of the accident, the location of the management area, time, and body temperature (T), and then manages the generated second accidental information. At the same time as transmitting to (7), it is transmitted to the speakers 11 and the monitor 12.

At this time, when the speakers 11 and the monitor 12 receive the second unexpected information from the local server 3, they output pre-made announcements and announcements, and the management server 7 from the local server 3 Upon receiving the second breakthrough information, the second breakthrough information is transmitted to the preset manager terminal 9 of the corresponding management target. In addition, the management platform 8 is configured to expose the second unexpected information to the manager terminal 9 in a pop-up method when a second unexpected situation occurs, so that the manager can immediately recognize that the second unexpected situation has occurred, and thus prompt follow-up measures. Can be achieved.

The management server 7 receives and stores the access information and occupancy information received from the local servers 3-1, ..., (3-N) and monitors it at the same time.

In addition, when the management server 7 receives the first accidental information or the second accidental information from the local servers 3-1, ..., (3-N), the preset manager terminal 9 of the management area The first or second unexpected information transmitted to is transmitted.

In addition, the management server 7 provides a management platform service to the connected manager terminal 9.

6 is an exemplary diagram for explaining a management server, a management platform, and a manager terminal of FIG. 2.

As shown in FIG. 6, the management platform 8 provides access information and occupancy information according to the request of the connected manager terminal 9 through a pre-made graphic user interface (GUI), web page, etc. At the same time as the provision, when a first or second unexpected situation occurs, the first or second unexpected information is provided to the manager terminal 9 through text, SNS, pop-up method, or the like.

That is, the manager 1) interlocks with the management platform 8 provided by the management server 7 through the manager terminal 9, and access information of the corresponding management target (D), each management area (D1), ..., In addition to being able to request and monitor the occupancy information of (Dn), 2) when an unexpected situation occurs, it is possible to immediately recognize the unexpected situation through the unexpected information displayed on the manager terminal 9 and perform a prompt follow-up response. do.

7 is a block diagram illustrating a local server of FIG. 2.

As shown in FIG. 7, the local server 3 includes a control unit 30, a memory 31, a communication interface unit 32, a first breakdown determination unit 33, and a first breakthrough information generation unit 34. ), a second breakthrough determination unit 35, a second breakthrough information generation unit 36, and an accessory drive control unit 37.

At this time, in the present invention, it has been described for example that the local server 3 performs computational processing to determine whether an unexpected situation has occurred, but the first occurrence determination unit 33 of the local server 3, generating the first unexpected information The unit 34, the second breakout determination unit 35, and the second breakout information generation unit 36 may be configured to be included in the controller 201 of the body temperature measurement unit of FIG. 11 to be described later.

The control unit 30 is an OS (Operating System) of the local server 3, and manages the control targets 31, 32, 33, 34, 35, 36, and 37. Control.

In addition, when the access information is received from the first controller 41, the control unit 30 temporarily stores the transmitted access information in the memory 31 and simultaneously inputs the received access information to the first emergency determination unit 33, and the received access information The communication interface unit 32 is controlled so that is transmitted to the management server 7.

In addition, when it is determined that the first accidental situation has occurred by the first accidental detection unit 33, the control unit 30 executes the first accidental information generation unit 34.

In addition, when receiving occupancy information from the second controller 51, the control unit 30 temporarily stores the received occupancy information in the memory 31 and inputs the transmitted occupancy information to the second breakout determination unit 35, and the transmitted occupancy information The communication interface unit 32 is controlled so that is transmitted to the management server 7.

In addition, when it is determined that the second accidental situation has occurred by the second accidental detection unit 35, the control unit 30 executes the second accidental information generation unit 36.

In the memory 31, the location and identification information of the management target D in which the local server 3 is installed, and the location and identification information of each management area D1, ..., Dn are preset and stored.

In addition, the location and identification information of each of the speakers 11 and the monitors 12 are preset and stored in the memory 31.

In addition, access information and occupancy information are temporarily stored in the memory 31. At this time, the access information includes entry or exit details, time, number of people entering (N) and body temperature (T) information of the entrance 20, and occupancy information includes entry or exit details, time, and number of occupants ( N2) and body temperature (T) information.

In addition, the memory 31 stores the first breakthrough information generated by the first breakthrough information generation unit 34 and the second breakthrough information generated by the second breakthrough information.

In addition, the previously produced announcement and announcement are stored in the memory 31.

The communication interface unit 32 transmits and receives data to and from the management server 7 connected through the communication network 10.

8 is a block diagram illustrating a first occurrence determining unit of FIG. 7.

As shown in FIG. 8, the first accident determination unit 33 includes an access information input module 331, a body temperature information extraction module 332, a comparison module 333, and a first accidental situation determination module ( 334).

The access information input module 331 receives the access information transmitted from the first controller 41. At this time, as described above, the access information is composed of information on the entry or exit of the entrance 20, time, number of persons entering (N) and body temperature (T).

The body temperature information extraction module 332 extracts body temperature (T) information from the access information input through the access information input module 331.

The comparison module 333 compares the body temperature (T) information extracted by the body temperature information extraction module 332 with a preset set value (TH). At this time, the set value TH is defined as the minimum value of body temperature that can determine the object as a high fever person.

In the comparison module 333, the first sudden situation determination module 334 determines that the first sudden situation has not occurred when the body temperature T is less than the set value TH, but the body temperature T is the set value ( TH) or more, it is judged that the first unexpected situation has occurred. At this time, the first sudden situation means a situation in which the person passing through the entrance 20 is a high fever person.

At this time, when it is determined that the first unexpected situation has occurred by the first sudden situation determination module 334, the control unit 30 executes the first unexpected information generation unit 34.

The first unexpected information generation unit 34 is executed when it is determined that the first unexpected situation has occurred by the first sudden situation determination module 334.

In addition, the first breakthrough information generation unit 34 generates first breakthrough information including breakdown content, location, time, and body temperature (T).

At this time, the first breakthrough information generated by the first breakthrough information generation unit 34 is input to the accessory drive control unit 37 under the control of the control unit 30 and at the same time, the management server 7 through the communication interface unit 32 ).

9 is a block diagram illustrating a second occurrence determining unit of FIG. 7.

As shown in FIG. 9, the second accident determination unit 35 includes an occupancy information input module 351, a second body temperature information extraction module 352, a second comparison module 353, and a second accidental situation occurs. It consists of a determination module (354).

The occupancy information input module 351 receives occupancy information transmitted from the second controller 51. At this time, the occupancy information is composed of the entry or exit details of the door of each management area, time, number of people entering (N), and body temperature (T) information, as described above.

The second body temperature information extraction module 352 extracts body temperature (T) information from the occupancy information input through the occupancy information input module 351.

At this time, the body temperature (T) information means a temperature value of each block when divided into a plurality of blocks of each management area.

The second comparison module 353 compares the body temperature T information extracted by the second body temperature information extraction module 352, that is, each of the temperature values for each block with a preset set value TH.

In the second comparison module 353, the second sudden situation determination module 354 determines that the second sudden situation does not occur if all of the temperature values for each block are less than the set value TH, but the temperature for each block If at least one of the values exceeds the set value TH, it is determined that a second unexpected situation has occurred. In this case, the second sudden situation refers to a situation in which at least one high fever person is detected among the residents of the corresponding detective younger.

At this time, when it is determined that the second unexpected situation has occurred by the second sudden situation determination module 354, the control unit 30 executes the second unexpected information generation unit 36.

The second unexpected information generation unit 36 is executed when it is determined that the second unexpected situation has occurred by the second sudden situation determination module 354.

In addition, the second breakthrough information generation unit 34 generates second breakthrough information including breakdown content, location, time, and body temperature (T).

At this time, the second breakthrough information generated by the second breakthrough information generation unit 36 is input to the accessory drive control unit 37 under the control of the control unit 30, and at the same time, the management server 7 through the communication interface unit 32 ).

Returning to FIG. 7 and looking at the accessory drive control unit 37, the accessory drive control unit 37 receives the first breakthrough information from the first breakthrough information generation unit 34 or the second breakthrough information generation unit 36 When the second unexpected information is input from, it is executed under the control of the control unit 30.

In addition, the accessory drive control unit 37 controls the speakers 11 to output pre-made announcements from the speakers 11 when receiving the first or second unexpected information, and at the same time, the monitors 12 The monitors 12 are controlled so that the pre-made guide phrase is displayed.

10 is an exemplary view showing a body temperature measuring unit applied to the present invention.

The body temperature measurement unit 200 of the present invention is a device applied to the body temperature measurement unit 4 for visitors in FIG. 4 and the body temperature measurement unit 5 for occupants of FIG. 5 described above.

In addition, the body temperature measuring unit 200 includes a controller 201 and a body temperature measuring device 203 comprising a plurality of heat-sensing sensors, as shown in FIG. 10.

At this time, the temperature measuring device 203 detects the temperature value of the passer through the detection area S divided into N×N blocks using a plurality of heat-sensing sensors for each block, and the controller 201 analyzes the pattern It is configured to accurately detect and count passers by analyzing the temperature values for each block detected by the temperature measuring instrument 203 using an algorithm.

The heat-sensing sensors of the body temperature measuring device 203 measure the temperature value of the detection area S according to a preset period, and in detail, the temperature value of the detection area S every 5 times per second (T1). It is desirable to measure.

In addition, the temperature measuring device 203 inputs the measured temperature values to the controller 201.

That is, the body temperature measuring device 203 measures temperature value data of each block of the detection area S when measuring the temperature. At this time, in the present invention, for convenience of explanation, it has been described for example that the detection area S is divided into 4×4 blocks, but the detection area S is divided into N×N (N>2) blocks. It is natural that it can be formed.

At this time, the detection area S has a length in a direction perpendicular to the movement direction X, and a reference line L dividing the detection area S in half is formed.

In addition, when the body temperature measurement unit 200 is used for counting purposes, such as the body temperature measurement device 43 for the first person in FIG. 4 or the body temperature measurement device 53 for the first occupant of FIG. 5 described above, the body temperature measurement unit 200 When the object passes through the reference line (L), the controller 201 of'+1' or'-1' sets the number of people entering (N) or number of occupants (N1) in accordance with the moving direction.

For example, in the case of the entrance 20 of the detection area (S) or the door of each management area, the controller 201 of the body temperature measurement unit 200 is used when the object passes the reference line (L) in the direction of +X. Counting is performed by adding 1 to the number of persons, but when passing through the baseline (L) in the direction of -X, the number is counted by subtracting 1 from the existing number. At this time, regardless of the moving direction, the total occupancy can be calculated by summing the quantity passing through the reference line L.

On the other hand, when the body temperature measuring unit 200 is used for measuring the body temperature of a person passing through the entrance, such as the body temperature measuring device 45 for the second person in FIG. 4 described above, the body temperature measuring unit 203 is placed at a predetermined height from the ground. After installation, it can be installed to detect heat in a horizontal direction while facing the entrance.

In addition, when the body temperature measuring unit 200 is used for measuring the temperature of each block in a predetermined area, like the second occupant body temperature measuring device 55 of FIG. 5 described above, the body temperature measuring device 203 is used as a ceiling or upper structure. After installation, it can be installed in a direction from top to bottom. At this time, the temperature measuring device 203 is preferably installed so that the detection area S includes a management area.

11 is a block diagram illustrating a controller when the body temperature measurement unit of FIG. 10 is used for counting purposes.

The controller 201 of FIG. 11 is applied when the body temperature measuring unit 200 is used for counting purposes, such as the first visitor's body temperature measuring device 43 of FIG. 4 or the first occupant's body temperature measuring device 53 of FIG. do.

In addition, as shown in FIG. 11, the controller 201 includes a control module 211, a memory 212, a data transmission/reception module 213, a sensor control module 214, a difference value calculation module 215 for each block, It consists of a maximum difference value detection module 216, a counting module 217, and a counting module 37.

The control module 211 is an O.S (Operating system) of the controller 201, and manages and controls the control targets 212, 213, 214, 215, 216, and 217.

In addition, the control module 211 drives the sensor control module 214 every preset first cycle (T1 = 5 times per second), and according to the control of the sensor control module 214, the heat-sensing sensors of the body temperature measuring instrument 203 The temperature is measured for each block every first period T1.

In addition, the control module 211 inputs the temperature data for each block measured by the heat-sensing sensor through the sensor control module 214 to the difference value calculation module 215 for each block and stores it in the memory 212.

In addition, the control module 211 inputs the difference value data for each block calculated by the difference value calculation module 215 for each block to the maximum difference value detection module 216 and stores it in the memory 212 at the same time.

In addition, the control module 211 inputs the maximum difference value data detected by the maximum difference value detection module 216 to the counting module 217, and the number of people entering or occupied by the counting module 217 (N1) is stored in the memory 212.

The first period T1 is preset and stored in the memory 212.

In addition, the reference line L information of FIG. 10 described above is stored in the memory 212.

In addition, the memory 212 includes temperature value data for each block measured by the sensor control module 214, difference value data for each block calculated by the difference value calculation module 215 for each block, and a maximum difference value detection module. The maximum difference value data detected by 216 and the number of persons entering (N) or number of persons occupied (N1) detected by the counting module 217 are stored.

The data transmission/reception module 213 transmits and receives data to and from the local server 3.

The sensor control module 214 drives the heat-sensing sensors of the temperature measuring device 203 every first period T1 according to the control of the control module 211, thereby forming a block of the detection area S every first period T1. Make sure the temperature is measured separately.

In addition, when temperature value data for each block are input from the heat-sensing sensors of the body temperature measuring device 203, the sensor control module 214 inputs the input temperature value data for each block to the difference value calculation module 215 for each block.

The difference value calculation module 215 for each block calculates difference values for each block, which is a difference value between each of the temperature value data for each block input from the sensor control module 214 and a preset reference value data C.

For example, if the reference value data C is '180', the temperature value data of 1 block is '190', and the temperature value data of 2 blocks is '194', the difference value calculation module 215 for each block The difference value of 1 block calculated by is '10', and the difference value of 2 blocks is '4'.

That is, the difference value calculation module 215 for each block calculates difference values between the reference value data C and the temperature value data for each block, respectively. At this time, the calculated difference value data for each block are input to the maximum difference value detection module 216.

The maximum difference value detection module 216 detects the maximum difference value data having the largest size among the input difference value data for each block.

At this time, the maximum difference value data detected by the maximum difference value detection module 216 is input to the counting module 217.

12 is a block diagram showing the counting module of FIG. 11.

The counting module 217 includes a comparison and determination module 2171, a trajectory tracking module 2173, and a number calculation module 2175, as shown in FIG. 12.

The comparison and determination module 2171 compares the maximum difference value data input from the maximum difference value detection module 216 with a preset second set value TH2 and Threshold2. At this time, the second set value TH2 is defined as the minimum value of the maximum difference value that can be determined that the human body has entered.

In addition, the comparison and determination module 2171 determines that if the maximum difference value is less than the second set value TH2, it is determined that no person has entered the block, and if the maximum difference value is more than the second set value TH2, It is determined that a person has entered the block.

In general, even when the human body does not enter the detection area S, the temperature of the blocks may have a predetermined difference due to the external environment, so in the present invention, the maximum difference value is the second set value TH2. Compared to, it is possible to verify whether a person has entered.

In addition, if the maximum difference value is greater than or equal to the second set value TH2, the comparison and determination module 2171 determines the block in which the maximum difference value is generated as a'entry block', which is a block into which a person has entered, and the determined'entry block' 'Data is input to the trajectory tracking module 2173.

The trajectory tracking module 2173 receives'entry block' data from the comparison and determination module 2171, and determines whether the trajectory of the entry blocks passes through the reference line L by tracking the trajectory of the entry blocks in a continuous period.

Also, the trajectory tracking module 2173 drives the counting module 2175 if the trajectory of the entry blocks passes through the reference line L.

When the entry blocks pass through the reference line (L) in the +A direction by the trajectory tracking module 2175, the people measuring module 2175 adds 1 to the existing passer quantity (N) to update the passer quantity (N), When the entry blocks pass through the reference line (L) in the direction A, the number of passers (N) is updated by subtracting 1 from the number of passers-by (N).

On the other hand, when the body temperature measuring unit 200 is used for measuring body temperature, such as the second body temperature measuring device 45 of FIG. 4 or the second occupant body temperature measuring device 55 of FIG. 5 described above, the controller 201 11 may be configured to exclude the difference value calculation module 215 for each block, the maximum difference value detection module 216, the counting module 217, and the counting module 37 among the above-described components of FIG. 11.

That is, the controller 201 includes the control module 211 of FIG. 11 described above, the memory 212, the data transmission/reception module 213, and the sensor control module 214.

As described above, the heat-sensing monitoring system 1 according to an embodiment of the present invention does not use an expensive thermal imager, but uses a temperature measuring device 203 made of inexpensive heat-sensing sensors to count personnel and detect high fever. By being configured so that it is possible to reduce the purchase and operation cost, it is possible to reduce the economic burden on the manager or the company.

In addition, the heat-sensing monitoring system 1 of the present invention, when an unexpected situation occurs in which a high fever person exists among accessors and occupants, the alarm information, time, location, and body temperature (T) information of the high fever person to the administrator terminal 9 By being configured to output information, the manager immediately responds to an unexpected situation, thereby minimizing the spread of damage and maximizing heat dissipation efficiency.

In addition, in the heat-sensing monitoring system 1 of the present invention, the management server 7 provides access number (N) and body temperature information of the person entering the management target at the request of the manager terminal 9, and the current occupancy of each management area. By being configured to provide the current status including the personnel N1 and body temperature information, the manager can immediately monitor the current status through the manager terminal regardless of time and location.

In addition, the heat-sensing monitoring system 1 of the present invention is a pre-produced announcement through the speakers 11 and monitors 12 installed in the management target and each management area when the local server 3 unexpectedly occurs. And by being configured to display a guide phrase, it is possible to further improve the heat dissipation efficiency by making a quick response to an unexpected situation.

In addition, in the heat-sensing monitoring system 1 of the present invention, the body temperature measuring device 203 is composed of a plurality of heat-sensing sensors, and the detection area S is divided into a plurality of N×N blocks to perform temperature detection. As a result, it is possible to further improve the convenience of use and cost burden as the temperature meter can be used separately for counting and body temperature purposes according to the installation direction (heat sensing direction) of the body temperature meter.

1: Thermal-sensing monitoring system 3-1, ..., 3-N: local servers
4: Body temperature measurement unit for entrance 5: Body temperature measurement unit for occupants
7: Management Server 8: Management Platform
9: Administrator terminal 10: Communication network
11: Speakers 12: Monitors
30: control unit 31: memory
32: communication interface unit 33: first occurrence determination unit
34: first breakthrough information generation unit 35: second breakthrough determination unit
36: second unexpected information generation unit 37: accessory drive control unit
41: the first controller 43: a body temperature measuring device for the first visitor
45: second visitor body temperature meter 51: second controller
53: a thermometer for the first occupant 55: a thermometer for the second occupant
200: body temperature measurement unit 201: controller
203: body temperature measuring instrument

Claims (7)

At least one body temperature measurement unit for a person who is installed at the entrance of a predetermined management target (D) to measure the body temperature of the person;
At least one occupant body temperature measuring unit for the occupant for measuring the body temperature of the occupant of the management target (D);
By analyzing the body temperature information installed on the management target (D) and transmitted from the body temperature measurement unit for the visitor and the body temperature measurement unit for occupants, the body temperature of the visitor or the body temperature of the occupant is higher than a preset set value (TH, Threshold) At least one local server for generating sudden information including contents, time, and body temperature after determining that the sudden situation has occurred when detected;
When receiving the incident information from the local server, including a management server for transmitting the incident information to a preset manager terminal as a manager of the management target (D),
The body temperature measurement unit for the visitor
A body temperature measuring device for a first visitor for counting the number of persons N;
A body temperature measuring device for a second person to measure the body temperature of a person;
The number of people entering (N) is counted by analyzing the sensing information input from the first visitor's body temperature meter, and the body temperature of the visitor is detected by analyzing the detection information inputted from the second visitor's body temperature meter, and the detection time, access After generating access information including personnel (N) and body temperature information, including a first controller for transmitting to the local server,
The local server transmits the access information received from the first controller to the management server,
The management server stores the access information transmitted from the local server and at the same time provides the stored access information according to the request of the administrator terminal,
The management target consists of a plurality of management areas,
The body temperature measurement unit for occupants is installed in each of the management areas,
The body temperature measurement unit for occupants
A first occupant temperature measuring device installed on the door of the management area and counting the number of occupants N1 in the management area;
A second occupant body temperature measuring device for measuring the body temperature of the occupant in the corresponding management area;
By analyzing the sensing information input from the first occupant body temperature measuring device, the number of occupants (N) in the corresponding management area is counted, and the body temperature of the occupant in the corresponding management area by analyzing the sensing information input from the second occupant body temperature measuring device. And a second controller that detects and transmits the sensing time, occupancy number (N1) and body temperature information to the local server after generating occupancy information,
The local server transmits occupancy information received from the second controllers of the occupant body temperature measuring units to the management server,
The management server stores occupancy information transmitted from the local server and provides stored occupancy information at the request of the administrator terminal,
The first accessor's body temperature measuring device includes a plurality of heat-sensing sensors and divides the detection area (S) into N×N blocks to measure the temperature value for each block, and is installed on the upper structure of the entrance of the subject to be managed. It is installed to detect heat in a direction from top to bottom,
The first controller
After calculating the block-by-block difference values, which are the difference values of the block-by-block temperature values input from the preset reference value (C) and the first visitor's body temperature meter, the maximum difference value, which is the maximum among the calculated block-by-block difference values, is calculated. It detects, and after determining the block with the maximum difference value as the entry block, the trajectory of the entry block is tracked, and when the trajectory of the entry block passes a preset reference line (L) in the detection area (S), it passes. Increase or deduct the number of people entering (N) by '1' according to the direction,
The first occupant body temperature meter includes a plurality of heat-sensing sensors and divides the detection area S into N×N blocks to measure the temperature value for each block, and is installed on the upper structure of the door of the corresponding management area. It is installed to detect heat in a direction from top to bottom,
The second controller
After calculating the block-by-block difference values, which are the difference values of the block-by-block temperature values input from the preset reference value C and the first occupant's body temperature meter, the maximum difference value, which is the maximum value among the calculated block-by-block difference values, is calculated. It detects, and after determining the block with the maximum difference value as the entry block, the trajectory of the entry block is tracked, and when the trajectory of the entry block passes a preset reference line (L) in the detection area (S), it passes. Heat-sensing monitoring system, characterized in that increasing or subtracting the number of occupied persons (N1) by '1' according to the direction. delete delete The method of claim 1, wherein the heat-sensing monitoring system further comprises speakers installed in each of the management areas, and monitors installed in each of the management areas,
And the local server controls the speakers and the monitors to output pre-made announcements and announcements to the speakers and the monitors when an unexpected situation occurs.
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