KR102776606B1 - Environmental information collection and analysis system using assembled sensing devices - Google Patents

Abstract

The present invention relates to an environmental information collection and analysis system utilizing an assembled sensing device, and more specifically, to an environmental information collection and analysis system utilizing an assembled sensing device capable of providing a video connection service between a shared terminal and a customer terminal based on a customer environmental condition evaluated according to sensing information. To this end, the environmental information collection and analysis system utilizing the assembled sensing device includes an information collection unit that collects sensing information for each device from a plurality of assembled sensing devices through a network, an information authentication unit that authenticates device information transmitted from one of the plurality of assembled sensing devices through a customer terminal, a list generation unit that generates a service target list by mapping target sensing information measured through one of the assembled sensing devices and customer information upon authenticating the device information, an information service unit that provides the target sensing information to the customer terminal in real time through an environmental management service based on the service target list, and an integrated service unit that services a video connection between one of the previously registered shared terminals and the customer terminal through the environmental management service based on a customer environmental state evaluated according to the target sensing information.

Description

{ENVIRONMENTAL INFORMATION COLLECTION AND ANALYSIS SYSTEM USING ASSEMBLED SENSING DEVICES}

The present invention relates to an environmental information collection and analysis system utilizing an assembled sensing device, and more specifically, to an environmental information collection and analysis system utilizing an assembled sensing device capable of providing a video connection service between a shared terminal and a customer terminal based on a customer environmental condition evaluated according to sensing information.

A sensor is a device that measures information about objects in the natural world and changes it into an electrical signal. With recent technological advancements, sensors that can measure information about various objects are being developed. However, these sensors are manufactured as an integrated unit attached to the product in the form of a package, which makes it difficult to maintain and repair the product.

The present invention is intended to solve the above problems, and an object of the present invention is to provide an environmental information collection and analysis system utilizing an assembled sensing device capable of selectively providing a video connection between a shared terminal and a customer terminal through an environmental management service based on the customer environmental status.

The above and other objects and advantages of the present invention will become apparent from the following description of preferred embodiments.

According to one embodiment of the present invention for achieving the above purpose, an environmental information collection and analysis system utilizing an assembled sensing device includes an information collection unit that collects sensing information for each device from a plurality of assembled sensing devices through a network, an information authentication unit that authenticates device information transmitted from one of the plurality of assembled sensing devices through a customer terminal, a list generation unit that generates a service target list by mapping target sensing information measured through one of the assembled sensing devices and customer information upon authenticating the device information, an information service unit that provides the target sensing information to the customer terminal in real time through an environmental management service based on the service target list, and an integrated service unit that provides a video connection between one of the previously registered shared terminals and the customer terminal through the environmental management service based on a customer environmental state evaluated according to the target sensing information.

In order to achieve the above object, according to another embodiment of the present invention, an environmental information collection and analysis system utilizing an assembled sensing device comprises an assembled sensing device in which at least one sensor module, a control module, and an air circulation module are formed to be detachably attached to each other in an assembled manner, a customer terminal connected to the assembled sensing device through short-range communication, an integrated management server for relaying sensing information measured through the at least one sensor module to the customer terminal in real time through an environmental management service by authenticating device information transmitted from the assembled sensing device through the customer terminal, and one sharing terminal for sharing the sensing information through the environmental management service, wherein the integrated management server provides a location providing unit for arranging in distance order public institution locations corresponding to non-polluted areas identified in an environmental status map output based on the location information when location information collected from the customer terminal is identified as a polluted area, a customized route guide unit for guiding a customized route corresponding to a minimum number of polluted areas among a plurality of routes searched according to a destination keyword input from the customer terminal through the environmental status map, and the It includes a page linking unit that generates a pollution level comparison statistical graph page based on a pair of location information selected through the environmental status map from a customer terminal and links it to the environmental status map.

According to an embodiment of the present invention, by selectively providing a video connection between a shared terminal and a customer terminal through an environment management service based on the customer environment status, a service can be provided that enables more efficient identification and response to risk situations according to the customer environment status.

FIG. 1 is a diagram schematically showing an environmental information collection and analysis system (1000) utilizing an assembled sensing device (100) according to one embodiment of the present invention.
FIG. 2 is an example for specifically explaining the assembled sensing device (e.g., 100_1) of FIG. 1.
Figure 3 shows examples of environmental management services.
Figure 4 is a block diagram specifically explaining the integrated service unit (250) of Figure 1.
Figure 5 is a block diagram specifically explaining the service management unit (254) of Figure 4.
Figure 6 is a block diagram specifically explaining the information service unit (240) of Figure 1.

Hereinafter, the present invention will be described in detail with reference to examples and drawings of the present invention. It will be apparent to those skilled in the art that these examples are presented only as examples to more specifically explain the present invention, and that the scope of the present invention is not limited by these examples.

Additionally, unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, and in case of conflict, the description in this specification, including definitions, shall prevail.

In order to clearly explain the invention proposed in the drawings, parts that are not related to the description have been omitted, and similar parts have been given similar drawing reference numerals throughout the specification. In addition, when a part is said to "include" a certain component, this does not mean that other components are excluded, but rather that other components can be further included, unless otherwise specifically stated. In addition, a "part" described in the specification means a single unit or block that performs a specific function.

In each step, the collection code (1st, 2nd, etc.) is used for convenience of explanation, and the collection code does not explain the order of each step, and each step may be performed in a different order than the stated order unless the context clearly indicates a specific order. That is, each step may be performed in the same order as the stated order, may be performed substantially simultaneously, or may be performed in the opposite order.

FIG. 1 is a diagram schematically showing an environmental information collection and analysis system (1000) using an assembled sensing device (100) according to one embodiment of the present invention, FIG. 2 is an example for specifically explaining the assembled sensing device (e.g., 100_1) of FIG. 1, and FIG. 3 is an example for showing an environmental management service.

Referring to FIGS. 1 to 3, an environmental information collection and analysis system (1000) utilizing an assembled sensing device may include a plurality of assembled sensing devices (100_1 to 100_N), a customer terminal (10), and an integrated management server (200).

First, each of the plurality of assembled sensing devices (100_1 to 100_N) can be formed such that at least one sensing module (110_1 to 110_N), a control module (120), and an air circulation module (130) can be detachably attached to each other in an assembled manner, as illustrated in FIG. 2a.

These multiple assembled sensing devices (100_1 to 100_N) can measure each sensing information and transmit it to the integrated management server (200) through the network. Here, the sensing information can include at least one of noise, sunlight, volatile organic compounds, formaldehyde, fine dust, and ultrafine dust.

Specifically, each sensing module (110_1 to 110_N) may be formed so that one side can be fit-coupled to the coupling area of the control module (120), and the other side may be formed so as to correspond to the shape of the coupling area of the control module (120).

At least one of these sensing modules (110_1 to 110_N) can be vertically stacked in multiple layers by being interlocked with each other.

For example, at least one sensing module (110_1 to 110_N) may mean a sensor group in which each sensor is vertically stacked in multiple layers.

Additionally, each sensing module (110_1 to 110_N) may have an air passage formed along the central axis through which air passes.

In addition, the control module (120) can control the output of the environmental status color for each sensor through each LED terminal (not shown) provided in each sensing module (110_1 to 110_N) based on the measured values for each module as power is supplied to each sensing module (110_1 to 110_N).

According to an embodiment, the control module (120) may further include a sensing module for measuring temperature, humidity, and carbon dioxide therein, as illustrated in FIG. 2b.

This control module (120) can sequentially perform the measurement mode and the transmission mode.

Here, the measurement mode may be an operation mode that integrates the measurement values of each sensor measured during a preset measurement period into one sensing data, and the transmission mode may be an operation mode that encrypts the corresponding one sensing data during a preset transmission period and wirelessly transmits it to the integrated management server.

Additionally, the air circulation module (130) can be arranged to be detachably coupled at the top of at least one sensing module (110_1 to 110_N).

This air circulation module (130) has a circulation fan inside and may have multiple perforated holes formed on the upper surface.

According to an embodiment, the control module (120) can rotate the circulation fan of the air circulation module (130) in a first direction in the measurement mode, and can rotate the circulation fan of the air circulation module (130) in a second direction in the transmission mode.

Here, the first and second directions may be directions that rotate in opposite directions to each other.

That is, the control module (120) can refresh the air flowing into at least one sensing module (110_1 to 110_N) by changing the rotation direction of the circulation fan of the air circulation module (130) in the transmission mode and the measurement mode.

Next, the customer terminal (10) can be connected to one of the assembled sensing devices (e.g., 100_1) among the plurality of assembled sensing devices (100_1 to 100_N) via short-range communication and receive device information and sensing information.

Here, device information may include model number, product number, and certification number.

Meanwhile, the customer terminal (10) can automatically share target sensing information transmitted from one assembled sensing device (e.g., 100_1) to at least one pre-registered shared terminal (11_1 to 11_N) through the environmental management service provided to the integrated management server (200).

The integrated management server (200) according to the embodiment may include an information collection unit (210), a device authentication unit (220), a list generation unit (230), an information service unit (240), and an integrated service unit (250).

First, the information collection unit (210) can collect sensing information for each device from multiple assembled sensing devices (100_1 to 100_N) through a network and store it in a storage DB (500).

Next, the device authentication unit (220) can authenticate device information transmitted through the customer terminal (10) from one of the assembled sensing devices (e.g., 100_1) among the plurality of assembled sensing devices (100_1 to 100_N).

Here, device information may include model number, product number, and certification number.

Next, the list generation unit (230) can generate a service target list by mapping target sensing information measured through one assembled sensing device (e.g., 100_1) and customer information as device information is authenticated.

Next, the information service department (240) can provide target sensing information to the customer terminal (10) in real time through the environmental management service based on the service target list.

Here, the environmental management service is provided as an app or program installed on each of a plurality of customer terminals and one shared terminal (11_1 to 11_N) through a web server, as illustrated in Fig. 3, and can provide different services depending on the member information entered from each terminal.

Next, at step S150, the integrated service department (250) can selectively provide a video connection between a customer terminal (10) and one of the previously registered shared terminals (11_1 to 11_N) through the environment management service based on the customer environment status evaluated according to the target sensing information.

Here, any one of the pre-registered shared terminals (11_1 to 11_N) may be a terminal possessed by a guardian or child of a customer possessing a customer terminal (10).

For example, if the customer environment status evaluated based on target sensing information is in a dangerous state, the integrated service department (250) can provide a video connection service between any one of the pre-registered shared terminals (11_1 to 11_N) and the customer terminal (10).

Meanwhile, if the customer environment status evaluated based on the target sensing information is normal or good, the integrated service department (250) can share the target sensing information with any one of the previously registered shared terminals (11_1 to 11_N) through the environment management service.

According to one embodiment, the integrated service department (250) can individually provide an environmental status map and a pollution level comparison template based on payment details processed through an environmental management service from a customer terminal (10) and one of the previously registered shared terminals (11_1 to 11_N).

Here, the environmental status map may be a menu tool that enables searching for environmental status by location, and the pollution level comparison template may be a menu tool that provides a pollution level comparison analysis graph by location.

According to another embodiment, the integrated service department (250) can use a preset artificial intelligence-based location-specific ventilation diagnosis model to predict whether there is a possibility of improving the environmental condition for location-specific ventilation information and provide the service to the customer terminal (10) through an environmental management service.

Here, location-specific ventilation information may include location information, number of ventilations, and ventilation time.

At this time, the preset artificial intelligence-based location-specific ventilation diagnosis model may be an artificial neural network algorithm that is modeled by learning through machine learning that inputs location-specific ventilation information and outputs whether the location-specific environmental condition has improved as confirmed through an environmental condition map.

This location-specific ventilation diagnosis model can output an output probability value corresponding to whether or not the environmental condition of each location has changed by applying location-specific ventilation information received through an environmental management service from a customer terminal (10) to the location-specific ventilation diagnosis model.

Hereinafter, the configuration of the present invention and the effects thereof will be described in more detail through specific examples and comparative examples. However, these examples are intended to explain the present invention more specifically, and the scope of the present invention is not limited to these examples.

Figure 4 is a block diagram specifically explaining the integrated service unit (250) of Figure 1.

Referring to FIG. 1 and FIG. 4, the integrated service department (250) may include a condition assessment department (251), a calculation department (252), an emergency decision department (253), and a service management department (254).

First, the condition evaluation unit (251) can evaluate the customer environment condition for each specific item based on the comparison results between the sensor-specific measurement data extracted from the target sensing information and the standard value range.

Here, the reference value may be an average value for each sensing information collected through the storage DB (500) from multiple assembled sensing devices (100_1 to 100_N).

At this time, the customer environment status for each specific item may be status information indicating the environmental status for noise, sunlight, volatile organic compounds, formaldehyde, and fine dust as one of good, normal, and dangerous conditions.

For example, if the first sensor measurement data exceeds the reference value range, the condition evaluation unit (211) can evaluate the first sensor environmental condition as a dangerous condition. In addition, if the second sensor measurement data is within the reference value range, the condition evaluation unit (211) can evaluate the second sensor environmental condition as a normal condition. In addition, if the third sensor measurement data is below the reference value range, the condition evaluation unit (211) can evaluate the third sensor environmental condition as a good condition.

Then, the output unit (252) can calculate the integrated status judgment value by calculating the measurement data for each sensor using a preset arithmetic formula.

At this time, the emergency judgment unit (253) can determine whether or not an assembled sensing device (e.g., 100_1) is subject to emergency ventilation based on the customer environment status and integrated status judgment value for each specific item.

For example, if at least two customer environment conditions among the customer environment conditions for each specific item are dangerous and the integrated condition judgment value is higher than a preset value, the emergency judgment unit (253) can determine that one assembled sensing device (e.g., 100_1) is subject to emergency ventilation.

Then, the service management unit (254) can provide a service to transmit a ventilation warning alarm message to any one of the pre-registered shared terminals (11_1 to 11_N) and the customer terminal (10) through the environmental management service based on the result of determining whether or not an assembled sensing device (e.g., 100_1) is a target for emergency ventilation.

According to one embodiment, the service management unit (254) can remotely adjust the output intensity of an alarm alarm for one assembled sensing device (e.g., 100_1) based on a change value for target sensing information measured through one assembled sensing device (e.g., 100_1) by transmitting a ventilation alarm alarm message.

According to another embodiment, when any one of the customer environment conditions for each specific item remains in a dangerous state for a preset cumulative period of time, the service management unit (254) may transmit an evacuation guidance message based on a bio-signal transmitted upon request to the customer terminal through the environment management service.

Here, the bio-signals may include respiration and heart rate signals measured through a radar sensor equipped in the customer terminal (10) and movement activity signals measured through an acceleration sensor equipped in the customer terminal (10).

Figure 5 is a block diagram specifically explaining the service management unit (254) of Figure 4.

Referring to FIGS. 4 and 5, the service management unit (254) may include an image request unit (254_1), an object detection unit (254_2), an assembly diagnosis unit (254_3), and a module diagnosis unit (254_4).

First, the image request unit (254_1) can request upload of a sensing device image to the customer terminal (10) through the environmental management service by checking the number of measurement sensors from the measurement data for each sensor.

Next, the object detection unit (254_2) can detect a device object of a preset shape from a sensing device image uploaded through an environmental management service from a customer terminal (10).

Next, the assembly diagnosis unit (254_3) can diagnose the assembly status of one assembled sensing device (e.g., 100_1) as either a normal state or an abnormal state based on the output probability value derived by applying the device object to an artificial intelligence-based assembly status diagnosis model.

Here, the AI-based assembly status diagnosis model may be an artificial neural network algorithm derived by learning the collected sensing device images and assembly status information for each image through machine learning.

Next, the module diagnostic unit (254_4) can diagnose whether there is a sensing failure based on the difference between the number of sensor objects counted in the device object and the number of measurement sensors when the assembly status is diagnosed as normal.

For example, if the number of sensor objects and the number of measurement targets are different, the module diagnosis unit (254_4) can diagnose the sensing status of at least one sensor module (110_1 to 110_N) as a faulty state. On the other hand, if the number of sensor objects and the number of measurement targets are the same, the module diagnosis unit (254_4) can diagnose the sensing status of at least one sensor module (110_1 to 110_N) as a normal state.

According to one embodiment, when the assembly status is diagnosed as abnormal, the module diagnostic unit (254_4) can provide a sensing device assembly guide image to the customer terminal (10) through the environmental management service.

According to another embodiment, the module diagnostic unit (254_4) may selectively provide a video consultation service between the customer terminal (10) and the responsible employee terminal (not shown) based on the test results for presence of a sensing failure.

Figure 6 is a block diagram specifically explaining the information service unit (240) of Figure 1.

Referring to FIGS. 1 to 6, the information service unit (240) may include a location provision unit (241), a customized route guide unit (242), and a page linking unit (243).

First, if the location information collected from the customer terminal (10) is confirmed to be a polluted area, the location provider (241) can provide public institution locations corresponding to non-polluted areas confirmed in the environmental status map output based on the location information transmitted from the customer terminal (10) in order of distance.

Next, the customized route guide unit (242) can guide the customized route with the minimum number of polluted areas among multiple routes searched based on the destination keyword input through the environmental status map from the customer terminal (10).

According to an embodiment, the customized path guide unit (255_2) can provide a real-time service of a non-polluting path between the first and second location information to the customer terminal (10) and at least one shared terminal (11_1 to 11_N) through the environmental management service based on the first location information collected from one shared terminal (11_1 to 11_N) through the environmental management service and the second location information collected from the customer terminal (10).

Next, the page linking unit (243) can generate a pollution level comparison statistics graph page based on a pair of location information selected through the environmental status map from the customer terminal (10) and link it to the environmental status map.

Although this specification describes only a few examples among various embodiments implemented by the inventors of the present invention, the technical idea of the present invention is not limited or restricted thereto, and can be modified and implemented in various ways by those skilled in the art.

10: Customer terminal
11_1~11_N: Shared terminal
100_1~100_N: Multiple assembled sensing devices
200: Integrated Management Server
210: Information Collection Department
220: Device Authentication Section
230: List generation section
240: Information Services Department
250: Integrated Services Department
1000: Environmental information collection and analysis system using assembled sensing devices

Claims (7)

An information collection unit that collects sensing information for each device from multiple assembled sensing devices through a network;
An information authentication unit that authenticates device information transmitted through a customer terminal from one of the plurality of assembled sensing devices;
A list generation unit that generates a service target list by mapping target sensing information measured through any one of the assembled sensing devices and customer information upon authenticating the above device information;
An information service department that provides the target sensing information in real time to the customer terminal through an environmental management service based on the above service target list; and
An environmental information collection and analysis system utilizing an assembled sensing device, including an integrated service unit that provides a video connection between a shared terminal registered through the environmental management service and the customer terminal based on the customer environmental status evaluated according to the target sensing information. In the first paragraph,
The above integrated service department uses a pre-established artificial intelligence-based location-specific ventilation diagnosis model to predict whether environmental conditions can be improved for location-specific ventilation information and provides environmental management services to customer terminals.
The above location-specific ventilation information includes location information, ventilation frequency, and ventilation time input from the customer terminal through the environmental management service.
The above-mentioned artificial intelligence-based location-specific ventilation diagnosis model is an environmental information collection and analysis system using an assembled sensing device, which is an artificial neural network algorithm that is modeled by learning through machine learning that inputs the location-specific ventilation information and outputs whether the location-specific environmental condition has improved as confirmed through an environmental condition map. In the first paragraph,
The above integrated service department includes a condition evaluation department that evaluates the customer environment condition for each specific item based on the comparison results between the sensor-specific measurement data extracted from the target sensing information and the standard value range; and
A calculation unit that calculates the integrated status judgment value by calculating the measurement data for each sensor using a preset arithmetic formula;
An emergency judgment unit that determines whether an assembled sensing device is subject to emergency ventilation based on the customer environment status for each of the above specific items and the integrated status judgment value; and
An environmental information collection and analysis system utilizing an assembled sensing device, including a service management unit that provides a service to transmit a ventilation warning alarm message to one of the shared terminals and the customer terminal registered through the environmental management service based on the result of determining whether or not one of the assembled sensing devices above is a target for emergency ventilation. In the third paragraph,
The above service management unit confirms the number of measurement sensors from the measurement data for each sensor, and requests an image request unit to upload a sensing device image to the customer terminal through the environmental management service;
An object detection unit that detects a device object of a preset shape from the sensing device image uploaded through the environmental management service from the customer terminal;
An assembly diagnosis unit that diagnoses the assembly status of any one of the assembled sensing devices as either a normal state or an abnormal state based on an output probability value derived by applying the above device object to an artificial intelligence-based assembly status diagnosis model; and
An environmental information collection and analysis system utilizing an assembled sensing device, comprising a module diagnostic unit that diagnoses whether there is a sensing failure based on the difference between the number of sensor objects counted in the device object and the number of measurement sensors when the above assembly state is diagnosed as normal. In paragraph 4,
The above module diagnostic unit provides the sensing device assembly guide video to the customer terminal through the environmental management service when the above assembly status is diagnosed as abnormal.
An environmental information collection and analysis system utilizing an assembled sensing device that selectively provides a video consultation service between the customer terminal and the employee terminal based on the test results for the presence or absence of the sensing failure. In the first paragraph,
Each of the above plurality of assembled sensing devices is formed such that at least one sensor module, a control module, and an air circulation module are detachably attached to each other in an assembled manner.
The above air circulation module is placed at the top of at least one sensing module, has a circulation fan inside, and has a plurality of perforated holes formed on the upper surface.
The above control module sequentially performs measurement mode and transmission mode,
The above measurement mode is an operation mode that integrates the measurement values for each sensor measured during a preset measurement period into one sensing data.
The above transmission mode is an operation mode that encrypts a single sensing data and transmits it wirelessly to the integrated management server during a preset transmission period.
The above control module rotates the circulation fan of the air circulation module in the first direction in the above measurement mode,
An environmental information collection and analysis system utilizing an assembled sensing device that rotates the circulation fan of the air circulation module in a second direction in the above transmission mode. An assembled sensing device in which at least one sensor module, a control module, and an air circulation module are formed to be detachably attached to each other in an assembled manner;
A customer terminal connected via short-range communication from the above assembled sensing device;
An integrated management server that authenticates device information transmitted from the assembled sensing device through the customer terminal and relays sensing information measured through at least one sensor module to the customer terminal in real time through an environmental management service; and
Including one shared terminal that shares the above sensing information through the above environmental management service,
The above integrated management server
If the location information collected from the customer terminal above is confirmed to be a polluted area, a location provision section provides public institution locations corresponding to non-polluted areas sorted in order of distance on an environmental status map output based on the location information;
A customized route guide unit that guides a customized route with the minimum number of polluted areas among multiple routes searched based on a destination keyword input from the customer terminal through the environmental status map; and
An environmental information collection and analysis system utilizing an assembled sensing device, comprising a page linking unit that generates a pollution level comparison statistical graph page based on a pair of location information selected through the environmental status map from the customer terminal and links it to the environmental status map.