CN115235423A - Existing house safety monitoring terminal and system based on Internet of things - Google Patents

Abstract

The invention provides an existing house safety monitoring terminal based on the Internet of things, which comprises: the house information detection module is used for acquiring information related to the life of a house; the power supply module is used for supplying power to the existing house safety monitoring terminal; the control module is used for acquiring and analyzing the information acquired by the house information detection module; the communication module is used for communicating with the cloud platform. The invention provides an existing house safety monitoring terminal and a cloud platform for carrying out cloud computing analysis, the internet of things technology is used as a transmission medium, new energy such as solar energy is used as a power source, and the intelligent house safety monitoring terminal has the advantages of advanced modular design, flexible iteration, low cost, low installation, low maintenance and the like.

Description

Existing house safety monitoring terminal and system based on Internet of things

Technical Field

The invention relates to a house safety monitoring terminal, in particular to an existing house safety monitoring terminal based on the Internet of things, and belongs to the fields of Internet technologies, communication technologies, data processing technologies, cloud storage technologies, platform application technologies and the like.

Background

After the house is built for many years, the house sinks and inclines due to reasons such as foundations and the like, so that the house is dangerous to use. In order to ensure the use safety of the house, a house safety monitoring terminal needs to be installed on the house, but the traditional house safety monitoring terminal has the following disadvantages: (1) The adoption of electric detection equipment requires the installation of a fixed power supply circuit, so that the installation difficulty is high; (2) A fixed wired broadband line or wireless WIFI is adopted for communication, and a wired broadband line needs to be applied for each detection part, so that the network architecture is complex, and the early cost is high; (3) A fixed power supply is adopted for supplying power, and a power supply needs to be applied to a property or a power supply office; (4) The integrated design, which develops independent equipment aiming at each detection requirement, has poor standard; (5) The technical route takes the solution of the current detection requirement as a starting point and is only used as a simple tool of an engineering reinforcement company; (6) In the installation aspect, besides the sensor, fixed communication and power supply circuits need to be installed, so that a large amount of approval and installation workload is involved, and the installation difficulty is high; (7) purchasing cost aspect: the method has no rapid large-scale capability, and the cost reduction space is limited; (8) operation cost aspect: the method has the advantages that the factors limited by the outside are more, the engineering reinforcement company is used to operate in a project mode, the marginal cost is higher, the method can be popularized in a short period, but the cost for large-scale popularization in the future is higher, and the flexibility and convenience of a cloud platform are lacked

Disclosure of Invention

The invention provides an existing house safety monitoring terminal and system based on the Internet of things, and aims to reduce the installation difficulty and the use difficulty of the house safety monitoring terminal.

The invention provides an existing house safety monitoring terminal based on the Internet of things, which comprises:

the house information detection module is used for acquiring information related to the life of a house;

the power supply module is used for supplying power to the existing house safety monitoring terminal;

the control module is used for acquiring and analyzing the information acquired by the house information detection module;

the communication module is used for communicating with the cloud platform.

Furthermore, the existing house safety monitoring terminal also comprises a solar receiving panel, an interface module and a solar lithium battery management module, wherein the power supply module comprises a lithium iron phosphate storage battery; the solar receiving panel is used for performing photoelectric conversion, and the control module is connected with the solar receiving panel through the interface module; the solar lithium battery management module is used for managing the lithium iron phosphate storage battery.

Further, the communication module is one of a 4G NB-IOT communication module or a 5G communication module of the Internet of things.

Further, the house information detection module at least comprises one of an inclination sensor module, a settlement sensor module and a displacement sensor module.

In another aspect of the present invention, the system of the existing house security monitoring terminal is applied, the system includes a cloud platform, the cloud platform is in communication connection with the existing house security monitoring terminal, and the cloud platform includes:

the visual map scene module is used for acquiring the information of the house where the existing house safety monitoring terminal is located and displaying a visual map;

the safety evaluation module is used for acquiring the information detected by the house information detection module and carrying out safety evaluation;

the early warning decision-making module carries out early warning analysis according to the safety evaluation result of the safety evaluation module and issues an early warning notice;

and the information issuing module is used for sending an early warning notice to the user terminal.

Further, the cloud platform is provided with a single-layer or multi-layer house subprogram and a high-rise house subprogram, and is further provided with a program selection process, wherein the program selection process comprises the following steps:

s101, house information is obtained, wherein the house information at least comprises one of the total height of a house and the number of house floors;

s102, matching with a preset threshold value, and if the preset threshold value is not exceeded, performing early warning analysis on the house by adopting a single-layer or multi-layer house subprogram; and if the preset threshold value is exceeded, early warning analysis is carried out on the house by adopting a high-rise house subprogram.

Still further, the single or multi-floor house subroutine includes:

s201, determining whether the current house is cracked;

s202, if the house is cracked and the current house is a single-layer house, judging the inclination rate of the current house;

if the current inclination rate of the house is greater than a threshold value a1, setting the house as a red early warning;

if the current inclination rate of the house is greater than a threshold value a2, setting the house as an orange early warning;

if the inclination rate of the current house is greater than a threshold value a3, setting the current house as a yellow early warning;

if the inclination rate of the current house is greater than a threshold value a4, setting the current house as a blue early warning;

s203, if the house is cracked and the current house is a multi-layer house, judging the inclination rate of the current house;

if the current inclination rate of the house is larger than the threshold b1, setting the house as a red early warning;

if the current inclination rate of the house is greater than the threshold b2, setting the house as an orange early warning;

if the current inclination rate of the house is greater than the threshold b3, setting the house as a yellow early warning;

if the current inclination rate of the house is greater than the threshold b4, setting the current inclination rate as a blue early warning;

s204, if the house is not cracked and the current house is a multi-storey house, judging the inclination rate of the current house;

if the current inclination rate of the house is larger than the threshold value c1, setting the house as a red early warning;

if the current inclination rate of the house is greater than the threshold value c2, setting the house as an orange early warning;

if the inclination rate of the current house is greater than the threshold value c3, setting the current house as a yellow early warning;

and if the current house inclination rate is greater than the threshold c4, setting the current house inclination rate as a blue early warning.

Still further, the high-rise building subroutine includes:

s301, determining the change value of the inclination rate of the current house in unit time, and if the change value of the inclination rate exceeds a threshold value x1, setting the current house as a red early warning.

Further, the high-rise building subroutine further includes:

s302, determining whether the house is cracked, and if so, setting red warning.

Still further, the high-rise building subroutine further includes:

s303, determining the height of the current house, and if the height and the inclination rate are determined;

s304, if the height is larger than a threshold value H, judging the inclination rate of the current house;

if the current inclination rate of the house is larger than the threshold value d1, setting the house as a red early warning;

if the current inclination rate of the house is larger than the threshold value d2, setting the house as an orange early warning;

if the inclination rate of the current house is greater than the threshold value d3, setting the current house as a yellow early warning;

if the inclination rate of the current house is greater than the threshold value d4, setting the current house as a blue early warning;

s305, if the height is not greater than the threshold value H, judging the inclination rate of the current house;

if the current inclination rate of the house is larger than a threshold value e1, setting the house as a red early warning;

if the current inclination rate of the house is greater than a threshold value e2, setting the house as an orange early warning;

if the current inclination rate of the house is greater than a threshold value e3, setting the house as a yellow early warning;

and if the current house inclination rate is greater than the threshold e4, setting the current house inclination rate as a blue early warning.

Compared with the prior art, the invention provides the existing house safety monitoring terminal and the cloud platform for carrying out cloud computing analysis, takes the internet of things technology as a transmission medium, takes new energy such as solar energy and the like as a power source, and has the advantages of advanced modular design, flexible iteration, low cost, low installation, low maintenance and the like. Meanwhile, the monitoring result is analyzed professionally by the cloud platform, the scientificity of the analysis result is guaranteed to a great extent, and the owner can inquire the safety parameters of the building in real time through mobile terminal equipment of the mobile phone to obtain the corresponding safety rating.

Drawings

FIG. 1 is a diagram of a building security monitoring architecture and hierarchy;

FIG. 2 is a general system framework diagram of the existing house security monitoring terminal and the monitoring terminal of the cloud platform;

FIG. 3 is a diagram of a dynamic algorithm main program;

FIG. 4 is a diagram of a dynamic algorithm single or multi-floor house subroutine;

FIG. 5 is a diagram of a dynamic algorithm high-level house subroutine;

fig. 6 is a diagram showing the frequency setting (time/time) of terminal data reporting.

Detailed Description

In order to make the technical solutions of the present invention better understood by those skilled in the art, the technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments.

The embodiment of the invention discloses an existing house safety monitoring terminal based on the Internet of things, which comprises the following components:

the house information detection module is used for acquiring information related to the life of a house;

the power supply module is used for supplying power to the existing house safety monitoring terminal;

the control module is used for acquiring and analyzing the information acquired by the house information detection module;

the communication module is used for communicating with the cloud platform.

Wherein the information related to the house life relates to a house sinking situation, a house tilting situation, a house cracking situation, etc. The control module is an MCU module, and the house information detection module is a house inclination detection module.

Optionally, the existing house safety monitoring terminal further comprises a solar receiving panel, an interface module and a solar lithium battery management module, and the power supply module comprises a lithium iron phosphate storage battery; the solar receiving panel is used for photoelectric conversion, and the control module is connected with the solar receiving panel through the interface module; the solar lithium battery management module is used for managing the lithium iron phosphate storage battery.

Wherein, the power supply adopts a solar energy receiving plate and a lithium iron phosphate storage battery. The interface module is a detachable interface, and the control module is connected with the power supply module, the communication module and the house information detection module through the interface module.

The embodiment of the invention adopts the lithium iron phosphate storage battery and is matched with the solar receiving panel, so that the house safety monitoring terminal has an electric energy storage function, can support multi-day work in rainy days (the continuous work can be continued for 15 days by selecting the lithium iron phosphate storage battery with proper capacitance), and solves the problem that the prior art needs to have a fixed power-on circuit. Meanwhile, the embodiment of the invention enables detection, communication and power supply to be separated by the interface module in cooperation with a modular design structure, different sensors can be flexibly replaced according to field requirements during actual use, measurement of various parameters such as inclination, settlement, vibration, strain and the like is realized, different communication modules can be flexibly replaced according to field communication capacity to realize 2G/4G/5G Internet of things communication, the replaceability and the detachability are higher, and the problem that in the prior art, only integrated design is realized, independent equipment needs to be developed according to each detection requirement, and the cost is higher is solved; through the large-scale design of equipment, each functional module separable assembly, the standardization level is high, can realize large-scale production, reduces purchasing cost, has solved prior art and has not possessed quick scale ability, and the cost reduction space is limited problem. In addition, the embodiment of the invention takes the large-scale application of the smart city as a starting point, has the capabilities of flexible iteration, low cost, low installation and low maintenance, and can be quickly applied in batch in full name to form a bottom layer equipment network of the smart city.

Optionally, the communication module is one of a 4G NB-IOT internet of things communication module or a 5G internet of things communication module.

The communication module adopts a wireless 4G NB-IOT (network-based information technology) internet of things technology, can be upgraded to a 5G internet of things, realizes data transmission by using nearby telecommunication base stations, and overcomes the defects of traditional wired network transmission in the prior art.

Optionally, the house information detection module at least includes one of an inclination sensor module, a settlement sensor module, and a displacement sensor module.

In another aspect of the embodiment of the present invention, a system using the existing house security monitoring terminal includes a cloud platform, the cloud platform is in communication connection with the existing house security monitoring terminal, and the cloud platform includes:

the visual map scene module is used for acquiring the information of the house where the existing house safety monitoring terminal is located and displaying a visual map;

the cloud platform detects the inclination, settlement and displacement data of the building through the Internet of things monitoring terminal (sensors of different types), and transmits the monitoring data to the cloud platform in real time through a China telecom 4G/5G network, so that the cloud platform can fit the building condition to form a virtual three-dimensional graph, and the visual map scene display is realized.

The safety evaluation module is used for acquiring the information detected by the house information detection module and carrying out safety evaluation;

the early warning decision-making module carries out early warning analysis according to the safety evaluation result of the safety evaluation module and issues an early warning notice;

and the information release module is used for sending an early warning notice to the user terminal.

As shown in fig. 1, the system according to the embodiment of the present invention includes a data sensing layer, a platform layer, and an application layer, where the data sensing layer and the platform layer are located on an existing house security monitoring terminal, and the application layer is located on a cloud platform. The safety evaluation module and the early warning decision module of the cloud platform have big data analysis capability, and the safety situation of the houses in the urban parcel is sensed and early warning is given out as required by carrying out artificial intelligent analysis on real-time data.

The embodiment of the invention realizes cloud computing and cloud analysis by using a cloud platform technology, performs comparison analysis by case analysis to obtain a corresponding monitoring result, and sends information to mobile terminals such as owners' mobile phones through an information issuing module, thereby solving the problems of closure, flexibility and non-universality of the design in the prior art. In addition, the embodiment of the invention can realize the processing of safety evaluation, early warning and the like by adopting the safety evaluation module and the early warning decision module, and once a dangerous case occurs, the information issuing module is utilized to send information to the mobile phones of related personnel and inform the dangerous case and the measures required to be taken.

Optionally, as shown in fig. 3, the cloud platform is provided with a single-layer or multi-layer house subprogram and a high-layer house subprogram, and the cloud platform is further provided with a program selection process, where the program selection process includes:

s101, acquiring house information, wherein the house information at least comprises one of the total height of a house and the number of house floors;

s102, matching with a preset threshold value, and if the preset threshold value is not exceeded, performing early warning analysis on the house by adopting a single-layer or multi-layer house subprogram; and if the preset threshold value is exceeded, early warning analysis is carried out on the house by adopting a high-rise house subprogram.

The preset threshold value comprises a house floor number threshold value 7 and a house overall height threshold value 20m. When the house information is compared with the house floor threshold value 7 and the house total height threshold value 20m, if the house information exceeds the house floor threshold value 7 and one or two of the house total height threshold values 20m, the house is determined to be a high-rise house at the moment, and early warning analysis is performed by using a high-rise house subprogram; if the floor number threshold value 7 of the house is not exceeded, and any one of the overall height threshold values 20m of the house is judged to be a single-layer or multi-layer house at the moment, and early warning analysis is carried out by utilizing a single-layer or multi-layer house subprogram.

Specifically, as shown in fig. 4, the single-floor or multi-floor house subroutine includes:

s201, determining whether the current house is cracked;

s202, if the house is cracked and the current house is a single-layer house, judging the inclination rate of the current house;

if the current inclination rate of the house is greater than a threshold value a1, setting the house as a red early warning;

if the current inclination rate of the house is greater than a threshold value a2, an orange early warning is set;

if the inclination rate of the current house is greater than a threshold value a3, setting the current house as a yellow early warning;

if the inclination rate of the current house is greater than a threshold value a4, setting the current house as a blue early warning;

wherein a1 is more than a2 and more than a3 is more than a4, and if the inclination rate of the current house is not more than a threshold value a4, the current house is set to be green;

s203, if the house is cracked and the current house is a multi-storey house, judging the inclination rate of the current house;

if the current inclination rate of the house is greater than the threshold b1, setting the house as a red early warning;

if the current inclination rate of the house is greater than the threshold b2, setting the house as an orange early warning;

if the current inclination rate of the house is greater than the threshold b3, setting the house as a yellow early warning;

if the current inclination rate of the house is greater than the threshold b4, setting the current inclination rate as a blue early warning;

b1 is greater than b2 and greater than b3 is greater than b4, and if the inclination rate of the current house is not greater than the threshold b4, the current house is set to be green;

s204, if the house is not cracked and the current house is a multi-storey house, judging the inclination rate of the current house;

if the current inclination rate of the house is larger than the threshold value c1, setting the house as a red early warning;

if the current inclination rate of the house is larger than the threshold value c2, setting the house as an orange early warning;

if the inclination rate of the current house is greater than the threshold value c3, setting the current house as a yellow early warning;

and if the current house inclination rate is greater than the threshold c4, setting the current house inclination rate as a blue early warning.

C1 > c2 > c3 > c4, and if the inclination rate of the current house is not greater than the threshold value c4, setting the house as green; c1 > a1 > b1, c2 > a2 > b2, c3 > a3 > b3, c4 > a4 > b4.

The values of the embodiment of the invention are as follows: a1=1%; a2=0.5%; a3=0.2%; a4=0.1%; b1=2%; b2=1%; b3=0.5%; b4=0.2%; c1=3%; c2=1.5%; c3=0.7%; c4=0.3%.

According to the embodiment of the invention, the single-layer or multi-layer house subprogram can realize multi-angle and multi-level effective mark division according to the house body perfection degree (whether cracking occurs) and the house structure (single-layer or multi-layer house) and the specific inclination rate, and can determine the current house safety degree.

Specifically, as shown in fig. 5, the high-rise building subroutine includes:

s301, determining the change value of the inclination rate of the current house in unit time, and if the change value of the inclination rate exceeds a threshold value x1, setting the current house as a red early warning.

Wherein the unit time is set to be 2 months.

According to the embodiment of the invention, through carrying out artificial intelligence analysis on historical data, the geological deformation trend of the urban area is known, and the land subsidence and collapse are predicted, and the method can be possibly used as an earthquake prediction means.

Specifically, as shown in fig. 5, the high-rise building subroutine further includes:

s302, determining whether the house is cracked, and if so, setting red warning.

Specifically, as shown in fig. 5, the high-rise building subroutine further includes:

s303, determining the height of the current house, and if the height and the inclination rate are determined;

s304, if the height is larger than a threshold value H, judging the inclination rate of the current house;

wherein the threshold H is 60m.

If the current inclination rate of the house is larger than the threshold value d1, setting the house as a red early warning;

if the current inclination rate of the house is greater than the threshold value d2, setting the house as an orange early warning;

if the inclination rate of the current house is greater than the threshold value d3, setting the current house as a yellow early warning;

if the inclination rate of the current house is greater than the threshold value d4, setting the current house as a blue early warning;

s305, if the height is not larger than a threshold value H, judging the inclination rate of the current house;

if the current inclination rate of the house is greater than a threshold value e1, setting the house as a red early warning;

if the current inclination rate of the house is greater than a threshold value e2, setting the house as an orange early warning;

if the current inclination rate of the house is greater than a threshold value e3, setting the house as a yellow early warning;

and if the current house inclination rate is greater than the threshold e4, setting the current house inclination rate as a blue early warning.

Wherein d1 is greater than d2 and greater than d3 is greater than d4, and if the inclination rate of the current house is not greater than the threshold value d4, the current house is set to be green; d1 > e1, d2 > e2, d3 > e3, d4 > e4.

The values of the embodiment of the invention are as follows: d1=0.5%; d2=0.2%; d3=0.1%; d4=0.05%; e1=0.7%; e2=0.5%; e3=0.3%; e4=0.2%.

The high-rise house program provided by the embodiment of the invention can realize multi-angle and multi-stage effective mark division by matching the change of the inclination rate of the house body in a short time according to the perfect degree (whether the house body cracks) and the house structure (the specific house height) and the specific inclination rate, and determine the current house safety degree.

Finally, it should be noted that the above-mentioned embodiments are only used for illustrating the technical solutions of the present invention and not for limiting the same, and although the present invention is described in detail with reference to the above-mentioned embodiments, it should be understood by those skilled in the art that the modifications and equivalents of the specific embodiments of the present invention can be made by those skilled in the art after reading the present specification, but these modifications and variations do not depart from the scope of the claims of the present application.

Claims (10)

1. Existing house safety monitoring terminal based on thing networking, its characterized in that, existing house safety monitoring terminal includes:

the house information detection module is used for acquiring information related to the life of a house;

the power supply module is used for supplying power to the existing house safety monitoring terminal;

the control module is used for acquiring and analyzing the information acquired by the house information detection module;

the communication module is used for communicating with the cloud platform.

2. The existing house safety monitoring terminal based on the internet of things according to claim 1, characterized by further comprising a solar receiving panel, an interface module and a solar lithium battery management module, wherein the power supply module comprises a lithium iron phosphate storage battery; the solar receiving panel is used for performing photoelectric conversion, and the control module is connected with the solar receiving panel through the interface module; the solar lithium battery management module is used for managing the lithium iron phosphate storage battery.

3. The existing house safety monitoring terminal based on the internet of things of claim 1, wherein the communication module is one of a 4G NB-IOT internet of things communication module or a 5G internet of things communication module.

4. The existing house safety monitoring terminal based on the internet of things according to claim 1, wherein the house information detection module at least comprises one of an inclination sensor module, a settlement sensor module and a displacement sensor module.

5. A system using the existing house security monitoring terminal of any one of claims 1 to 6, wherein the system comprises a cloud platform, the cloud platform is in communication connection with the existing house security monitoring terminal, and the cloud platform comprises:

the visual map scene module is used for acquiring the information of the house where the existing house safety monitoring terminal is located and displaying a visual map;

the safety evaluation module is used for acquiring the information detected by the house information detection module and carrying out safety evaluation;

the early warning decision module carries out early warning analysis and issues early warning notification according to the safety evaluation result of the safety evaluation module;

and the information issuing module is used for sending an early warning notice to the user terminal.

6. The system of claim 5, wherein the cloud platform is provided with a single-story or multi-story house subprogram, a high-rise house subprogram, and a program selection process, and the program selection process comprises:

s101, house information is obtained, wherein the house information at least comprises one of the total height of a house and the number of house floors;

s102, matching with a preset threshold, and if the preset threshold is not exceeded, performing early warning analysis on the house by adopting a single-layer or multi-layer house subprogram; and if the preset threshold value is exceeded, early warning analysis is carried out on the house by adopting a high-rise house subprogram.

7. The system of claim 6, wherein the single or multi-floor house subroutine comprises:

s201, determining whether the current house is cracked;

s202, if the house is cracked and the current house is a single-layer house, judging the inclination rate of the current house;

if the current inclination rate of the house is greater than a threshold value a1, setting the house as a red early warning;

if the current inclination rate of the house is greater than a threshold value a2, setting the house as an orange early warning;

if the inclination rate of the current house is greater than a threshold value a3, setting the current house as a yellow early warning;

if the current inclination rate of the house is larger than a threshold value a4, setting the house as a blue early warning;

s203, if the house is cracked and the current house is a multi-layer house, judging the inclination rate of the current house;

if the current inclination rate of the house is greater than the threshold b1, setting the house as a red early warning;

if the current inclination rate of the house is greater than the threshold b2, setting the house as an orange early warning;

if the current inclination rate of the house is greater than the threshold b3, setting the house as a yellow early warning;

if the current inclination rate of the house is larger than the threshold b4, setting the house as a blue early warning;

s204, if the house is not cracked and the current house is a multi-storey house, judging the inclination rate of the current house;

if the current inclination rate of the house is larger than the threshold value c1, setting the house as a red early warning;

if the current inclination rate of the house is greater than the threshold value c2, setting the house as an orange early warning;

if the inclination rate of the current house is greater than the threshold value c3, setting the current house as a yellow early warning;

and if the current house inclination rate is greater than the threshold c4, setting the current house inclination rate as a blue early warning.

8. The system of claim 6, wherein the high-rise building subroutine comprises:

s301, determining the change value of the inclination rate of the current house in unit time, and if the change value of the inclination rate exceeds a threshold value x1, setting the current house as a red early warning.

9. The system of claim 8, wherein the high-rise building subroutine further comprises:

s302, determining whether the house cracks, and if so, setting the house to be red for early warning.

10. The system of claim 6, wherein the high-rise building subroutine further comprises:

s303, determining the height of the current house, and if the height and the inclination rate are determined;

s304, if the height is larger than a threshold value H, judging the inclination rate of the current house;

if the current inclination rate of the house is larger than the threshold value d1, setting the house as a red early warning;

if the current inclination rate of the house is greater than the threshold value d2, setting the house as an orange early warning;

if the inclination rate of the current house is greater than the threshold value d3, setting the current house as a yellow early warning;

if the current inclination rate of the house is larger than the threshold value d4, setting the house as a blue early warning;

s305, if the height is not greater than the threshold value H, judging the inclination rate of the current house;

if the current inclination rate of the house is greater than a threshold value e1, setting the house as a red early warning;

if the current inclination rate of the house is greater than a threshold value e2, setting the house as an orange early warning;

if the current inclination rate of the house is greater than a threshold value e3, setting the house as a yellow early warning;

and if the current house inclination rate is greater than the threshold e4, setting the current house inclination rate as a blue early warning.

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