WO2016141859A1 - Anti-drowning system, method and swimming pool, and construction method and reconstruction method of swimming pool - Google Patents

Abstract

An anti-drowning system, method and swimming pool, and a construction method and reconstruction method of a swimming pool. The system comprises: a plurality of first radio frequency identification electronic tag devices (2) with address codes indicating positions thereof in a swimming pool and distributed on the bottom of the swimming pool in an array manner; a wearable second radio frequency identification electronic tag device (3) having an exclusive identification serial number and at least including a water pressure detection sensor for judging whether to be at a drowning state, the second radio frequency identification electronic tag devices (3) separately performing radio frequency identification with the first radio frequency identification electronic tag devices (1) on the bottom of the swimming pool, and the address code of the first radio frequency identification electronic tag device (1) with the strongest radio frequency signal being used as an address code of the position of the second radio frequency identification electronic tag device (2) in the swimming pool; and at least one wireless signal acquisition device (4) performing wireless communication with the second radio frequency identification electronic tag device (3) and capable of sending the address code of the position of the second radio frequency identification electronic tag device (3) in the swimming pool to a control terminal (5).

Description

Flood prevention system, method, swimming pool, swimming pool construction method and reconstruction method Technical field

The invention relates to the technical field of security protection, and more particularly to a flood prevention safety monitoring and guarantee system based on RFID internet of things technology.

Background technique

Swimming is a traditional and popular sport, both adults and children participate in sports activities in various forms every year. In recent years, children's drowning incidents in swimming pools have been staged. In recent years, in the Shanghai area, there have been many incidents of children drowning in some relatively regular swimming pools, which not only bring great grief to the family, but also the business risk of the business unit. How to ensure the safety of children swimming, how to strengthen the protection mechanism of swimming pools is a common hot topic in society.

The current core solutions and technologies have the following core issues:

1. It is not suitable for people with dense waters: for example, the design of underwater infrared detection and judging the static time of the obstruction is not suitable for people with dense waters, and is not suitable for intelligent supervision of large-volume personnel.

2. High false positive rate: Due to the problem of the alarm algorithm, the false alarm rate of the SOS alarm signal is high, causing panic and discord on the spot, which invisibly increases the pressure and fatigue of the lifeguard. Moreover, the physical reaction mechanism at the time of the SOS event is too primitive and monotonous, and cannot be effectively detected and disposed of in time.

3, the alarm prompt is not clear and subject to real-time network and network PC server networking: the current state of the art mostly uses video surveillance or through the swimming image comparison algorithm and other means, in addition to the supervisors are easy to visual fatigue and negligence, more importantly, need to advance Conduct data collection and definitions for swimmers. Moreover, the results of image acquisition and comparison and calculation are more complicated and must be realized in real-time online operation with network PC server and CCTV monitoring system, and the reliability is poor.

4. Inaccurate position judgment: Taking spatial stereoscopic recognition as an example, there is currently an algorithm for RFID three-dimensional multi-point detection and recognition technology, which can realize coarse position determination, but is susceptible to external factors and position drift, and there is positioning. Unreliable and unreliable problems can easily mislead the lifeguard to the wrong position and lose the best rescue time. Moreover, the method adopts three-point wireless detection and recognition technology, the technology is not mature and the cost is high, and the most important thing is to install at least three card reader devices (signal angle, intensity, time difference, etc.) in the clear place. Stereo algorithm), in addition to affecting the appearance, when the water surface and underwater environment and conditions are uncertain and messy, the position of the tag signal read by the card reader has a large error and error.

Summary of the invention

The object of the present invention is to provide a flood prevention system, a method, a swimming pool, a swimming pool construction method and a reconstruction method, overcome the difficulties of the prior art, and can accurately locate the location of the drowning person in a dense water area in order to start the rescue measure in time.

According to an aspect of the invention, a water flood prevention system is provided, which is disposed in a swimming pool and includes:

a plurality of first radio frequency identification electronic tag devices, the array being arranged at the bottom of the pool, the first radio frequency identification electronic tag device having a unique identification number and an address code indicating its location in the pool;

At least one wearable second radio frequency identification electronic tag device, each of the second radio frequency identification electronic tag devices having a unique identification number and including at least one water pressure detecting sensor for determining whether it is in a hydrophobic state, the second Radio frequency identification electronic tag devices each performing radio frequency identification with the first radio frequency identification electronic tag device at the bottom of the pool, and encoding an address of the first radio frequency identification electronic tag device having the strongest radio frequency signal as the second radio frequency identification An address code of the location of the electronic tag device in the pool; and

At least one wireless signal collecting device, wherein the wireless signal collecting device wirelessly communicates with the second radio frequency identification electronic tag device, and at least addresses the location of the second radio frequency identification electronic tag device in the pool in a hydrophobic state The code is sent to a control terminal.

Preferably, the first radio frequency identification electronic tag device comprises a certain radio frequency identification electronic tag, and the second radio frequency identification electronic tag device comprises a radio frequency identification electronic tag reader.

Preferably, the first radio frequency identification electronic tag device comprises a certain radio frequency identification electronic tag reader, and the second radio frequency identification electronic tag device comprises a radio frequency identification electronic tag.

Preferably, the first radio frequency identification electronic tag device is arranged in a matrix on the bottom of the pool.

Preferably, each of said first radio frequency identification electronic tag devices is connected to said control terminal via a plurality of data lines at the bottom of said pool.

Preferably, each of the first radio frequency identification electronic tag devices further comprises a rectangular waterproof floor disposed at the bottom of the swimming pool, and the adjacent first radio frequency identification electronic tag devices are mutually spliced by the rectangular waterproof floor Positioning.

Preferably, the data line is embedded in the rectangular waterproof floor or between the rectangular waterproof floor and the bottom of the swimming pool.

Preferably, the method further includes a first wireless signal transceiver relay end and a second wireless signal transceiver relay end; each of the first radio frequency identification electronic tag devices is connected to one through a plurality of data lines at the bottom of the swimming pool a first wireless signal transceiver relay end, the control terminal is connected to the second wireless signal transceiver relay end, and the first wireless signal transceiver relay end and the second wireless signal transceiver relay The data is exchanged between the terminals through wireless communication.

Preferably, each of the first radio frequency identification electronic tag devices has an independent power source and a wireless communication module, and the first radio frequency identification electronic tag device wirelessly communicates with the wireless signal acquisition device.

Preferably, the spacing between the first radio frequency identification electronic tag devices is equal.

Preferably, the spacing of the adjacent first radio frequency identification electronic tag devices is greater than 1 meter and less than 3 meters.

Preferably, the arrangement density of the first radio frequency identification electronic tag device increases as the depth of the bottom of the pool increases.

Preferably, the first radio frequency identification electronic tag device further comprises at least one alarm device activated when a water-repellent state occurs, the alarm device being one of an LED flashing light, an alarm speaker, and a camera, the LED flashing light is vertically upward. Flashing light.

Preferably, the second radio frequency identification electronic tag device prestores at least one safety time threshold and at least one safety water pressure threshold, the water pressure detection sensor measures real-time water pressure, if the measured real-time water pressure is higher than safety If the duration of the water pressure threshold is greater than the safety time threshold, it is judged to be in a drowning state.

Preferably, when the real-time measured water pressure of the second radio frequency identification electronic tag device is zero, the duration is cleared.

Preferably, the second radio frequency identification electronic tag device further comprises at least one alarm device activated when a water-repellent state occurs, the alarm device being one of an LED flashing light, an alarm speaker, and a camera, the LED flashing light flashing .

Preferably, the second radio frequency identification electronic tag device is worn on the head or wrist of the swimmer.

Preferably, the second radio frequency identification electronic tag device has a help button forcibly determining a drowning state.

Preferably, the method further includes at least one LED beam directing device activated when the water is in a state of being connected, and the control terminal is connected by wired communication or wireless communication.

Preferably, the LED beam directing device comprises a searchlight fixture, a position adjustment decoder and a stepping motor, and the position adjustment decoder is in the pool according to the second radio frequency identification electronic tag device in a drowning state The address code of the position drives the stepping motor to adjust the illumination direction, and drives the searchlight to photograph the position in the pool corresponding to the address code.

Preferably, the alarm speaker activated when at least one of the water-repellent state is activated is further connected to the control terminal by wired communication or wireless communication.

Preferably, the wireless signal acquisition device is disposed above the swimming pool or at the bottom of the swimming pool.

According to another aspect of the present invention, there is also provided a method for preventing flooding, using the above-described water flood prevention system, comprising an acquisition step and a rescue step;

The collecting step includes: the second radio frequency identification electronic tag device worn by the swimmer and the first radio frequency identification electronic tag device at the bottom of the swimming pool respectively perform radio frequency identification, and the wireless radio frequency signal is the strongest first The address code of the RFID tag device is encoded as an address of the location of the second radio frequency identification tag device in the pool, and is determined by the water pressure detecting sensor whether it is in a drowning state, and if so, the first state in the drowning state The address code of the location of the RFID-enabled electronic tag device in the pool is sent to a control terminal, and a rescue step is performed for the pool location where the address code is located.

Preferably, the second radio frequency identification electronic tag device prestores at least one safety time threshold and at least one safety water pressure threshold, the water pressure detection sensor measures real-time water pressure, if the measured real-time water pressure is higher than safety If the duration of the water pressure threshold is greater than the safety time threshold, it is judged to be in a drowning state.

Preferably, when the real-time measured water pressure of the second radio frequency identification electronic tag device is zero, the duration is cleared.

Preferably, the rescue step comprises at least one alarm device activated by the first radio frequency identification electronic tag device, the alarm device being one of an LED flashing light, an alarm speaker, and a camera, the LED flashing light flashing vertically upwards Glowing.

Preferably, the rescue step comprises at least one alarm device activated by the second radio frequency identification electronic tag device, the alarm device being one of an LED flashing light, an alarm speaker, and a camera, the LED flashing light flashing vertically upwards Glowing.

Preferably, the rescue step includes activating an LED beam directing device, the LED beam directing device comprising a searchlight fixture, a position adjustment decoder and a stepper motor, the position adjustment decoder being in accordance with the state of being in a drowning state The address code of the position of the second radio frequency identification electronic tag device in the swimming pool drives the stepping motor to adjust the illumination direction, and drives the searchlight to photograph the position in the pool corresponding to the address code.

Preferably, the rescue step includes activating an alarm speaker.

According to another aspect of the present invention, there is also provided a flood prevention swimming pool having the above-described flood prevention system.

According to another aspect of the present invention, there is also provided a method of constructing a flood prevention swimming pool for forming a water flood prevention system as described above, comprising: constructing a swimming pool, and arranging a plurality of first radio frequency identification electronic tag device arrays arranged in the swimming pool At the bottom, the first radio frequency identification electronic tag device has a unique identification number and an address code indicating its location in the pool;

And, at least one wireless signal collecting device is disposed above the swimming pool or at the bottom of the swimming pool, and each of the first radio frequency identification electronic tag devices is connected to the control terminal through a plurality of data lines at the bottom of the swimming pool.

Preferably, each of the first radio frequency identification electronic tag devices has an independent power source and a wireless communication module, and the first radio frequency identification electronic tag device wirelessly communicates with the wireless signal acquisition device.

According to another aspect of the present invention, there is also provided a water repellent modification method for a swimming pool, comprising: forming a water repellent system as described above, comprising: arranging, in a swimming pool, a plurality of arrays of first radio frequency identification electronic tag devices arranged in a swimming pool At the bottom, the first radio frequency identification electronic tag device has a unique identification number and an address code indicating its location in the pool;

And at least one wireless signal collecting device is disposed above the swimming pool or at the bottom of the swimming pool, and each of the first radio frequency identification electronic tag devices is connected to the control terminal through a plurality of data lines at the bottom of the swimming pool, each of the The first radio frequency identification electronic tag device further includes a rectangular waterproof floor disposed at the bottom of the swimming pool, and the adjacent first radio frequency identification electronic tag devices are spliced and positioned by the rectangular waterproof floor, the data line Embedded in the rectangular waterproof floor or between the rectangular waterproof floor and the bottom of the pool.

Preferably, each of the first radio frequency identification electronic tag devices has an independent power source and a wireless communication module, and the first radio frequency identification electronic tag device wirelessly communicates with the wireless signal acquisition device.

Due to the use of the above technology, the system of the present invention has high technical content, high integration, high degree of automation, and reduced number of security administrators, thereby effectively reducing the cost of the stadium personnel. The system is accurate and accurate in complex environment. Each unit module in the system has independent and intelligent judgment and control characteristics. Through simple and humanized technology management means, it is realized in the real sense of the Internet of Things. The typical construction and application of a modern technology swimming pool with a core theme.

The greatest innovation value of the invention is safety, stability, reliability, precision and sensitivity. The invention adopts the RFID radio frequency technology combined with the network format physical positioning concept, and adopts a safe and reliable mature product technology solution to reduce the operating cost and avoid and reduce the casualties of the personnel. Therefore, the invention has high practicability and Marketing value,

The invention has the following beneficial effects:

1. Solve the problem of positional drift caused by external environmental influences, overcome the influence of environment and people, and achieve accurate positioning at any time, with an error of less than 2 square meters;

2. Solve the problem of on-site panic caused by false alarm of SOS sound and light alarm, effectively alleviate and reduce the fatigue and tension of lifeguards. Create a comfortable application experience in the swimming pool with real, effective and accurate humanized supervision and automatic silent reminder mode;

3. In the case that the system and the PC server are offline and disconnected, the complete flood control system of the present invention can complete all intelligent determination and action execution independently and independently, and get rid of the system function of the system due to various factors of the PC server. achieve. Especially in terms of response speed and response time to achieve the most ideal state;

4. When the SOS event occurs or is about to occur, the LED beam steering device installed under water and water will serve as a multi-event decision grading reminder and automatically guide the position quickly and accurately. Different event signals pass the action combination mode, stroboscopic mode, stroboscopic color of the LED light and combine with other automatic reminders such as voice and open sound and light alarms to drive the lifeguards and surrounding people to attract attention in a quiet and harmonious environment. And take correct measures and methods to find and rescue in time.

5. The first radio frequency identification electronic tag device adopts the embedded embedded installation, and does not destroy the overall visual environment of the swimming pool, thereby realizing the system function to achieve the goal.

6. Due to the originality of the design of the system, when the existing swimming pool is not modified, the first radio frequency identification electronic label device 2 and the flexible plastic wood flooring can be flexibly assembled. In combination, the plastic wood floor containing the first radio frequency identification electronic label device 2 can be laid on the bottom surface of the swimming pool without damaging the on-site environment. Quick wiring and waterproof plugs are provided at each plastic-wood floor connection for quick networking.

7. Through the wearable RFID electronic tag and the fixed end of the fixed omnidirectional wireless signal transceiver, the present invention will perform real-time supervision on all the personnel on the water and on the swimming pool for the whole process. The real-time number of people in the venue, time-sharing, automatic reminder to the clock, and automatic waiting for waiting time outside the venue, provide accurate and timely intelligent analysis and push, and achieve and meet the core requirements of the smart swimming pool.

8. Considering the extension of the card function, the wearable RFID electronic tag itself is embedded with the NFC electronic tag radio frequency IC chip, which can be used together with the electronic consumption and the proximity sensing to open the locker locker.

DRAWINGS

1 is a schematic diagram of module connection of a water flood prevention system of the present invention;

Figure 2 is a perspective view of the water repellency prevention system of the present invention;

Figure 3 is a partial enlarged view of Figure 2;

Figure 4 is a side view of the water flood prevention system of the present invention;

Figure 5 is a plan view of a swimming pool equipped with the flood prevention system of the present invention;

Figure 6 is a data line layout diagram of a swimming pool for constructing the flood prevention system of the present invention;

Figure 7 is a side view showing the water-repellent water of the swimming pool of the present invention;

Figure 8 is a partial enlarged view of Figure 7;

9 to 11 are schematic views showing an implementation process of the flood prevention system of the present invention;

Figure 12 is a side view of a second flood prevention system of the present invention;

Figure 13 is a plan view of a third flood control system incorporating the present invention;

Figure 14 is a side view of a fourth flood prevention system of the present invention;

Figure 15 is a side elevational view of a fifth flood control system of the present invention.

detailed description

A detailed description of the embodiments of the present invention will be given below. While the invention will be described and illustrated in conjunction with the specific embodiments, it should be understood that the invention On the contrary, modifications or equivalents of the invention are intended to be included within the scope of the appended claims.

In addition, numerous specific details are set forth in the Detailed Description of the invention in the Detailed Description. Those skilled in the art will appreciate that the present invention may be practiced without these specific details. In other instances, well-known structures and components have not been described in detail in order to facilitate the invention.

1 is a schematic view showing the module connection of the water flood prevention system of the present invention. Figure 2 is a perspective view of the water flood prevention system of the present invention. As shown in FIG. 1 to FIG. 2, the present invention provides a water-repellent prevention system, which is disposed in a swimming pool 1, and includes: a plurality of first radio frequency identification electronic label devices 2 arranged in the bottom of the swimming pool 1, and a wearable second radio frequency. The electronic tag device 3, the wireless signal acquisition device 4, and the control terminal 5 are identified.

The first radio frequency identification electronic tag device 2 has a unique identification number and an address code indicating its location in the pool 1. In this embodiment, each of the first radio frequency identification electronic tag devices 2 further includes at least one alarm device activated when a water-repellent state occurs, and the alarm device is one of an LED flashing light, an alarm speaker, and a camera, and the LED flashing light flashes vertically upward. Luminous, but not limited to this.

Each swimmer can be equipped with a second radio frequency identification electronic tag device 3, which can be worn by the swimmer with the head, wrist, shoulder, waist and the like. Each of the second radio frequency identification electronic tag devices 3 has a unique identification number and includes at least one water pressure detecting sensor for determining whether it is in a water-repellent state, and the second radio frequency identification electronic tag device 3 and the first radio frequency identification of the bottom of the swimming pool 1 respectively The electronic tag device 2 performs radio frequency identification, and encodes the address of the first radio frequency identification electronic tag device 2 with the strongest radio frequency signal as the address of the second radio frequency identification electronic tag device 3 in the pool 1.

In this embodiment, the first radio frequency identification electronic tag device 2 includes a certain radio frequency identification electronic tag (RFID tag), and the second radio frequency identification electronic tag device 3 includes a radio frequency identification electronic tag reader (RFID tag reader). The present invention determines the pool by sensing between a directional RFID tag and a radio frequency identification tag reader The specific location in the address can be decoded by the address encoding of the directional radio frequency identification electronic tag (RFID tag) of the strongest signal at the bottom of the pool detected by the radio frequency identification electronic tag reader (RFID tag reader) of the swimmer. The position of the RFID tag reader (RFID tag reader) in the pool is encoded and transmitted to the control terminal 5 via the wireless signal acquisition device 4 (described in detail below). But not limited to this. The layout of the directional RFID tag and the RFID tag reader may also be exchanged such that the first RFID tag device 2 includes a radio frequency identification tag reader (RFID tag reader), and the second radio frequency identification The electronic tag device 3 includes a radio frequency identification electronic tag (RFID tag). The address of the most powerful one of the signals of the directional radio frequency identification (RFID tag) accompanying the swimmer detected in the plurality of radio frequency identification electronic tag readers (RFID tag readers) at the bottom of the pool is decoded as a swimmer. In the position in the pool, the radio frequency identification electronic tag reader (RFID tag reader) transmits the address code to the control terminal 5 through the data line 6, but not limited thereto, and can also identify the electronic tag through each radio frequency. The reader (RFID tag reader) transmits the signals of the identified directional radio frequency identification electronic tag (RFID tag) to the control terminal 5, and the control terminal 5 determines that each directional radio frequency identification electronic tag (RFID tag) corresponds thereto. The RFID tag reader (RFID tag reader) that detects the strongest signal can also obtain the address code of the location where each directional RFID tag (RFID tag) is located.

Each second RFID tag device 3 prestores at least one safety time threshold and at least one safety water pressure threshold, and the water pressure detecting sensor measures the real-time water pressure, if the measured real-time water pressure is higher than the safety water pressure threshold If the duration is greater than the safe time threshold, it is judged to be in a drowning state. When the real-time measurement water pressure of the second radio frequency identification electronic tag device 3 is zero, the duration is cleared. The second radio frequency identification electronic tag device 3 further includes at least one alarm device activated when a water-repellent state occurs. The alarm device is one of an LED flashing light, an alarm speaker, and a camera, and the LED flashing light flashes. The second radio frequency identification electronic tag device 3 has a help button forcibly judging to a drowning state.

The wireless signal collecting device 4 is disposed above the swimming pool 1 or at the bottom of the swimming pool 1. In this embodiment, the wireless signal collecting device 4 is horizontally suspended at a suitable height above the swimming pool 1 to wirelessly receive data of the second radio frequency identification electronic tag device 3 worn by the swimmer. The wireless signal acquisition device 4 wirelessly communicates with the second radio frequency identification electronic tag device 3 to transmit at least the address code of the second radio frequency identification electronic tag device 3 in the pooled state to the control terminal 5.

In a preferred embodiment, the flood prevention system of the present invention may further comprise: at least one LED beam directing device 14 and an alarm speaker 15 that are activated when a hydrophobic state occurs. The LED beam directing device 14 is connected to the control terminal 5 by wired communication or wireless communication. The LED beam directing device 14 includes a searchlight fixture, a position adjustment decoder and a stepping motor. The position adjustment decoder drives the stepping according to the address of the position of the second radio frequency identification electronic tag device 3 in the pool 1 in the hydrophobic state. The motor adjusts the direction of illumination and drives the searchlight to take a picture of the location in the pool 1 corresponding to the address code. The LED beam directing device 14 can be a colorful, flashable LED light. The alarm speaker 15 is connected to the control terminal 5 by wired communication or wireless communication.

In a preferred embodiment, the flood prevention system of the present invention may further comprise: a vertical or hanging screen 17 for displaying information, a card issuer 19 for issuing an RFID electronic tag, and for managing network management of the card issuer 19 The client 18, the above device is connected to the background server 16 through an internal local area network, and the background server 16 is connected to the control terminal 5.

In a preferred embodiment, the second radio frequency identification electronic tag device 3 (e.g., a built-in pressure transmitter) determines (determined by the CPU logic control circuit) the type of event (event code) based on the measured water pressure and the combined water intake time. For example, when the water pressure measured by the second radio frequency identification electronic tag device 3 is lower than the first threshold and the duration is lower than the first time, it is determined as a normal event; when the water pressure is higher than the first threshold and the duration is lower than the first At the time of time, it is also determined as a normal event; when the water pressure is higher than the first threshold and the duration is higher than the first time, it is determined as a reminding event; when the water pressure is higher than the first threshold and the duration is higher than the second time, Determined as an alarm event; when the water pressure is higher than the second threshold, it is also determined as an alarm event.

The working principle of the embedded hydraulic pressure sensor is the potential difference, that is, the working mode is that the bridge impedance difference is converted into a pressure value, and is output to the CPU logic control circuit through the IIC digital signal, and the continuous pressure value and the continuous corresponding time relationship are Real-time event coding is generated by the CPU control circuit at different stages of the continuous process to achieve the final SOS alarm and reminder.

In a preferred embodiment, the second radio frequency identification electronic tag device 3 may include an MCU (CPU) central processing chip, a driving power control circuit, a relay input control circuit, a battery signal input and output circuit, an LED colorful LED, and a light emitting diode control circuit. , LED beam lens, 2.4G wireless microwave transceiver circuit, wireless microwave antenna, wired / wireless network communication data transmission interface. The LED colorful LEDs can display a plurality of colors and strobe effects according to different event encoding codes (described in detail below) generated from the second RFID-enabled electronic tag device 3. The second radio frequency identification electronic tag device 3 also has CPU logic control circuitry for intuitively turning on and off different LED light event color reminders based on receipt of different event codes from the second radio frequency identification electronic tag device 3.

As shown in FIG. 3, the first radio frequency identification electronic tag device 2 is partially or completely covered at the bottom of the swimming pool by uniformly distributing the mesh at the bottom of the pool, but is not limited thereto. The first radio frequency identification electronic tag device 2 is preferably a radio frequency identification electronic tag (RFID tag) because the directional radio frequency identification electronic tag (RFID tag) can enter the area mainly along a sector signal radiating area perpendicular to the bottom surface of the swimming pool. The RFID tag reader (RFID tag reader) can easily recognize the signal. Therefore, the swimmer wearing the second radio frequency identification electronic tag device 3 is located between the four first radio frequency identification electronic tag devices 2, and then the second radio frequency identification electronic tag device 3 can sense at least the radio frequency identification electronic tag 21 and the radio frequency. The signals of the electronic tag 22, the radio frequency identification electronic tag 23, and the radio frequency identification electronic tag 24 are identified. Since the position of the radio frequency identification electronic tag 21 is closest to the swimmer, the signal of the radio frequency identification electronic tag 21 sensed by the second radio frequency identification electronic tag device 3 is the strongest, and the position range of the radio frequency identification electronic tag 21 is worn. The radio frequency identification electronic tag device 3 is currently in the position of the swimmer, and even if the swimmer moves the position due to struggling after drowning, the first radio frequency identification electronic tag device 2 and the wearable second radio frequency identification electronic device of the present invention The tag device 3 can also know the location of the swimmer in time in this way according to the strongest signal location.

Figure 4 is a side elevational view of the flood protection system of the present invention. Figure 5 is a top plan view of a swimming pool incorporating the flood protection system of the present invention. As shown in FIGS. 4 and 5, the first radio frequency identification electronic tag device 2 is arranged in a matrix on the bottom of the pool 1. Every first The radio frequency identification electronic tag device 2 is connected to the control terminal 5 through a number of data lines 6 at the bottom of the pool 1. The first radio frequency identification electronic tag device 2 is mainly partially or completely covered at the bottom of the swimming pool by a uniform distribution in a square grid shape at the bottom of the pool, but is not limited thereto. The spacing between the first radio frequency identification electronic tag devices 2 is equal. The spacing of the adjacent first RFID-tagged electronic tag devices 2 is greater than 0.5 meters and less than 3 meters. Obviously, the greater the density, the higher the accuracy of positioning.

The present invention also provides a method for preventing flooding, comprising the above-mentioned water-repellent prevention system, comprising an acquisition step and a rescue step; the collecting step comprises: the first radio frequency identification electronic tag device 3 worn by the swimmer and the first radio frequency at the bottom of the swimming pool 1 Identifying the electronic tag device 2 for performing radio frequency identification, encoding the address of the first radio frequency identification electronic tag device 2 with the strongest radio frequency signal as the address of the second radio frequency identification electronic tag device 3 in the pool 1, and passing the water pressure The detecting sensor determines whether it is in a drowning state, and if so, transmits the address code of the position of the second radio frequency identification electronic tag device 3 in the pooled state to the control terminal 5, and performs a rescue step for the pool 1 position where the address code is located.

In the collecting step, the second radio frequency identification electronic tag device 3 prestores at least one safety time threshold and at least one safety water pressure threshold, and the water pressure detecting sensor measures the real-time water pressure, if the measured real-time water pressure is higher than the safety water pressure valve If the value has a duration greater than the safe time threshold, it is judged to be in a drowning state. When the real-time measurement water pressure of the second radio frequency identification electronic tag device 3 is zero, the duration is cleared.

The rescue step includes at least one alarm device activated by the first radio frequency identification electronic tag device 2. The alarm device is one of an LED flashing light, an alarm speaker, and a camera, and the LED flashing light flashes vertically upward. The second radio frequency identification electronic tag device 3 activates at least one alarm device, and the alarm device is one of an LED flashing light, an alarm speaker, and a camera, and the LED flashing light flashes vertically upward. The LED beam directing device 14 is activated. The LED beam directing device 14 includes a searchlight, a position adjustment decoder and a stepping motor. The position adjustment decoder is located in the pool 1 according to the second radio frequency identification tag device 3 in the hydrophobic state. The address code drives the stepper motor to adjust the illumination direction, and drives the searchlight to photograph the position in the pool 1 corresponding to the address code. And an alarm speaker 15 is activated.

The working principle of the LED beam directing device 14 may be: firstly, the first radio frequency identification electronic tag device 2 in the directional swimming pool has a unique position code, and when the transceiver receives the event code from the RFID electronic tag and encodes the physical code, the transceiver The location code is transmitted along with the RFID event code and coded physical code to the intelligent central controller. After being confirmed by the intelligent central controller logic as an SOS alarm event, the controller transmits the event code together with the coded address code of the transceiver to the LED beam directing lamp. The LED indicator light includes a core control circuit such as an address code decoder control circuit and a CPU logic control. The LED indicator light determines the effect of the LED light according to the received coded event code, and the address code decoder receives the corresponding coded address code of the transceiver. The servo motor is driven to rotate in the X-axis and Y-axis motion modes according to the preset position specified in advance, and the LED beam lamp is driven to stop at the target corresponding position, thereby achieving the purpose of position guidance and time reminding, thereby accurately and conspicuously Guide the lifeguards to swim quickly to the swimmers.

The present invention also provides a flood prevention swimming pool 1 having the above-described flood prevention system, which will be further described herein.

Figure 6 is a data line layout of a swimming pool in which the flood control system of the present invention is constructed. As shown in FIG. 6, the present invention also provides a method for constructing a flood prevention swimming pool, which is used for forming a water flood prevention system as described above, comprising: constructing a swimming pool 1 and arranging a plurality of first radio frequency identification electronic label devices 2 in an array arrangement At the bottom of the pool 1, a positioning network was built. The first radio frequency identification electronic tag device 2 has a unique identification number and an address code indicating its location in the pool 1. And, at least one wireless signal collecting device 4 is disposed above the swimming pool 1 or at the bottom of the swimming pool 1, and each of the first radio frequency identification electronic tag devices 2 is connected to the control terminal 5 through a plurality of waterproof data lines 6 at the bottom of the swimming pool 1. In order to match the position of the first radio frequency identification electronic tag device 2, the data lines 6 at the bottom of the pool 1 may also be formed in a grid shape.

For example, the first radio frequency identification electronic tag device 2 for positioning is to embed the data cable 6 waterproof data cable 6 into the bottom surface of the swimming pool in advance when the swimming pool is under construction, and the overall consistency and coordination are stronger in appearance. Beautiful. The method is to bury the data line 6 and the wire trough in the underground when the tile at the bottom of the swimming pool is pasted. After the tile is pasted, the tile above the 6 boxes of the waterproof data cable embedded in the underground will be leaked, so as to be Secondary in-line installation of related electronic equipment. After the first radio frequency identification electronic tag device 2 device is installed in the underground pipe box, the upper cover with the glass lens is fastened and locked, and so on, all the first radio frequency identification electronic tag devices 2 that complete the positioning network assembly are completed. installation. The method can be applied to the renovation of a new swimming pool or an old building, and the tube, the line and the box are buried in the ground in advance to achieve uniformity and uniformity.

Fig. 7 is a side elevational view showing the water repellent of the swimming pool of the present invention. Figure 8 is a partial enlarged view of Figure 7. As shown in FIG. 7 and FIG. 8 , the present invention further provides a water repellent water remodeling method for a swimming pool, which is used for forming the above-mentioned anti-smashing water system, comprising: in a swimming pool 1 , a plurality of arrays of first radio frequency identification electronic tag devices 2 are arranged At the bottom of the pool 1, the first radio frequency identification tag device 2 has a unique identification number and an address code indicating its location in the pool 1. And, at least one wireless signal collecting device 4 is disposed above the swimming pool 1 or the bottom of the swimming pool 1, and each of the first radio frequency identification electronic tag devices 2 is connected to the control terminal 5 through a plurality of data lines 6 at the bottom of the swimming pool 1, each first The radio frequency identification electronic tag device 2 further includes a rectangular waterproof floor 7 disposed at the bottom of the swimming pool 1, and the adjacent first radio frequency identification electronic tag devices 2 are spliced and positioned by a rectangular waterproof floor 7, and the data line 6 is embedded in the rectangular waterproof Inside the floor 7, or between the rectangular waterproof floor 7 and the bottom of the pool 1.

For example, in order to quickly establish a positioning network without destroying the underside of the original swimming pool. The first radio frequency identification electronic label device 2 is embedded in the inner plywood of the rectangular waterproof floor 7 (plastic wood floor), and then the plastic wood floor is laid on the bottom of the swimming pool in the form of laying the floor, and the plastic wood floor is formed by splicing a plurality of floor units. The upward facing side of the floor unit is provided with an LED glass lens for enabling the light beam of the LED lamp of the first radio frequency identification electronic label device 2 to be emitted, the floor unit having a waterproof joint, the signal data line of the first radio frequency identification electronic label device 2 and The power source is led out via a waterproof connector, in a waterproof connector that is connected to another floor unit, in such a manner that a plurality of first radio frequency identification tag devices 2 are connected in series, wherein the signal data cable is sheathed in the waterproof connector.

Figure 8 shows a cross-sectional view of the spliced plastic-wood floor panel in which the first radio frequency identification electronic tag device 2 is arranged, There are two spliced plastic wood floor units, and the left side of the floor unit has grooves on the left and right sides. Accordingly, the right side of the floor unit has bumps on the left and right sides, and the bumps are used for inserting into the grooves. To stitch together. Of course, for a floor unit, it is also possible to have a groove on one side and a bump on one side. In each of the floor units, a first radio frequency identification electronic tag device 2 is disposed as an example of the floor unit, and an LED glass lens is disposed on an upward side of the floor unit for causing the LED of the first radio frequency identification electronic tag device 2 The beam of light can be emitted. The floor unit has a waterproof joint, and the data line 6 of the first radio frequency identification electronic label device 2 is taken out via a waterproof joint and electrically connected to the waterproof joint of the floor unit, so that the first radio frequency identification electronic label device 2 is connected in series.

The first radio frequency identification electronic tag device 2 is networked in a grid manner, and is usually a local detection identification block in a square of 2M*2M or 3M*3M (which may of course also be a rectangle or a diamond shape, etc.). Accurate positioning of the target object can be performed according to the transceiver encoding of the first radio frequency identification electronic tag device 2. By adjusting the signal gain strength of each of the first radio frequency identification electronic tag devices 2, each of the first radio frequency identification electronic tag devices 2 can ensure an optimal local signal detection state, that is, the identification block can be effectively detected. The RFID tag signal inside. If the directional wireless transceiver 2 is laid out in other shapes, the effective identification block changes accordingly. In the case where the identification block is assumed to be square, each identification block is identified by four first radio frequency identification electronic tag devices 2 located at four vertices of the square, and the four first radio frequency identification electronic tag devices 2 can be used as one Identification unit. Each of the detectors included in each small unit will be connected to the bus through a serial connection, and finally the collected data will be aggregated to the control terminal 5, so that the present invention can convert the ordinary swimming pool to the prevention in the invention. Surabaya swimming pool.

9 to 11 are schematic views showing the implementation process of the flood prevention system of the present invention. As shown in FIGS. 9 to 11, wherein the first radio frequency identification electronic tag device 2 in the present invention is an RFID tag reader, and the second radio frequency identification electronic tag device 3 is an RFID electronic tag. When a swimmer wears an RFID tag into the pool, it is recognized by one of the identification units installed at the bottom of the pool, but the system typically does not handle normal security events. When the swimmer's head enters the water, the RFID tag sensor will start working, and the distance between the swimmer and the bottom RFID tag reader is also the most sensitive. When a swimmer enters an identification unit consisting of four RFID tag readers, the RFID tag will always be closest to one of the identified blocks and the signal is strongest (signal strength and number of receptions) Depending on the frequency), several RFID tag readers in one or a block closest to the RFID tag will have the strongest signal reception sensitivity, will determine the final precise position, and open a positioning area according to the event coding type. The opening of one or several RFID tag reader LEDs within the block. If the swimmer's head is out of the water, the pressure and time of the sensor will be zeroed, and will be activated again when the water enters the water again.

These RFID tags are worn on the head of the swimmer. The RFID electronic tag can be mounted on a swimming cap or goggle (fixed product) or in the form of a head strap embedded with an RFID tag in the form of an elastic strap. When a swimmer swims through an area in the pool, it is detected by the RFID tag reader at the bottom of the area pool. For each RFID tag that enters and passes, it will be detected by the identifier of the area to realize Accurate positioning, dynamic tracking, identification and SOS event information collection.

More specifically, when an RFID tag enters the bottom of any pool, the RFID tag reader is effectively probed. When the range is identified, the electronic tag code of the RFID tag will be recognized and recorded by the RFID tag reader. When the pressure transmitter embedded in the RFID electronic tag senses the water pressure, and the water pressure data will be combined with the length of the water into the water, the CPU logic control circuit generates different event coding types, and the CPU logic control circuit performs logic analysis on the change of time and pressure. Judging, different types of events are generated according to the result of the judgment, event codes are given to different types of events, and event codes are sent to the RFID tag reader at the bottom of the pool. At the same time, for different types of events, the LED of the directional wireless signal 2 at the bottom of the pool emits light of a corresponding color. For example, for normal events, the LED light may not light up or be displayed in green; for reminder events (such as swimming into deep water, or diving for 5 seconds), the LED light can be displayed as assuming yellow; for alarm events (eg diving) In 10 seconds, when the monitored water pressure and dive time exceed the peak value, the LED light can be displayed in red and can be flashed.

The control terminal 5 is configured to receive data of an RFID tag reader at the bottom of the pool, such as electronic tag encoding and event encoding of the RFID electronic tag. The control terminal 5 and the bottom RFID tag reader are connected by wire or wirelessly, and the wired mode is connected by, for example, an RS485 bus, and the wireless mode adopts a wired connection between the RFID tag reader at the bottom of the pool and the transceiver. Unified aggregation to the wireless signal transceiver relay end, and data exchange with the control terminal 5 through the 433M wireless mode relayed by the wireless signal transceiver relay terminal.

The control terminal 5 receives the information from the underwater RFID tag reader in real time, and determines which linkage action instruction is executed according to the different information content itself, so as to achieve the state of the fast drive linkage and the connected device being turned on and off. Preferably, the control terminal 5 performs real-time monitoring and integrated management, command release, data upload to a network PC server, etc., and then pushes client data through a network PC server, such as a human-machine interface client central control, electronic positioning map display. It displays the core functions of various types of information push, daily operation management, report statistics and summary.

In this embodiment, the safety time threshold is 10 seconds, and the safety water pressure threshold is 0.3 meters, but is not limited thereto.

As shown in FIG. 9, at this time, the swimmer floats on the water surface, and the data of the water pressure sensor in the second radio frequency identification electronic tag device 3 is substantially zero, which is a normal event. When the event is encoded as a normal event, the control terminal 5 does not activate the servo pan/tilt LED beam directing lamp 14 for linkage, that is to say, the normal encoding event intelligent central controller does not send data and related command signals like the LED pointing lamp device.

As shown in Figure 10, at this time, the swimmer dive down to 0.5 meters below the water surface and keep it for 3 seconds. At this time, the data of the water pressure sensor is 0.5 and the duration is 3 seconds, although the safety water pressure valve is exceeded. The value, but does not exceed the safe time threshold, so it is still a normal event.

As shown in FIG. 11, at this time, the swimmer is in a drowning state, and the safety time threshold and the safe water pressure threshold are both exceeded. When the event code rises to a high level reminding event, the control terminal 5 starts the linkage mechanism and goes to the servo cloud. The LED beam guiding lamp 14 sends the relevant linkage signal, and the servo pan/tilt LED beam guiding lamp 14 immediately starts and turns on the hypothetical yellow or red high-level beam to automatically project to the corresponding pool bottom wireless after receiving the first closing signal. The position of the signal transmitter 2 is such that the lifeguard can pay more attention or quickly lock the location of the possible drowning person and promptly rescue it.

Moreover, the second radio frequency identification electronic tag device 3 of the present invention can also distinguish the swimmers that are worn in advance. For example, the range of activities of the children swimmers is specifically limited to only in the shallow water area, and once the deep water area is entered, an alarm is issued, etc. I won't go into details here.

Figure 12 is a side elevational view of a second flood control system of the present invention. As shown in FIG. 12, the second flood prevention system of the present invention is different from the first flood prevention system in that the second flood prevention system is divided according to the deep water zone 1B of the swimming pool and the shallow water zone 1A, in the deep water zone. The first radio frequency identification tag device 2 is denser than the shallow water zone at the bottom of 1B. Since the usually dangerous drowning situation mainly occurs in the deep water area 1B, the densely-distributed first radio frequency identification electronic tag device 2 in the deep water area 1B can locate the drowning swimmer more accurately and timely, so as to timely implement rescue measures. Other technical features are the same as those of the first flood prevention system and will not be described here.

Figure 13 is a plan view of a third flood control system incorporating the present invention. As shown in FIG. 13, the third anti-water-repellent system of the present invention is arranged in a rectangular shape between the first radio-frequency identification electronic tag device 2 in the first anti-flooding system, and the third anti-smashing water system is in the swimming pool. At the bottom, the first radio frequency identification electronic tag device 2 is arranged in a matrix according to a triangular arrangement, and can also be positioned according to the first radio frequency identification electronic tag device 2 having the strongest signal at the three corners of the triangle. Other technical features are the same as those of the first flood prevention system and will not be described here.

Figure 14 is a side elevational view of a fourth flood control system of the present invention. As shown in FIG. 14, the fourth flood prevention system of the present invention is different from the first radio frequency identification electronic label device 2 in the first flood prevention system in that the data line 6 needs to be connected to the control terminal 5. Each of the first radio frequency identification electronic tag devices 2 in the drowning system may have an independent power source and a wireless communication module, and the first radio frequency identification tag device 2 performs wireless communication with the wireless signal collecting device 4, and then passes through the wireless signal collecting device 4 and the control terminal. The data line between 5 is transmitted to the control terminal 5, and in this configuration, it is not necessary to arrange the data line 6 at the bottom. The fourth flood prevention system of the present invention is very advantageous for retrofitting an existing old swimming pool without remodeling the bottom of the swimming pool 1 (laying cables), and only needs to follow the first radio frequency identification electronic label device 2 capable of wireless communication. The matrix arrangement is fixed to the bottom of the swimming pool 1 to achieve the effects of the present invention.

Figure 15 is a side elevational view of a fifth flood control system of the present invention. As shown in Fig. 15, in the fifth flood prevention system of the present invention, unlike the first flood prevention system, a wireless communication device is widely used in the fifth flood prevention system.

The first radio frequency identification tag device 2 at the bottom of the pool is connected to the first wireless signal transceiver relay 8 via a data line 6, and the LED beam directing device 14 and the alarm speaker 15 are connected to the third wireless signal transceiver relay 10, The wireless signal acquisition device 4 is connected to the fifth wireless signal transceiver relay 12, respectively. The control terminal 5 is connected to the second wireless signal transceiver relay terminal 9, the fourth wireless signal transceiver relay terminal 11, and the sixth wireless signal transceiver relay terminal 13 through the background server 16, respectively. The first wireless signal transceiver relay 8 and the second wireless signal transceiver relay 9 exchange data by wireless communication. The third wireless signal transceiver repeater 10 and the fourth wireless signal transceiver repeater 11 exchange data by wireless communication. The fifth wireless signal transceiver relay terminal 12 and the sixth wireless signal transceiver relay terminal 13 exchange data by wireless communication. In this structure, the cable layout is greatly reduced, the difficulty in constructing the flood prevention system is reduced, and the flexibility of the wireless signal acquisition device 4, the LED beam directing device 14 and the alarm speaker 15 is improved.

The first radio frequency identification electronic tag device 2 can be installed at the bottom of the swimming pool as a grid coordinate position point, and adopts a network format equal-proportional multi-point distribution installation manner to achieve partial or full coverage of the bottom of the swimming pool. By setting and adjusting the signal transmission gain intensity of the electronic tag, each electronic tag wireless signal transmission can ensure an optimal local effective range (local range is 2M*2M or 3M*3M as a square for effectively identifying the block) Each identification block has 4 electronic tags as one identification unit, and each electronic tag has a unique code identification code, and each identification code will be the only effective coordinate position in the grid. For each of the wearable second radio frequency identification electronic tag devices 3 that enters and passes, the second radio frequency identification electronic tag device 3 identifies and collects the electronic tag position code at the bottom of the pool, and passes the collected information through itself. The wireless radio frequency circuit is coupled to the wireless signal acquisition device 4 with the embedded antenna to achieve the core functions of precise positioning, dynamic tracking, identification, and SOS event information collection. The second radio frequency identification electronic tag device 3 is the only electronic sensing device worn on the body of the swimmer. When the embedded microsensor detects the change of the physical value of the pressure, the electronic transceiver will perform time and pressure through its own CPU logic control circuit. The difference changes are logically analyzed and judged, and the result of the judgment generates different types of event signal codes and together with the electronic tag position codes, the event signals are simultaneously transmitted to the wireless signal collecting device 4 and the underwater first radio frequency identification electronic tag device 2 unit. When the first radio frequency identification electronic tag device 2 and the wireless signal acquisition device 4 receive the code of any wearable electronic transceiver, the electronic tag code address code, and the different event codes, the LED of the first radio frequency identification electronic tag device 2 is first According to the event code, the colorful tube flashes for warning and reminding. At the same time, the fixed signal transceiver will send this information to the central controller end in real time, and finally the central control will analyze and lock the position, identity, event type, and automatically execute all the intelligent switch actions preset by the system.

In summary, the system of the present invention has the characteristics of high technical content, high integration, high degree of automation, and reduced number of security administrators, thereby effectively reducing the cost of the stadium personnel. The system is accurate and accurate in complex environment. Each unit module in the system has independent and intelligent judgment and control characteristics. Through simple and humanized technology management means, it is realized in the real sense of the Internet of Things. The typical construction and application of a modern technology swimming pool with a core theme.

The above is only a specific application example of the present invention, and does not impose any limitation on the scope of protection of the present invention. In addition to the above-described embodiments, the invention may have other embodiments. Any technical solution formed by equivalent replacement or equivalent transformation is within the scope of the claimed invention.

Claims (18)

1. A water-repellent prevention system is provided in a swimming pool (1), characterized in that it comprises:

   a plurality of first radio frequency identification electronic tag devices (2) arranged in a row at the bottom of the pool (1), the first radio frequency identification tag device (2) having a unique identification number and a representation of the pool (1) Address encoding in the middle position;

   At least one wearable second radio frequency identification electronic tag device (3), each of the second radio frequency identification electronic tag devices (3) having a unique identification number and including at least one water pressure detection for determining whether it is in a hydrophobic state a second radio frequency identification electronic tag device (3) for performing radio frequency identification with the first radio frequency identification electronic tag device (2) at the bottom of the swimming pool (1), the first of which is the strongest radio frequency signal An address code of the radio frequency identification electronic tag device (2) as an address code of a location of the second radio frequency identification electronic tag device (3) in the pool (1);

   At least one wireless signal collecting device (4), the wireless signal collecting device (4) wirelessly communicating with the second radio frequency identification electronic tag device (3), and at least the second radio frequency identification electronic tag in a drowning state The address code of the location of the device (3) in the pool (1) is sent to a control terminal (5).
2. The flood prevention system according to claim 1, wherein said first radio frequency identification electronic tag device (2) comprises a certain radio frequency identification electronic tag, and said second radio frequency identification electronic tag device (3) comprises a radio frequency Identify the electronic tag reader.
3. The water flood prevention system according to claim 1, wherein said first radio frequency identification electronic tag device (2) comprises a certain radio frequency identification electronic tag reader, said second radio frequency identification electronic tag device (3) Includes a radio frequency identification electronic tag.
4. A water flood prevention system according to any one of claims 1 to 3, wherein said first radio frequency identification electronic tag device (2) is arranged in a matrix on the bottom of said pool (1), each said A first radio frequency identification electronic tag device (2) is connected to the control terminal (5) via a number of data lines (6) at the bottom of the pool (1).
5. A water flood prevention system according to claim 4, wherein each of said first radio frequency identification electronic tag device (2) further comprises a rectangular waterproof floor (7) disposed at the bottom of said swimming pool (1), phase Between the adjacent first radio frequency identification electronic tag devices (2) being spliced and positioned by the rectangular waterproof floor (7), the data line (6) is embedded in the rectangular waterproof floor (7), or It is located between the rectangular waterproof floor (7) and the bottom of the pool (1).
6. A flood prevention system according to claim 4, wherein each of said first radio frequency identification electronic tag device (2) has an independent power source and a wireless communication module, said first radio frequency identification electronic tag device (2) The wireless signal acquisition device (4) performs wireless communication.
7. The water flood prevention system according to claim 4, wherein the spacing between the first radio frequency identification electronic tag devices (2) is equal, and the spacing of adjacent first radio frequency identification electronic tag devices (2) More than 1 meter, less than 3 meters.
8. The flood prevention system according to claim 4, characterized in that the arrangement density of the first radio frequency identification tag device (2) increases as the depth of the bottom of the pool (1) increases.
9. The anti-flooding system according to claim 4, wherein said first radio frequency identification electronic tag device (2) further comprises at least one alarm device activated when a water-repellent state occurs, said alarm device being an LED flashing light, an alarm One of a speaker and a camera, the LED flashing light flashes vertically upwards.
10. The water flood prevention system according to any one of claims 1 to 3, wherein at least one safety time threshold and at least one safety water pressure threshold are pre-stored in the second radio frequency identification electronic label device (3). The water pressure detecting sensor measures the real-time water pressure, and if the measured real-time water pressure is higher than the safe water pressure threshold for a duration greater than the safety time threshold, it is judged to be in a hydrophobic state.
11. The anti-flooding system according to claim 10, wherein said second radio frequency identification electronic tag device (3) further comprises at least one alarm device activated when a water-repellent state occurs, said alarm device being an LED flashing light, an alarm One of a speaker and a camera, the LED flashing light flashes.
12. A flood protection system according to claim 10, further comprising at least one LED beam directing means (14) activated in the presence of a hydrophobic state, said control terminal (5) being connected by wired communication or wireless communication.
13. A flood protection system according to claim 12, wherein said LED beam directing means (14) comprises a searchlight fixture, a position adjustment decoder and a stepper motor, said position adjustment decoder being in a drowning state Address encoding of the location of the second radio frequency identification electronic tag device (3) in the swimming pool (1), driving the stepping motor to adjust the illumination direction, and driving the searchlight to photograph the pool corresponding to the address code ( 1) The location in the middle.
14. A water repellency prevention method, comprising the water repellency prevention system according to claim 1, comprising: an acquisition step and a rescue step;

    The collecting step includes: the second radio frequency identification electronic tag device (3) worn by the swimmer is each performing radio frequency identification with the first radio frequency identification electronic tag device (2) at the bottom of the swimming pool (1), Address coding of the first radio frequency identification electronic tag device (2) having the strongest radio frequency signal as the address of the location of the second radio frequency identification electronic tag device (3) in the pool (1), and passing water pressure The detecting sensor determines whether it is in a drowning state, and if so, sends the address code of the position of the second radio frequency identification electronic tag device (3) in the swimming pool (1) to a control terminal (5) for The rescue step is performed at the location of the pool (1) where the address code is located.
15. The method for preventing flooding according to claim 14, wherein at least one safety time threshold and at least one safety water pressure threshold are pre-stored in said second radio frequency identification electronic label device (3), said water pressure detecting sensor Measuring the real-time water pressure, if the measured real-time water pressure is higher than the safe water pressure threshold for a duration greater than the safety time threshold, determining that the water is in a damp state, the second radio frequency identification electronic tag device (3) real-time measuring water When the pressure is zero, the duration is cleared.
16. A flood prevention swimming pool having the flood prevention system according to any one of claims 1 to 13.
17. A method for constructing a flood prevention swimming pool for forming a water flood prevention system according to any one of claims 1 to 13, comprising: constructing a swimming pool (1), and providing a plurality of first radio frequency identification electronic label devices (2) An array arranged at the bottom of the pool (1), the first radio frequency identification tag device (2) having a unique identification number and an address code indicating its location in the pool (1);

    And at least one wireless signal collecting device (4) is disposed above the swimming pool (1) or at the bottom of the swimming pool (1), and each of the first radio frequency identification electronic tag devices (2) passes through the swimming pool (1) A number of data lines (6) at the bottom are connected to the control terminal (5).
18. A flood prevention water remodeling method for a swimming pool, comprising: a water repellent prevention system according to any one of claims 1 to 13, comprising: in a swimming pool (1), a plurality of first radio frequency identification electronic tag devices (2) An array arranged at the bottom of the pool (1), the first radio frequency identification tag device (2) having a unique identification number and an address code indicating its location in the pool (1);

    And at least one wireless signal collecting device (4) is disposed above the swimming pool (1) or at the bottom of the swimming pool (1), and each of the first radio frequency identification electronic tag devices (2) passes through the swimming pool (1) A plurality of data lines (6) at the bottom are connected to the control terminal (5), and each of the first radio frequency identification electronic tag devices (2) further includes a rectangular waterproof floor (7) disposed at the bottom of the swimming pool (1). Between the adjacent first radio frequency identification electronic tag devices (2) being spliced and positioned by the rectangular waterproof floor (7), the data line (6) is embedded in the rectangular waterproof floor (7) Inside or between the rectangular waterproof floor (7) and the bottom of the swimming pool (1), each of the first radio frequency identification electronic tag devices (2) has an independent power source and a wireless communication module, the first radio frequency identification The electronic tag device (2) wirelessly communicates with the wireless signal acquisition device (4).

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