CN108801352B - Bathing pool environment monitoring system and working method thereof - Google Patents
Bathing pool environment monitoring system and working method thereof Download PDFInfo
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- CN108801352B CN108801352B CN201810697767.2A CN201810697767A CN108801352B CN 108801352 B CN108801352 B CN 108801352B CN 201810697767 A CN201810697767 A CN 201810697767A CN 108801352 B CN108801352 B CN 108801352B
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Abstract
The invention relates to a bathing pool environment monitoring system and a working method thereof, wherein the bathing pool environment monitoring system comprises: the system comprises a cloud server, a remote terminal and a bath pool environment detection device; wherein the bath environment detection device comprises: the temperature sensor comprises a control module, and a communication module, a temperature sensor and a pressure sensor which are connected with the control module; the temperature sensor is suitable for detecting the water temperature of the bath; the pressure sensor is suitable for detecting the water pressure of the bath; the cloud server stores threshold ranges of bath water temperature data and bath water pressure data; when the cloud server judges that the bath water temperature data and the bath water pressure data are both within the threshold range, the bath water temperature data and the bath water pressure data are stored; otherwise, sending the water temperature data of the bathing pool, the water pressure data of the bathing pool and corresponding alarm information to a remote terminal; the bathing pool environment monitoring system can remotely monitor the water temperature of the bathing pool and the water pressure of the bathing pool in real time, and alarm when the water temperature of the bathing pool or the water pressure of the bathing pool is abnormal.
Description
Technical Field
The invention relates to a bathing pool environment monitoring system and a working method thereof.
Background
At present, along with the development of trades such as science and technology and production, the temperature of certain environment often need to be monitored, for example in the bathing pool, the real-time supervision of temperature and water pressure is favorable to the grasp to the bathing comfort level, because can not have the labour to go to monitor temperature and water pressure in the bathing pool always, so both not good to labourer's health, waste time, and work efficiency and working effect are also not as far as possible, consequently need a bathing pool environment monitoring system to realize the temperature and the water pressure of long-range real-time supervision bathing pool to improve people's quality of life.
Disclosure of Invention
The invention provides a bathing pool environment monitoring system and a working method thereof, which are used for realizing real-time remote monitoring of water temperature and water pressure of a bathing pool and alarming when the water temperature or the water pressure of the bathing pool is abnormal.
In order to solve the above technical problem, the present invention provides a bathing pool environment monitoring system, comprising: the system comprises a cloud server, a remote terminal and a bath pool environment detection device; wherein the bath environment detection device comprises: the temperature sensor comprises a control module, and a communication module, a temperature sensor and a pressure sensor which are connected with the control module; the temperature sensor is suitable for detecting the water temperature of the bath and sending the water temperature data of the bath to the cloud server through the communication module; the pressure sensor is suitable for detecting the water pressure of the bath and sending the water pressure data of the bath to the cloud server through the communication module; the cloud server stores threshold ranges of bath water temperature data and bath water pressure data; when the cloud server judges that the bath water temperature data and the bath water pressure data are both within the threshold range, the bath water temperature data and the bath water pressure data are stored; otherwise, the water temperature data of the bathing pool, the water pressure data of the bathing pool and corresponding alarm information are sent to the remote terminal.
Furthermore, the bath environment monitoring system also comprises an intelligent subsystem for safely transmitting files containing bath water temperature data, bath water pressure data and corresponding alarm information; the intelligent subsystem comprises: the remote terminal, the proxy server and the server; wherein the remote terminal comprises: an acquisition module: the device is used for acquiring a file containing bath water temperature data, bath water pressure data and corresponding alarm information and judging the type of the file; a judging module: the file partitioning module is used for partitioning the file when the file is judged to be a large file; each file subblock is provided with an associated file header, and the file header comprises a block identifier, a tail byte of a previous file subblock and a CRC (cyclic redundancy check) value of the previous file subblock; the file header of the first file sub-block comprises a tail byte of the last file sub-block and a CRC (cyclic redundancy check) value of the last file sub-block; a grouping module: the device is used for grouping the file subblocks after being partitioned; the number of the file subblocks in the group is set according to the number of the parallel links, and the block identifiers of the file subblocks in the group are discontinuous blocks; and a transmission module: for transmitting each packet in turn to the proxy server using a parallel link.
Further, the transmitting the packets to the proxy server by using the parallel link in sequence comprises: randomly distributing file subblocks in the group to each virtual port, and then transmitting the file subblocks to a proxy server by using a parallel link; when the proxy server receives all the file groups, determining whether all the file sub-blocks are received according to the block identifiers; when the file is determined to be received, all the file subblocks are transmitted to a server, and the server checks each file subblock; and when the verification is passed, recombining to obtain the file.
Further, before the current file packet is transmitted, the method further comprises the following steps: judging the network state, namely transmitting the current file packet when the network state is good; otherwise, the state to be transmitted is carried out, and the network state is periodically detected.
Further, virtual ports are arranged on the remote terminal and the proxy server, and parallel transmission paths are established through the virtual ports; and the number of the virtual ports is set according to the bandwidth between the remote terminal and the proxy server.
Furthermore, the proxy server is located at the server side and performs data transmission with the server by using a proprietary channel.
In another aspect, the present invention further provides a method for operating a bathing pool environment monitoring system, including: the system comprises a cloud server, a remote terminal and a bath pool environment detection device; wherein the bath environment detection device comprises: the temperature sensor comprises a control module, and a communication module, a temperature sensor and a pressure sensor which are connected with the control module; the temperature sensor is suitable for detecting the water temperature of the bath and sending the water temperature data of the bath to the cloud server through the communication module; the pressure sensor is suitable for detecting the water pressure of the bath and sending the water pressure data of the bath to the cloud server through the communication module; the cloud server stores threshold ranges of bath water temperature data and bath water pressure data; when the cloud server judges that the bath water temperature data and the bath water pressure data are both within the threshold range, the bath water temperature data and the bath water pressure data are stored; otherwise, the water temperature data of the bathing pool, the water pressure data of the bathing pool and corresponding alarm information are sent to the remote terminal.
The bathing pool environment monitoring system has the beneficial effects that the bathing pool water temperature and the bathing pool water pressure can be remotely monitored in real time through the cloud server and the remote terminal, and the water temperature can be ensured to be normal by combining the alarm function, so that unnecessary danger or accidents are avoided; and through the intelligent subsystem, the remote terminal can acquire the water temperature data of the bathing pool and the water pressure data of the bathing pool in time.
Drawings
The invention is further illustrated with reference to the following figures and examples.
FIG. 1 is a schematic block diagram of a bath environment monitoring system of the present invention;
fig. 2 is a schematic block diagram of an intelligent subsystem in the bath environment monitoring system of the present invention.
Detailed Description
The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.
Example 1
FIG. 1 is a schematic block diagram of a bath environment monitoring system of the present invention;
as shown in fig. 1, the present embodiment provides a bathing pool environment monitoring system, which includes: the system comprises a cloud server, a remote terminal and a bath pool environment detection device; wherein the bath environment detection device comprises: the temperature sensor comprises a control module, and a communication module, a temperature sensor and a pressure sensor which are connected with the control module; the temperature sensor is suitable for detecting the water temperature of the bath and sending the water temperature data of the bath to the cloud server through the communication module; the pressure sensor is suitable for detecting the water pressure of the bath and sending the water pressure data of the bath to the cloud server through the communication module; the cloud server stores threshold ranges of bath water temperature data and bath water pressure data; when the cloud server judges that the bath water temperature data and the bath water pressure data are both within the threshold range, the bath water temperature data and the bath water pressure data are stored; otherwise, the water temperature data of the bathing pool, the water pressure data of the bathing pool and corresponding alarm information are sent to the remote terminal.
Specifically, the communication module is, for example, but not limited to, an ethernet interface module or a WiFi module.
Specifically, a plurality of temperature sensors and pressure sensors can be arranged according to the size of the bath pool, so that the water temperature data and the water pressure data of the whole bath pool can be comprehensively monitored.
Specifically, the bathing pool environment monitoring system of the embodiment can remotely monitor the water temperature of the bathing pool and the water pressure of the bathing pool in real time through the cloud server and the remote terminal, and alarm when the water temperature of the bathing pool or the water pressure of the bathing pool is abnormal, so that the abnormality is solved in time, and unnecessary dangers or accidents are avoided; the bathing pool environment monitoring system of the embodiment also does not need to be monitored on site by personnel, so that the labor cost is saved.
Fig. 2 is a schematic block diagram of an intelligent subsystem in the bath environment monitoring system of the present invention.
Further, as shown in fig. 2, in order to ensure that the collected bath water temperature data and bath water pressure data can be sent out in time and improve the transmission safety of the bath water temperature data and the bath water pressure data, the bath environment monitoring system of the embodiment further includes an intelligent subsystem for safely transmitting a file containing the bath water temperature data, the bath water pressure data and corresponding alarm information; the intelligent subsystem comprises: a remote terminal at a user side, and a proxy server and a server at a network side; wherein the remote terminal comprises:
an acquisition module: the method is used for obtaining a file containing bath water temperature data, bath water pressure data and corresponding alarm information and judging the type of the file.
Specifically, due to the diversity of network files, in order to improve the processing efficiency of files, files are divided into ordinary files (small files) and large files.
A judging module: the file partitioning module is used for partitioning the file when the file is judged to be a large file, wherein each file sub-block is provided with an associated file header, and the file header comprises a block identifier, tail bytes of a previous file sub-block and a CRC (cyclic redundancy check) value of a previous word block; the file header of the first file sub-block includes the last file sub-block's tail byte and the last file block's CRC check value.
Specifically, the setting of the block relevance can facilitate the verification and restoration of data on the network side, and the processing efficiency of the file is improved conveniently.
Preferably, the block identifier in the first file header may be set according to a file type identifier, the file type identifier is a predefined encoding sequence, and the subsequent block identifiers are incremented based on a specific step size, where the step size is greater than 1, so that the block identifiers are encoded according to a form agreed by a sender and a server, thereby effectively improving data security.
A grouping module: the device comprises a group of file subblocks, a plurality of parallel links, a plurality of groups of file subblocks and a plurality of groups of file subblocks, wherein the file subblocks are arranged in the group; the random grouping of the file subblocks can ensure the safety in the transmission process.
A transmission module: the proxy server is used for transmitting each group to the proxy server by using the parallel link in sequence; the method specifically comprises the steps of distributing file subblocks in a group to each virtual port randomly, then transmitting the file subblocks to a proxy server by using a parallel link, determining whether all the file subblocks are received or not according to a block identifier after the proxy server receives all the file groups, transmitting the file subblocks to the server when all the file subblocks are determined to be received, verifying each file subblock by the server, and recombining to obtain the file after the verification is passed.
Because different packets are transmitted by using parallel links in sequence, in order to ensure the stability of transmission, the state of the network is judged before the current packet is transmitted, when the state is good, the current packet is transmitted, otherwise, the state to be transmitted is carried out, and the state of the network is periodically detected; the random transmission of the file subblocks can effectively improve the data security.
Virtual ports are arranged on the remote terminal and the proxy server, and parallel transmission paths are established through the virtual ports. The number of the virtual ports is set according to the bandwidth between the remote terminal and the proxy server, so that the effective utilization of resources is guaranteed.
The proxy server is positioned at the server side and performs data transmission with the server by using a special channel; the proprietary channel can improve the security of data transmission.
The intelligent subsystem for network file safe transmission of the embodiment establishes the correlated groups after the large files are blocked, the file subblocks in the group are discontinuous and are independently transmitted in parallel, so that the file safety is improved, and meanwhile, a virtual port is used between a remote terminal and a proxy server to establish a parallel transmission path, so that the resource utilization rate can be effectively improved, and the data transmission efficiency is improved.
Example 2
On the basis of embodiment 1, this embodiment 2 provides a working method of a bathing pool environment monitoring system, including: the system comprises a cloud server, a remote terminal and a bath pool environment detection device; wherein the bath environment detection device comprises: the temperature sensor comprises a control module, and a communication module, a temperature sensor and a pressure sensor which are connected with the control module; the temperature sensor is suitable for detecting the water temperature of the bath and sending the water temperature data of the bath to the cloud server through the communication module; the pressure sensor is suitable for detecting the water pressure of the bath and sending the water pressure data of the bath to the cloud server through the communication module; the cloud server stores threshold ranges of bath water temperature data and bath water pressure data; when the cloud server judges that the bath water temperature data and the bath water pressure data are both within the threshold range, the bath water temperature data and the bath water pressure data are stored; otherwise, the water temperature data of the bathing pool, the water pressure data of the bathing pool and corresponding alarm information are sent to the remote terminal.
Specifically, the working principle, the working method, and the working process of the bathing pool environment monitoring system described in this embodiment are the same as those of the bathing pool environment monitoring system in embodiment 1, and are not described herein again.
In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.
Claims (4)
1. A bathing pool environment monitoring system, comprising:
the system comprises a cloud server, a remote terminal and a bath pool environment detection device; wherein
The bath environment detection device comprises: the temperature sensor comprises a control module, and a communication module, a temperature sensor and a pressure sensor which are connected with the control module;
the temperature sensor is suitable for detecting the water temperature of the bath and sending the water temperature data of the bath to the cloud server through the communication module;
the pressure sensor is suitable for detecting the water pressure of the bath and sending the water pressure data of the bath to the cloud server through the communication module;
the cloud server stores threshold ranges of bath water temperature data and bath water pressure data; and
when the cloud server judges that the bath water temperature data and the bath water pressure data are both within the threshold range, the bath water temperature data and the bath water pressure data are stored; otherwise, sending the water temperature data of the bathing pool, the water pressure data of the bathing pool and corresponding alarm information to a remote terminal;
the bath environment monitoring system also comprises an intelligent subsystem for safely transmitting files containing bath water temperature data, bath water pressure data and corresponding alarm information;
the intelligent subsystem comprises: the remote terminal, the proxy server and the server; wherein
The remote terminal includes:
an acquisition module: the device is used for acquiring a file containing bath water temperature data, bath water pressure data and corresponding alarm information and judging the type of the file;
a judging module: the file partitioning module is used for partitioning the file when the file is judged to be a large file;
each file subblock is provided with an associated file header, and the file header comprises a block identifier, a tail byte of a previous file subblock and a CRC (cyclic redundancy check) value of the previous file subblock; the file header of the first file sub-block comprises a tail byte of the last file sub-block and a CRC (cyclic redundancy check) value of the last file sub-block;
a grouping module: the device is used for grouping the file subblocks after being partitioned and establishing a group which is related to each other;
the number of the file subblocks in the group is set according to the number of the parallel links, and the block identifiers of the file subblocks in the group are discontinuous blocks, namely the file subblocks in the group are discontinuous and are independently transmitted in parallel; and
a transmission module: the proxy server is used for transmitting each group to the proxy server by using the parallel link in sequence;
virtual ports are arranged on the remote terminal and the proxy server, and parallel transmission paths are established through the virtual ports; and
the number of virtual ports is set according to the bandwidth between the remote terminal and the proxy server.
2. The bath environment monitoring system of claim 1,
the transmission of the packets to the proxy server by using the parallel link in turn comprises the following steps: randomly distributing file subblocks in the group to each virtual port, and then transmitting the file subblocks to a proxy server by using a parallel link;
when the proxy server receives all the file groups, determining whether all the file sub-blocks are received according to the block identifiers; when the file is determined to be received, all the file subblocks are transmitted to a server, and the server checks each file subblock; and when the verification is passed, recombining to obtain the file.
3. The bath environment monitoring system of claim 2,
before the current file packet is transmitted, the method further comprises the following steps: determination of the state of the network, i.e.
When the network state is good, transmitting the current file packet; otherwise, the state to be transmitted is carried out, and the network state is periodically detected.
4. The bath environment monitoring system of claim 3,
the proxy server is positioned at the server side and performs data transmission with the server by using a special channel.
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