AU2017279582B2 - Remote control method and system for water pump - Google Patents
Remote control method and system for water pump Download PDFInfo
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- AU2017279582B2 AU2017279582B2 AU2017279582A AU2017279582A AU2017279582B2 AU 2017279582 B2 AU2017279582 B2 AU 2017279582B2 AU 2017279582 A AU2017279582 A AU 2017279582A AU 2017279582 A AU2017279582 A AU 2017279582A AU 2017279582 B2 AU2017279582 B2 AU 2017279582B2
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Abstract
The present invention discloses a remote control method and system for a water pump.
The method comprises: installing, on a water pump having a pump body and a motor, a water pump
control and data collection device configured to collect water pump operating condition data and
control the water pump, and a water pump communication device configured to transmit and
receive data; transmitting, by the water pump control and data collection device, the collected water
pump operating condition data to the water pump communication device during operation of the
water pump; transmitting, by the water pump communication device, the received water pump
operating condition data to a server platform located at a network side; analyzing, by the server
platform, the operating condition data to obtain an analysis result, and transmitting the analysis
result to a mobile terminal employed to control the water pump, thereby facilitating the mobile
terminal remotely controlling the water pump according to the analysis result.
9695601_1 (GHMattes) P107326.AU
12
Installing, on a water pump having a pump body and a motor, a water pump control and
data collection device configured to collect water pump operating condition data and
control the water pump, and a water pump communication device configured to transmit
and receive data
Transmitting, by the water pump control and data collection device, the collected water
pump operating condition data to the water pump communication device during operation
of the water pump
Transmitting, by the water pump communication device, the received water pump
operating condition data to a server platform located at a network side
Analyzing, by the server platform, the operating condition data to obtain an analysis
result, and transmitting the analysis result to a mobile terminal employed to control the
water pump, thereby facilitating the mobile terminal remotely controlling the water pump
according to the analysis result
Fig. 1
Mobile terminal
Waterpump
communication I
device
I Water pump control I Server platform
and data collection
device
Smart water pump
Waterpump I
Fig. 2
9695601_1 (GHMatters) P107326.AU
Description
Installing, on a water pump having a pump body and a motor, a water pump control and data collection device configured to collect water pump operating condition data and control the water pump, and a water pump communication device configured to transmit and receive data
Transmitting, by the water pump control and data collection device, the collected water pump operating condition data to the water pump communication device during operation of the water pump
Transmitting, by the water pump communication device, the received water pump operating condition data to a server platform located at a network side
Analyzing, by the server platform, the operating condition data to obtain an analysis result, and transmitting the analysis result to a mobile terminal employed to control the water pump, thereby facilitating the mobile terminal remotely controlling the water pump according to the analysis result
Fig. 1
Mobile terminal
Waterpump communication I device
I Water pump control I Server platform and data collection device
Smart water pump Waterpump I
Fig. 2
9695601_1 (GHMatters) P107326.AU
Technical Field Embodiments of the present invention relate to the technical field of water pump control, and more particularly, to a remote control method and system for a water
pump.
Background Art As one of the basic industries of national economy, the pump industry plays an important role in national economy and social development. Pumps are general machinery equipment, which are wide in application scope and have been extensively applied to such fields as petroleum, chemical industry, metallurgy, power, mine, urban construction, nuclear power, national defense and military industry, and the like. Moreover, there exist numerous pumps, which, as one of the major energy-consuming equipment in the industry area in China, may consume the power accounting for about 20% of the total power generation throughout the country. Therefore, monitoring the operating condition of a water pump for reducing the time of operation in fault for the water pump and improving the operating efficiency of the water pump may produce significant social and economic benefits.
Summary of the Invention It may desirable to provide a remote control method and system for a water pump allowing remote control on a water pump, which can be used for remotely monitoring the operating condition of the water pump and remotely controlling the water pump according to the monitoring. According to a first aspect, the present disclosure provides a remote control system for a water pump, the system comprising:
a water pump having a pump body and a motor; a water pump control and data collection device installed on the water pump and configured to control the water pump to operate according to a remote control instruction and collect water pump operating condition data during operation of the water pump; a water pump communication device installed on the water pump and configured to transmit the water pump operating condition data collected by the water pump control and data collection device and transmit the received remote control instruction to the water pump control and data collection device; a server platform located at a network side and configured to receive and analyze the water pump operating condition data from the water pump communication device and transmit an analysis result to a mobile terminal employed to control the water pump; and the mobile terminal employed to generate the remote control instruction based on the analysis result transmitted from the server platform and transmit the generated remote control instruction to the water pump communication device so as to remotely control the water pump; wherein the motor of the water pump comprises a rotating shaft, an internal motor cavity defined by front end cover and rear end cover, and an outer rotor housed in the internal motor cavity, and an inner stator made from a high magnetic conductive material; wherein the outer rotor comprises a magnetic steel and a support made from a low magnetic conductive material, the support being a drum with a center hole and the portion of the center hole of the drum protruding up to form a protruding ring; wherein the pump body comprises a front pump cover and an impeller, a cavity is defined by the front pump cover and the front end cover which is heaved toward the internal motor cavity to be recessed; wherein a cooling duct is disposed in a position on the front end cover that corresponds to the cavity; wherein the water pump control and data collection device compares a value of any of parameters of the operating condition data with a corresponding threshold in real time, and generates the warning information in the event that a comparison result exceeds a predetermined range, and transmitting the warning information to the mobile terminal via the water pump communication device; and wherein the operating condition data includes at least one parameter of supply voltage, operating frequency, water-use flow, water way pressure and water-use energy consumption of the water pump. Preferably, the mobile terminal remotely controls the water pump according to the analysis result, which specifically includes: generating, by the mobile terminal, a corresponding remote control instruction according to the received analysis result; transmitting, by the mobile terminal, the remote control instruction to the water pump communication device over a wireless link of point-to-point communication with the water pump communication device; and transmitting, by the water pump communication device, the received remote control instruction to the water pump control and data collection device which is thereby allowed to control the water pump according to the remote control instruction. Preferably, the mobile terminal sets up the wireless link of point-to-point communication with the water pump communication device after generating the remote control instruction. Preferably, the drum sleeves the inner stator; a magnetic steel is disposed between an internal circumferential wall of the drum and an external lateral wall of the inner stator and is fixedly connected to the internal circumferential wall of the drum; and the protruding ring closely sleeves the rotating shaft. Preferably, the rear end cover is in lock-in connection with the front end cover; the middle part of the front end cover is heaved toward the internal motor cavity to form a bulge loop; and the inner stator closely sleeves the bulge loop. Preferably, the impeller is housed in the front of the cavity; the rotating shaft extends through the support, the front end cover and the impeller in sequence; the rear end cover is fixed to the rotating shaft, and the rotating shaft is rotatable relatively to the rear end cover; the front end cover is provided, at an end thereof adjacent to the cavity, with a seal chamber, and a seal ring is disposed in the seal chamber; and the seal ring sleeves the rotating shaft and seals the cavity. Besides, the remote control system for a water pump also comprises a mobile terminal executing an active query for the water pump operating condition data, which specifically comprises: transmitting, by the mobile terminal, a query request including a water pump ID and a query content to the server platform; searching, by the server platform, for the corresponding water pump operating condition data according to the water pump ID in the query request; and obtaining, by the server platform according to the query content in the query request, query information conforming to the query content from the supply voltage, operating frequency, water-use flow, water way pressure and water-use energy consumption of the water pump recorded therein, and responding to the mobile terminal with the obtained query information. Besides, the remote control system for a water pump also comprises transmitting water charge information to the mobile terminal, which specifically comprises: transmitting, by the server platform, a water-use flow to a water supply management platform at a preset time interval; and generating, by the water supply management platform, corresponding water charge information according to the water-use flow and transmitting the water charge information to the mobile terminal.
Embodiments may have the following advantages: by using the Internet of Things technology, uploading all data, including operating conditions and pipeline information, of various household smart water pumps in a housing estate to a server platform is achieved by water pump communication devices for comprehensive analysis on water pump operation and pipeline conditions. If abnormity warning from a water pump is detected, voice or message notification may be immediately sent to the user. A user can log in to APP software on a mobile phone or a computer to achieve real-time monitoring and query of the operating condition and water-use energy consumption of the water pump, remote control of water pump start and stop, setting of an operating period of time of the water pump, and constant pressure control.
Brief Description of the Drawings Fig. 1 is a flowchart showing steps of a method of controlling a water pump. Fig. 2 is a schematic structure diagram of a system for controlling a water pump for implementing the method of controlling a water pump. Fig. 3 is a schematic structure diagram of a water pump. Fig. 4 is a schematic structure diagram of a front end cover shown in Fig. 3. Introduction of reference numerals: a seal ring is represented by 3, while a fluid by 4,a rubber thrower by 5, a front pump cover by 11, an impeller by 12, a water inlet by 13, a water outlet by 14, a rotating shaft by 21, an internal motor cavity by 22, a motor unit by 23, an inner stator by 231, an outer rotor by 232, a magnetic steel by 2321, a support by 2322, a drum by 2322a, a protruding ring by 2322b, a front end cover by 24, a bulge loop by 241, a cooling duct by 242, a bearing chamber by 243, a drip chamber by 244, a drain ditch by 245, a lower end by 245a, a seal chamber by 246, a rear end cover by 25, and a cavity by M.
Detailed Description of the Invention To illustrate in detail the technical contents of the present invention, objectives to achieve and resulting effects, the following descriptions are made with embodiments in conjunction with the accompanying drawings. Fig. 2 shows a remote control system for a water pump of an embodiment. The system comprises a smart water pump, a server platform, and a mobile terminal.
The smart water pump comprises: a water pump control and data collection device installed on a water pump having a pump body and a motor and configured to control the water pump to operate according to a remote control instruction and collect water pump operating condition data during operation of the water pump; and a water pump communication device installed on the water pump and configured to transmit the water pump operating condition data collected by the water pump control and data collection device and transmit the received remote control instruction to the water pump control and data collection device. The server platform is located at a network side and configured to receive and analyze the water pump operating condition data from the water pump communication device and transmit an analysis result to a mobile terminal employed to control the water pump. The mobile terminal generates the remote control instruction based on the analysis result transmitted from the server platform and transmits the generated remote control instruction to the water pump communication device so as to remotely control the water pump. The motor of the water pump comprises a rotating shaft, an internal motor cavity and an outer rotor housed in the internal motor cavity, and an inner stator made from a high magnetic conductive material. The outer rotor comprises a magnetic steel and a support made from a low magnetic conductive material. The support is a drum with a center hole and the portion of the center hole of the drum protrudes up to form a protruding ring. The operating condition data includes at least one parameter of supply voltage, operating frequency, water-use flow, water way pressure and water-use energy consumption of the water pump. By using the Internet of Things technology, uploading all data, including operating conditions and pipeline information, of various household smart water pumps in a housing estate to a server platform is achieved by water pump communication devices for potentially comprehensive analysis on water pump operation and pipeline conditions. If abnormity warning from a water pump is detected, voice or message notification may be immediately sent to the user. A user can log in to APP software on a mobile phone or a computer to achieve real-time monitoring and query of the operating condition and water-use energy consumption of the water pump, remote control of water pump start and stop, setting of an operating period of time of the water pump, and constant pressure control. Fig. 1 shows a method of achieving remote control on a water pump. The method may be implemented in the system shown in Fig. 2, the method comprising: installing, on a water pump having a pump body and a motor, a water pump control and data collection device configured to collect water pump operating condition data and control the water pump, and a water pump communication device configured to transmit and receive data; transmitting, by the water pump control and data collection device, the collected water pump operating condition data to the water pump communication device during operation of the water pump; transmitting, by the water pump communication device, the received water pump operating condition data to a server platform located at a network side; and analyzing, by the server platform, the operating condition data to obtain an analysis result, and transmitting the analysis result to a mobile terminal employed to control the water pump, thereby facilitating the mobile terminal remotely controlling the water pump according to the analysis result; wherein the motor of the water pump comprises a rotating shaft, an internal motor cavity and an outer rotor housed in the internal motor cavity, and an inner stator made from a high magnetic conductive material; wherein the outer rotor comprises a magnetic steel and a support made from a low magnetic conductive material, the support being a drum with a center hole and the portion of the center hole of the drum protruding up to form a protruding ring; and wherein the operating condition data includes at least one parameter of supply voltage, operating frequency, water-use flow, water way pressure and water-use energy consumption of the water pump. The mobile terminal remotely controls the water pump according to the analysis result, which specifically includes: generating, by the mobile terminal, a corresponding remote control instruction according to the received analysis result; transmitting, by the mobile terminal, the remote control instruction to the water pump communication device over a wireless link of point-to-point communication with the water pump communication device; and transmitting, by the water pump communication device, the received remote control instruction to the water pump control and data collection device which is thereby allowed to control the water pump according to the remote control instruction. The mobile terminal sets up the wireless link of point-to-point communication with the water pump communication device after generating the remote control instruction. As can be seen from the above descriptions, the mobile terminal uses another link rather than the server platform when remotely controlling and managing the smart water pump because the transmission efficiency can be improved when a large quantity of data needing to be transmitted by the smart water pump and minimal data of the operating instruction transmitted by the mobile terminal are not transmitted over the same link. The remote control system for a water pump also comprises the mobile terminal executing an active query for the water pump operating condition data, which specifically comprises: transmitting, by the mobile terminal, a query request including a water pump ID and a query content to the server platform; searching, by the server platform, for the corresponding water pump operating condition data according to the water pump ID in the query request; and obtaining, by the server platform according to the query content in the query request, query information conforming to the query content from the supply voltage, operating frequency, water-use flow, water way pressure and water-use energy consumption of the water pump recorded therein, and responding to the mobile terminal with the obtained query information. The remote control system for a water pump also comprises a step of transmitting water charge information to the mobile terminal, which specifically comprises: transmitting, by the server platform, a water-use flow to a water supply management platform at a preset time interval; and generating, by the water supply management platform, corresponding water charge information according to the water-use flow and transmitting the water charge information to the mobile terminal. As can be seen from the above descriptions, by implementing the present invention, a user can make a query for historical records at a server platform by means of a mobile terminal. For example, if the user wants to know the water consumption of each month, the user can just make a query at the server platform to know that. The server platform is provided with a database for storing relevant data. In an embodiment, generally at the preset time interval of a month, the server platform transmits the water-use flow of a user to the water supply management platform, and a background supervisor may calculate corresponding water charge; or the system automatically generates the corresponding water charge and transmits it to the user's mobile phone. The remote control system for a water pump in the present invention also comprises a step of the water pump control and data collection device directly transmitting warning information to the mobile terminal, which specifically comprises: comparing, by the water pump control and data collection device, a value of any of parameters of the operating condition data with a corresponding threshold in real time; and generating, by the water pump control and data collection device, the warning information in the event that a comparison result exceeds a predetermined range, and transmitting the warning information to the mobile terminal via the water pump communication device. As can be seen from the above descriptions, in case of an emergency, it would be better that the emergency is detected earlier. Therefore, a threshold is set for determination at the end of the smart water pump, and a warning is given upon exceeding the threshold. Thus, adverse consequences of lagging in warning due to backend determination may be avoided. After a water pump is integrated with the water pump control and data collection device and the water pump communication device, the smart water pump records water pump operating conditions (water pump operating conditions such as supply voltage, operating frequency, water-use flow, water way pressure and water-use energy consumption) and transmits data to a cloud server platform in a certain period by means of a communication module. The service platform achieves collection and statistics, comparative analysis and exchange of data, and the finally calculated reference data is transmitted by a data center to a user and a centralized water supply center for advanced maintenance, water supply pipeline fault elimination, rescue, charge renewal and payment, etc. After installing a smart water pump in place, a user may activate an Internet of Things card (installed in the water pump), and then the smart water pump is powered on to operate. The user installs an APP developed correspondingly to the interaction method in the present invention on a mobile terminal. Then, the user registers water pump information, including an SIM card number, a water pump terminal number, a user' number for receiving warning information, etc. After successful registration and login to the APP software, the user can remotely set water pump energy consumption, operating condition and constant pressure control parameters, and an operating period of time, etc. A client is generated automatically by binding the smart water pump or scanning a unique identifier of the smart water pump by the user, and then the water- use energy consumption condition, water pump operating parameters, water supply pipeline pressure and water supply conditions of the water pump can be monitored at any time at the client. Moreover, instructions can be remotely transmitted to the smart water pump by the client so that smart water pump operation values such as start and stop of water pump use, and parameter setting can be achieved. Thus, water saving and energy saving control is facilitated and a human-machine interaction function is realized. Meanwhile, a data transmission function integrated into the smart water pump transmits the operating conditions of the smart water pump, allowing the user to know the operating condition of the water pump, the energy consumption condition and the pipeline condition in real time, to implement maintenance before the proposed maintenance and to renew and pay the charge. Thus, the service life of the power supply system can be effectively improved and fault early warning is also achieved. Fig. 3 shows a structure of a water pump. As shown in Fig, 3, the water pump in the present invention comprises a pump body and a motor. The motor comprises a rotating shaft 21, an internal motor cavity 22 and an outer rotor 23 housed in the internal motor cavity 22, a front end cover 24 and a rear end cover 25. The internal motor cavity 22 is defined by the front end cover 24 and the rear end cover 25, and the rear end cover 25 is in lock-in connection with the front end cover 24. The middle part of the front end cover 24 is heaved toward the internal motor cavity 22 to form a bulge loop 241. Now turning to Fig. 3, the motor unit 23 comprises an inner stator 231 and an outer rotor 232, where the inner stator 231 closely sleeves the bulge loop 241. The outer rotor 232 comprises a magnetic steel 2321 and a support 2322. The support 2322 is a drum 2322a with a center hole and the portion of the center hole of the drum 2322 protrudes up to form a protruding ring 2322b. The drum 2322a sleeves the inner stator 231, and the magnetic steel 2321 is disposed between the internal circumferential wall of the drum 2322a and an external lateral wall of the inner stator 231 and is fixedly connected to the internal circumferential wall of the drum 2322a. The protruding ring 2322b closely sleeves a rotating shaft 21. The support 2322 is made from a low magnetic conductive material. Preferably, the support 2322 is a stainless steel sheet or an aluminum alloy sheet. The inner stator 231 is made from a high magnetic conductive material. Now turning back to Fig. 3,the pump body comprises a front pump cover 11 and an impeller 12. A cavity M is defined by the front pump cover 11 and the front end cover 24, and the impeller 12 is housed in the front of the cavity M. The rotating shaft 21 extends through the support 2322, the front end cover 24 and the impeller 12 in sequence. The rear end cover 25 is fixed to the rotating shaft 21, and the rotating shaft 21 is rotatable relatively to the rear end cover 25. Next, turning back to Fig. 3 and to Fig. 4, the front end cover 246 is provided, at an end thereof adjacent to the cavity M, with a seal chamber 24, and a seal ring 3 is disposed in the seal chamber 246. The seal ring 3 sleeves the rotating shaft 21 and seals the cavity M. A cooling duct 242 is disposed in a position on the front end cover 24 that corresponds to the cavity M. Thus, the contact area of a fluid 4 in the pump, i.e., in the cavity M with the part of the front end cover 24 where the inner stator 231 is fixed. The heat generated by the iron core when the motor is operating is taken away by the fluid 4 circulating in the pump, thereby achieving the purpose of cooling. The front end cover 24 is also provided with a bearing chamber 243, a drip chamber 244 and a drain ditch 245. The bearing chamber 243 is located at the end portion, corresponding to the internal motor cavity 22, of the front end cover 24. The drip chamber 244 is located between the seal chamber 241 and the bearing chamber 243, and a rubber thrower 5 sleeves the portion, corresponding to the drip chamber 244, of the rotating shaft 21. The upper portion of the drain ditch 245 communicates with the drip chamber 244, and the lower end 245a thereof is located on the outer sidewall of the front end cover 24. Long-term use of the pump may cause wear of the seal ring 3, which may lead to slight leakage. To prevent the leaking fluid 4 from entering into the motor along the rotating shaft 21, the drip chamber 244 is provided between the seal chamber 241 and the bearing chamber 243 and the rubber thrower 5 is mounted on the rotating shaft 21. When a leakage fault occurs, the fluid 4 is blocked and thrown away by the rubber thrower 5, and finally, the leaking fluid 4 is discharged out of the motor via the drain ditch 245. Now turning back to Fig. 3, when embodiments are applied in operation, after power on, the outer rotor 232 rotates and drives the impeller to rotate by means of the rotating shaft. The fluid 4 is drawn in via the water inlet 13 of the pump body and accelerated by the impeller to gain energy so as to be thrown away out of the water outlet 14 of the pump body. In this process, the cavity M defined by the pump body and the front end cover 24 is full of high speed circulating fluid 4, and the cooling duct 242 is also full of flowing fluid 4. In this case, the heat generated during the operating of the motor is conducted to the fluid 4 in the cavity M through heat transfer and then taken away out of the pump by the circulating fluid 4, thereby achieving the purpose of cooling. According to embodiments, with the structure of the outer rotor 232 and the inner 231, which may have the advantages of small size, low weight, high efficiency and energy saving, the material costs are significantly saved and the size of the electric pump is greatly reduced. The base and the front end cover, which may be two of two independent components for a traditional electric pump, are integrated in the present invention, leading to a reduced overall size. Also, by changing air cooling of a traditional motor into water cooling, the heat dissipation effect is greatly improved. To sum up, according to embodiments, by using the Internet of Things technology, uploading all data, including operating conditions and pipeline information, of various household smart water pumps in a housing estate to a server platform may be achieved by water pump communication devices for comprehensive analysis on water pump operation and pipeline conditions. If abnormity warning from a water pump is detected, voice or message notification may be immediately sent to the user. A user can log in to APP software on a mobile phone or a computer to achieve real-time monitoring and query of the operating condition and water-use energy consumption of the water pump, remote control of water pump start and stop, setting of an operating period of time of the water pump, and constant pressure control. A data interactive method and system for a smart water pump provided in embodiments can achieve smart management on water supply of different smart water pump terminals and a plurality of water pumps one by one, and be especially suitable for supplying water for high building in property management of residence, for solving the problems of water way fault early warning, unattended water pump, agricultural and forestall irrigation, and for achieving smart control, pipeline monitoring and early warning, etc. The above are merely descriptions of the embodiments and not intended to thereby limit the present invention in any form. Any equivalent alterations with the descriptions and drawings of embodiments or direct or indirect utilization thereof in the related technical field shall all be encompassed in the scope of patent protection of the present invention in the same way. In the claims which follow and in the preceding description of the invention, except where the context requires otherwise due to express language or necessary implication, the word "comprise" or variations such as "comprises" or "comprising" is used in an inclusive sense, i.e. to specify the presence of the stated features but not to preclude the presence or addition of further features in various embodiments.
Claims (9)
1. A remote control system for a water pump, the system comprising:
a water pump having a pump body and a motor;
a water pump control and data collection device installed on the water pump
and configured to control the water pump to operate according to a remote control
instruction and collect water pump operating condition data during operation of the
water pump;
a water pump communication device installed on the water pump and
configured to transmit the water pump operating condition data collected by the water
pump control and data collection device and transmit the received remote control
instruction to the water pump control and data collection device;
a server platform located at a network side and configured to receive and
analyze the water pump operating condition data from the water pump communication
device and transmit an analysis result to a mobile terminal employed to control the
water pump; and
the mobile terminal employed to generate the remote control instruction
based on the analysis result transmitted from the server platform and transmit the
generated remote control instruction to the water pump communication device so as to
remotely control the water pump;
wherein the motor of the water pump comprises a rotating shaft, an internal
motor cavity defined by front end cover and rear end cover, and an outer rotor housed
in the internal motor cavity, and an inner stator made from a high magnetic conductive
material;
wherein the outer rotor comprises a magnetic steel and a support made from
a low magnetic conductive material, the support being a drum with a center hole and
the portion of the center hole of the drum protruding up to form a protruding ring;
wherein the pump body comprises a front pump cover and an impeller, a
cavity is defined by the front pump cover and the front end cover which is heaved
toward the internal motor cavity to be recessed;
wherein a cooling duct is disposed in a position on the front end cover that corresponds to the cavity; wherein the water pump control and data collection device compares a value of any of parameters of the operating condition data with a corresponding threshold in real time, and generates the warning information in the event that a comparison result exceeds a predetermined range, and transmitting the warning information to the mobile terminal via the water pump communication device; and wherein the operating condition data includes at least one parameter of supply voltage, operating frequency, water-use flow, water way pressure and water-use energy consumption of the water pump.
2. The remote control system according to claim 1, wherein the mobile
terminal remotely controls the water pump according to the analysis result, which
specifically includes:
generating, by the mobile terminal, a corresponding remote control
instruction according to the received analysis result;
transmitting, by the mobile terminal, the remote control instruction to the
water pump communication device over a wireless link of point-to-point
communication with the water pump communication device; and
transmitting, by the water pump communication device, the received
remote control instruction to the water pump control and data collection device which
is thereby allowed to control the water pump according to the remote control instruction.
3. The remote control system according to claim 2, wherein the mobile
terminal sets up the wireless link of point-to-point communication with the water pump
communication device after generating the remote control instruction.
4. The remote control system according to claim 1, wherein the drum sleeves
the inner stator; a magnetic steel is disposed between an internal circumferential wall
of the drum and an external lateral wall of the inner stator and is fixedly connected to
the internal circumferential wall of the drum; and the protruding ring closely sleeves a rotating shaft.
5. The remote control system according to claim 4, wherein the rear end cover,
and the rear end cover is in lock-in connection with the front end cover; the middle part
of the front end cover is heaved toward the internal motor cavity to form a bulge loop;
and the inner stator closely sleeves the bulge loop.
6. The remote control system according to claim 5, wherein the impeller is
housed in the front of the cavity; the rotating shaft extends through the support, the
front end cover and the impeller in sequence; the rear end cover is fixed to the rotating
shaft, and the rotating shaft is rotatable relatively to the rear end cover; the front end
cover is provided, at an end thereof adjacent to the cavity, with a seal chamber, and a
seal ring is disposed in the seal chamber; and the seal ring sleeves the rotating shaft and
seals the cavity.
7. The remote control system according to claim 1, also comprising mobile
terminal executing an active query for the water pump operating condition data, which
specifically comprises:
transmitting, by the mobile terminal, a query request including a water
pump ID and a query content to the server platform;
searching, by the server platform, for the corresponding water pump
operating condition data according to the water pump ID in the query request; and
obtaining, by the server platform according to the query content in the query
request, query information conforming to the query content from the supply voltage,
operating frequency, water-use flow, water way pressure and water-use energy
consumption of the water pump recorded therein, and responding to the mobile terminal
with the obtained query information.
8. The remote control system according to claim 7, also comprising
transmitting water charge information to the mobile terminal, which specifically comprises: transmitting, by the server platform, a water-use flow to a water supply management platform at a preset time interval; and generating, by the water supply management platform, corresponding water charge information according to the water-use flow and transmitting the water charge information to the mobile terminal.
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Applications Claiming Priority (4)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201710205509.3 | 2017-03-31 | ||
| CN201710205509.3A CN106837765A (en) | 2017-03-31 | 2017-03-31 | The data interactive method and system of a kind of intelligent water pump |
| CN201711038588.X | 2017-10-29 | ||
| CN201711038588 | 2017-10-29 |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| AU2017279582A1 AU2017279582A1 (en) | 2018-10-18 |
| AU2017279582B2 true AU2017279582B2 (en) | 2020-01-02 |
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| AU2017279582A Ceased AU2017279582B2 (en) | 2017-03-31 | 2017-12-18 | Remote control method and system for water pump |
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| AU (1) | AU2017279582B2 (en) |
Families Citing this family (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN110988294A (en) * | 2019-12-30 | 2020-04-10 | 江苏东恒环境控股有限公司 | An intelligent monitoring system for water environment in small watersheds |
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| US5478222A (en) * | 1991-04-10 | 1995-12-26 | Heidelberg; Goetz | Fluid pump having a pressure sealed motor chamber |
| US6536272B1 (en) * | 1999-08-06 | 2003-03-25 | University Of Miami | Water monitoring, data collection, and transmission module |
| US20030093236A1 (en) * | 2001-11-14 | 2003-05-15 | Wu Zheng Yi | Method and system for automatic water distribution model calibration |
| US20050230527A1 (en) * | 2000-03-10 | 2005-10-20 | Silansky Edward R | Internet linked environmental data collection system and method |
| US20090283457A1 (en) * | 2008-05-14 | 2009-11-19 | Isos Ventures Llc | Waste water management system and method |
| WO2015149659A1 (en) * | 2014-04-04 | 2015-10-08 | 苏州泰格动力机器有限公司 | Multi-pole permanent magnet electric motor for shallow water and shallow water type submersible pump using same |
-
2017
- 2017-12-18 AU AU2017279582A patent/AU2017279582B2/en not_active Ceased
Patent Citations (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US5478222A (en) * | 1991-04-10 | 1995-12-26 | Heidelberg; Goetz | Fluid pump having a pressure sealed motor chamber |
| US6536272B1 (en) * | 1999-08-06 | 2003-03-25 | University Of Miami | Water monitoring, data collection, and transmission module |
| US20050230527A1 (en) * | 2000-03-10 | 2005-10-20 | Silansky Edward R | Internet linked environmental data collection system and method |
| US20030093236A1 (en) * | 2001-11-14 | 2003-05-15 | Wu Zheng Yi | Method and system for automatic water distribution model calibration |
| US20090283457A1 (en) * | 2008-05-14 | 2009-11-19 | Isos Ventures Llc | Waste water management system and method |
| WO2015149659A1 (en) * | 2014-04-04 | 2015-10-08 | 苏州泰格动力机器有限公司 | Multi-pole permanent magnet electric motor for shallow water and shallow water type submersible pump using same |
Also Published As
| Publication number | Publication date |
|---|---|
| AU2017279582A1 (en) | 2018-10-18 |
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| FGA | Letters patent sealed or granted (standard patent) | ||
| MK14 | Patent ceased section 143(a) (annual fees not paid) or expired |