TW201617775A - Power monitoring and feedback system and its implementing method - Google Patents

Abstract

The presented invention discloses a power monitoring and feedback system and its implementing method. The power monitoring and feedback system comprises a power monitoring device, a mobile device and a cloud power management system. When power monitoring device is connected to the power supply site and electrical equipment, it can detect and get the power consumption data regularly. The power consumption data which stored in cloud power management system can generate a power consumption history. Moreover, the cloud power management system can produce suggestion and reminder information after analyzing power consumption data. Therefore, user can know the power consumption condition of electrical equipment through mobile device, and to conserve energy.

Description

Power monitoring and feedback system and implementation method thereof

The invention relates to a power supply monitoring and feedback system and an implementation method thereof. The invention particularly relates to a power supply monitoring and feedback system for monitoring the power consumption status of electrical equipment through the combination of the power monitoring device and the cloud device, and feeding back the power related information. method.

According to estimates by the World Energy Council (WEC), the world's oil will be exhausted within 40 to 50 years, and with the wave of energy exhaustion, the environmental awareness of Chinese people will gradually increase, from government agencies, From the private enterprise units to the general households, it is important to know that energy conservation and carbon reduction are important. Therefore, related energy-saving products have also appeared one after another, such as energy-saving bulbs, inverter refrigerators, inverter air conditioners and inverter washing machines, etc., in addition to the energy-saving effect of the products themselves, There are related auxiliary energy-saving products, including smart plugs and smart sockets, such as the Republic of China Invention Patent Notice No. I448022 "Smart Plugs, Sockets and Adapters", which exposes a detection module and an identification module. A smart plug/seat constructed by a group and a network module, with a detection module After the configured electronic circuit is detected, the identification module can know the identification data of the electrical equipment to which it belongs, and finally, it can be transmitted to the external information device through the network module for understanding the electrical equipment. Power consumption; or such as the Republic of China New Patent Bulletin No. M450896 "Power Supply Device for Cloud Control", which discloses a power supply module, a switch module, a signal transmission module and a cloud server Smart socket, cloud server can monitor the power consumption status of the power supply module, and generate power consumption statistics after recording. The cloud server can also judge whether the power supply module has abnormal condition. If yes, send a remote control signal to After receiving the signal transmission module, the signal transmission module controls the power supply module by the switch module (such as emergency power-off operation); and, as in the Republic of China new patent announcement No. I448692, "Power information display interface, display Method and device thereof, which discloses a power information display device including a power detection module, a computing module and a power The display module, the power detection module can be directly connected to the source of the household power supply, or indirectly connected to a smart plug or a smart socket, and calculate the specific electrical equipment, the socket or the entire power circuit by the calculation module. Power consumption, finally, through the power information display interface to display a real-time information by means of numbers, symbols or lights, and other prior art for reference, as follows: (1) The Republic of China new patent announcement M461906 "Energy Monitoring and Socket Structure"; (2) China Invention Patent Notice No. CN102193550 "Networked Smart Home Power Optimization Control Method"; (3) China Invention Patent Publication No. CN103885368 "Based on Bluetooth Communication "Intelligent switch control system for letter"; (4) China Utility Model Patent Publication No. CN202145516 "Intelligent Monitoring Socket"; (5) US Patent Publication No. US20120297217 "Power controller, power controlling device and power-saving method for Power controlling device".

However, it is known from the above-mentioned prior art that the conventional auxiliary energy-saving device can only monitor and record the power usage status, and form a power history record for the user to know, or can use the electricity history record. To determine whether there is an abnormality in the electrical equipment, or even more, through the mobile communication device, the remote connection to the cloud server for real-time control of the auxiliary energy-saving device, however, if the user is not familiar with the electrical equipment Basic electricity consumption (such as Taiwan's Sanyo model SR-A533BV power-saving refrigerator, the average monthly electricity consumption is about 33 watt-hours), even if you know the history of electricity consumption, you still can't judge whether it has achieved the goal of saving power. Moreover, if the electrical equipment is known to be wasting power, the user cannot obtain relevant information in a timely manner and timely.

In view of the above problems, the inventors have studied and analyzed existing system architectures based on years of experience in related industries and product design, and are able to design a better power monitoring and feedback system; thus, the present invention The main purpose is to provide a kind of power consumption condition in addition to monitoring the electrical equipment, and to analyze and compare the power consumption status, and to save energy. Power monitoring and feedback system and its implementation method.

The power monitoring and feedback system and the method for implementing the same according to the present invention include a power monitoring device, a mobile communication device, and a cloud power management device. The power monitoring device is connectable. The power supply source and an electrical device are used to detect a power consumption data of the electrical device. The mobile communication device is pre-installed with a power management application, and the mobile communication management application can complete the pairing of the mobile communication device and the smart socket. And the mobile communication device information is connected to the cloud power management device, and the cloud power management device includes a power history recording module and a power data analysis module, and the power history recording module can mark the power data. A power usage time, and the electricity data and power consumption time are recorded to form a power history information, and the power data analysis module can retrieve the power history information and a power standard parameter, and compare them. After that, generate a power recommendation message or a power reminder message, and use the electricity suggestion information and power usage reminder information, all through the cloud power tube Means for transmitting to the mobile communication device, and rendering through power management applications.

In order for your review board to have a clear understanding of the purpose, technical features and effects of the present invention, the following description will be used in conjunction with the illustrations, please refer to it.

1‧‧‧Power Monitoring and Feedback System

11‧‧‧Power monitoring device

111‧‧‧plug end processing module

112‧‧‧ Plug-end transmission module

113‧‧‧ Circuit Detection Module

114‧‧‧Switch setting module

115‧‧‧Output/input module

12‧‧‧Mobile communication devices

121‧‧‧Device-side processing module

122‧‧‧Device-side transmission module

123‧‧‧Power management application

1231‧‧‧plug search interface

1232‧‧‧Electricity information

1233‧‧‧Communication comparison information

1234‧‧‧Electrical advice

1235‧‧‧Electric reminder information

13‧‧‧Cloud power management device

131‧‧‧Servo transmission module

132‧‧‧Electric history recording module

1321‧‧‧recording unit

1322‧‧‧clock unit

133‧‧‧Electric data analysis module

1331‧‧‧Capture unit

1332‧‧‧ comparison unit

1333‧‧‧ Suggested units

1334‧‧‧Reminder unit

135‧‧‧ parameter collection module

134‧‧‧Database

1341‧‧‧First data area

1342‧‧‧Second data area

20‧‧‧Electrical equipment

21‧‧‧Electrical equipment

22‧‧‧Electrical equipment

23‧‧‧Electrical equipment

24‧‧‧Electrical equipment

25‧‧‧Electrical equipment

P‧‧‧Power supply source

S101‧‧‧ Pairing steps

S102‧‧‧Detection and recording steps

S201‧‧‧Electrical selection steps

S202‧‧‧Electric data acquisition steps

S203‧‧‧Standard parameter acquisition steps

S204‧‧‧ alignment steps

S205‧‧‧Power Recommendation Steps

S206‧‧‧Electric reminder steps

Figure 1 is a schematic diagram of the system architecture of the present invention.

Fig. 2 is a schematic view showing the structure of the detailed system of the present invention (1).

Figure 3 is a schematic diagram of the detailed system architecture of the present invention (2).

Figure 4 is a schematic view (I) of the implementation of the present invention.

Figure 5 is a schematic view (2) of the present invention.

Figure 6 is a schematic view (3) of the implementation of the present invention.

Figure 7 is a schematic view (4) of the implementation of the present invention.

Figure 8 is a schematic view (5) of the implementation of the present invention.

Figure 9 is a schematic view (6) of the implementation of the present invention.

Figure 10 is a schematic view (1) of the steps of the present invention.

Figure 11 is a schematic view (2) of the implementation steps of the present invention.

Figure 12 is a schematic diagram (I) of another system architecture of the present invention.

Figure 13 is a schematic view showing another embodiment of the present invention.

Figure 14 is a schematic diagram of another system architecture of the present invention (2).

Please refer to FIG. 1 , which is a schematic diagram of the system architecture of the present invention. As shown in the figure, the power monitoring and feedback system 1 of the present invention includes at least one power monitoring device 11 , a mobile communication device 12 , and a cloud For the electric management device 13, please refer to "2nd drawing". The figure shows the schematic structure of the detailed system of the present invention (1). As shown in the figure, the power monitoring device 11 has a plug end processing module 111 and has a plug. The end transmission module 112, the circuit detection module 113 and the switch setting module 114 are respectively connected with the plug end processing module 111, and the power monitoring device 11 further has an output/input mode. The group 115 is electrically connected to the circuit detecting module 113, and the plug end processing module 111 is provided for actuating and controlling the power monitoring device 11, which can be a microprocessor controller (MCU), central processing The circuit detection module 113 is an ammeter or a voltmeter, and is provided by a central processing unit (CPU), a microprocessor unit (MPU), or a digital signal processing (DSP). Detecting a current value or a voltage value between a power supply source and an electrical device electrically connected to the power monitoring device 11 and generating a power consumption data, wherein the electrical device can be a household appliance device (such as an individual) Computers, refrigerators, electric light bulbs, air conditioners, etc., and factory electrical equipment (such as generators and industrial computers, etc.), but not limited to this, special first, the plug-end transmission module 112 has Bluetooth transmission The function and wireless transmission function, the plug-end transmission module 112 with the Bluetooth transmission function can be matched by the power monitoring device 11 and the mobile communication device 12. In the preferred embodiment, it can be Bluetooth 4.0 ( Bluetooth 4.0), or Bluetooth low energy (BTLE) transmission technology, however, any Bluetooth transmission technology that can form a pairing state between the two devices can be implemented with wireless transmission. The function of the plug-end transmission module 112 can transmit the power consumption data detected by the circuit detection module 113 to the cloud power management device 13, which can be a transmission technology such as WI-FI, Bluetooth or IR, and the switch setting The module 114 can be used for periodic or task opening and closing of the power monitoring device; the output/input module 115 is a power socket (Socket) and a power pin (Pin), in other words, the power monitoring device 11 can Through the power jack of the output/in module 115, it is electrically connected with external electrical equipment, and then output/input The power pin of the module 115 is electrically connected to an external power supply source to obtain a power source and is provided for the electrical device to operate; and the mobile communication device 12 can be a smart phone or a tablet computer. For the notebook computer and the personal computer, the mobile communication device 12 includes a device processing module 121, a device terminal transmission module 122 and a power management application 123, and the device terminal processing module 121 can actuate and control the mobile communication device. 12. The device-side transmission module 122 and the device-side processing module 121 are in an information connection, and also have a Bluetooth transmission function and a wireless transmission function, and a device-side transmission module 122 having a Bluetooth transmission function, which is available for the mobile communication device. 12 is paired with the power monitoring device, and the device-side transmission module 122 having the wireless transmission function can be wirelessly connected to the cloud power management device 13, wherein the device-side processing module 121 and the device-side transmission module 122 are implemented. The same can be the same as the plug-end processing module 111 and the plug-end transmission module 112, so that it will not be described in detail here, and the power management application 123 is pre-processed. Firstly installed in the device-end processing module 121, the user performs the power management application 123 to complete the pairing of the mobile communication device 12 with the power monitoring device 11, and further connects the mobile communication device 12 to the cloud power management device. 13, to obtain the required electricity data of electrical equipment.

As shown in the figure, the system architecture of the present invention is shown in the figure. As shown in the figure, the cloud power management device 13 includes a servo transmission module 131 and a power usage history. The recording module 132, a power data analyzing module 133 and a data library 134, the server transmitting module 131 has a wireless transmission function, and can receive the plug end from the power monitoring device 11. The power consumption data of the transmission module 112 can also transmit the data of the power history recording module 132 and the power data analysis module 133 to the device end transmission module 122 of the mobile communication device 12, and the power history recording module 132. There is a recording unit 1321 and a clock unit 1322. The clock unit 1322 can mark a power consumption time (including year, month, day, minute and second) of the power data received by the server transmission module 131, and the recording unit 1321 can For the purpose of recording the electricity consumption data and the electricity consumption time, and forming a power history information (not shown), the electricity data, the electricity usage time and the electricity history information are all stored in the first data of the database 134. In the area 1341, please refer to "FIG. 3", which is a schematic diagram of the detailed system architecture (2) of the present invention. As shown in the figure, the power data analysis module 133 includes a capture unit 1331. The matching unit 1332, a suggesting unit 1333, and a reminding unit 1334, the capturing unit 1331 of the power data analyzing module 133, in addition to the power history information stored in the first data area 1341 of the database 134, Can be retrieved in the second of the database 134 A power standard parameter (not shown in the figure) of the material area 1342, wherein the power standard parameter can be used for the annual power consumption of the national standard product produced by the government agency, and the standard consumption of the electrical equipment issued by the electrical equipment manufacturer. Electricity, and the average electricity consumption of electrical equipment or the average hours of use of electrical equipment, as measured by third-party statistical units, and not limited to this, special first, the comparison unit 1332 can use electricity history information and electricity The standard parameters are compared to generate a power comparison result, and the suggesting unit 1333 generates a power recommendation information according to the comparison result of the comparison unit 1332, and the reminding unit 1334 also generates the power comparison result according to the power comparison result. A reminder message is used, and the electricity recommendation information and the electricity reminder information are transmitted through the servo transmission module. The 131 is transmitted to the mobile communication device 12, and after being received by the device-side transmission module 122, it is presented through the power management application.

Please refer to FIG. 4, which is a schematic diagram of the implementation of the present invention (1), and please refer to "1st to 3rd drawings". As shown in the figure, in the implementation of the present invention, the power monitoring device 11 is first introduced ( In this embodiment, a smart plug is connected to the power supply source P (this embodiment is a household electrical outlet, and in other embodiments, if it is in a wiring of a total power supply, not limited to the socket form) Between the electrical device 20 (in this embodiment, a lamp or a light bulb) for power monitoring, wherein the power monitoring device 11 forms a power with the power supply source P through the power pin of the output/input module 115. The power connection device is connected to the electrical device of the power supply device 20 to electrically connect the power source to the electrical device 20, and then refer to the power supply device. FIG. 5 is a schematic view showing the implementation of the present invention (2). As shown in the figure, after the connection with the power supply source P and the electrical device 20 is completed, the power management application of the mobile communication device 12 can be executed. 123, and enter a plug search interface 1 231, for searching and pairing the power monitoring device 11, wherein the searching and pairing manner can send a Bluetooth signal to the device-side transmission module 122 of the mobile communication device 12, and the plug-end transmission of the power monitoring device 11 The module 112 receives the Bluetooth signal. However, the Bluetooth signal can be sent by the plug-end transmission module 112 of the power monitoring device 11. The device-side transmission module 122 of the mobile communication device 12 receives the Bluetooth signal when the power monitoring is completed. After the searching and pairing of the device 11, the circuit detecting module 113 of the power monitoring device 11 starts detecting the electrical device 20 The power usage data is transmitted to the cloud power management device 13 in real time.

Please refer to "Figure 6", which shows the schematic diagram (3) of the implementation of the present invention, and please refer to "Figures 1~4". As shown in the figure, the electricity consumption data of the electrical equipment 20 will be managed by the cloud. The device 13 performs recording and storage. When the user wants to know the power usage status of the electrical device 20, the power management application 123 of the mobile communication device 12 can be executed, and a power history request is sent to the cloud power management device 13. The power history recording module 132 can instantly count and record the power consumption data and the power consumption time of a specific period (such as the comparison of the "two-day usage" in this embodiment) to generate the power history information 1232. And transmitting to the device-side transmission module 122 through the server-side transmission module 131 for presentation on the mobile communication device, wherein the user may have a need to understand the power usage status of "last month" or "last quarter". Therefore, the power history recording module 132 of the present invention can also periodically record the power consumption data and the power consumption time, and generate the power history information 1232, and store it in the first data area 1341 of the database 134 in advance.

Please refer to "Figures 7~8". The figure shows the implementation of the present invention (4)~(5), and please refer to "1~4", as shown in the figure, when the user wants to get electrical equipment. When the power supply recommendation of 20 is performed, the power management application 123 of the communication device 12 can be executed, and the type of the electrical device 20 electrically connected to the power monitoring device 11 (such as the desk lamp in this embodiment) is selected. Then, a power request request is sent to the cloud power management device 13, and the capture unit 1331 of the power data analysis module 133 is used to store the first resource. The power history information of the electrical equipment 20 of the material area 1341 (such as 10/05~10/11 in this embodiment, measuring 46 watts), and simultaneously stored in the second data area 1342, and the electrical equipment 20 (B light bulb of the desk lamp of the embodiment) The electrical power standard parameters of the same type of electrical equipment (such as other A bulbs and C bulbs of the embodiment), the comparison unit 1332 uses the electrical history information of the electrical equipment 20 The electrical standard parameters are compared to generate a power comparison result, and the power comparison result is that the B bulb used by the user is compared with the power consumption of the A bulb, and the recommended unit 1333 is According to the result of the power comparison, the power recommendation information 1234 is generated and transmitted to the device-side transmission module 122 through the server-side transmission module 131 for presentation on the mobile communication device, as in the embodiment, "recommended to use the A-light bulb". Moreover, in order to better understand the power comparison result for the user, the power data analysis module 133 of the present invention can also generate a power comparison information 1233, and can also be presented in the mobile communication device 12.

Please refer to "Fig. 9", which shows the schematic diagram of the implementation of the present invention (6), and please refer to "1~3", as shown in the figure, if the type of electrical equipment 23 selected by the user is TV In the case of the machine, the suggestion unit 1333 of the power data analysis module 133 can also generate the relevant power recommendation information 1234. The reminder unit 1334 of the power data analysis module 133 of the present invention can actively generate a power reminder. The information 1235 is presented to the mobile communication device 12 to remind the user of the usage status of the electrical device 23, wherein the generation method of the electricity reminding information 1235 is used to generate the weekly electricity history information by using the electrical history recording module 132. After (as in the example 05/11~05/17 of the embodiment, measuring 85 watts and using 28 hours), the capturing unit 1331 of the electrical data analysis module 133 Then, the power consumption standard parameters related to the electrical equipment 23 are actively taken. If the average time for the Chinese to watch the television is 16 hours/week, the comparison unit 1332 of the electrical data analysis module 133 compares and finds the electrical appliance. The usage time of the device 23 (28 hours) exceeds the power consumption standard parameter (16 hours), and the reminding unit 1334 generates the power reminding information 1235, which is “Reminder less watching TV” in the embodiment, and is sent to the mobile communication device. 12.

Please refer to FIG. 10, which is a schematic diagram (1) of the implementation steps of the present invention. As shown in the figure, the method for implementing the power monitoring and feedback system of the present invention comprises the following steps: a pairing step S101: monitoring power supply The device 11 is connected between the power supply source P and the electrical device 20 to be monitored for power supply (as shown in FIG. 4). After the connection with the power supply source P and the electrical device 20 is completed, the mobile communication device 12 is executed. The power management application 123 enters a plug search interface 1231 for searching and pairing the power monitoring device 11 (as shown in FIG. 5), wherein the search and pairing method can be an action The device-side transmission module 122 of the communication device 12 transmits a Bluetooth signal, and the plug-end transmission module 112 of the power monitoring device 11 receives the Bluetooth signal. Alternatively, the device can transmit the blue signal from the plug-end transmission module 112 of the power monitoring device 11. The device signal transmission module 122 of the mobile communication device 12 receives the Bluetooth signal; a detection and recording step S102: when the search and pairing of the power source monitoring device 11 is completed, the circuit of the power source monitoring device 11 The detecting module 113 starts to detect a power consumption data of the electrical device 20, and transmits the power data in real time. To the cloud power management device 13, a clock unit 1322 of the electric history recording module 132 marks a power consumption time of the received power data, and a recording unit 1321 of the electricity history recording module 132 uses the power data and The electricity time is used for recording and forms a history of electricity usage (as shown in Figure 6).

Please refer to "Figure 11" for reference. The figure shows the implementation steps of the present invention (2). As shown in the figure, the implementation method of the power monitoring and feedback system of the present invention completes the pairing step S101 and the detection. After the step S102 is measured and recorded, the following steps may be further included: an electrical appliance selecting step S201: when the user wants to obtain the power suggestion of the electrical appliance 20, in the preferred embodiment, the power of the mobile communication device 12 is first executed. The application 123 is selected, and the type of the electrical device 20 electrically connected to the power monitoring device 11 is selected (as shown in FIG. 7). After the selection is completed, a power request request is sent to the cloud power management device 13. However, in other embodiments, the cloud power management system 13 can also actively determine the type of the connected electrical device 20, so it is not limited by the passive selection of the user, and any other way of judging the electrical device can be The implementation of the present invention; a power consumption data acquisition step S202: after the cloud power management device 13 receives the power request request, the data acquisition module 1331 of the power data analysis module 133 retrieves the data stored in the database 134. A power history information of the electrical equipment 20; a standard parameter extraction step S203: At the same time, the capturing unit 1331 of the electrical data analysis module 133 retrieves the electrical equipment stored in the database 134 and of the same type as the electrical equipment 20 One power standard parameter; After the step S204: the power consumption information and the power consumption standard parameter are extracted, the comparison unit 1332 of the power data analysis module 133 compares the power history information of the electrical device 20 with the power standard parameter. A power usage comparison result is generated; a power recommendation step S205: the recommendation unit 1333 of the power data analysis module 133 generates a power recommendation information 1234 according to the power comparison result, and transmits the power recommendation module 1234 through the servo transmission module 131. The device is transmitted to the device-side transmission module 122 for presentation in the mobile communication device (as shown in FIG. 8); a power-on reminding step S206: the reminding unit 1334 of the power-using data analysis module 133 is used to compare the results according to the power usage. A power reminder information 1235 (shown in FIG. 9) is actively generated and transmitted to the device side transmission module 122 through the server transmission module 131 for presentation on the mobile communication device.

Please refer to "Figure 12", which shows a schematic diagram of another system architecture of the present invention (1), and please refer to "Figure 2". As shown in the figure, the power monitoring and feedback system 1 of the present invention can be For the implementation of the plurality of power monitoring devices 11, please refer to "FIG. 13", which is a schematic diagram of another embodiment of the present invention. As shown in the figure, when a plurality of power monitoring devices 11 are connected to different electrical devices ( 24, 25), when the power management application 123 of the mobile communication device 12 is executed, there is a plug selection interface (not shown) for selecting the power monitoring device 11 to be paired, and The power monitoring and feedback system 1 of the present invention can also be used for the mobile communication device 12 to perform pairing with the power monitoring device 11 through the Bluetooth transmission function device transmission module 122, as detected by the power monitoring device 11. Electricity number The data is directly transmitted to the cloud power management device 13 through the plug-end transmission module 112 having the wireless transmission function, and is managed and analyzed by the cloud power management device 13. Therefore, the mobile communication device 12 can be used. The direct information is connected to the cloud power management device 13, and the power monitoring device 11 is controlled and managed, and the power history information, the power recommendation information, and the power usage reminder information are known.

Please refer to FIG. 14 , which is a schematic diagram of another system architecture of the present invention (2). As shown in the figure, the cloud power management device 13 of the power monitoring and feedback system 1 of the present invention may further include a parameter. The collection module 135 is connected to the server transmission module 131 and the data library 134, and the parameter collection module 135 can be connected to the external database through the server transmission module 131 to collect the latest power consumption. The standard parameters are stored in the second data area 1342 of the database 134 for use by the power data analysis module 133.

As can be seen from the above, the power monitoring and feedback system of the present invention mainly includes at least one power monitoring device, a mobile communication device, and a cloud power management device, wherein: the power monitoring device has a plug end processing module, and A plug-end transmission module, a circuit detection module and a switch setting module are respectively connected with the plug-end processing module, and the power monitoring device further has an output/input module and a circuit detection module. Electrically connected, the output/incoming module can be connected to a power supply source and an electrical device, and the circuit detection module can be used for detection A power consumption data of the electrical measuring device; the mobile communication device has a device-side processing module, a device-side transmission module and a power management application, and the power management application system is pre-installed in the device-side processing module, and executes The power management application enables the mobile communication device to be paired with the smart socket and the information is connected to the cloud power management device; the cloud power management device includes a server transmission module, a power history recording module, and a use The electric data analysis module and a database, the servo end transmission module can receive the power consumption data transmitted by the plug end transmission module, and can also transmit the related data to the device end transmission module, and the electricity history recording module has a The recording unit and a clock unit, the clock unit can mark a power consumption time of the power data received by the server transmission module, and the recording unit can record the power consumption data and the power consumption time, and form a power history information. The power data analysis module includes a capture unit, a comparison unit, a suggestion unit and a reminder unit, and the capture unit can be stored in the data. The electricity history information can also retrieve a standard parameter stored in the database, wherein the electricity history information is stored in the first data area of the database, and the electrical standard parameters are stored in the second of the database. In the data area, the comparison unit can compare the power history information with the power standard parameters to generate a power comparison result, and the suggestion unit generates a power recommendation information according to the power comparison result, and the reminder unit uses the data. The result of the electrical comparison produces a reminder message for use, and the information on the electricity recommendation and the information on the electricity use are transmitted to the mobile communication device through the servo transmission module. After receiving the transmission module, the application is managed by the power management application. Presenting; The method for implementing the power monitoring and feedback system of the present invention mainly includes the following steps: a pairing step: connecting a power monitoring device to a power supply source and an electrical device to be monitored by the power source, and Performing a power management application of a mobile communication device to enter a plug search interface for searching and pairing the power monitoring device; a detecting and recording step: after completing the searching and pairing of the power monitoring device, the power monitoring device A circuit detection module detects a power consumption data of the electrical device, and transmits the power data to the cloud power management device in real time, and uses a clock unit of the power history recording module to mark the use of the power data. The electric time, a recording unit records the electricity consumption data and the electricity consumption time, and generates a power history information; an electrical appliance selection step: when the user wants to obtain the power recommendation of the electrical equipment, the power management application is executed. And select the type of electrical equipment electrically connected to the power monitoring device. After the selection is completed, send a power to the cloud power management device. Request for a power data acquisition step: after receiving the power request request, the cloud power management device uses the data acquisition module of the power data analysis module to retrieve a power history information of the electrical equipment stored in the data base. a standard parameter extraction step: at the same time, the extraction unit of the electrical data analysis module retrieves a standard parameter of the electrical equipment stored in the database and has the same type as the electrical equipment; a comparison step: using electricity The comparison unit of the data analysis module compares the power history information of the electrical equipment with the standard parameters of the electricity consumption to generate a power consumption Comparison result; a power recommendation step: the recommended unit of the electricity data analysis module generates a power recommendation information according to the power comparison result, and transmits the information to the device transmission module through the servo transmission module, in action The communication device is presented; a power reminding step: the reminder unit of the power data analysis module actively generates a power reminder information according to the power comparison result, and transmits the power reminder information to the device side transmission mode through the servo end transmission module. Group, presented in a mobile communication device.

Therefore, after the implementation of the present invention, it is indeed possible to provide a power monitoring and feedback system that can analyze and compare the power usage status in addition to the power usage of the electrical equipment that can be monitored, and feedback the power consumption information. And its implementation method.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the scope of the present invention; any changes and modifications made by those skilled in the art without departing from the spirit and scope of the invention All should be covered by the patent of the present invention.

In summary, the effects of the present invention are patents such as "industry availability," "novelty," and "progressiveness" of the invention; the applicant filed an invention patent with the bureau in accordance with the provisions of the Patent Law. Application.

1‧‧‧Power Monitoring and Feedback System

11‧‧‧Power monitoring device

12‧‧‧Mobile communication device

121‧‧‧Device-side processing module

122‧‧‧Device-side transmission module

123‧‧‧Power management application

13‧‧‧Cloud power management device

131‧‧‧Servo transmission module

132‧‧‧Electric history recording module

1321‧‧‧recording unit

1322‧‧‧clock unit

133‧‧‧Electric data analysis module

134‧‧‧Database

1341‧‧‧First data area

1342‧‧‧Second data area

Claims (10)

A power monitoring and feedback system includes: at least one power monitoring device, having an output/input module and a plug end processing module, and a circuit detecting module and a plug end transmitting module, respectively The circuit processing module is electrically connected to the output/input module, and the output/input module is connected to a power supply source and an electrical device. The circuit detection module Detecting a power consumption data of the electrical device; a cloud power management device having a database, and a power history recording module and a power data analysis module respectively providing information connection with the data library, the data The library stores the power consumption data and a power standard parameter, and the power history recording module can generate a power history information, and the power data analysis module can generate a power recommendation information and a power reminding information; a mobile communication device having a device-side transmission module and a device-side processing module, wherein the device-side processing module is provided with a power management application; and the power data is transmitted through the plug-end transmission module Go to the cloud power management device, execute the power management application of the mobile communication device, and connect to the cloud power management device by using the device-side transmission module information to learn the power history information and use the Electricity advice information and the electricity reminder information. The power monitoring and feedback system of claim 1, wherein the cloud power management device has a server transmission module, and the power history recording module is connected to the information, and the power data is transmitted through the The plug end transmission module is transmitted to the servo end transmission module and stored in the database. The power monitoring and feedback system of claim 1, wherein the database has a first data area and a second data area, the first data area stores the power consumption data, and the second data area stores the power standard parameter. The power monitoring and feedback system of claim 3, wherein the power data analysis module has a matching unit, and has a capturing unit, a suggesting unit and a reminding unit, respectively The unit is in an information connection, and the capturing unit retrieves the power history information and the power standard parameter, and the comparison unit compares the power history information with the power standard parameter, and obtains a power comparison. As a result, the suggesting unit generates the power recommendation information according to the power comparison result, and the reminding unit generates the power reminding information according to the power comparison result. The power monitoring and feedback system of claim 1, wherein the power history recording module has a clock unit and a recording unit, wherein the clock unit is capable of marking a power consumption time of the power data. The recording unit is configured to record the power consumption data and the power consumption time, and the power history recording module generates the power history information according to the power consumption data and the power usage time. A method for implementing a power monitoring and feedback system includes the following steps: a power data acquisition step: one of the cloud power management devices uses a capture unit of the power data analysis module to capture an electrical device The electric history information, the electricity history information is stored in a database of a cloud power management device; a standard parameter extraction step: at the same time, the extraction unit of the electricity data analysis module captures the electrical equipment a power standard parameter, the power standard parameter is stored in the database of the cloud power management device; a comparison step: after the power history information and the power standard parameter are completed, the power data analysis a comparison unit of the module, comparing the power history information with the power standard parameter, and generating a power comparison result; A power recommendation step: after the comparison is completed, a recommended unit of the power data analysis module generates a power recommendation message according to the power comparison result; and an electricity reminder step: the power data analysis mode A reminding unit of the group generates a power reminding information according to the power comparison result. The method for implementing a power monitoring and feedback system according to claim 6, wherein the power data capturing step further comprises an electrical selecting step for performing a power management application by using a mobile communication device. The program selects the type of an electrical device to which the power monitoring device is connected, or actively identifies the electrical device to which the smart plug is connected by the cloud power management system. The method for implementing a power monitoring and feedback system according to claim 7, wherein before the step of selecting the electrical device, the method further includes a detecting and recording step for detecting a circuit detecting module of the power monitoring device Measure a power consumption data of the electrical device, and transmit the power data to the plug end transmission module of the cloud power management device through the plug end transmission module, after the plug end transmission module receives the A power history recording module of the cloud power management device records the power consumption data and generates a power history information. The method for implementing the power monitoring and feedback system of claim 8, wherein before the detecting and recording step, the method further includes a pairing step of connecting the power monitoring device to a power supply source and the After the electrical device, a power management application of the mobile communication device is executed, and a device-side transmission module of the mobile communication device is connected to a plug-end transmission module of the power monitoring device to form a pairing state. . The method for implementing a power monitoring and feedback system according to claim 8 , wherein the power history recording module has a clock unit and a recording unit, and the clock unit marks the use The power consumption time of the electrical data, the recording unit records the power consumption data and the power consumption time, and the power history recording module generates the power history information according to the power consumption data and the power consumption time.