TWM461022U - Air conditioning system using integrated intelligence handheld device software - Google Patents

Description

Air conditioning control system that integrates smart handheld applications

This creation is about an air conditioning control system that integrates smart handheld device applications, especially an air conditioning control system that combines smart handheld devices with smart meters.

Air conditioners, electric fans and heaters are quite common home temperature control devices. For example, air conditioners and electric fans are air-heating devices in hot summer temperatures, while heaters are heating and heating devices in cold winters.

According to the statistics of Taipower, household air-conditioning electricity consumption is the main summer electricity expenditure, and the summer electricity price is up to 28.97% more than the non-summer month. Therefore, the Energy Bureau of the Ministry of Economic Affairs advises people to purchase air conditioners with higher energy efficiency (EER) and set the temperature between 26 and 28 degrees Celsius, using electric fans to save electricity and electricity, and controlling heating in winter. The amount of machine used to reduce the burden of electricity bills increased throughout the year.

However, when using these thermostats, it is often difficult for the general public to grasp the power consumption of each device and accurately control the room temperature to the ideal temperature, let alone balance energy saving, lower electricity bills, and maintain a comfortable ambient temperature.

In view of the above-mentioned problems of the prior art, one of the aims of the present invention is to provide an air conditioning control system integrating an intelligent handheld device application, the air conditioning control system including at least an air conditioner controller, an application (App), and a plurality of air conditioners. Device and a number of smart meters.

The air conditioning controller includes a temperature sensing unit, and the temperature sensing unit is a sensing environment. Temperature to send temperature signals.

In other words, the application (App) is installed on the smart handheld device. The application receives and sends an operation signal to the air conditioner controller according to the temperature signal through the smart handheld device. Then, the air conditioner controller sends the first control signal according to the operation signal. The air conditioner controller transmits the first control signal by using an omnidirectional infrared technology.

In other words, a plurality of air conditioning units receive and operate in accordance with the first control signal. The air conditioning device can be, for example, an air conditioner, an electric fan or a heater.

The aforementioned air conditioning controller utilizes Bluetooth, Zigbee, Radio Frequency (RF), Wireless Fidelity (Wi-Fi), and Worldwide Interoperability for Microwave Access ( Worldwide Interoperability for Microwave Access, WiMAX), General Packet Radio Service (GPRS), 3rd-generation (3G), 3.5th Generation (3.5G) Or Long Term Evolution (LTE) technology sends temperature signals and receives operation signals.

To be continued, a plurality of smart meters are electrically connected to each air conditioner to upload the power consumption and power history of each air conditioner to the Internet, so that the application can obtain the power consumption of each air conditioner through the Internet. And electricity history. In addition, the application can obtain real-time electricity and contract capacity through the Internet.

The aforementioned application can further control the operation mode of each air conditioner by transmitting a second control signal through the air conditioner controller according to the instantaneous electricity price. By integrating real-time electricity prices with applications, you can control the operation mode of high-energy-consuming air-conditioning units to save power during peak hours.

The application can send a third control signal through the air conditioner controller according to the contract capacity, so that when the power consumption of the air conditioner exceeds the contract capacity, the application controls the air conditioner to stop operating through the air conditioner controller. By integrating the contract capacity with the application, you can monitor the power consumption of each air conditioner to avoid over-budgeting.

In addition, when the ambient temperature deviates from the preset temperature set by the application, the air conditioner controller controls the operation, stop or operation mode adjustment of each air conditioner to adjust the ambient temperature to the preset temperature. Therefore, by using the application of the smart handheld device to set the preset temperature, a plurality of air conditioners can be simultaneously controlled to achieve constant temperature and energy saving effects.

Among them, the preset temperature is more corresponding to different time intervals, and the application is more based on The preset temperature within the time interval to adjust the ambient temperature within the time interval to a preset temperature. Therefore, when using the smart handheld device to set the preset temperature for different time periods during sleep, the sleep quality can be improved to avoid the environment temperature being too cold or overheated during sleep.

In addition, the application operates the instantaneous power price, the contract capacity, and the ambient temperature by using a fuzzy logic algorithm to transmit the first control signal, the second control signal, and the third control signal through the air conditioner controller.

As described above, the air conditioning control system of the integrated smart handheld device application according to the present invention may have one or more of the following advantages:

(1) The air-conditioning control system of the integrated smart handheld device application of this creation can easily monitor the power consumption and power consumption history of each air-conditioning device through a smart handheld device by integrating smart meters and applications.

(2) The air-conditioning control system of the integrated smart handheld device application of this creation can control the operation mode of the high-energy-consumption air-conditioning device by integrating the real-time electricity price with the application to save power consumption during peak hours.

(3) The air conditioning control system of the integrated intelligent handheld device application of this creation can monitor the power consumption of each air conditioner by the application to integrate the contract capacity to avoid the electricity bill exceeding the budget.

(4) The air conditioning control system of the integrated intelligent handheld device application of the present invention can control a plurality of air conditioners simultaneously by using the application of the smart handheld device to set the preset temperature to achieve constant temperature and energy saving effects.

(5) The air conditioning control system of the integrated intelligent handheld device application of this creation can improve the sleep quality by using the application of the smart handheld device during sleep to set the preset temperature for different time periods, so as to avoid the ambient temperature being too cold during sleep. Or overheated conditions.

In order to give your reviewers a better understanding and understanding of the technical features of the creation and the efficiencies achieved, please refer to the preferred examples and the detailed descriptions below.

10‧‧‧Air Conditioning Controller

11‧‧‧Temperature sensing unit

12‧‧‧ Temperature signal

13‧‧‧Control signal

20‧‧‧Smart Phone

21‧‧‧Application

22‧‧‧Operation signal

23‧‧‧Environmental temperature

24‧‧‧Preset temperature

25‧‧‧Warning message

30‧‧‧Air conditioning unit

31‧‧‧Air Conditioner

32‧‧‧heater

33‧‧‧Electric fan

40‧‧‧Smart meter

50‧‧‧Internet

60‧‧‧ Instant electricity price

Figure 1 is a block diagram of the air conditioning control system for the integrated smart handheld device application.

Figure 2 is a schematic diagram of a first embodiment of an air conditioning control system for an integrated smart handheld device application of the present invention.

Figure 3 is a schematic diagram of a second embodiment of an air conditioning control system for an integrated smart handheld device application of the present invention.

Figure 4 is a schematic diagram of a third embodiment of an air conditioning control system for an integrated smart handheld device application of the present invention.

The embodiments of the air conditioning control system of the integrated smart handheld device application according to the present invention will be described below with reference to the related drawings. For ease of understanding, the same components in the following embodiments are denoted by the same reference numerals.

Please refer to Figure 1. Figure 1 is a block diagram of the air conditioning control system for the integrated smart handheld device application. The air conditioning control system of the integrated smart handheld device application includes at least an air conditioner controller 10, an application (App) 21 and a plurality of air conditioners 30. The air conditioner 30 can be, for example, an air conditioner, an electric fan or a heater.

The air conditioner controller 10 includes a temperature sensing unit 11 that senses the ambient temperature to transmit the temperature signal 12 to the smart handheld device that installs the application 21. The smart handheld device can be, for example, a smart phone 20, a tablet computer, a personal digital assistant (PDA), or a notebook computer.

Taking the smart phone 20 as an example, the application 21 receives the smart phone 20 and transmits the operation signal 22 to the air conditioner controller 10 according to the temperature signal 12. Then, the air conditioner controller 10 sends the control signal 13 to the plurality of air conditioners 30 according to the operation signal 22.

The aforementioned air conditioner controller 10 can utilize, for example, Bluetooth, Zigbee, Radio Frequency (RF), Wireless Fidelity (Wi-Fi), Global Interoperability Microwave. Worldwide Interoperability for Microwave Access (WiMAX), General Packet Radio Service (GPRS), 3rd-generation (3G), 3rd Generation 5th Generation (3.5th Generation, The 3.5G) or Long Term Evolution (LTE) technology transmits the temperature signal 12 and receives the operation signal 22.

The air conditioner controller 10 described above transmits the control signal 13 to the plurality of air conditioners 30 by using the omnidirectional infrared technology, so that the plurality of air conditioners 30 receive and operate according to the control signal 13. Among them, the air conditioner controller 10 can manufacture an omnidirectional infrared controller by using an ATMEGA328P-PU micro control wafer manufactured by Atmel, for example, to control air conditioners 30 of various brands.

In addition, the air conditioning control system integrated with the smart handheld device application further includes a plurality of smart meters 40 electrically connected to the plurality of air conditioners 30 to upload the power consumption and power consumption history of each air conditioner 30 to the Internet 50. The application 21 can obtain the power consumption and power consumption history of each air conditioner 30 through the Internet 50. However, the present invention is not limited thereto, and the air conditioning control system can also electrically connect the respective air conditioners 30 by using a single smart meter 40.

The application 21 can obtain the real-time electricity price and the contract capacity through the Internet 50, and automatically control the instantaneous electricity price and the contract capacity to control the power consumption of each air-conditioning device 30.

In addition, the application 21 can fuzzify the instantaneous power price, the contract capacity, and the ambient temperature, for example, using a fuzzy logic algorithm, and perform fuzzy inference using fuzzy logic rules to generate fuzzy inference values. Then, the fuzzy inference value is defuzzified to generate a control signal 13 through the air conditioner controller 10 to control the operation modes of the plurality of air conditioners 30. However, the present invention is not limited thereto, and any calculation method that can control the operation modes of a plurality of air conditioners 30 should be within the scope of protection claimed by the present invention.

Please refer to FIG. 1 and FIG. 2, which is a schematic diagram of a first embodiment of an air conditioning control system for an integrated smart handheld device application of the present invention.

The application 21 of the air conditioning control system integrating the smart handheld device application has different operating modes to control the operation mode of each air conditioning device 30 according to different energy saving strategies.

For example, the application 21 of the smart phone 20 can set the preset temperature 24 to adjust the ambient temperature 23 to the preset temperature 24 by controlling the operation mode of each air conditioner 30 by the air conditioner controller 10. Therefore, when the ambient temperature 23 deviates from the preset temperature 24 set by the application 21, the air conditioner controller 10 can, for example, control the air conditioner 31, the electric fan 33, or the heater 32 to operate, stop, or operate mode adjustment, respectively, to adjust the environment. Temperature 23 to preset temperature 24. Thereby, the air conditioner 31, the electric fan 33 or the heater 32 can be controlled synchronously to achieve the effect of constant temperature and energy saving.

In addition, the preset temperature 24 can correspond to different time intervals, and the application 21 can adjust the ambient temperature 23 to the preset temperature 24 according to the preset temperature 24 in each time interval. Therefore, for example, when the application 21 of the smart phone 20 can be used to set the preset temperature 24 for different time periods during sleep, the sleep quality can be improved to avoid the situation that the ambient temperature 23 is too cold or overheated during sleep.

In addition, the application 21 can adjust the operation mode of each air conditioner 30 according to the preference of the user, and the application 21 can be used to close all the air conditioners 30, or the application of the smart phone 20 when the user goes out or leaves. When the signal of the program 21 is unresponsive for a certain period of time, all the air conditioners 30 are also automatically turned off to achieve the energy saving effect in an unmanned environment.

Please refer to FIG. 1 and FIG. 3, which is a schematic diagram of a second embodiment of an air conditioning control system for an integrated smart handheld device application of the present invention.

The application 21 can obtain the instantaneous electricity price 60 through the Internet 50, for example, to transmit the control signal 13 through the air conditioner controller 10 according to the instantaneous electricity price 60 to control the operation modes of the plurality of air conditioners 30.

For example, when the power consumption peak period is high, the instant electricity price 60 is higher than the peak time period, and the application 21 can send the control signal 13 to the high-energy-consumption air conditioner 30 such as the air conditioner 31 through the air conditioner controller 10, In order to cause the air conditioner 31 to be turned off during a peak period in which the instantaneous electricity price 60 is high, for example, only the electric fan 33 is turned on to adjust the ambient temperature.

On the other hand, when the power consumption is lower than the peak period, the instant electricity price 60 is lower, and the application 21 can send the control signal 13 to the high-energy-consumption air conditioner 31 through the air conditioner controller 10, so that the air conditioner 31 is at the instantaneous electricity price. 60 lower off peak period is on. Therefore, by integrating the instant electricity price 60 by the application 21, the operation mode of the high-energy-consumption air conditioner 30 can be controlled to save power consumption during peak hours.

Please refer to FIG. 1 and FIG. 4, which is a schematic diagram of a third embodiment of an air conditioning control system for an integrated smart handheld device application of the present invention.

The application 21 can further transmit the control signal 13 to each of the air conditioners 30 through the air conditioner controller 10 according to the contract capacity, so that, for example, when the power consumption of the air conditioner 31, the electric fan 33, and the heater 32 is about to exceed, equal to, or exceed the contract capacity. The application 21 can display an alert, for example The message 25 is simultaneously controlled by the air conditioner controller 10 to stop the operation of the air conditioner 31, the electric fan 33, and the heater 32. Therefore, by integrating the contract capacity by the application 21, the power consumption of each air conditioner 30 can be monitored to prevent the electricity bill from exceeding the budget.

Further, the application program 21 can also set the upper limit of the amount of the air conditioner 31, the electric fan 33, and the heater 32, for example, to control the power consumption of each of the air conditioners 30, thereby effectively achieving energy saving and power saving.

The above is intended to be illustrative only and not limiting. Any equivalent modifications or alterations to the spirit and scope of this creation shall be included in the scope of the appended patent application.

10‧‧‧Air Conditioning Controller

11‧‧‧Temperature sensing unit

12‧‧‧ Temperature signal

13‧‧‧Control signal

20‧‧‧Smart Phone

21‧‧‧Application

22‧‧‧Operation signal

30‧‧‧Air conditioning unit

40‧‧‧Smart meter

50‧‧‧Internet

Claims (10)

An air conditioning control system for integrating a smart handheld device application, comprising: an air conditioning controller, comprising a temperature sensing unit, wherein the temperature sensing unit senses an ambient temperature to send a temperature signal; an application (App Is installed in a smart handheld device, and the application receives and sends an operation signal to the air conditioner controller according to the temperature signal, and the air conditioner controller sends a first signal according to the operation signal. a control signal; a plurality of air conditioners are received and operated according to the first control signal; and a plurality of smart meters are electrically connected to the air conditioners to upload power consumption and power history of the air conditioners to The Internet, in which the application obtains the power consumption and power history of the air conditioners via the Internet. For example, the air conditioning control system of the integrated smart handheld device application described in claim 1 wherein the application obtains an instant electricity price and a contract capacity through the Internet. An air conditioning control system for integrating a smart handheld device application according to claim 2, wherein the application further transmits a second control signal through the air conditioner controller according to the instantaneous electricity price to control the air conditioning device. Mode of operation. An air conditioning control system for integrating a smart handheld device application according to claim 3, wherein the application transmits a third control signal through the air conditioner controller according to the contract capacity, when the air conditioners consume When the power exceeds the contract capacity, the application controls the air conditioners to stop operating through the air conditioner controller. An air conditioning control system for integrating a smart handheld device application according to claim 4, wherein the application operates the instant electricity price, the contract capacity and the ambient temperature by a fuzzy logic algorithm to transmit the air conditioner The controller sends the first control signal, the second control signal, and the third control signal. Air conditioning control for integrated smart handheld device applications as described in claim 1 The system, wherein the air conditioner controller utilizes Bluetooth, Zigbee, Radio Frequency (RF), Wireless Fidelity (Wi-Fi), Global Interoperability Microwave Memory (Worldwide Interoperability for Microwave Access, WiMAX), General Packet Radio Service (GPRS), 3rd-generation (3G), 3rd Generation 5th Generation (3.5th Generation, 3.5) G) or Long Term Evolution (LTE) technology sends the temperature signal and receives the operation signal. The air conditioning control system of the integrated smart handheld device application of claim 1, wherein the air conditioning controller transmits the first control signal by using an omnidirectional infrared technology. The air conditioning control system for integrating the smart handheld device application according to claim 1, wherein the air conditioning device is an air conditioner, an electric fan or a heater. The air conditioning control system of the integrated smart handheld device application of claim 1, wherein the air conditioning controller controls the air conditioning device when the ambient temperature deviates from a preset temperature set by the application Operate, stop, or operate mode adjustments to adjust the ambient temperature to the preset temperature. The air conditioning control system for integrating the smart handheld device application according to claim 9, wherein the preset temperature corresponds to different time intervals, and the application is further based on the preset temperature in the time intervals. And adjusting the ambient temperature in the time intervals to the preset temperature.