TW201700925A - Cloud-control air conditioning system capable of easily setting up the air conditioning device without using signal lines between the indoor unit and the outdoor unit - Google Patents

Abstract

The invention provides an air conditioning device and a cloud-control air conditioning system. The air conditioning device includes an outdoor unit module, at least one indoor unit module, a first control module connected to the indoor unit module via signals, and a second control module connected to the outdoor unit module via signals. The first control module is able to control the operation of the indoor unit module and wirelessly transmit control commands to the second control module, so as to drive the second control module to correspondingly control the operation of the outdoor unit module. With the structure design of using wireless communication for transmitting and receiving control commands between the first control module and the second control module, the air conditioning device of the present invention can be set up more easily, so as to eliminate the problem of signal line setup between the indoor unit and the outdoor unit.

Description

Air conditioning unit and cloud control air conditioning system

The invention relates to an air conditioning device and system, in particular to a separate air conditioning device and a cloud controlled air conditioning system using cloud control technology.

The split type air conditioner generally includes an indoor unit and an outdoor unit. When the split type cold air is installed, the indoor unit is installed indoors, and the outdoor unit is installed outdoors, and the outdoor unit and the indoor unit are connected to each other. An air conditioning duct, and a control line is connected between the two to control the operation of the outdoor unit via the indoor unit. However, when the distance between the indoor unit and the outdoor unit is too far, in addition to causing the control line to be too long and increasing the cost, how to pull the signal line is also difficult. In addition, the current central air-conditioning system design of the building is composed of one outdoor unit with multiple indoor units, and the outdoor unit will be fixed and powerful regardless of how many indoor units are turned on. It is a kind of air-conditioned air conditioner. system design.

Since the wireless communication technology and the cloud technology are quite mature, if the wireless communication technology and the cloud technology are combined and applied to the air conditioner, the above problems can be improved, and the air conditioner can be conveniently monitored and managed by the cloud technology.

Accordingly, it is an object of the present invention to provide an air conditioning apparatus having a wireless communication function.

Another object of the present invention is to provide a cloud control air conditioning system that monitors in conjunction with cloud technology.

Therefore, the air conditioner of the present invention comprises an outdoor unit module that can be driven to generate air-conditioning gas, at least one indoor unit that is connected to the outdoor unit module and can be controlled to discharge the air-conditioning gas generated by the outdoor unit module. The module, a signal is connected to the first control module of the indoor unit module, and a second control module is connected to the outdoor unit module. The first control module is controlled by a remote control signal to control the operation of the indoor unit module, and includes a first control unit that can be driven by the remote control signal to control the operation of the indoor unit module and correspondingly generate a control command, and A first communication unit that is drivable by the first control unit to wirelessly transmit the control command. The second control module includes a second communication unit that can wirelessly receive the control command, and a second control unit that can be driven by the control command received by the second communication unit to control the operation of the outdoor unit module. .

Thus, the cloud control air conditioning system of the present invention comprises an air conditioning device and a servo device connected to the air conditioning device via an internet. The air conditioning device includes an outdoor unit module that can be driven to generate air-conditioning gas, at least one indoor unit module that is connected to the outdoor unit module and can be controlled to discharge the air-conditioning gas generated by the outdoor unit module, and a The signal is connected to the first control module of the indoor unit module, and a second control module is connected to the outdoor unit module. The first control module includes a a first control unit that can be driven by a remote control signal to control the operation of the indoor unit module and correspondingly generate a control command, and a first control unit can be driven to connect to the internet and transmit the control command to The first communication unit of the servo device. The second control module includes a second communication unit that can be connected to the Internet to receive the control command transferred by the servo device, and a control command that can be received by the second communication unit is driven to correspondingly control the The second control unit for the operation of the outdoor unit module.

The effect of the present invention: through the structural design of the air conditioner and the servo device, the cloud control air conditioning system of the present invention can learn to record the usage of the air conditioner in addition to remotely monitoring the power consumption of the air conditioner. The air conditioner is automatically controlled according to the user's habit to adjust the indoor environment to a suitable comfortable state.

3‧‧‧Air conditioning unit

31‧‧‧Indoor unit module

311‧‧‧ indoor unit

312‧‧‧ Temperature Sensor

313‧‧‧Humidity Sensor

314‧‧‧First power meter

32‧‧‧Outdoor unit module

321‧‧‧Outdoor unit body

322‧‧‧Second electricity detector

33‧‧‧First Control Module

331‧‧‧First Control Unit

332‧‧‧First communication unit

333‧‧‧First wireless communication interface

334‧‧‧First network interface

34‧‧‧Second control module

341‧‧‧Second control unit

342‧‧‧Second communication unit

343‧‧‧Second wireless communication interface

344‧‧‧Second network interface

5‧‧‧Servo

51‧‧‧Network communication module

52‧‧‧Climate Information Capture Module

53‧‧‧ learning module

54‧‧‧Air conditioning recommendation module

55‧‧‧Power Control Module

56‧‧‧Power Forecasting Module

57‧‧‧Outdoor machine control module

800‧‧‧ mobile devices

Other features and effects of the present invention will be apparent from the following description of the drawings, wherein: FIG. 1 is a schematic structural diagram of a first embodiment of the cloud control air conditioning system of the present invention; FIG. 2 is the first implementation FIG. 3 is a schematic structural diagram of a second embodiment of the cloud control air conditioning system of the present invention; and FIG. 4 is a functional block diagram of the second embodiment.

Before the present invention is described in detail, it should be noted in the following In the description, similar elements are denoted by the same reference numerals.

As shown in FIG. 1 and FIG. 2, the first embodiment of the cloud control air conditioning system of the present invention comprises an air conditioner 3 and a servo device 5, and the air conditioner 3 and the servo device 5 can be connected to each other via the Internet. And the servo device 5 can also perform communication and data transmission with a mobile device 800 held by the user of the air conditioner 3 via the Internet. The mobile device 800 may be a mobile phone, a tablet computer, a notebook computer, a smart watch, smart glasses, etc., but is not limited to the above types.

The air conditioner 3 includes an outdoor unit module 32, an indoor unit module 31, a first control module 33 mounted to the indoor unit module 31, and a second control mounted to the outdoor unit module 32. Module 34.

The outdoor unit module 32 includes an outdoor unit body 321 that can be driven to generate air-conditioning gas, and a second power consumption detector 322 that is electrically connected to the outdoor unit body 321 . The second power consumption detector 322 The power consumed by the operation of the outdoor unit body 321 can be monitored, and the power consumption information of the outdoor unit is output correspondingly.

The indoor unit module 31 includes an indoor unit body 311, and a first power consumption detector 314, a temperature sensor 312 and a humidity sensor 313 respectively mounted to the indoor unit body 311. The indoor unit body 311 is connected to the outdoor unit main body 321 through an air conditioning duct (not shown), and is driven to output the air conditioner gas generated by the outdoor unit main body 321 and injected into the air conditioning duct. The first power consumption detector 314 can measure the power consumed by the indoor unit body 311 and output an indoor unit power consumption information. The temperature sensor 312 can sense the indoor unit body 311 At a temperature of the environment to output a temperature information, the humidity sensor 313 can sense the humidity of the environment in which the indoor unit body 311 is located to output a humidity information.

The first control module 33 is located in an environment provided by the indoor unit body 311, and can be remotely controlled by a remote controller (not shown), and correspondingly controls the indoor unit body 311 and the second control module. 34 operation. The first control module 33 includes a first control unit 331 and a first communication unit 332. The first communication unit 332 includes a first wireless communication interface 333 that can communicate with the second control module 34 via wireless communication technology, and a first communication network capable of communicating with the servo device 5 Network interface 334. The first control unit 331 can be triggered by the remote control signal to control the operation of the indoor unit body 311, and correspondingly generate a control command for controlling the second control module 34, and the first wireless communication is performed. The interface 333 transmits the control command to the second control module 34. In addition, the first control unit 331 can also receive the power consumption information of the indoor unit, and can integrate the temperature information and the humidity information into an indoor environment parameter, and record the air conditioning function and start of the indoor unit body 311 that is controlled to be activated. The air conditioner usage information is generated, and the indoor unit power consumption information, the indoor environment parameter, and the air conditioner usage information are transmitted to the servo device 5 via the first network interface 334.

The second control module 34 includes a second communication unit 342 and a second control unit 341. The second communication unit 342 has a second wireless communication interface 343 that can communicate with the first wireless communication interface 333 to receive the control command, and a connectable internet network and the server The second network interface 344 is communicated by the device 5, and the second control unit 341 can transmit the outdoor unit power consumption information to the servo device 5 via the second network interface 344. .

In this embodiment, the wireless communication technology refers to a communication technology that cannot be connected to the Internet, such as Bluetooth, ZigBee, and the like, but is not limited thereto, and the first network interface 334 and the first The second network interface 344 connects to the Internet through wired network technology and/or wireless network technology, such as connecting a wireless router (not shown) through WIFI to connect to the Internet.

The server device 5 includes a network communication module 51 capable of connecting to the Internet, a climate information capturing module 52, a learning module 53, an air conditioning suggesting module 54, and a power management module 55, and A power prediction module 56.

The network communication module 51 can be connected to the first network interface 334 and the second network interface 344 via the Internet, and can receive the power consumption information of the indoor unit, the indoor environment parameter, and the air conditioner usage information. Power consumption information with the outdoor unit. The climate information capture module 52 can connect to the Internet via the network communication module 51, and capture the current local climate information of the area where the air conditioner 3 is located from a specific weather website, and weather forecast for a specific period in the future. News.

The learning module 53 can receive the local climate information, the indoor environment parameter and the air conditioner usage information when the indoor unit body 311 is activated, and establish a habit parameter about the indoor unit module 31, and Further record and analyze all customary parameters for a specific period of time, and A habit estimation mode for the indoor unit module 31 is established, for example, a neural network, a support vector machine or other statistical analysis technique is used to analyze and establish the habit estimation mode, but the implementation is not limited to the above method. The air conditioning suggesting module 54 can analyze the local climate information currently captured by the climate information capturing module 52 according to the custom estimation mode, and the indoor environment parameter currently uploaded by the first control module 33 to generate a a recommended air conditioning parameter for the current suitable operating condition of the indoor unit module 31, and transmitting the recommended air conditioning parameter to the first control module 33 and the second control module 34 via the network communication module 51 to drive the The second control module 34 controls the operation of the outdoor unit module 32 according to the recommended air conditioning parameter, and drives the first control module 33 to control the operation of the indoor unit module 31, thereby changing the indoor unit module 31. The temperature and humidity conditions of the indoor environment, at this time, the air conditioning conditions of the indoor environment will be quite in line with the user's habits and needs.

The power control module 55 can preset the total available power of the air conditioner 3 for a certain period of time, and can comprehensively collect the power consumption information of the indoor unit and the power consumption information of the outdoor unit to calculate and output the air conditioner. The total power consumption of the device 3, and further analyzing the proportional relationship between the total available power and the total power consumption to output a total power consumption information. In addition, the power control module 55 can also send a reminder message to the first control mode via the network communication module 51 when the total power consumption reaches a certain proportion of the total available power, for example, up to 80%. The group 33 or the mobile device 800 can be configured to send a shutdown command to the first control module 33 and the second control module 34 when the total power consumption is equal to the total power consumption, to drive the first The control module 33 turns off the indoor unit module 31 and drives the second control The module 34 closes the outdoor unit module 32.

The power prediction module 56 can receive and analyze the climate forecast information captured by the climate information capture module 52 for a specific period in the future, and the habit estimation mode established by the learning module 53 to generate a The power consumption prediction information of the specific period is transmitted to the mobile device 800 to remind the user to pay attention.

After the erection of the cloud control air conditioning system of the present invention is completed, the air conditioning device 3 periodically uploads the indoor environmental parameters to the servo device 5, and the servo device 5 automatically captures the local climate information and the weather forecast information. When the cloud control air conditioner system is used, the user can send a remote control signal for controlling the operation of the air conditioner 3 to the first control module 33 through the remote controller, and drive the first control module 33 to correspondingly control the indoor unit module. The operation of 31, for example, starts the indoor unit module 31 to start outputting air-conditioning cold air, and controls the air volume, the wind direction, and the like. At the same time, the first control module 33 generates a control command correspondingly, and sends the control command to the second control module 34 through the wireless communication technology, so that the second control module 34 controls the outdoor unit correspondingly. The operation of the module 32, for example, drives the outdoor unit module 32 to operate to generate air conditioning gas, as well as control its operating power and the like.

After the air conditioner 3 is activated, the servo device 5 starts to receive the indoor environment parameter uploaded by the first control module 33 and the second control module 34, the indoor unit power consumption information, and the outdoor unit power consumption. Information on the use of electrical information and air conditioning to analyze and generate this habit estimation model. By this design, the servo device 5 can analyze the current indoor environmental parameters and the local climate information according to the custom estimation mode at any time, and generate a suitable recommended air conditioning parameter. And automatically controlling the air conditioner to generate an air conditioning environment suitable for the user's habit, or to facilitate the user to remotely control the operation of the air conditioner 3 according to the recommended air conditioning parameter to generate a current climate and indoor environment parameters. Air conditioning environment.

Through the above design, in addition to being designed to directly control the operation of the air conditioner 3 directly by the servo device 5, the recommended air conditioner parameters can also be designed to be transmitted to a mobile device 800, so that the air conditioner device 3 can be set by the user. The operation of the air conditioner 3 and the air conditioning environment generated by the air conditioner 3 are quite compatible with the user's usage habits and needs, so the indoor environment can be adjusted to a relatively comfortable state. In addition, the servo device 5 can also control the total accumulated power consumption of the air conditioner 3, and can send a warning message when the total power consumption reaches a certain proportion of the preset total available power, exceeding the preset total. It is quite convenient to automatically power off and control when the power is available, and it can further predict the power consumption forecasting information for a certain period of time, so that users can plan the response measures for future power consumption.

As shown in FIGS. 3 and 4, the second embodiment of the cloud control air conditioning system of the present invention differs from the first embodiment in the structural design of the air conditioning device 3 and the functional design of the servo device 5. For convenience of description, only the differences between the present embodiment and the first embodiment will be described below.

In this embodiment, the air conditioner 3 includes a plurality of indoor unit modules 31 connected to the first control module 33, and the first control module 33 can separately generate one for each indoor unit module 31. The indoor environment parameter, and the indoor environment parameter of each indoor unit module 31, the indoor unit power consumption information, and the air conditioner use information are transmitted to the servo device 5.

The servo device 5 can separately analyze and generate the custom estimation mode and the recommended air conditioning parameter for each indoor unit module 31, and can set the available power of each unit of the indoor unit module 31, and further analyze the available power of the single unit and correspondingly The indoor unit consumes power information of the indoor unit module 31 to generate a single unit power consumption information.

In addition, the server device 5 further includes an outdoor unit control module 57, and the outdoor unit control module 57 can receive the air conditioner usage information of each indoor unit module 31 uploaded by the first control module 33. Knowing the number of indoor unit modules 31 that have been activated, and transmitting an operation control signal for controlling the running intensity of the outdoor unit module 32 according to the number of activated indoor unit modules 31, the second control module 34 can receive The operation control signal is corresponding to the operation state of the outdoor unit module 32. For example, when only one indoor unit module 31 is turned on, the operation control signal drives the second control module 34 to control the outdoor unit module. When the plurality of indoor unit modules 31 are successively started, the second control module 34 gradually enhances the running strength of the outdoor unit module 32 according to the received operation control signal. With this design, the high power consumption problem that the outdoor unit of the central air conditioning system of the conventional building can only operate at a fixed operation intensity can be improved, so that the power consumption of the air conditioner 3 can be effectively reduced.

Furthermore, in the above embodiment, the first control module 33 and the second control module 34 both connect the servo device 5 via the Internet, and the first control module 33 and the second control module The group 34 can directly communicate wirelessly. However, if the first control module 33 is too far away from the second control module 34 to perform wireless communication, the first control module can be driven. The control command is transmitted to the servo device 5 via the Internet, and the control command is transferred to the second control module 34 by the servo device 5. In addition, the second control module 34 is not required to be connected to the Internet. The first control module 33 can be configured to connect to the Internet to receive the recommended air conditioning parameters and shutdown commands. The first control module 33 controls the operation of the outdoor unit module 32 by remotely controlling the second control module 34 via the wireless communication technology according to the recommended air conditioning parameter and the shutdown command.

In summary, the structural design of transmitting and receiving the control command by using the wireless communication between the first control module 33 and the second control module 34 makes the erection of the air conditioner 3 of the present invention more convenient and can be exempted from the indoor unit. The module 31 and the outdoor unit module 32 pull the problem of erecting the signal line.

In addition, by the functional design between the air conditioner 3 and the servo device 5, the cloud control air conditioner system of the present invention can learn to record the user's use of the air conditioner in addition to remotely monitoring the power consumption of the air conditioner 3. The use of 3 to establish a habit estimation mode for the air conditioner 3, and to analyze and provide a recommended air conditioning parameter suitable for the current local climate information and the indoor environmental parameter to automatically control the air conditioner 3 to the indoor The environment is adjusted to suit the user's habits and needs, and is quite convenient and practical. It is an innovative air-conditioning device 3 and cloud-controlled air-conditioning system design. Therefore, the creative purpose of the present invention can be achieved.

The above is only the preferred embodiment of the present invention, and the scope of the present invention is not limited thereto, and the simple equivalent changes and modifications made by the scope of the patent application and the patent specification of the present invention are It is still within the scope of the invention patent.

3‧‧‧Air conditioning unit

31‧‧‧Indoor unit module

32‧‧‧Outdoor unit module

33‧‧‧First Control Module

34‧‧‧Second control module

5‧‧‧Servo

800‧‧‧ mobile devices

Claims (21)

An air conditioning device comprising: an outdoor unit module that can be driven to generate air conditioning gas; at least one indoor unit module connected to the outdoor unit module and controlled to discharge the air conditioner generated by the outdoor unit module Gas; a first control module, the signal is connected to the indoor unit module, and can be controlled by a remote control signal to control the operation of the indoor unit module, including a remote control signal to control the operation of the indoor unit module And corresponding to a first control unit for generating a control command, and a first communication unit capable of wirelessly transmitting the control command; and a second control module, the signal is connected to the outdoor unit module, including a wirelessly receivable control And a second communication unit of the command, and a second control unit driven by the control command received by the second communication unit to control the operation of the outdoor unit module. The air conditioning device of claim 1, wherein the first communication unit comprises a first wireless communication interface that can wirelessly transmit the remote control command to the second communication unit, and the second communication unit includes a wirelessly receivable a second wireless communication interface of the remote command sent by a wireless communication interface. The air conditioner according to claim 2, wherein the indoor unit module is configured to communicate with a servo device via an internet, wherein the indoor unit module includes an indoor unit body that can be driven by the first control unit to output air conditioning gas, and a a temperature sensor that senses the temperature of the environment in which the indoor unit is located to output a temperature information, and a sensor that senses the location of the indoor unit The humidity of the environment corresponds to a humidity sensor that outputs a humidity information, and the first communication unit further includes a first network interface connected to the servo signal by the connectable internet, and the first control unit can receive The humidity information and the temperature information are collected to generate an indoor environment parameter, and the indoor environment parameter is sent to the servo device via the first network interface. The air conditioning device according to claim 1, wherein the first communication unit includes a connectable internet network and transmits the remote control command to the server device. In a network interface, the second communication unit includes a second network interface that can be connected to the Internet to receive the remote command transmitted by the server. The air conditioner according to claim 4, wherein the indoor unit module includes an indoor unit body that can be driven by the first control unit to output an air-conditioning gas, and a temperature that can sense an environment of the indoor unit body to output a temperature sensing unit for temperature information, and at least one humidity sensing unit capable of sensing the humidity of the environment of the indoor unit body and correspondingly outputting a humidity information, the first control unit receiving and receiving the humidity information and the temperature information An indoor environmental parameter is generated, and the indoor environmental parameter is sent to the servo device via the first network interface. The air conditioner according to claim 3 or 5, wherein the indoor unit module further includes a first power measuring device capable of sensing power consumption of the indoor unit body and outputting an indoor unit power consumption information. The first control unit can also transmit the power consumption information of the indoor unit via the first network interface. Send to the servo. The air conditioner according to claim 3, wherein the outdoor unit module includes an outdoor unit body that can be controlled to operate to generate the air-conditioning gas, and an outdoor unit that senses the power consumption of the outdoor unit body and outputs an outdoor unit The second power unit of the machine power consumption information, the second communication unit further includes a second network interface that can connect to the Internet to communicate with the server, and the second control unit can The second network interface transmits the outdoor unit power consumption information to the servo device. The air conditioner according to claim 6, wherein the outdoor unit module includes an outdoor unit body that can be controlled to operate to generate the air-conditioning gas, and an outdoor unit that senses the power consumption of the outdoor unit body and outputs an outdoor unit The second power consumption device of the machine power consumption information, the second control unit can transmit the outdoor unit power consumption information to the servo device via the second network interface. The air conditioner according to claim 3 or 5, comprising a plurality of indoor unit modules respectively connected to the outdoor unit module and capable of outputting air-conditioning gas, wherein the first control module is connected to the indoor unit by signals The first control unit can respectively receive the temperature information and the humidity information of each indoor unit module to generate an indoor environment parameter. A cloud control air conditioning system includes an air conditioning device and a servo device connected to the air conditioner via an internet, the air conditioner comprising: an outdoor unit module that can be driven to generate air conditioning gas; at least one indoor unit a module connected to the outdoor unit module, And can be controlled to discharge the air-conditioning gas generated by the outdoor unit module; a first control module, the signal is connected to the indoor unit module, and comprises a remote control signal to control the operation of the indoor unit module and corresponding a first control unit that generates a control command, and a first communication unit that can connect to the Internet and transmit the control command to the servo device; and a second control module that is connected to the outdoor unit module a second communication unit that can be connected to the Internet to receive the control command forwarded by the server, and a control command that can be received by the second communication unit to control the outdoor unit module The second control unit that operates. The cloud control air conditioning system of claim 10, wherein the indoor unit module includes an indoor unit body that can be driven by the first control unit to output air conditioning gas, and a temperature that can sense an environment of the indoor unit body a temperature sensing unit for outputting a temperature information, and a humidity sensing unit capable of sensing the humidity of the environment of the indoor unit body and outputting a humidity information, the first control unit may receive and collect the humidity information and the temperature information And generating an indoor environmental parameter, and transmitting the indoor environmental parameter to the servo device via the first communication unit. The cloud control air conditioning system of claim 11, wherein the servo device comprises a network communication module capable of receiving the control command and transferring the control command to the second communication unit, and a network communication module The communication module connects to the Internet to capture the climate information acquisition module of the local climate information of the area where the air conditioner is located, and an acceptable analysis The climate information corresponding to the indoor environment parameter transmitted by the first control module corresponds to an air conditioning suggestion module that proposes an air conditioning parameter. The cloud control air conditioning system of claim 12, wherein the first control unit is further configured to record an air conditioner function and an activation time of the indoor unit body to generate an air conditioner usage information, and The air conditioner uses information to transmit to the servo device, the servo device further includes a learning module, wherein the learning module can analyze the local climate information currently received, the indoor environment parameter and the air conditioner usage information to generate a habit parameter, and The habit estimation parameter can be cumulatively analyzed to establish a habit estimation mode, and the air conditioning suggesting module can analyze the current local climate information and the indoor environmental parameter according to the habit estimation mode, and correspondingly generate the Recommended air conditioning parameters. The cloud control air conditioning system of claim 12 or 13, wherein the air conditioning suggestion module can transmit the recommended air conditioning parameter to the second control module via the network communication module, the second control unit The second communication unit receives the recommended air conditioning parameter, and controls the operation of the outdoor unit module according to the recommended air conditioning parameter. The cloud control air conditioning system of claim 12 or 13 may be further connected to a mobile device for communication, wherein the air conditioning suggestion module can transmit the recommended air conditioning parameter to the action via the network communication module. Device. The cloud control air conditioning system of claim 12 or 13, wherein the first communication unit includes a connectable internet network to transmit the control command and the indoor environment parameter to the first network interface of the server ,and a first wireless communication interface that can be activated to directly transmit the control command to the second communication unit, the first control unit can connect the network communication module via the first network interface to receive the recommended air conditioner And generating a control command corresponding to the recommended air conditioning parameter, and transmitting the control command to the second control module via the first wireless interface that has been activated. The cloud control air conditioning system of claim 16, wherein the second communication unit comprises a connectable internet network to receive the second network interface that the network communication module transmits to the control command, and one a second wireless communication interface that is activated to wirelessly receive the control command transmitted by the first wireless communication module. The cloud control air conditioning system of claim 12 or 13, wherein the indoor unit module further comprises a first power meter electrically connected to the indoor unit body and capable of measuring and outputting an indoor unit power consumption information The first control unit can transmit the indoor unit power consumption information to the servo device via the first communication unit, the outdoor unit module includes an outdoor unit body that can be driven to generate air-conditioning gas, and one is electrically connected to the The outdoor unit body and the second power measuring device capable of outputting an outdoor unit power consumption information, wherein the second control unit can transmit the outdoor unit power consumption information to the servo device via the second communication unit, the servo The device further includes a power management module, and the power management module can receive the power consumption information of the indoor unit and the power consumption information of the outdoor unit via the network communication module to estimate a total power consumption. The cloud control air conditioning system according to claim 18, wherein the air conditioner The system includes a plurality of indoor unit modules respectively connected to the first controller, and the power control module is configured to set a single unit available power of each indoor unit module in a specific period, and the communication module is available through the network Receiving the power consumption information of the indoor units to estimate the power consumption of the single unit of each indoor unit module, and analyzing the ratio of the power consumption of the single unit of each indoor unit module to the available power of the single unit to output a single unit power consumption News. The cloud control air conditioning system of claim 18, wherein the servo device further comprises a power prediction module, wherein the power prediction module can connect to the Internet through the network communication module to capture a specific period Weather forecast information, and can receive and analyze the weather forecast information and the habit estimation mode, and output a power consumption forecasting information corresponding to a specific period. The cloud control air conditioning system of claim 13, wherein the air conditioning device comprises a plurality of indoor unit modules respectively connected to the first controller, wherein the first control unit can record the air conditioners in which the indoor units are activated. The function and the activation time respectively generate the air conditioner usage information, and the air conditioner usage information is transmitted to the servo device via the first communication unit, the servo device further includes an outdoor unit management module, and the outdoor unit management module The air conditioner usage information may be collected to confirm the number of indoor unit modules that are currently activated, and an operation adjustment signal is generated correspondingly, and the operation and adjustment signal is transmitted to the second control module via the network communication module. The second control unit can be touched by the operation adjustment signal to adjust the operation of the outdoor unit module.