TWM580838U - Multi-zone intelligent electrical appliance control system - Google Patents

Abstract

The present invention provides a multi-zone intelligent electrical appliance control system. The multi-zone intelligent electrical appliance control system includes a first control device group, a first lighting device group, a first Bluetooth-infrared control device group, a second control device group, a second lighting device group, and a second Bluetooth-infrared control device group. A mobile device provides a Bluetooth control signal to the server to control an electrical device through a second communication path of the first control device group or the second control device group, and the first Bluetooth-infrared control device group or the second Bluetooth-infrared control device group.

Description

Multi-zone intelligent electrical control system

The present invention relates to an electrical control system, and more particularly to a multi-zone intelligent electrical control system combining wired communication and wireless communication.

The traditional electrical control system is limited by different wireless communication protocols, and the power supply cannot be properly provided. It is impossible to achieve unified control and precise control of electrical control in different areas.

Therefore, providing a multi-zone intelligent electrical control system combining wired communication and wireless communication has become an important issue in the industry.

The technical problem to be solved by the present invention is to provide a multi-region intelligent electric appliance control system for the deficiencies of the prior art, comprising: a first control device group including a plurality of first control devices, each of the first control devices including a sequence a control module, a Bluetooth control module, and a driving module, wherein the sequence control module of each of the first control devices is electrically connected to the Bluetooth control module of each of the first control devices, wherein The plurality of first control devices are electrically connected to each other, and the sequence control module of each of the first control devices is electrically connected to the driving module of each of the first control devices; a group of luminaire devices disposed in a first area, the first luminaire device group includes a plurality of first luminaire devices, each of the first luminaire devices electrically connected to the plurality of first control devices One of the first Bluetooth infrared control device groups, comprising a plurality of first Bluetooth infrared control devices, each of the first Bluetooth infrared control devices electrically connecting the plurality of first control devices One of the first Bluetooth infrared control devices provides a first infrared signal to control an electrical device; a second control device group includes a plurality of second control devices, the plurality of second control devices Electrically connected, each of the second control devices includes a sequence control module, a Bluetooth control module, and a drive module, and the sequence control module of each of the second control devices is electrically connected to each of the The Bluetooth control module of the second control device, wherein the sequence control module of each of the second control devices is electrically connected to the driving module of each of the second control devices, wherein One of the plurality of second control devices of the second group of control devices is electrically connected to one of the plurality of first control devices of the first group of control devices; a second lamp device a group, the second luminaire device group includes a plurality of second luminaire devices, each of the second luminaire devices being electrically connected to one of the plurality of second control devices; And a second blue The infrared control device group includes a plurality of second Bluetooth infrared control devices, each of the second Bluetooth infrared control devices is electrically connected to one of the plurality of second control devices, wherein each second Bluetooth infrared control device Providing a second infrared signal to control another electrical device; wherein the first control device group and the second control device group are respectively connected to a server; wherein the first area and the first The two areas are different areas; wherein a mobile device provides a luminaire control signal to the server, and at least the first communication path of the first control device group or the second control device group is controlled by the first communication path One of the plurality of first luminaire devices of the first luminaire device group, one of the plurality of second luminaire devices of the second luminaire device group, or the other An electrical device; wherein the mobile device provides a Bluetooth control signal to the server, through the first control device group or a second of the second control device group And a communication path and the first Bluetooth infrared control device group or the second Bluetooth infrared control device group to control the another electrical device.

One of the beneficial effects of this creation is that the multi-zone intelligent electrical control system uses a sequence control module and a Bluetooth control module in each control assembly, and is equipped with multiple Bluetooth infrared control devices, and transmits signals by different serial communication paths. To improve communication efficiency and reduce signal interference, and to achieve electrical control by means of cross-region wired or wireless signal transmission.

In order to further understand the features and technical contents of this creation, please refer to the following detailed description and drawings of the present invention. However, the drawings are provided for reference and description only, and are not intended to limit the creation.

The following is a description of an embodiment of the "lighting device" disclosed in the present disclosure by a specific embodiment, and those skilled in the art can understand the advantages and effects of the present invention from the contents disclosed in the present specification. The present invention can be implemented or applied in various other specific embodiments. The details of the present specification can also be variously modified and changed without departing from the concept of the present invention. In addition, the drawings of the present creation are only for the purpose of simple illustration, and are not stated in advance according to the actual size. The following embodiments will further explain the related technical content of the present invention, but the disclosure is not intended to limit the scope of protection of the present invention.

It should be understood that, although the terms "first", "second", "third", and the like may be used herein to describe various elements or signals, these elements or signals are not limited by these terms. These terms are primarily used to distinguish one element from another, or one signal and another. In addition, the term "or" as used herein may include a combination of any one or more of the associated listed items, depending on the actual situation.

[First Embodiment]

Please refer to FIG. 1. FIG. 1 is a schematic diagram of a multi-zone intelligent electrical control system according to an embodiment of the present invention. 2 is another schematic diagram of a multi-zone intelligent appliance control system of the present embodiment.

In this embodiment, the multi-zone intelligent appliance control system 1 includes a first control device group S1, a second control device group S2, and a third control device group S3. The first control device group S1, the second control device group S2, and the third control device group S3 are respectively disposed in a first area A1, a second area A2, and a third area A3. The first area A1, the second area A2, and the third area A3 are different areas, respectively. The number of areas can be adjusted according to actual needs, and there is no restriction in this creation.

In this embodiment, each control device group includes a plurality of control devices. Each control device has a sequence number. These sequential numbers are sorted according to an arrangement order. As shown in Fig. 1, the arrangement order is arranged in accordance with the sequence number of each control device. In the present embodiment, these control devices are arranged in a ring shape. In other embodiments, these control devices may be arranged in other ways, and are not limited in this creation. Further, these control devices sequentially transmit signals in accordance with the arrangement order.

In this embodiment, the first control device group S1 includes a plurality of control devices S1-1~S1-12, and the plurality of control devices S1-1~S1-12 respectively pass a first communication path P1 and a first The second communication path P2 performs the transmission of different types of signals. The second control device group S2 includes a plurality of control devices S2-1 to S2-12, and the plurality of control devices S2-1 to S2-12 are also respectively performed through a first communication path P1 and a second communication path P2. The transmission of different types of signals. The third control device group S3 includes a plurality of control devices S3-1 to S3-12, and the plurality of control devices S3-1 to S3-12 are respectively different through a first communication path P1 and a second communication path P2. The transmission of type signals. The number of control devices in each control device group can be adjusted according to actual needs, and no limitation is imposed in the present creation.

Please refer to FIG. 2. FIG. 2 is another schematic diagram of the multi-zone intelligent electrical control system of the second embodiment of the present invention.

In the present embodiment, the multi-zone smart appliance control system 2' includes a first control device group S1', a second control device group S2', and a third control device group S3'. In this embodiment, the first control device group S1 ′, the second control device group S2 ′, and the third control device group S3 ′ are respectively disposed in a first area (not shown) and a second area. (not shown) and a third area (not shown). The first area (not shown), the second area (not shown), and the third area (not shown) are different areas.

In the present embodiment, the first control device group S1' includes five first control devices S1-1' to S1-5'. The second control device group S2' includes five second control devices S2-1' to S2-5'. The third control device group S3' includes six third control devices S3-1' to S3-5'.

Here, as described in the previous embodiment, the first control devices S1-1' to S1-5' are electrically connected to each other. The second control devices S2-1' to S2-5' are electrically connected to each other. The third control devices S3-1' to S3-6' are electrically connected to each other.

In this embodiment, the multi-zone smart electrical control system 1 ′ further includes a first luminaire device group (not shown) and a second luminaire device group (not shown) and a third luminaire device group ( The figure is not shown). The first luminaire device group (not shown) includes first luminaire devices T1-1'~T1-4'. The second luminaire device group (not shown) includes second luminaire devices T2-1'~T2-4'. The third luminaire device group (not shown) includes third luminaire devices T3-1'~T3-5'. In this embodiment, the first lamp devices T1-1'~T1-4', the second lamp devices T2-1'~T2-4', and the third lamp devices T3-1'~T3-5' are all illuminated. Diode lighting fixture. However, none of the first lamp devices T1-1' to T1-4', the second lamp devices T2-1' to T2-4', and the third lamp devices T3-1' to T3-5' do not include any DC. Or AC drive circuit.

In the present embodiment, the first control devices S1-1' to S1-4' are electrically connected to the first lamp devices T1-1' to T1-4', respectively. The second control devices S2-1' to S2-4' are electrically connected to the second lamp devices T2-1' to T2-4', respectively. The third control devices S3-1' to S3-5' are electrically connected to the third lamp devices T3-1' to T3-5', respectively.

That is, the first control device S1-5', the second control device S2-5', and the third control device S3-6' are not electrically connected to the lamp device. In this embodiment, each control device can be electrically connected to the lighting device, the Bluetooth infrared control module, or other Bluetooth devices according to actual needs, and is not limited in the present creation.

In this embodiment, the multi-zone intelligent appliance control system 1' further includes a first Bluetooth infrared control device group BR1', a second Bluetooth infrared control device group BR2', and a third Bluetooth infrared control device group BR2. '. In this embodiment, the first Bluetooth infrared control device group BR1', the second Bluetooth infrared control device group BR2', and the third Bluetooth infrared control device group BR2' respectively include a first Bluetooth infrared control device BR1. -1'~BR3-1' and a second Bluetooth infrared control device BR1-2'~BR3-2'.

In this embodiment, the first Bluetooth infrared control device group BR1', a second Bluetooth infrared control device group BR2', and a third Bluetooth infrared control device group BR2' of the first Bluetooth infrared control device BR1-1 '~BR3-1' and the second Bluetooth infrared control device BR1-2'~BR3-2' are electrically connected to the first control device S1-2', the second control device S2-2' and the third control device S3- 2'. In this embodiment, the Bluetooth infrared control device is configured to convert the Bluetooth control signal or the control signal into an infrared control signal after receiving the Bluetooth control signal or the control signal to control the electrical device having the infrared receiving module.

In this embodiment, the first Bluetooth infrared control device BR1-1'~BR3-1' and the second Bluetooth infrared control device BR1-2'~BR3-2' may respectively provide a first infrared signal or a second Infrared signal to control an electrical device (not shown).

Please refer to FIG. 3. FIG. 3 is a schematic diagram of a first control device of the present embodiment. In the present embodiment, only the first control device S1-1' is taken as an example, and the architecture and functions of the other control devices are the same as those of the first control device S1-1', and no limitation is imposed in the present creation.

In this embodiment, the first control device S1-1' includes a sequence control module S1-100', a Bluetooth control module S1-101', and a drive module S1-102'. The sequence control module S1-100' of the first control device S1-1' is electrically connected to the Bluetooth control module S1-101' of the first control device S1-1'. The sequence control module S1-101' of the first control device S1-1' is electrically connected to the drive module S1-102' of the first control device S1-1'. Similarly, the sequence control module (not shown) of the first control device S1-2'~S1-5' is electrically connected to the Bluetooth control module of the first control device S1-2'~S1-5' (not shown) Show). The sequence control modules (not shown) of the first control devices S1-2' to S1-5' are electrically connected to the drive modules (not shown) of the first control devices S1-2' to S1-5'.

In other embodiments, the control device of the same area may set the Bluetooth control module (not shown) with only one control device, and the other control devices do not set the Bluetooth control module. That is, the way of signal transmission is mainly transmitted by the sequence control module.

Similarly, the sequence control module (not shown) of the second control device S2-1'~S2-5' is electrically connected to the Bluetooth control module of the second control device S2-1'~S2-5' (not shown) Show). The sequence control modules (not shown) of the second control devices S2-1' to S2-5' are electrically connected to the drive modules (not shown) of the second control devices S2-1' to S2-5'. The sequence control module (not shown) of the third control device S3-1'~S3-6' is electrically connected to the Bluetooth control module (not shown) of the third control device S3-1'~S3-6'. The sequence control modules (not shown) of the third control devices S3-1' to S3-6' are electrically connected to the drive modules (not shown) of the third control devices S3-1' to S3-6'.

In the present embodiment, the first control device group S1', the second control device group S2', and the third control device group S3' are communicably connected to a server 9' via a gateway device 2'.

That is, the user can transmit a control signal to the server 9' using a mobile device (not shown). The server 9' can transmit the control signal to the first control device group S1', the second control device group S2' or the third control device group S3' through the gateway device 2' to control the first light device device T1. -1'-T1-4', the second lamp device T2-1'-T2-4', the third lamp device T3-1'-T3-5', and one of electrical equipment (not shown).

The user can also transmit a Bluetooth control signal to the first Bluetooth infrared control device BR1-1'~BR3-1' or the second Bluetooth infrared control device BR1-2'~BR3-2' by using a mobile device (not shown). Transmitting the signal through the sequence control module of the first control device group S1', the second control device group S2' or the third control device group S3' to control the first lamp device T1-1'-T1 -4', the second lamp device T2-1'-T2-4', the third lamp device T3-1'-T3-5', and one of electrical equipment (not shown). That is, in the present embodiment, the user can perform electrical control across the first area (not shown), the second area (not shown), and the third area (not shown).

In the present embodiment, the server 9' is communicatively coupled to the gateway device 2' via a first communication protocol. In this embodiment, the server 9' may be disposed at the local end or in an area disposed at the far end, and is not limited in this creation.

In this embodiment, the first communication protocol includes a Wi-Fi protocol (Wi-Fi), a Zigbee protocol, a Bluetooth protocol, a LoRa protocol, and a Sigfox protocol. It can be adjusted according to actual needs, and there is no restriction in this creation.

In this embodiment, the first lamp devices T1-1'-T1-5', the second lamp devices T2-1'-T2-4', and the third lamp devices T3-1'-T3-4' are respectively passed a first sequence communication path of the first control device S1-1'~S1-5', the second control device S2-1'~S2-5', and the third control device S3-1'~S3-6' transfer.

The first Bluetooth infrared control device BR1-1'~BR3-1' or the second Bluetooth infrared control device BR1-2'~BR3-2' pass the first control device S1-1'~S1-5', A second sequence communication path of the second control device S2-1'~S2-5' and the third control device S3-1'~S3-6' performs signal transmission. In this embodiment, the first sequence communication path and the second sequence communication path are the first control devices S1-1' to S1-5', the second control devices S2-1' to S2-5', and the third control device. Different communication paths between multiple sequence control modules (not shown) of S3-1'~S3-6'. That is, in this embodiment, each of the first control devices is electrically connected to the sequence control module of the other first control device by using the respective sequence control module. Similarly, each second control device is electrically connected to the sequence control module of the other second control device by using the respective sequence control module. Each third control device is electrically connected to the sequence control module of the other third control device by using the respective sequence control module.

In the present embodiment, the sequence control of the first control devices S1-1' to S1-5', the second control devices S2-1' to S2-5', and the third control devices S3-1' to S3-6' The module can be an RS485 sequence control module or an RS232 sequence control module.

In the present embodiment, the Bluetooth communication module of the third control device S3-6' of the third control device group S3' of the multi-zone smart device control system 1' is communicatively coupled to a first Bluetooth device BT1'. That is, the first Bluetooth device BT1' is an independent Bluetooth device. In this embodiment, the first Bluetooth device BT1' may be in communication connection with the first Bluetooth infrared control device BR3-1' or the second Bluetooth infrared control device BR3-2' by Bluetooth communication protocol. Similarly, if the distance between the first Bluetooth infrared control device BR3-1' and the second Bluetooth infrared control device BR3-2' is less than or equal to a predetermined wireless communication distance, the first Bluetooth infrared control device BR3-1' and the second The Bluetooth Infrared Control Unit BR3-2' can be connected wirelessly. If the distance between the first Bluetooth infrared control device BR3-1' and the second Bluetooth infrared control device BR3-2' is greater than a predetermined wireless communication distance, the first Bluetooth infrared control device BR3-1' and the second Bluetooth infrared control device BR3 Between -2', a wired communication connection can be made through a second sequence communication path between the sequence control modules (not shown) of the third control device S3-1'~S3-6'.

That is, if the user needs to control the electrical equipment of the first area (not shown) in the third area (not shown). The first Bluetooth infrared control device BR3-1' or the second Bluetooth infrared control device BR3-2' for controlling the signal to the third area (not shown) can be transmitted by the mobile device. Then, the control signal is transmitted to the first area (not shown) through a second sequence communication path between the sequence control modules (not shown) of the third control device S3-1'~S3-6' A first control device S1-5' of the control device group S1'. Then, the control signal is transmitted to the first area (not shown) by the sequence control device of the first control device S1-1'~S1-5' to the first Bluetooth infrared control device BR1-1' or the second Bluetooth infrared control. The device BR1-2' is configured to cause the first Bluetooth infrared control device BR1-1' or the second Bluetooth infrared control device BR1-2' to convert the control signal into an infrared control signal to control the corresponding electrical device.

In addition, in this embodiment, the first control device S1-5' of the first control device group S1', the second control device S2-5' of the second control device group S2', and the third control device group The third control device S3-6' of S3' is electrically connected to a first power source (not shown), a second power source (not shown), and a third power source (not shown) to receive the first The driving power required by the control device group S1', the second control device group S2', and the third control device group S3'. In the present embodiment, the first control device S1-5' of the first control device group S1' can provide drive power to the first control devices S1-1' to S1-4' using the sequence control module. The second control device S2-5' of the second control device group S2' can also provide drive power to the second control devices S2-1' to S2-4' by the sequence control module. The third control device S3-6' of the third control device group S3' may also provide drive power to the third control devices S3-1' to S3-6' by the sequence control module.

In addition, in this embodiment, the first Bluetooth infrared control device BR1-1'~BR3-1' or the second Bluetooth infrared control device BR1-2'~BR3-2' are respectively controlled by the first control device S1. -2', the first control device S1-5', the second control device S2-2', the second control device S2-5', and the third control device S3-2' provide driving power. That is, the plurality of first Bluetooth infrared control devices of the first Bluetooth infrared control device group BR' are powered by a plurality of first control devices that are electrically connected.

Referring to FIG. 4 and FIG. 5, FIG. 4 is a partial schematic diagram of the multi-zone intelligent electrical control system of the present embodiment set in a first area. FIG. 5 is a schematic diagram of another portion of the multi-zone intelligent electric appliance control system of the present embodiment set in the first area.

As shown in FIG. 4, in the first area, the user provides a control signal to the first Bluetooth infrared control device BR1-1' or the second Bluetooth infrared control device BR1-2' by using the mobile device to the first region. Electrical equipment E1-E5 is controlled. In FIG. 5, the first Bluetooth infrared control device BR1-1' or the second Bluetooth infrared control device BR1-2' passes through the sequence control module of the first first control device S1-1'~S1-5' The two-sequence communication path SW2 performs signal transmission. In Fig. 5, the first Bluetooth infrared control device BR1-1' or the second Bluetooth infrared control device BR1-2' can also perform signal transmission via a wireless communication connection.

Figure 5 shows the first sequence communication of the control signals of the first lamp device T1-1'-T1-5' through the sequence control module of the first control device S1-1'~S1-5' in the first region. A schematic diagram of the path SW1 is delivered.

In this embodiment, the electrical equipment E1-E5 is an electrical appliance including an infrared control module, that is, the electrical equipment E1-E5 can receive the first Bluetooth infrared control module BR1-1' or the second Bluetooth infrared control module. Infrared control signal from BR1-2' for adjustment and operation.

[Advantageous Effects of Embodiments]

One of the beneficial effects of this creation is that the multi-zone intelligent electrical control system uses a sequence control module and a Bluetooth control module in each control assembly, and is equipped with multiple Bluetooth infrared control devices, and transmits signals by different serial communication paths. To improve communication efficiency and reduce signal interference, and to achieve electrical control by means of cross-region wired or wireless signal transmission.

The above disclosure is only a preferred and feasible embodiment of the present invention, and is not intended to limit the scope of the patent application of the present invention. Therefore, any equivalent technical changes made by using the present specification and the content of the schema are included in the application for this creation. Within the scope of the patent.

1‧‧‧Multi-regional intelligent electrical control system

S1‧‧‧First Control Unit Group

S2‧‧‧Second Control Unit Group

S3‧‧‧ third control unit group

S1-1~S1-12, S1-1'~S1-5'‧‧‧ first control device

S2-1~S2-12, S2-1'~S2-5'‧‧‧second control device

S3-1~S3-12, S3-1'~S3-6'‧‧‧ third control device

P1‧‧‧First communication path

P2‧‧‧Second communication path

BR1’‧‧‧First Bluetooth Infrared Control Unit Group

BR2’‧‧‧Second Bluetooth Infrared Control Unit Group

BR3’‧‧‧ Third Bluetooth Infrared Control Unit Group

BR1-1’~BR3-1’‧‧‧First Bluetooth Infrared Control

BR1-2’~BR3-2’‧‧‧Second Bluetooth Infrared Control Device

T1-1’~T1-5’‧‧‧First luminaire installation

T2-1'~T2-4'‧‧‧Second lighting fixture

T3-1’~T3-5’‧‧‧ Third luminaire installation

2'‧‧‧Gateway installation

9’‧‧‧Server

S1-100’‧‧‧Sequence Control Module

S1-101'‧‧‧Bluetooth Control Module

S1-102'‧‧‧ drive module

SW1‧‧‧ first sequence communication path

SW2‧‧‧Second serial communication path

E1-E5‧‧‧Electrical equipment

BT1’‧‧‧First Bluetooth device

1 is a schematic diagram of a multi-zone intelligent electric appliance control system of the first embodiment of the present invention.

2 is another schematic diagram of a multi-zone intelligent appliance control system of the second embodiment of the present invention.

3 is a schematic diagram of a first control device of the present embodiment.

4 is a partial schematic view showing the multi-zone intelligent electric appliance control system of the present embodiment set in the first area.

FIG. 5 is a schematic diagram of another portion of the multi-zone intelligent electric appliance control system of the present embodiment set in the first area.

Claims (8)

A multi-zone intelligent electrical control system includes: a first control device group comprising a plurality of first control devices, each first control device comprising a sequence control module, a Bluetooth control module, and a drive module, The sequence control module of each of the first control devices is electrically connected to the Bluetooth control module of each of the first control devices, wherein the plurality of first control devices are electrically connected to each other. The sequence control module of the first control device is electrically connected to the driving module of each of the first control devices; a group of first lighting devices is disposed in a first area, the first a luminaire device group includes a plurality of first luminaire devices, each of the first luminaire devices electrically connecting one of the plurality of first control devices; a first Bluetooth infrared control device group, including a plurality a first Bluetooth infrared control device, each first Bluetooth infrared control device is electrically connected to one of the plurality of first control devices, wherein each first Bluetooth infrared control device provides a first An external signal to control an electrical device; a second control device group comprising a plurality of second control devices, the plurality of second control devices being electrically connected to each other, each second control device comprising a sequence control module, a Bluetooth control module and a driving module, the sequence control module of each of the second control devices is electrically connected to the Bluetooth control module of each of the second control devices, wherein each The sequence control module of the second control device is electrically connected to the drive module of each of the second control devices, wherein the plurality of second control devices of the second control device group One of the plurality of first control devices electrically connected to the first control device group; one second light device device group disposed in a second region, the second light fixture device group The group includes a plurality of second luminaire devices, each of the second luminaire devices being electrically connected to one of the plurality of second control devices; and a second Bluetooth infrared ray control device group including a plurality of second Bluetooth devices Infrared control Each of the second Bluetooth infrared control devices is electrically connected to one of the plurality of second control devices, wherein each second Bluetooth infrared control device provides a second infrared signal to control another electrical device; The first control device group and the second control device group are respectively connected to a server; wherein the first area and the second area are different areas; wherein a mobile device provides a light fixture Controlling, by the server, the at least one first luminaire of the first luminaire device group by a first communication path of the first control device group or the second control device group One of the devices, one of the plurality of second luminaire devices of the second luminaire device group, the electrical device or the other electrical device; wherein the mobile device provides a Bluetooth control Signaling to the server, through the first control device group or a second communication path of the second control device group and the first Bluetooth infrared control device group The second Bluetooth device groups infrared control, to control the other electrical equipment. The multi-zone intelligent electric appliance control system according to claim 1, wherein the control signal is transmitted to the first control device group or the second control device group through a gateway device. The multi-zone intelligent electrical control system of claim 2, wherein the server is in communication with the gateway device via a first communication protocol. The multi-region intelligent electric appliance control system according to claim 3, wherein the first communication protocol comprises a Wi-Fi protocol, a Zigbee protocol, and a Bluetooth communication. Agreement (Bluetooth), a LoRa protocol, and a Sigfox protocol. The multi-zone intelligent electrical control system of claim 1, wherein the sequence control module of each of the first control devices is an RS485 sequence control module or an RS232 sequence control module. The multi-zone intelligent electric appliance control system of claim 1, wherein each of the first control devices is electrically connected to the other first control device by using the respective one-sequence control module. Each of the second control devices is electrically connected to the other second control device by using the respective one of the sequence control modules, and a first Bluetooth device is communicably connected to one of the plurality of first control devices. One of the Bluetooth control module or the plurality of first Bluetooth infrared control devices. The multi-zone intelligent electric appliance control system of claim 1, wherein the plurality of first Bluetooth infrared control devices of the first Bluetooth infrared control device group are caused by the plurality of corresponding electrical connections. The first control device provides a driving power source. The multi-zone intelligent electric appliance control system of claim 5, wherein the plurality of first control devices of the first control device group respectively have a sequence number, the plurality of first control devices The respective sequence numbers are sorted according to a first order, the plurality of first control devices sequentially transmitting signals according to the first sequence, and the plurality of second control devices of the second control device group Each of the plurality of second control devices sequentially sorts the sequential numbers according to a second sequence, and the plurality of second control devices sequentially transmit the signals according to the second sequence.