CN114124986A - Intelligent power distribution system with remote and near range interconnection and intercommunication and multi-million mutual control - Google Patents

Abstract

The invention discloses an intelligent power distribution system with remote and near range interconnection and intercommunication trillion-control, relating to the field of power distribution, comprising: the network remote module is used for logging in the cloud platform through a mobile phone and a computer, inputting signals in the cloud platform, and outputting the signals to the main control module through the Ethernet, the CAN bus and the RS232 communication interface; compared with the prior art, the invention has the beneficial effects that: the remote control receiving template is additionally arranged in each electric appliance, so that all single intelligent and non-intelligent electric appliance products can be integrally or independently controlled in a far-short range and an independent-short range in an interconnected mode, the system equipment can be integrally interconnected and intercommunicated regardless of the distribution of the equipment, and the effect of trillion control is achieved, so that various problems of artificial intelligence are solved, meanwhile, the artificial intelligence brings incomparable rapidness and convenience to people, the happiness and the acquisition feeling of the life index of the people are further improved, and more updated national efficiency can be created for the country.

Description

Intelligent power distribution system with remote and near range interconnection and intercommunication and multi-million mutual control

Technical Field

The invention relates to the field of power distribution, in particular to an intelligent power distribution system with remote and near range interconnection and intercommunication and multi-gang mutual hundred million control.

Background

Interconnection and intercommunication device and system for controlling interconnection and intercommunication control in a million-in-one manner, namely, devices and systems for controlling interconnection and intercommunication control in a long and short way, without limitation to multiple people and regions and without limitation to multiple devices. N computers and X mobile phones log on at any time and any place, and are directly linked with on-site ordinary switches, custom switches and the like for control. The intelligent household intelligent control system can be widely applied to all electrical appliances in the fields of intelligent homes, villas, hotels, industrial electromechanics, stations, high buildings, islands, bridges, urban landscapes, traffic, electric power, water conservancy, military industry and the like, integrated control is realized, independent control can be realized, and the functions can be set at will.

In the current intelligent environment, the paradigm of single intelligence is not winning the number, can not realize this firm and the integrative interconnection of the electrical apparatus product of that firm to each electrical apparatus has each different APP, and the operation flow is turned over to be loaded down with trivial details moreover, and most APP can not directly download on the computer and directly link on the spot with the cell-phone, has so far hindered that a majority of working clan must download the login with the cell-phone.

Disclosure of Invention

The invention aims to provide an intelligent power distribution system with remote and near distance interconnection and intercommunication and multi-million-control-based mutual control, so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

an intelligent power distribution system with multi-link and multi-hundred million-control mutual communication in long-distance and short-distance interconnection comprises:

the network remote module is used for logging in the cloud platform through a mobile phone and a computer, inputting signals in the cloud platform, and outputting the signals to the main control module through the Ethernet, the CAN bus and the RS232 communication interface;

the sensor module is used for collecting external environment information and outputting the information to the main control module,

the main control module is used for comprehensively processing the received information, uploading the information input by the sensor module to the cloud platform in a communication manner, and controlling the high-frequency infrared remote control module and the relay module to work;

the high-frequency infrared remote control module is used for transmitting high-frequency infrared signals to control machines (such as an air conditioner, a television and the like) controlled by the infrared signals and interconnected with the network remote module;

the relay module is used for controlling the on and off of the switch to control the working state of the electric appliance;

the network remote module is connected with the main control module in a bidirectional mode, the sensor module is connected with the main control module, and the main control module is connected with the high-frequency infrared remote control module and the relay module.

As a still further scheme of the invention: the relay module includes electronic empty eight way control circuit that open, electronic empty eight way control circuit that open includes 8 electronic electric leakage circuit, electronic electric leakage circuit includes electronic flexible push rod K1, emergent manual push-and-pull rod K2, earth leakage protection circuit breaker TA, live wire L1, live wire L2, live wire L3 passes through switch S1 and connects fuse FU, earth leakage protection ware TA is connected to fuse FU' S the other end, electronic flexible push rod K1, emergent manual push-and-pull rod K2 locates switch S1 department.

As a still further scheme of the invention: fuse FU opens when current is at 600A.

As a still further scheme of the invention: the relay module comprises a star three-start control circuit, the star three-start control circuit comprises a fuse FU1, a fuse FU2, a motor M1, a live wire L1, a live wire L2, a live wire L3 is connected with three fuse FU1 through a switch QS respectively, the other end of the three fuse FU1 is connected with the first end of a switch KM-3, the second end and the third end, the fourth end, the fifth end and the sixth end of the switch KM-3 are connected with the first end, the second end and the third end of the motor M1 respectively, the fourth end, the fifth end and the sixth end of the switch KM-3 are connected with the fourth end, the fifth end and the sixth end of the motor M1 through a switch KM delta-3 respectively, and one end of the fuse FU2 is connected with a relay KT, a relay KMY and a relay KMdelta.

As a still further scheme of the invention: the relay module comprises a forward and reverse rotation control circuit, the forward and reverse rotation control circuit comprises a switch-KM 1-1-6, a switch-KM 2-1-6, a relay-KM 1 and a relay-KM 2, a zero line N is connected with the A2 end of the relay-KM 1 and the A2 end of the relay-KM 2, the A1 end of the relay-KM 1 is connected with the switch-KM 2-11-12, the other end of the switch-KM 2-11-12 is connected with the switch-SB 2-13-14, the switch-KM 1-13-14, the other end of the switch-SB 2-13-14 is connected with the other end of the switch-KM 1-13-14, the switch-SB 3-13-14 and the switch-KM 2-13-14, the other end of the switch-SB 3-13-14 is connected with the other end of the switch-KM 2-13-14, switch-KM 1-11-12, the other end of switch-KM 1-11-12 is connected with A1 end of relay-KM 2, one end of switch-KM 1-1-6 is connected with one end of switch-KM 2-1-6 and thermorelay-FR, and the other end of thermorelay-FR is connected with motor M2.

As a still further scheme of the invention: the relay module comprises a self-locking control circuit, the self-locking control circuit comprises a motor M3, a thermal relay FR1, a switch S11, a switch S12, a switch S13, a relay S14 and a switch FR2, the motor M3 is connected with the thermal relay FR1, the other end of the thermal relay FR1 is connected with the switch S11, the other end of the switch S11 is connected with the switch S12, one end of the switch S13 is connected with the relay S14, and the other end of the relay S14 is connected with the switch FR 2.

As a still further scheme of the invention: the relay module comprises thirty-six control circuits, the thirty-six control circuits have 36 control lines in total, and each control line outputs 220V voltage and 40A/63A/80A current.

Compared with the prior art, the invention has the beneficial effects that: the invention enables all electrical products of single intelligence and non-intelligence to be integrally or independently controlled by far and short range interconnection, and the equipment can be integrally interconnected and intercommunicated and controlled by billions no matter where the equipment is distributed, thereby solving a plurality of problems of artificial intelligence, simultaneously enabling artificial intelligence to bring incomparable rapidness and convenience to people, further improving the happy life index of people, and creating stronger updating efficiency for the country.

Drawings

Fig. 1 is a schematic diagram of a remote and near distance interconnection and interconnection multi-gang multi-billion-control intelligent power distribution system.

Fig. 2 is a circuit diagram of the relay module electric air switch.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by a person of ordinary skill in the art without creative efforts based on the embodiments of the present invention belong to the protection scope of the present invention.

Referring to fig. 1, a remote and near distance interconnection and intercommunication intelligent power distribution system with trillion mutual control includes:

the network remote module is used for logging in the cloud platform through a mobile phone and a computer, inputting signals in the cloud platform, and outputting the signals to the main control module through the Ethernet, the CAN bus and the RS232 communication interface;

the sensor module is used for collecting external environment information and outputting the information to the main control module,

the main control module is used for comprehensively processing the received information, uploading the information input by the sensor module to the cloud platform in a communication manner, and controlling the high-frequency infrared remote control module and the relay module to work;

the high-frequency infrared remote control module is used for transmitting a high-frequency infrared signal to control a machine controlled by the infrared signal;

the relay module is used for controlling the on and off of the switch to control the working state of the electric appliance;

the network remote module is connected with the main control module in a bidirectional mode, the sensor module is connected with the main control module, and the main control module is connected with the high-frequency infrared remote control module and the relay module.

In a specific embodiment: referring to fig. 1, the distance and the distance are controlled by a network remote module, wired on-site switch control and wireless remote control interconnection control, and are combined with various sensors (intelligent voice module, face swiping, card swiping, finger film, password, infrared ray and the like) to be overlaid into a whole for arbitrary joint control. Such as: when the electric appliances are controlled to be connected or edited in a certain area, the sensors matched with the equipment can be independently linked with the switch after the field switch is operated. Meanwhile, the equipment is provided with a multi-channel combined integral programming interface, each single electric appliance which needs to be continuously controlled is connected in sequence, and the equipment APP, the remote control panel and each corresponding single sensor are directly connected and controlled to realize interconnection and mutual control. The operation response speed of the interconnection joint control is within 0.1-1.0 second according to network signals. When some electric appliance needs to be operated, the electric appliance is directly connected with the set switch, the keys and the sensors. In the control process, no matter on APP of a mobile phone and a computer, or on each wired switch or each wireless sensor, the linkage speed is fast to how fast the operation is, and the electric appliance starts to reflect how fast the operation is.

Remote control: through the connected electronic terminals such as mobile phones, computers and the like, the N devices are connected to local network signals after being electrified no matter where the N devices are installed, and a unified login account or an independent account is set, so that the intelligent mobile phones and the computers can directly log in the joint control. Such as: in urban buildings, no matter how high the buildings are, the high buildings have several floors, after the device is installed, all lighting systems, security systems, fire control management, ventilation management, water supply and drainage, heating and air supply, doors and windows, curtains and the like of each building are downloaded by a mobile phone or a computer, the APP is installed on the device, a set account and a set password are directly opened by login, and the device is integrated with sensors on the spot or independently controlled according to requirements. The APP can also be provided with an individual or regional plate account (such as one-family control, multiple remote joint control, or integration of office, family or famous shops, factories and enterprises) to be matched and linked with various sensors on the spot, so that the ideal intelligent life of interconnection and intercommunication and trillion control is really realized.

Field operation: the wired switch is in superposition linkage with various sensors such as an infrared remote control sensor, an intelligent voice sensor, a face sensor, a card reader, a finger film sensor, a password sensor and the like. Can connect a plurality of switches and many sets of sensor and long-range integrative interconnection of carrying out mutual accuse with network APP. Namely: when a switch is turned on, any one of the sensors can be turned off, and vice versa. The defect of single function control of each electric appliance is overcome. When the device is switched in and out of a plurality of networks, normal use is not influenced when the network is suddenly disconnected or not available in the use process of the electric appliance. The equipment adopts the multi-path route of the Internet of things to switch in, and utilizes each telecommunication network signal platform to selectively receive network signal supply, thereby solving the trouble that once a circuit is bitten by a mouse when a single network is switched in, the circuit is carelessly torn off when in decoration and other inequality factors, and meanwhile, in the technical innovation, the equipment emphasizes that each electric appliance is not influenced by the broken network when the network is not available or is completely unavailable. The ideal effect that the power is not cut off when the network is disconnected (automatic switching when the network is available) is achieved. After years of power-on operation practice, the equipment has no abnormity in the operation performance and debugging operation in various climates and environments, and can be directly installed and used.

The implementation scheme of each electric appliance in fig. 2 is as follows:

the principle of a common current fusing master switch is as follows: an electric telescopic push rod K1 is additionally arranged on an original handle switching-on and switching-off operating rod, so that the intelligent automatic separation and switching-on functions of the power distribution main brake in the original manual operation can be realized. The control line is accessed into the intelligent system, is in line connection with the network module mainboard, and is in wireless parallel processing with the high-frequency remote control receiving module and the intelligent AI voice module through the self-designed integrated circuit control circuit board system. The device is directly controlled in a wired parallel connection mode on the spot by a common button switch, an external infrared sensor, a human body proximity switch sensor, a finger mode password and face swiping card switch sensor and an external fire fighting system sensor. Realizes not only manual but also intelligent remote linkage

The current action electric circuit breaker has the functions of leakage protection (produced by original manufacturers), leakage protection, overload protection, overvoltage, undervoltage, short circuit prevention, zero line shortage prevention, phase line shortage prevention protection, large-range adjustable rated current and manual and automatic integration.

Three, 220V single-phase electric air switch, 380V three-phase four-wire electric air switch, original manufacturer produces, only the on-off function. Through the technical innovation, the network, the remote control module and the related sensors are additionally arranged, and the linkage of the programming module is adopted to realize the near-remote interconnection and mutual control and the program starting and separation.

And fourthly, the common contactor has an intelligent control function, and the network remote control and on-site common button switch interconnection mutual control is realized by self-resetting connection of the original traditional circuit control foundation, the network relay module and the high-frequency remote control module.

And fifthly, the remote control emitter matched with each sensor of the device is directly linked with each electric door and window, the curtain, the lighting system, the security joint control system and the like through the network module and each sensor module in a direct wireless and wired control mode.

In this embodiment: referring to fig. 2, the relay module includes eight control circuits of electric idle switch, the eight control circuits of electric idle switch include 8 electric leakage circuits, the electric leakage circuits include electric telescopic push rod K1, emergency manual push-pull rod K2, leakage protection breaker TA, live wire L1, live wire L2, live wire L3 connect fuse FU through switch S1, leakage protection ware TA is connected to the other end of fuse FU, electric telescopic push rod K1, emergency manual push-pull rod K2 locate switch S1.

The circuit switch S1 is controlled to be switched on through the electric telescopic push rod K1 and the emergency manual push-pull rod K2, and the electric telescopic push rod K1 is connected with the network editor.

In this embodiment: referring to FIG. 2, fuse FU is opened when current is 600A.

And each device is prevented from being damaged by large current.

In this embodiment: referring to fig. 2, the relay module includes a three-star start control circuit, the three-star start control circuit includes a fuse FU1, a fuse FU2, and a motor M1, a live wire L1, a live wire L2, and a live wire L3 are respectively connected to three fuses FU1 through a switch QS, another end of the three fuses FU1 is connected to a first end, a second end, and a third end of a switch KM-3, a fourth end, a fifth end, and a sixth end of the switch KM-3 are respectively connected to a first end, a second end, and a third end of the motor M1, a fourth end, a fifth end, and a sixth end of the switch KM-3 are respectively connected to a fourth end, a fifth end, and a sixth end of the motor M1 through a switch KM Δ -3, and one end of the fuse FU2 is connected to a relay KT, a relay KMY, a relay KM, and a relay Δ KM.

When the load has no strict requirement on the starting torque of the motor M1 and the starting current of the motor M1 needs to be limited, the motor meets the 380V/delta connection condition, and the stator windings are connected into a triangle when the motor M1 normally runs.

In this embodiment: referring to fig. 2, the relay module comprises a forward and reverse rotation control circuit, the forward and reverse rotation control circuit comprises a switch-KM 1-1-6, a switch-KM 2-1-6, a relay-KM 1 and a relay-KM 2, a zero line N is connected with an end A2 of the relay-KM 1 and an end A2 of the relay-KM 2, an end A1 of the relay-KM 1 is connected with a switch-KM 2-11-12, the other end of the switch-KM 2-11-12 is connected with a switch-SB 2-13-14 and a switch-KM 1-13-14, the other end of the switch-SB 2-13-14 is connected with the other end of the switch-KM 1-13-14, the switch-SB 3-13-14 and the switch-KM 2-13-14, and the other end of the switch-SB 3-13-14 is connected with the other end of the switch-KM 2-13-14 One end of the switch-KM is connected with the switch-KM 1-11-12, the other end of the switch-KM 1-11-12 is connected with the A1 end of the relay-KM 2, one end of the switch-KM 1-1-6 is connected with one end of the switch-KM 2-1-6 and the thermorelay-FR, and the other end of the thermorelay-FR is connected with the motor M2.

The relay-KM 1 and the relay-KM 2 respectively control the switch-KM 1-1-6 and the switch-KM 2-1-6, the rotating directions of the motor M2 are opposite when the switch-KM 1-1-6 is closed and when the switch-KM 2-1-6 is closed, the motor M2 is controlled to complete forward and reverse rotation through the relay-KM 1 and the relay-KM 2, and the relay-KM 1 and the relay-KM 2 are interlocked, so that the switch-KM 1-1-6 and the switch-KM 2-1-6 are not closed at the same time.

In this embodiment: referring to fig. 2, the relay module includes a self-locking control circuit, the self-locking control circuit includes a motor M3, a thermal relay FR1, a switch S11, a switch S12, a switch S13, a relay S14, and a switch FR2, the motor M3 is connected to the thermal relay FR1, the other end of the thermal relay FR1 is connected to the switch S11, the other end of the switch S11 is connected to the switch S12, one end of the switch S13 is connected to the relay S14, and the other end of the relay S14 is connected to the switch FR 2.

After the button switch is pressed (the button switch on the switch S13 in fig. 2), the relay S14 is powered on, the control switch S11 and the switch S13 are closed, after the button switch is flicked, the switch S13 is closed, the relay S14 continues to be powered on to work, self-locking is completed, the thermal relay FR1 prevents the working temperature of the motor M3 from being too high, when the temperature is too high, the switch FR2 is disconnected, the relay S14 is powered off, the switch S11 flicks, the motor M3 is stopped to continue to work, and the motor M3 is protected.

In this embodiment: referring to fig. 2, the relay module includes thirty-six control circuits, which have 36 control lines in total, and each control line outputs 220V voltage and 40A/63A/80A current.

The 36 control lines can select different current outputs to meet different electrical appliance requirements.

The working principle of the invention is as follows: the network remote module logs in the cloud platform through a mobile phone and a computer, signals are input in the cloud platform, and the signals are output to the main control module through the Ethernet, the CAN bus and the RS232 communication interface; meanwhile, the sensor module collects external environment information and outputs the information to the main control module, the main control module comprehensively processes the received information, the information input by the sensor module is uploaded to the cloud platform in a communication mode, and the high-frequency infrared remote control module and the relay module are controlled to work; the switch is controlled to be closed or flicked through the high-frequency infrared remote control module and the relay module, and control over different electric appliances is met.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (7)

1. The utility model provides an intelligent power distribution system that distance interconnection intercommunication, the billion of mutual accuse, its characterized in that:

this long-range and short-range interconnection intercommunication, intelligent distribution system that ten thousand ally controlled each other includes:

the network remote module is used for logging in the cloud platform through a mobile phone and a computer, inputting signals in the cloud platform, and outputting the signals to the main control module through the Ethernet, the CAN bus and the RS232 communication interface;

the sensor module is used for collecting external environment information and outputting the information to the main control module,

the main control module is used for comprehensively processing the received information, uploading the information input by the sensor module to the cloud platform in a communication manner, and controlling the high-frequency infrared remote control module and the relay module to work;

the high-frequency infrared remote control module is used for transmitting high-frequency infrared signals to control machines controlled by the infrared signals and interconnected with the network remote module;

the relay module is used for controlling the on and off of the switch to control the working state of the electric appliance;

the network remote module is connected with the main control module in a bidirectional mode, the sensor module is connected with the main control module, and the main control module is connected with the high-frequency infrared remote control module and the relay module.

2. The remote and near distance interconnection and interconnection intelligent power distribution system controlled by billions of millions of units is characterized in that the relay module comprises an electric air opening eight-way control circuit, the electric air opening eight-way control circuit comprises 8 electric leakage circuits, the electric leakage circuits comprise an electric telescopic push rod K1, an emergency manual direct push pull rod K2 and a leakage protection circuit breaker QS, a live wire L1, a live wire L2 and a live wire L3 are connected with a fuse through a switch S1, the other end of the fuse FU is connected with the leakage protection FU QS, and the electric telescopic push rod K1 and the emergency manual push pull rod K2 are arranged at the switch S1.

3. The far and near range interconnection trillion controlled intelligent power distribution system of claim 2, wherein fuse FU opens at a current of 600A.

4. The far-near-distance interconnection and interconnection multi-million-control intelligent power distribution system according to claim 1, wherein the relay module comprises a three-star start control circuit, the three-star start control circuit comprises a fuse FU1, a fuse FU2 and a motor M1, a live wire L1, a live wire L2 and a live wire L3 are respectively connected with three fuses FU1 through a switch QS, the other end of the three fuses FU1 is connected with a first end, a second end and a third end of a switch KM-3, a fourth end, a fifth end and a sixth end of the switch KM-3 are respectively connected with a first end, a second end and a third end of the motor M1, a fourth end, a fifth end and a sixth end of the switch KM-3 are respectively connected with a fourth end, a fifth end and a sixth end of the motor M1 through a switch KM delta-3, and one end of the fuse FU2 is connected with a relay KT, a relay KMY, a relay KM and a relay KMdelta.

5. The intelligent power distribution system of claim 1, wherein the relay module comprises a forward-reverse control circuit, a forward-reverse control circuit and a reverse-reverse control circuit, the forward-reverse control circuit comprises a switch-KM 1-1-6, a switch-KM 2-1-6, a relay-KM 1 and a relay-KM 2, a neutral line N is connected with an A2 end of the relay-KM 1 and an A2 end of the relay-KM 2, an A1 end of the relay-KM 1 is connected with a switch-KM 2-11-12, the other end of the switch-KM 2-11-12 is connected with a switch-SB 2-13-14 and a switch-KM 1-13-14, the other end of the switch-SB 2-13-14 is connected with the other end of the switch-KM 1-13-14, the switch-SB 3-13-14, The other end of the switch-KM 2-13-14, the other end of the switch-SB 3-13-14 is connected with the other end of the switch-KM 2-13-14 and the switch-KM 1-11-12, the other end of the switch-KM 1-11-12 is connected with the A1 end of the relay-KM 2, one end of the switch-KM 1-1-6 is connected with one end of the switch-KM 2-1-6 and the thermorelay-FR, and the other end of the thermorelay-FR is connected with the motor M2.

6. The intelligent power distribution system of claim 1, wherein the relay module comprises a self-locking control circuit, the self-locking control circuit comprises a motor M3, a thermal relay FR1, a switch S11, a switch S12, a switch S13, a relay S14 and a switch FR2, the motor M3 is connected with the thermal relay FR1, the other end of the thermal relay FR1 is connected with the switch S11, the other end of the switch S11 is connected with the switch S12, one end of the switch S13 is connected with the relay S14, and the other end of the relay S14 is connected with the switch FR 2.

7. The far and near distance interconnection and interconnection trillion-control intelligent power distribution system according to claim 1, characterized in that the relay module comprises thirty-six control circuits, the thirty-six control circuits have 36 control lines, and each control line outputs 220V voltage and 40A or 63A or 80A current.

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