CN206817833U - Line control machine and air energy heat pump - Google Patents

Abstract

The utility model discloses a kind of line control machine and air energy heat pump, wherein, the line control machine includes power carrier communication circuit, MCU control module and WIFI module, and the power carrier communication circuit, MCU control module and WIFI module interconnect two-by-two；Wherein, the power carrier communication circuit is connected by two core power carrier lines with controlled device, to receive the power supply of the controlled device conveying, and the MCU control module and WIFI module are supplied, while for mutual data transmission between the MCU control module and the controlled device；The WIFI module, with for mutual transmission signal between the MCU control module and intelligent terminal, it is intended to convenient installation.

Description

Line controller and air energy heat pump

Technical Field

The utility model relates to an air energy heat pump control field, in particular to drive-by-wire ware and air energy heat pump.

Background

An air-source heat pump is a device that transfers heat by heat exchange with air. In daily life, users generally obtain heated hot water and/or cooled, heated air through an air-energy heat pump. Namely, the air energy heat pump can absorb the heat in the air to heat the water; and the indoor temperature can be adjusted through the refrigerant circulation loop.

The air energy heat pump is generally installed outdoors, and a user generally needs to arrange a wire controller indoors to send out a control signal to the air energy heat pump and monitor the operation condition of the air energy heat pump in real time. Therefore, when the line controller is installed indoors, the power line needs to be connected to supply power to the line controller, and a signal line for transmitting and receiving signals needs to be connected. The installation of wire controller needs to use the wire rod in a large number, leads to the installation of wire controller comparatively complicated, and the installation degree of difficulty is high.

SUMMERY OF THE UTILITY MODEL

The utility model mainly aims at providing a drive-by-wire ware and air energy heat pump, aim at easy to assemble.

In order to achieve the purpose, the utility model provides a line controller comprises a power line carrier communication circuit, an MCU control module and a WIFI module, wherein the power line carrier communication circuit, the MCU control module and the WIFI module are interconnected in pairs; the power carrier communication circuit is connected with the controlled equipment through a two-core power carrier wire so as to receive the power supply transmitted by the controlled equipment, supply the power supply to the MCU control module and the WIFI module and simultaneously supply the MCU control module and the controlled equipment to transmit data mutually; and the WIFI module is used for mutual signal transmission between the MCU control module and the intelligent terminal.

Preferably, the two-core power carrier wire is a non-polar two-core power carrier wire.

Preferably, the power carrier communication circuit includes a power circuit and a communication circuit, the power circuit and the communication circuit are respectively connected to the power carrier line, the communication circuit is connected to the MCU control module, and the power circuit is respectively connected to the MCU control module and the WIFI module.

Preferably, the wire controller further comprises a storage device, and the storage device is connected with the power circuit; the storage device is connected with the MCU control module.

Preferably, the wire controller further comprises a display screen, and the display screen is connected with the power circuit; the display screen is connected with the MCU control module.

Preferably, the display screen is a touch screen.

Preferably, the wire controller further comprises a key input circuit, and the key input circuit is connected with the power supply circuit; the key input circuit is connected with the MCU control module.

Preferably, the keys in the key input circuit are touch keys.

The utility model also provides an air energy heat pump, the air energy heat pump includes the line controller, the line controller includes power line carrier communication circuit, MCU control module and WIFI module, power line carrier communication circuit, MCU control module and WIFI module are two-two interconnected; the power carrier communication circuit is connected with the controlled equipment through a two-core non-polar power carrier wire so as to receive the power supply transmitted by the controlled equipment, supply the power supply to the MCU control module and the WIFI module, and simultaneously supply the MCU control module and the controlled equipment to transmit data mutually; and the WIFI module is used for mutual signal transmission between the MCU control module and the intelligent terminal.

Preferably, the wire controller is provided with a plurality of wire controllers which are connected in a bidirectional mode.

The utility model discloses a line controller, on the one hand, line controller passes through nonpolarity power line carrier line as the medium, receives the power that is carried by the accuse equipment to supply power to line controller, and, supply with through power line carrier communication circuit MCU control module and WIFI module. On the other hand, the wire controller enables the MCU control module and the controlled device to mutually transmit data by taking the two-core power carrier wire as a medium. Because the line controller is connected through the two-core power line carrier, the number of connector lugs is reduced, and the wiring is not required to be in one-to-one correspondence with the wiring terminals, so that the installation difficulty is reduced, and the installation of the line controller is more convenient. Meanwhile, the wire controller is not required to be connected with controlled equipment through a special power supply wire and a special signal wire, so that wire material consumption is saved. The operation information of the controlled equipment can be sent to the cloud end through the WIFI module, and other line controllers or mobile terminals can call the operation information of the controlled equipment through the cloud end. The transmission distance of the signal is not limited by the physical connection distance of the wire controller any more, and the installation of the wire controller is facilitated.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic connection diagram of an embodiment of the line controller of the present invention;

fig. 2 is a schematic view of the internal connection of an embodiment of the line controller according to the present invention;

fig. 3 is a schematic diagram of the internal connection of the power line carrier communication circuit according to an embodiment of the present invention;

fig. 4 is a schematic connection diagram of an embodiment of the air-source heat pump of the present invention.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)
				10	Wire controller	102	Communication circuit
20	Two-core power carrier wire	201	MCU control module
				30	Controlled equipment	301	WIFI Module
31	Main controller	401	Storage device
				100	Power carrier communication circuit	501	Display screen
101	Power supply circuit	601	Key input circuit

The objects, features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

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

It should be noted that, if directional indications (such as upper, lower, left, right, front and rear … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description relating to "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

The utility model provides a line controller, it is shown with reference to figure 1, in an embodiment, line controller includes two liang of power carrier communication circuit 100 that link to each other, MCU control module 201 and WIFI module 301, and power carrier communication circuit 100 is connected with controlled equipment 30 through two power carrier lines 20, and controlled equipment can be the air energy heat pump of air conditioner or water heater. On one hand, the line controller 10 receives the power supplied by the controlled device 30 through the two-core power carrier line 20 as a medium to supply power to the line controller 10, and supplies power to the MCU control module 201 and the WIFI module 301 through the power carrier communication circuit 100. On the other hand, the line controller 10 enables the MCU control module 201 and the controlled device 30 to transmit data to each other via the two-core power carrier line 20, where the data may be a control signal or information about the operating condition of the controlled device. The power carrier communication circuit 100 is connected to the MCU control module 201 to supply power to the MCU control module 201 and exchange data with the MCU control module 201. The power carrier communication circuit 100 outputs information such as the operation state of the controlled device received by the line controller 10 after being processed by the MCU control module 201. The control instruction generated by the MCU control module 201 may be sent to the controlled device 30 through the power carrier communication circuit 100 to control the operation of the controlled device 30. Because the drive-by-wire ware 10 has adopted two cores power carrier line 20 to be connected with controlled equipment 30 for power signal and data signal can pass through power carrier line 20 simultaneous transmission, need not to be connected with controlled equipment 30 through dedicated power supply electric wire and signal line, consequently, have reduced the quantity of wiring, have saved the wire rod material, have reduced the installation degree of difficulty, thereby make drive-by-wire ware 10 installation more convenient.

In this embodiment, the power carrier communication circuit 100 is connected to the WIFI module 301 to supply power to the WIFI module 301. The MCU control module 201 is connected to the WIFI module 301, so that the operating status information of the controlled device 30 is processed by the MCU control module 201 and then transmitted to the intelligent terminal via a wireless signal. Or, after the control signal sent by the intelligent terminal can be received by the WIFI module 301, the MCU control module 201 further sends a control instruction to the controlled device 30, so that the control distance to the controlled device 30 is greatly increased. Because the wireless signal coverage replaces the wired installation, the wiring difficulty is further reduced in the installation process of the wire controller 10, for example, the wire controller 10 is arranged at a place with a partition wall, or the wire controller 10 is arranged at a place closer to the controlled device 30. The operation information of the controlled device 30 can be sent to the cloud end through the WIFI module 301, and other line controllers or mobile terminals can call the operation information of the controlled device 30 through the cloud end. Of course, the control command may also be issued to the line controller 10 through the cloud, and then the line controller 10 further sends the control command to the controlled device 30. Therefore, the transmission distance of the signal is no longer limited by the physical connection distance of the line controller 10, facilitating the installation of the line controller 10.

In this embodiment, the two-core power carrier line is a non-polar two-core power carrier line, so that the two-core power carrier line does not need to correspond to the wiring terminals one by one during wiring, and the installation of the line controller 10 is further facilitated. In order to extract the data signal from the two-core power carrier line 20. Referring to fig. 2 and 3, in the present embodiment, the power carrier communication circuit 100 includes a power circuit 101 and a communication circuit 102, and the power circuit 101 obtains power from the two-core power carrier wire 20 to supply power to the line controller 10. The communication circuit 102 extracts the signals of the two-core power carrier wire 20 and transmits the signals to the MCU control module 201, and can load the signals transmitted by the MCU control module 201 on the power signal. It should be noted that the controlled device 30 should also have a corresponding communication circuit to communicate with the communication circuit 102 of the line controller 10 via the two-wire power carrier line 20. Wherein, the communication circuit of the controlled device 30 and the communication circuit 102 of the line controller 10 are respectively provided with a pair of transmitter and receiver, and the signals are transmitted and received to each other by timing through the two-core power carrier wire 20 to realize signal transmission. Specifically, the transmitter couples the power signal with other electrical signals before transmission, and transmits the coupled power signal in the form of a carrier wave to the receiver via the two-core power carrier line 20, and the receiver separates the power signal from other electrical signals after receiving the signal. It should be appreciated that since it is well known in the art to transmit power signals and other electrical signals via a power carrier line 20 in the form of a carrier wave, the detailed circuit configuration of the transmitter and receiver is not provided herein. The communication circuit 102 is connected to the two-core power line carrier 20, so that both power and data signals can be transmitted through the two-core power line carrier 20, wherein it should be specifically stated that power can be transmitted from the controlled device 30 to the line controller 10 only in one direction. The data signal may be transmitted bi-directionally with the controlled device 30 over the two-core power carrier line 20. The communication circuit 102 is connected to the MCU control module 201, so that the MCU control module 201 performs data transmission with the controlled device 30 through the communication circuit 102 and the two-core power line 20. The power circuit 101 is connected to the MCU control module 201 and the WIFI module 301, respectively, so that the controlled device 30 supplies power to the MCU control module 201 and the WIFI module 301 through the two-core power carrier line 20 and the power circuit 101.

In view of recording the operating conditions of the controlled device 30, referring to fig. 2 and 3, in the present embodiment, the line controller 10 further includes a storage device 401, and the storage device 401 is connected to the power supply circuit 101 to supply power to the storage device 401. The storage device 401 is connected to the MCU control module 201, the MCU control module 201 sends a storage command to the storage device 401, and the storage device 401 is controlled to store the operation data transmitted to the MCU control module 201 by the controlled device 30. Of course, the MCU control module 201 may also send a call instruction to control the storage device 401 to call data to the MCU control module 201, and send the data through the MCU control module 201. It should be specifically stated that the transmission described herein may be transmitted to the mobile terminal through the WIFI module 301, or may be transmitted to the controlled device 30 through the communication circuit 102 and the two-core power carrier line 20.

In order to monitor the operation status of the controlled device 30 in real time, referring to fig. 2 and 3, in this embodiment, the line controller 10 further includes a display screen 501, so that the line controller 10 can display information. The display 501 is connected to the power supply circuit 101 to supply power to the display 501. The display screen 501 is connected to the MCU control module 201, and the MCU control module 201 displays real-time operation data of the controlled device 30 or historical operation data stored in the storage device 401 through the display screen 501. So that the user can intuitively know the operation condition of the controlled device 30. Of course, the display 501 is a touch screen for the convenience of user operation. Through the touch screen, a user can intuitively switch pages displaying information, and the operation of the user is facilitated.

For the purpose of facilitating the user to enter information, referring to fig. 2 and 3, in the present embodiment, the line controller 10 further includes a key input circuit 601, and the key input circuit 601 is connected to the power circuit 101 to supply power to the key input circuit 601. The key input circuit 601 is connected to the MCU control module 201, so that a user can input an instruction to the MCU control module 201 through the key input circuit 601, and after receiving the instruction, the MCU control module 201 controls the controlled device 30, or sends a control instruction to the storage device 401, or displays the input instruction through the display 501. In order to improve the operation reliability of the wired controller 10, the keys in the key input circuit 601 are touch keys, and the touch keys may be physical touch keys or virtual touch keys integrated in the touch screen. Those skilled in the art can obtain corresponding technical solutions through the embodiments of the present invention and the accompanying drawings, which are not described herein in detail. Through setting up the touch button, can avoid the contact failure condition that the button of metal conductive rubber formula exists, avoid causing whole drive-by-wire ware short circuit or malfunctioning to the reliability of drive-by-wire ware has been improved.

The utility model discloses still provide an air energy heat pump, it is shown with reference to figure 4, in an embodiment, the air energy heat pump supplies power to aforementioned drive-by-wire ware 10 after passing through the power cord and connecting the commercial power. The air-source heat pump is provided with a main controller 31, the main controller 31 is connected with the power carrier communication circuit 100 of the line controller 10 through the two-core power carrier line 20 to transmit the electric energy and the operation condition information of the air-source heat pump to the line controller 10, and meanwhile, receives the signal of the line controller 10 to control the operation of the air-source heat pump. In order to flexibly install the air-source heat pump, in the present embodiment, there are a plurality of line controllers 10 of the air-source heat pump, and the plurality of line controllers 10 are connected in two ways, where the two ways may be connected by a non-polar power carrier line 20 or by a common power line. A plurality of line accuse wares 10 all supply power through air energy heat pump, can call the operation data of air energy heat pump from the high in the clouds through WIFI module 301 between a plurality of line accuse wares 10, also can control air energy heat pump through line accuse ware 10 that non-polar power line carrier line 20 connects to further made things convenient for the installation of air energy heat pump.

The above only be the preferred embodiment of the utility model discloses a not consequently restriction the utility model discloses a patent range, all are in the utility model discloses a conceive, utilize the equivalent structure transform of what the content was done in the description and the attached drawing, or direct/indirect application all is included in other relevant technical field the utility model discloses a patent protection within range.

Claims (10)

1. The wire controller is characterized by comprising a power line carrier communication circuit, an MCU control module and a WIFI module, wherein the power line carrier communication circuit, the MCU control module and the WIFI module are connected in pairs; wherein,

the power carrier communication circuit is connected with the controlled equipment through a two-core power carrier wire so as to receive the power supply transmitted by the controlled equipment, supply the power supply to the MCU control module and the WIFI module and simultaneously supply the MCU control module and the controlled equipment to mutually transmit data;

and the WIFI module is used for mutual signal transmission between the MCU control module and the intelligent terminal.

2. The line controller of claim 1, wherein the two-core power carrier line is a non-polar two-core power carrier line.

3. The line controller of claim 2, wherein the power carrier communication circuit comprises a power circuit and a communication circuit, the power circuit and the communication circuit are respectively connected with the power carrier line, the communication circuit is connected with the MCU control module, and the power circuit is respectively connected with the MCU control module and the WIFI module.

4. The drive-by-wire of claim 3, further comprising a storage device, the storage device being coupled to the power circuit; the storage device is connected with the MCU control module.

5. The drive-by-wire of claim 4, wherein the drive-by-wire further comprises a display screen, the display screen being connected to the power circuit; the display screen is connected with the MCU control module.

6. The line controller of claim 5, wherein the display screen is a touch screen.

7. The line controller of claim 6, further comprising a key input circuit, the key input circuit being coupled to the power circuit; the key input circuit is connected with the MCU control module.

8. The line controller of claim 7, wherein the keys in the key input circuit are touch keys.

9. An air-source heat pump characterized by comprising the line controller according to any one of claims 1 to 8.

10. The air-source heat pump of claim 9, wherein the line controller is a plurality of line controllers, and a plurality of the line controllers are connected in a bidirectional manner.