CN211261084U

CN211261084U - Radiation cold-warm dehumidification controller

Info

Publication number: CN211261084U
Application number: CN201921053929.5U
Authority: CN
Inventors: 王家华
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-07-08
Filing date: 2019-07-08
Publication date: 2020-08-14
Anticipated expiration: 2029-07-08

Abstract

The utility model relates to the technical field of air conditioner cold and warm control systems, in particular to a radiation cold and warm dehumidification controller, which comprises a mode controller, wherein the mode controller comprises a data acquisition end, the data acquisition end is connected with a 485 communication module, a mode switch passive contact, a linked switch mode contact, an air conditioning valve, a dehumidification valve, a floor heating valve, a radiation valve, a fan, a power supply zero line and a power supply live line through a connecting pin, the air conditioning valve, the dehumidification valve, the floor heating valve and the radiation valve all comprise an open state and a close state, the fan comprises three gears of low speed, medium speed and high speed, the three gears are respectively connected with the connecting pin of the data acquisition end, the mode controller can simultaneously control a refrigeration mode, a floor heating and dehumidification combined mode, a ventilation mode, an air disc heating mode and an air disc heating and heating mode combined mode of the air conditioner, the controller can realize linked control of a plurality of air conditioning modes, has the advantages of small volume, low cost and convenient operation.

Description

Radiation cold-warm dehumidification controller

Technical Field

The utility model relates to an air conditioner changes in temperature control system technical field, concretely relates to radiation cold and warm dehumidification controller.

Background

With the development of the air conditioning function, the air conditioning function comprises a refrigeration function, a heating function, a radiation function, a temperature regulation function and a dehumidification function, but the refrigeration function, the heating function, the radiation function, the temperature regulation function and the dehumidification function are operated independently, namely, only one mode can be selected at one time, so that more than two modes cannot be controlled independently at the same time, and only different control systems can be adopted to respectively control a refrigeration host, a heating host, a radiation host, a temperature regulation host and a dehumidification host, so that the controller is large in size, high in height, inconvenient to install and not simple and convenient to operate.

SUMMERY OF THE UTILITY MODEL

There is above-mentioned technical problem to prior art, the utility model provides a radiant cold warm dehumidification controller, this controller can the multiple air conditioner mode of coordinated control, have small, with low costs and the advantage of the operation of being convenient for.

In order to achieve the above object, the utility model provides a following technical scheme:

the utility model provides a radiation cold and warm dehumidification controller, which comprises an outer shell, be provided with display screen and button on the shell, be provided with mode controller in the shell, mode controller includes the data acquisition end, the data acquisition is served and is provided with a plurality of connecting feet, the data acquisition end is connected with 485 communication modules, mode switch passive contact, gang switch mode contact, air conditioning valve, dehumidification valve, warm up the valve, radiation valve, fan, power zero line and power live wire through connecting the connecting foot, the air conditioning valve the dehumidification valve warm up the valve with the radiation valve all includes open mode and closed condition, the fan includes low-speed, medium-speed and high-speed three gear, this three gear respectively with the connecting foot of data acquisition end is connected, mode controller is through adjusting mode switch passive contact, gang switch mode contact, air conditioning valve, The opening state or the closing state of the dehumidification valve, the floor heating valve, the radiation valve and the fan controls a refrigeration mode, a floor heating and dehumidification combined mode, a ventilation mode, a wind disc heating mode and a wind disc heating and floor heating combined mode of the air conditioner.

The 485 communication module comprises a 485A end and a 485B end, and the 485A end and the 485B end are respectively connected with the connecting pins of the data acquisition unit.

The display screen comprises an indoor temperature display, an indoor humidity display, a mode display and a time display, wherein the time display comprises a starting time display and a timing display.

The keys comprise a mode selection key, an upper selection key, a lower selection key and a power-on selection key.

The utility model has the advantages that:

the mode controller is provided with a mode switch passive contact, a linked switch mode contact, an air conditioning valve, a dehumidification valve, a floor heating valve, a radiation valve, a fan and a power supply zero line, the mode controller can integrate an original indoor air conditioner and a ground heating two-in-one linked temperature controller and an original dehumidification controller, one-controller multi-control is achieved, each controller can independently control temperature and humidity, and meanwhile, an air conditioner host can be controlled, the dehumidification host, a gas host, shutdown and mode conversion are achieved, operation can be simplified, the controller volume is greatly reduced, starting is facilitated, and cost reduction and installation are facilitated.

Drawings

Fig. 1 is a schematic structural view of the front side of the housing of the present invention;

fig. 2 is a schematic structural view of the back of the housing of the present invention;

fig. 3 is a schematic structural diagram of the mode controller before starting up the power supply of the present invention;

FIG. 4 is a schematic structural diagram of a mode controller when the temperature in the air pan heating mode does not reach the set temperature;

FIG. 5 is a schematic structural diagram of a mode controller when the temperature of the air pan heating mode reaches a set temperature;

fig. 6 is a schematic structural diagram of the mode controller when the temperature in the combined floor heating and air pan heating mode does not reach the set temperature;

fig. 7 is a schematic structural diagram of a mode controller when the temperature reaches a set temperature in the combined floor heating and air pan heating mode;

fig. 8 is a schematic structural diagram of a mode controller when the temperature of the floor heating mode does not reach the set temperature;

fig. 9 is a schematic structural diagram of a mode controller when the temperature of the floor heating mode reaches a set temperature;

FIG. 10 is a schematic structural diagram of a mode controller when the air conditioner cooling mode temperature does not reach the set temperature;

FIG. 11 is a schematic structural diagram of a mode controller when the air conditioner cooling mode temperature reaches a set temperature;

FIG. 12 is a schematic diagram of the configuration of the mode controller when the temperature does not reach the set temperature and the humidity does not reach the dew formation in the combined radiation cooling and dehumidification mode;

FIG. 13 is a schematic diagram of the mode controller when the temperature does not reach the set temperature and the humidity reaches the upper line 60% of the set temperature in the combined radiation cooling and dehumidification mode;

FIG. 14 is a schematic diagram of the mode controller when the temperature reaches the set temperature in the combined radiation cooling and dehumidification mode;

fig. 15 is a schematic structural view of a mode controller for a ventilation mode.

Reference numerals:

the device comprises a shell 1, a display screen 2, keys 3, a 485 communication module 4, a mode switch passive contact 5, a linkage switch mode contact 6, an air conditioner valve 7, a dehumidification valve 8, a floor heating valve 9, a radiation valve 10 and a fan 11.

Detailed Description

The present invention will be described in detail with reference to the following embodiments and accompanying drawings.

Examples

A radiation cold warm dehumidification controller of this embodiment, as shown in fig. 1, including shell 1, be provided with display screen 2 and button 3 on the shell 1, as shown in fig. 2 and fig. 3 combine, be provided with mode controller in the shell 1, mode controller includes data acquisition end 11, be provided with a plurality of connecting pin on the data acquisition end 11, data acquisition end 11 is connected with 485 communication module 4 through connecting the connecting pin, mode switch passive contact 5, gang switch mode contact 6, air conditioner valve 7, dehumidification valve 8, warm valves 9, radiant valve 10, fan 11, power zero line and power live wire, air conditioner valve 7, dehumidification valve 8, warm valves 9, radiant valve 10 all include open mode and closed state, fan 14 includes low-speed, medium-speed and high-speed three gears, these three gears are connected with the connecting pin of data acquisition end 11 respectively, mode controller is through adjusting mode switch passive contact 5, The opening state or the closing state of the switch mode contact 6, the air conditioner valve 7, the dehumidification valve 8, the floor heating valve 9, the radiation valve 10 and the fan 11 are linked to control the refrigeration mode, the floor heating and dehumidification combined mode, the ventilation mode, the air disc heating mode and the floor heating and heating combined mode of the air conditioner. Wherein, 485 communication module 4 includes 485A end and 485B end, and this 485A end and this 485B end are connected with data acquisition unit's connecting pin respectively.

As shown in fig. 1, the display screen 2 includes an indoor temperature display, an indoor humidity display, a mode display, and a time display, and the time display includes a power-on time display and a timing display.

As shown in fig. 1, the keys 3 include a mode selection key, an upper selection key, a lower selection key, and a power-on selection key.

The circuit connection state of the mode controller is as follows:

first, when the air panel heating mode is selected, the circuit-on state of the mode is as follows, as shown in fig. 4 and 5:

the data acquisition ends 1 and 2 are connected, output signals are transmitted to the host equipment to be converted into a heating mode, when the temperature does not reach the set temperature, the indoor motor of the air conditioner is started, and the air speed can be adjusted (high speed, medium speed, low speed and automatic). The air-conditioning valve is opened to output a live wire, the air-conditioning valve is started, after the air-conditioning valve is started for 1 minute (the time can be adjusted to 1 minute-8 minutes), the

data acquisition ends

3 and 4 are connected, and a signal is output to the host equipment for starting. When the temperature reaches the set temperature, the motor in the air conditioner stops running, the data acquisition ends 3 and 4 are disconnected, no output signal is generated, and the host equipment stops running. After the host equipment stops running for 5 minutes (the time can be adjusted to 1-8 minutes), the air-conditioning valve is opened without outputting a live wire, and meanwhile, the air-conditioning valve is closed to output the live wire and close the air-conditioning valve. When the indoor temperature is reduced by 1 ℃ to the set temperature and the return difference starting temperature is started again (the return difference starting temperature can be adjusted to be 0.5-3 ℃), the operation is carried out according to the sequence.

Secondly, when the combined floor heating and air disc heating mode is selected, the circuit connection state of the mode is as follows, as shown in fig. 6 and 7,

the data acquisition ends 1 and 2 are connected, output signals are transmitted to the host equipment to be converted into a heating mode, when the temperature does not reach the set temperature, the indoor motor of the air conditioner is started, and the air speed can be adjusted (high speed, medium speed, low speed and automatic). The air-conditioning valve is opened to output a live wire, the air-conditioning valve is started, the ground heating valve is opened to output a live wire, the ground heating valve is started, after the air-conditioning valve is started for 1 minute (the time can be adjusted for 1 minute to 8 minutes), the

data acquisition ends

3 and 4 are connected, and an output signal is sent to the host equipment for starting. When the temperature reaches the set temperature, the motor in the air conditioner stops running, the data acquisition ends 3 and 4 are disconnected, no output signal is generated, and the host equipment stops running. After the host equipment stops running for 5 minutes (the time can be adjusted to 1-8 minutes), the ground heating valve is opened without an output live wire, meanwhile, the ground heating valve is closed to output the live wire, the ground heating valve is closed, the air conditioning valve is opened without an output live wire, and meanwhile, the air conditioning valve is closed to output the live wire and close the air conditioning valve. When the indoor temperature is reduced by 1 ℃ to the set temperature and the starting return difference temperature is started again (the starting return difference temperature can be adjusted to be 0.5-3 ℃), the operation is carried out according to the sequence.

Thirdly, when the floor heating mode is selected, the circuit-on state of the mode is as follows, as shown in fig. 8 and 9,

data acquisition end

1, 2 switch-ons, and output signal gives the host computer equipment and converts to the mode of heating, and when the temperature did not reach the settlement temperature, the ground warm valve opened output live wire, starts the ground warm valve, and after the ground warm valve started 3 minutes (time adjustable 1 minute-8 minutes),

data acquisition end

3, 4 switch-ons, output signal gave the host computer equipment and starts. When the temperature reaches the set temperature, the data acquisition ends 3 and 4 are disconnected, no output signal is generated, and the host equipment stops running. After the host equipment stops running for 5 minutes (the time can be adjusted to 1-8 minutes), the ground heating valve is opened without outputting a live wire, and simultaneously the ground heating valve is closed to output the live wire and close the ground heating valve. When the indoor temperature is reduced by 1 ℃ to the set temperature and the starting return difference temperature is started again (the starting return difference temperature can be adjusted to be 0.5-3 ℃), the operation is carried out according to the sequence.

Thirdly, when the air-conditioning cooling mode is selected, the circuit connection state of the mode is as follows, and as shown by combining the figure 10 and the figure 11,

the data acquisition ends 1 and 2 are disconnected, the host equipment is switched to a refrigeration mode,

when the temperature does not reach the set temperature:

the motor in the air-conditioning room is started, and the wind speed can be adjusted (high speed, medium speed, low speed and automatic). The air-conditioning valve is opened to output a live wire, the air-conditioning valve is started, after the air-conditioning valve is started for 1 minute (the time can be adjusted to 1 minute-8 minutes), the

data acquisition ends

3 and 4 are connected, and a signal is output to the host equipment for starting.

When the temperature reaches the set temperature:

and (3) stopping running of the motor in the air conditioner room, disconnecting the

data acquisition ends

3 and 4, and stopping running of the host equipment without output signals. After the host equipment stops running for 5 minutes (the time can be adjusted to 1-8 minutes), the air-conditioning valve is opened without outputting a live wire, and meanwhile, the air-conditioning valve is closed to output the live wire and close the air-conditioning valve. When the indoor temperature is increased to the set temperature and the starting return difference temperature of 1 degree is added (the starting return difference temperature can be adjusted to 0.5-3 degrees), the operation is carried out according to the sequence.

Fifth, when the combined radiation cooling and dehumidification mode is selected, the circuit-on state of this mode is as follows, as shown in fig. 12, 13 and 14,

1. when the indoor temperature does not reach the set temperature:

when the indoor humidity is not 45% of the set lower line (the humidity lower line can be adjusted to be 30% -50%), the dehumidifying valve is opened to output a live wire, dehumidifying equipment is started, and the dehumidifying valve is started. The fan outputs a live wire at a low speed, an indoor motor of the air conditioner is started, and the wind speed is default to the low speed but can be manually adjusted (high speed, medium speed and low speed). The radiant valve is opened to output a live wire, the radiant valve is started, and the water mixing center is started. After the radiation valve is started for 2 minutes (the time can be adjusted to 1 minute-8 minutes), the data acquisition ends 3 and 4 are connected, and signals are output to the host equipment to be started.

2. When the indoor humidity reaches the lower set line of 45 percent (the lower humidity line can be adjusted to 30 to 50 percent):

the dehumidification valve is opened without an output live wire, and meanwhile, the dehumidification valve is closed to output the live wire, so that the dehumidification equipment is stopped, and the high, medium and low speed fans do not have the output live wire, so that the indoor motor of the air conditioner is stopped.

3. When the indoor humidity reaches 55 percent of the set upper line (the upper line of the humidity can be adjusted to 30 to 90 percent),

the dehumidification valve is closed to have no output live wire, and the dehumidification valve is opened and is output live wire, starts dehumidification equipment, starts the dehumidification valve. The fan outputs a live wire at a low speed, an indoor motor of the air conditioner is started, and the wind speed is default to the low speed but can be manually adjusted (high speed, medium speed and low speed). When the humidity stops again, the operation is carried out according to the sequence.

4. When the indoor temperature reaches the set temperature,

and (3) stopping running of the motor in the air conditioner room, disconnecting the data acquisition ends 3 and 4, and stopping running of the host equipment without output signals. After the host equipment stops running for 5 minutes (the time can be adjusted to be 1-8 minutes), the dehumidification valve is opened without an output live wire, the dehumidification valve is closed to output the live wire, the dehumidification valve is closed, the dehumidification equipment is closed, the radiation valve is opened without an output live wire, the radiation valve is closed to output the live wire, the radiation valve is closed, and the water mixing center is closed. When the indoor temperature reaches the set temperature and the power-on return difference of 1 degree is added (the power-on return difference temperature can be adjusted to 0.5-3 degrees), the operation is carried out according to the sequence when the temperature is restarted.

Sixth, when the on-air mode is selected, the circuit-on state of the mode is as follows, as shown in fig. 15,

the data acquisition ends 1 and 2 are disconnected, the indoor motor of the air conditioner is started, and the air speed can be adjusted (high speed, medium speed and low speed).

It should be finally noted that the above embodiments are only intended to illustrate the technical solutions of the present invention, and not to limit the scope of the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solutions of the present invention can be modified or replaced with equivalents without departing from the spirit and scope of the technical solutions of the present invention.

Claims

1. A radiation cold-warm dehumidification controller is characterized in that: the air conditioner comprises an outer shell, a display screen and keys are arranged on the outer shell, a mode controller is arranged in the outer shell and comprises a data acquisition end, a plurality of connecting pins are arranged on the data acquisition end, the data acquisition end is connected with a 485 communication module, a mode switch passive contact, a linked switch mode contact, an air conditioner valve, a dehumidification valve, a floor heating valve, a radiation valve, a fan, a power supply zero line and a power supply live line through the connecting pins, the air conditioner valve, the dehumidification valve, the floor heating valve and the radiation valve all comprise an opening state and a closing state, the fan comprises three gears of a low speed gear, a medium speed gear and a high speed gear, the three gears are respectively connected with the connecting pins of the data acquisition end, and the mode controller controls the refrigerating mode of the air conditioner by adjusting the opening state or the closing state of the mode switch passive contact, the linked switch mode contact, the air conditioner valve, the dehumidification valve, the floor heating valve, the radiation valve and, The system comprises a ground heating mode, a ground heating and dehumidification combined mode, a ventilation mode, a wind disc heating mode and a wind disc heating and ground heating combined mode.

2. A radiant heater dehumidification controller as claimed in claim 1, wherein: the 485 communication module comprises a 485A end and a 485B end, and the 485A end and the 485B end are respectively connected with the connecting pins of the data acquisition unit.

3. A radiant heater dehumidification controller as claimed in claim 1, wherein: the display screen comprises an indoor temperature display, an indoor humidity display, a mode display and a time display, wherein the time display comprises a starting time display and a timing display.

4. A radiant heater dehumidification controller as claimed in claim 1, wherein: the keys comprise a mode selection key, an upper selection key, a lower selection key and a power-on selection key.