Summary of the invention:
The problem that the utility model will solve provide to above deficiency exactly a kind of can be automatically according to indoor temperature and gas concentration lwevel automatically adjust temperature, humidity and the intelligence control system that new wind is provided as required, in good time.Its technical scheme is following:
It comprises air conditioning, handles all-in-one, air conditioning, processing all-in-one connection of intelligent master controller, and intelligent master controller connects the room controller in the room.Its key technology is that air conditioning, processing all-in-one comprise dehumidifying unit, new wind, air-treatment unit and air-conditioning unit; The intelligence master controller comprises new wind frequency-variable controller, dehumidifying frequency-variable controller, air-conditioning frequency-variable controller, mode control module, CO
2Concentration comparing module, air port controller, temperature comparing module, humidity comparing module and capillary valve door controller; Room controller connects CO
2Concentration sensor, temperature sensor, humidity sensor, air outlet valve and electric two-way valve.
Compared with prior art the utlity model has following beneficial effect:
1, this control system can utilize capillary radiation heating, refrigeration automatically according to indoor temperature;
2, this control system can carry out humidity control based on indoor temperature and humidity utilization dehumidifying unit automatically, reaches energy-saving and cost-reducing, comfortable purpose;
3, this control system can provide treated new wind based on indoor carbon dioxide concentration automatically as required, in good time;
4, in sum; This control system is through the control to indoor temperature and gas concentration lwevel; The person of being used in combination pre-sets and distributes the resh air requirement that gets into the room voluntarily, and refrigeration, the required hot and cold water yield of heating realize the accurate, intelligent of IAQ control; The health that realizes living at home in the city, comfortable, environmental protection, energy-conservation theory, modern architecture economizes on resources, the requirement of energy-conservation, low-carbon (LC) thereby satisfy.
The specific embodiment:
The utility model comprises air conditioning, handles all-in-one 1, air conditioning, processing all-in-one 1 connection of intelligent master controller 2, the room controller 7 in the intelligent master controller connection rooms 32.Its key technology is that air conditioning, processing all-in-one 1 comprise dehumidifying unit 4, new wind, air-treatment unit 5 and air-conditioning unit 6; Intelligence master controller 2 comprises new wind frequency-variable controller 19, dehumidifying frequency-variable controller 18, air-conditioning frequency-variable controller 20, mode control module 17, CO
2 Concentration comparing module 14, air port controller 16, temperature comparing module 15, humidity comparing module 13 and capillary valve door controller 12; Room controller 7 connects CO
2Concentration sensor 9, temperature sensor 10, humidity sensor 8, air outlet valve 11 and electric two-way valve 21.
Said mode control module 17 1 ends connect dehumidifying frequency-variable controller 18, new wind frequency-variable controller 19, air-conditioning frequency-variable controller 20, and the other end connects CO
2 Concentration comparing module 14, air port controller 16, temperature comparing module 15, humidity comparing module 13 and capillary valve door controller 12.
Said room controller 7 one ends connect CO
2 Concentration comparing module 14, air port controller 16, temperature comparing module 15, humidity comparing module 13 and capillary valve door controller 12.
Said air-conditioning unit 6 connects the capillary 23 in the room through pipeline.22 is water knockout drums among the figure.
Dehumidifying unit 4 connects dehumidifying frequency-variable controller 18 through holding wire five, and new wind, air-treatment unit 5 connect new wind frequency-variable controller 19 through holding wire 16, and air-conditioning unit 6 connects air-conditioning frequency-variable controller 20 through holding wire 21;
Dehumidifying frequency-variable controller 18, new wind frequency-variable controller 19, air-conditioning frequency-variable controller 20 are respectively through holding wire four, holding wire 15, holding wire 20 connection mode control modules 17;
Mode control module 17 connects capillary valve door controller 12, humidity comparing module 13, CO through holding wire nine, holding wire three, holding wire 14, holding wire 19, holding wire six respectively
2 Concentration comparing module 14, temperature comparing module 15, air port controller 16;
Capillary valve door controller 12, humidity comparing module 13, CO
2 Concentration comparing module 14, temperature comparing module 15, air port controller 16 connect room controller 7 through holding wire ten, holding wire two, holding wire 13, holding wire 18, holding wire seven respectively;
Electric two-way valve 21, humidity sensor 8, CO that room controller 7 connects on the capillary 23 through holding wire 11, holding wire one, holding wire 12, holding wire 17, holding wire eight respectively
2 Concentration sensor 9, temperature sensor 10, air outlet valve 11.
The utility model control procedure is following:
One, behind the system boot, at first indoor required CO manually is set at room controller 7 places
2Concentration, humidity, temperature, and manually choose new wind pattern, dehumidification mode, heating pattern, refrigeration mode.During start, system default is new wind pattern.
Two, dehumidification mode:
1, the humidity in the humidity sensor 8 detection at any time room airs and the data that detect are fed back to room controller 7 through holding wire one;
2, room controller 7 feeds back to humidity comparing module 13 with the humidity data that collects through holding wire two;
3, humidity comparing module 13 feeds back to mode control module 17 with comparison result through holding wire three;
When 3.1 comparison result need not dehumidify (indoor air humidity is to more than the dew point):
3.1.1 at first mode control module 17 signal that will open the capillary electric two-way valve feeds back to capillary valve door controller 12 through holding wire nine; Capillary valve door controller 12 feeds back to room controller 7 with start signal through holding wire ten, the electric two-way valve 21 that room controller 7 is opened on the capillary through holding wire 11;
3.1.2 next mode control module 17 will be closed the signal of dehumidification mode and fed back to dehumidifying frequency-variable controller 18 through holding wire four, dehumidifying frequency-variable controller 18 is closed dehumidifying unit 4 through holding wire five;
3.1.3 the running status that final mode control module 17 keeps VMC is (by CO
2Concentration parameter control VMC);
When 3.2 comparison result need dehumidify (indoor air humidity has arrived below the dew point):
3.2.1 at first mode control module 17 signal that will close the electric two-way valve 21 on the capillary feeds back to capillary valve door controller 12 through holding wire nine; Capillary valve door controller 12 feeds back to room controller 7 with shutdown signal through holding wire ten; Room controller 7 is closed the electric two-way valve on the capillary through holding wire 11; Cut off refrigerant or heating agent pipeline, this is extremely important when refrigeration mode;
3.2.2 secondly mode control module 17 is with the enforced opening VMC; Signal is fed back to air port controller 16 through holding wire six; Air port controller 16 will be opened signal feedback to the room controller 7 of air port valve through holding wire seven, room controller 7 opens air outlet valve 11 through the holding wire octavo.
3.2.3 final mode control module 17 will be opened the room number signal of dehumidifying and fed back to dehumidifying frequency-variable controller 18 through holding wire four, dehumidifying frequency-variable controller 18 is through holding wire five converting operations dehumidifying unit 4.
Three, new wind pattern:
CO
2Concentration sensor 9 is with detected room CO
2Concentration feeds back to room controller 7 through holding wire 12, and room controller 7 feeds back to CO through holding wire 13
2 Concentration comparing module 14, CO
2 Concentration comparing module 14 feeds back to mode control module 17 with comparison result through holding wire 14;
1. as room CO
2When concentration need be moved VMC above setting value:
1.1 if mode control module 17, is then pressed dehumidification mode operational system (during the dehumidification mode operation, VMC is also in operation) at the operation dehumidification system;
1.2 if mode control module 17 is not moved dehumidification system; 17 of mode control module are passed through holding wire six startup air port controllers 16; The signal that air port controller 16 will be opened room air outlet air-valve feeds back to room controller 7 through holding wire seven, and room controller 7 is opened air outlet valve 11 through holding wire eight; Simultaneously, mode control module 17 will need the room quantity of new wind to feed back to new wind frequency-variable controller 19 through holding wire 15, and new wind frequency-variable controller 19 is through the new wind of holding wire 16 converting operations, air-treatment unit 5;
2. as room CO
2Concentration is less than or equal to setting value, in the time of need not moving VMC:
2.1 if mode control module 17 is then pressed the dehumidification mode operational system at the operation dehumidification system;
2.2 if mode control module 17 is not moved dehumidification system; 17 of mode control module are passed through holding wire six startup air port controllers 16; The signal that air port controller 16 will cut out room air outlet air-valve feeds back to room controller 7 through holding wire seven, and room controller 7 is closed air outlet valve 11 through holding wire eight; Simultaneously, mode control module 17 will not need the signal of new wind to feed back to new wind frequency-variable controller 19 through holding wire 15, and new wind frequency-variable controller 19 is closed new wind, air-treatment unit 5 through holding wire 16.
Four, air conditioning mode:
Temperature sensor 10 feeds back to room controller 7 with detected room temperature through holding wire 17; Room controller 7 feeds back to temperature comparing module 15 through holding wire 18 with temperature signal, and temperature comparing module 15 feeds back to mode control module 17 with comparison result through holding wire 19;
1. refrigeration mode:
When 1.1. comparison result need freeze:
1.1.1 if mode control module 17 is then pressed the dehumidification mode operational system at the operation dehumidification system, do not start heating mode;
1.1.2 if mode control module 17 is not moved dehumidification system; 17 of mode control module are passed through holding wire nine and are started capillary valve door controllers 12; Capillary valve door controller 12 feeds back to room controller 7 with the signal of Open valve through holding wire ten, and room controller 7 is opened capillary electric two-way valve 21 through holding wire 11; The room quantity that while mode control module 17 will be freezed feeds back to air-conditioning frequency-variable controller 20 through holding wire 20, and air-conditioning frequency-variable controller 20 is through holding wire 21 converting operation air-conditioning units 6;
When 1.2. comparison result need not freeze; Mode control module 17 starts capillary valve door controller 12 through holding wire nine; The signal that capillary valve door controller 12 will be closed electric two-way valve 21 feeds back to room controller 7 through holding wire ten, and room controller 7 is closed electric two-way valve 21 through holding wire 11; The signal that while mode control module 17 will need not be freezed feeds back to air-conditioning frequency-variable controller 20 through holding wire 20, and air-conditioning frequency-variable controller 20 is closed air-conditioning unit 6 through holding wire 21;
2. heating mode:
Temperature sensor 10 feeds back to room controller 7 with detected room temperature through holding wire 17; Room controller 7 feeds back to temperature comparing module 15 through holding wire 18 with temperature signal, and temperature comparing module 15 feeds back to mode control module 17 with comparison result through holding wire 19;
When 2.1 comparison result need not heat; Mode control module 17 starts capillary valve door controller 12 through holding wire nine; The signal that capillary valve door controller 12 will be closed electric two-way valve feeds back to room controller 7 through holding wire ten, and room controller 7 is closed electric two-way valve 21 through holding wire 11; The signal that while mode control module 17 will need not be freezed feeds back to air-conditioning frequency-variable controller 20 through holding wire 20, and air-conditioning frequency-variable controller 20 is closed air-conditioning unit 6 through holding wire 21;
When 2.2 comparison result need heat; Mode control module 17 starts capillary valve door controller 12 through holding wire nine; Capillary valve door controller 12 feeds back to room controller 7 with the signal of Open valve through holding wire ten, and room controller 7 is opened electric two-way valve 21 through holding wire 11; The room quantity that while mode control module 17 will be freezed feeds back to air-conditioning frequency-variable controller 20 through holding wire 20, and air-conditioning frequency-variable controller 20 is through holding wire 21 converting operation air-conditioning units 6.