CN102147137B - Temperature and humidity linkage control method of air conditioner - Google Patents
Temperature and humidity linkage control method of air conditioner Download PDFInfo
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- CN102147137B CN102147137B CN 201010108994 CN201010108994A CN102147137B CN 102147137 B CN102147137 B CN 102147137B CN 201010108994 CN201010108994 CN 201010108994 CN 201010108994 A CN201010108994 A CN 201010108994A CN 102147137 B CN102147137 B CN 102147137B
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Abstract
The invention provides a temperature and humidity linkage control method of an air conditioner, which comprises the following steps of: (1) formulating a temperature and humidity curve according to requirements, and formulating a temperature control adjusting program in each range of the curve; (2) reading the humidity signal of a humidity sensor and the temperature signal of a temperature sensor, and judging the read humidity and temperature range according to the curve; and (3) adjusting the temperature according to the temperature control adjusting program in the humidity and temperature range, if a new humidity signal is input, returning to the step (2), and if no new humidity signal is input, ending. By the temperature and humidity linkage control method provided by the invention, the temperature can be adjusted by referring to the current humidity in the operating process of the air conditioner to enable people to obtain the same heat comfort, thereby creating a good sleep environment and achieving the purpose of saving energy.
Description
[technical field]
The present invention relates to field of air conditioning, refer in particular to a kind of air-conditioner control method.
[background technology]
Describe in a large number at the air-conditioning sleep pattern is existing in the prior art, but these technology major parts are the control at room temperature, even being arranged, small part considers that humidity also just considered the unlatching of humidifier, really do not consider the relation of temperature and humidity, and the thermal comfort of human body and ambient humidity are in close relations, only obtain under the best humiture ambient conditions in regulation and control, human body sensory the most comfortable, and present air-conditioning control model far can not satisfy the demands.
Therefore, provide a kind of and realize that the air-conditioner control method of humiture interlock control is real in necessary.
[summary of the invention]
The object of the present invention is to provide a kind of air-conditioner control method of realizing humiture interlock control.
For realizing the object of the invention, provide following technical scheme:
A kind of air-conditioner control method is provided, and it comprises step:
(1) formulates the humiture curve as required, and formulate each the scope temperature control of this curve and regulate formula, enter step (2);
(2) read the moisture signal of humidity sensor and the temperature signal of temperature sensor, according to scope under curve judgement institute's humidity that reads and the temperature, enter step (3);
(3) regulate formula according to scope temperature control under it and carry out adjustment, then return step (2) if any new moisture signal input, otherwise air-conditioning is by the running temperature operation after regulating.
This method can also be set humidity acquiescence minimum and peak in advance, when the humidity value that reads is then opened humidifier until reaching peak less than minimum.
In addition, CO can also be set
2Sensor, and CO is set
2Content default maximum and minimum of a value read CO
2The signal value of sensor is when the value that reads is just moved ventilatory until reaching minimum of a value greater than default maximum.Thereby guarantee that indoor long-term surrounding air is fresh.
Under the air-conditioning heating mode, divide a1, b1, four humiture control scopes of c1, d1 according to the humiture curve, and formulate each scope temperature control and regulate formula, a1 scope: T
0=T+1, b1 scope: T
0=T, c1 scope: T
0=T-1, d1 scope: T
0=T-2, wherein T is current indoor environment temperature value, T
0Be the running temperature value behind the temperature adjusting.
Under the air conditioner refrigerating pattern, divide a2, b2, c2, d2, five humiture control scopes of e2 according to the humiture curve, and formulate each scope temperature control and regulate formula, a2 scope: T
0=T+2, b2 scope: T
0=T+1, c2 scope: T
0=T, d2 scope: T
0=T-1, e2 scope: T
0=T-2, wherein T is current indoor environment temperature value, T
0Be the running temperature value behind the temperature adjusting.
This method also be provided with the afternoon nap pattern and night sleep pattern,
Can select User Defined control model or default mode after entering this afternoon nap pattern:
User Defined control model in the described afternoon nap pattern arranges the operation of air conditioner temperature T by the user
If, temperature increment Δ T and operation of air conditioner time t1, air-conditioner is according to the operation of user's design temperature and gradually running temperature is adjusted to T in the time t1 that the user sets
If+ Δ T keeps this temperature operation then; If new moisture signal input is arranged, then enter step (2), if there is not the moisture signal input, then running temperature remains T
If+ Δ T finished up to the running time of setting.
Default mode in the described afternoon nap pattern makes it equal design temperature T by the temperature that reads air-conditioning operation last time
If, the running time of adopting the air-conditioning acquiescence,
When air-conditioner is in refrigeration mode: temperature is divided a3, b3, three modification scopes of c3, if design temperature is in the a3 scope, after indoor environment temperature reaches design temperature, the running temperature of air-conditioner rises 2 ℃ within a certain period of time, then according to this temperature operation, if new moisture signal input is arranged, then enters step (2);
If design temperature is in the b3 scope, after indoor environment temperature reached design temperature, air-conditioner continues operation rose 1 ℃ indoor environment temperature within a certain period of time gradually, then according to this temperature operation, if new moisture signal input is arranged, then entered step (2);
If design temperature is c3, after indoor environment temperature reached design temperature, air-conditioner was failure to actuate, and then according to this temperature operation, if new moisture signal input is arranged, then entered step (2), finished up to the running time of setting.
When air-conditioner is in heating mode: temperature is divided a4, b4, three modification scopes of c4, if design temperature is in the a4 scope, after indoor environment temperature reaches design temperature, air-conditioner continues operation makes indoor environment temperature rise 3 ℃ within a certain period of time, air-conditioner is according to this temperature operation then, if new moisture signal input is arranged, then enter step (2), finish up to the running time of setting;
If design temperature is in the b4 scope, after indoor environment temperature reaches design temperature, air-conditioner continues operation rises 2 ℃ indoor environment temperature within a certain period of time gradually, air-conditioner is according to this temperature operation then, if new moisture signal input is arranged, then enter step (2), finish up to the running time of setting;
If design temperature is in the c4 scope, after indoor environment temperature reaches design temperature, air-conditioner continues operation rises 1 ℃ indoor environment temperature within a certain period of time gradually, air-conditioner is according to this temperature operation then, if new moisture signal input is arranged, then enter step (2), finish up to the running time of setting.
Equally, enter this night and can select User Defined control model or default mode after the sleep pattern.
User Defined control model in the described night sleep pattern is set air-conditioner running temperature T by the user
If, temperature increment Delta T and operation of air conditioner time t2, be divided into three phases running time, in the first running time section, the running temperature of air-conditioning is from T
If-Δ T rises to design temperature T gradually
If, air-conditioner is according to design temperature T in the second running time section
IfOperation, the operation of air conditioner temperature rises to T=T gradually in the 3rd running time
If+ Δ T;
Default mode in the described night sleep pattern, air-conditioner reads the design temperature when moving last time and makes it equal design temperature T
If,
When air-conditioner is in refrigeration mode: temperature is divided a5, b5, four modification scopes of c5, d5, when design temperature during in the a5 scope, after indoor environment temperature reaches design temperature, the running temperature of air-conditioner per hour temperature raises 1 ℃, raises to keep this temperature after 3 ℃, after moving 7 hours, temperature reduces by 1 ℃, under this temperature, move ever since, if new moisture signal input is arranged, then enter step (2);
When initial temperature is arranged on the b5 scope, after indoor environment temperature reaches design temperature, the running temperature of air-conditioner per hour temperature raises 1 ℃, raise and keep this temperature after 2 ℃, after operation 7 hours, temperature reduces by 1 ℃, moves under this temperature ever since, if new moisture signal input is arranged, then enters step (2);
When initial temperature is arranged on the c5 scope, after indoor environment temperature reaches design temperature, the running temperature of air-conditioner per hour temperature raises 1 ℃, raise and keep this temperature after 1 ℃, after operation 7 hours, temperature reduces by 1 ℃, moves under this temperature ever since, if new moisture signal input is arranged, then enters step (2);
When initial temperature is arranged on the d5 scope, under this temperature, move, after operation 7 hours, temperature reduces by 1 ℃, moves under this temperature ever since, if new moisture signal input is arranged, then enters step (2).
During heating mode: temperature is divided a6, b6, four modification scopes of c6, d6, when initial temperature is arranged on the a6 scope, after indoor environment temperature reaches design temperature, air-conditioner continue operation make running temperature per hour temperature reduce by 1 ℃, keep this temperature after reducing by 1 ℃, if new moisture signal input is arranged, then enters step (2);
When initial temperature is set to b6, after indoor environment temperature reaches design temperature, air-conditioner continue operation make running temperature per hour temperature reduce by 1 ℃, keep this temperature after reducing by 2 ℃, if the input of new moisture signal is arranged, then enter step (2);
When initial temperature is arranged on the c6 scope, after indoor environment temperature reaches design temperature, air-conditioner continue operation make running temperature per hour temperature reduce by 1 ℃, keep this temperature after reducing by 3 ℃, if the input of new moisture signal is arranged, then enter step (2);
When initial temperature is arranged on the d6 scope, under this temperature, move always.
The contrast prior art, the present invention has the following advantages:
The present invention proposes the control of humiture interlock, the humidity that air-conditioning can reference equivalent in running is adjusted temperature, makes the people obtain same thermal comfort, not only can create good sleep environment and can also reach purpose of energy saving.
[description of drawings]
Fig. 1 is overview flow chart of the present invention;
Fig. 2 is humidity control flow chart of the present invention;
Fig. 3 is air CO of the present invention
2The content control flow chart;
Fig. 4 is the present invention's refrigeration mode flow chart of taking a nap after lunch;
Fig. 5 is the present invention's heating mode flow chart of taking a nap after lunch;
Fig. 6 is the refrigeration mode flow chart of sleeping night of the present invention;
Fig. 7 is the heating mode flow chart of sleeping night of the present invention;
Fig. 8 is the refrigeration mode flow chart of humiture interlock control of the present invention;
Fig. 9 is the refrigeration mode humiture curve map of humiture interlock control of the present invention;
Figure 10 is the heating mode flow chart of humiture interlock control of the present invention;
Figure 11 is the heating mode humiture curve map of humiture interlock control of the present invention;
Figure 12 is flow process 7 schematic diagrames of the present invention;
Figure 13 is flow process 8 schematic diagrames of the present invention;
Figure 14 is flow process 9 schematic diagrames of the present invention;
Figure 15 is flow process 10 schematic diagrames of the present invention.
[specific embodiment]
See also Fig. 1, control model of the present invention can be controlled air-conditioning in conjunction with indoor temperature, humidity, CO2, and this pattern comprises temperature sensor, humidity sensor and CO2 sensor, can control variation of temperature in conjunction with indoor humidity, has created a good sleep environment.
Wherein temperature sensor output signal 1, humidity sensor output signal 2, CO2 sensor output signal 3, humidity control program and CO2 control program are started working simultaneously when the user starts shooting, and continual output live signal is provided with the back and uses.The humidity control program sees also Fig. 2, the CO2 control program sees also Fig. 3, wherein humidity range and CO2 scope are set certain scope according to GB or relevant criterion, be lower than this scope lower limit when detecting humidity value, then begin humidification, the upper limit that reaches this scope up to humidity value stops humidification; When detecting CO2 and be higher than this range limit, open ventilatory, reach this scope lower limit up to CO2 value and stop to take a breath.
Please refer to Fig. 8,9, refrigeration mode flow chart and the humiture curve map of humiture interlock control; And Figure 10,11, heating mode flow chart and the humiture curve map of humiture interlock control.
In the present embodiment, under the air-conditioning heating mode, divide a1, b1, four humiture control scopes of c1, d1 according to the humiture curve, and formulate each scope temperature control and regulate formula, a1 scope: T0=T+1, b1 scope: T0=T, c1 scope: T0=T-1, d1 scope: T0=T-2, wherein T is the current environmental temperature value, T0 is the running temperature value behind the temperature adjusting.
Under the air conditioner refrigerating pattern, divide a2, b2, c2, d2, five humiture control scopes of e2 according to the humiture curve, and formulate each scope temperature control and regulate formula, a2 scope: T
0=T+2, b2 scope: T
0=T+1, c2 scope: T
0=T, d2 scope: T
0=T-1, e2 scope: T
0=T-2, wherein T is the current environmental temperature value, T
0Be the running temperature value behind the temperature adjusting.
The control method of this air-conditioning sleep pattern, described sleep pattern are divided into afternoon nap pattern (Fig. 4,5) and sleep pattern at night (Fig. 6,7), and the manual variable of setup parameter after the user selects corresponding sleep pattern also can be selected default value.
Afternoon nap pattern detailed process is as follows: the user selects can select oneself to arrange operational factor after the afternoon nap pattern or select to carry out according to default parameters.As select oneself to regulate operational factor: the user can oneself arrange the operation of air conditioner temperature T
If, temperature increment Delta T and operation of air conditioner time.Air-conditioner rises temperature (perhaps descending) to T gradually according to the operation of user's design temperature and in the time that the user sets
If± Δ T.And humidity sensor is that signal 2 produces in the work that does not stop if any new humidity value during the course, and air-conditioning moves the scope that humiture interlock control program reads the real-time temperature value and finds out best output temperature according to the interlock of the humiture in appendix curve at once.The operation humiture interlock control program that air-conditioning does not stop was shut down after the running time that reaches user's setting.As select default parameters: the temperature that reads air-conditioning operation last time makes it equal design temperature.
As shown in Figure 4, during refrigeration mode: if design temperature is 16 ℃, after indoor environment temperature reaches design temperature, air-conditioner continues operation makes indoor environment temperature rise 3 ℃ within a certain period of time, carry out according to this temperature then, if new moisture signal input is arranged, then enter program 6.; If design temperature is 17~27 ℃, after indoor environment temperature reached design temperature, air-conditioner continues operation rose 2 ℃ indoor environment temperature within a certain period of time gradually, carry out according to this temperature then, if new moisture signal input is arranged, then enters program 6., shown in Fig. 8~11; If design temperature is 28~30 ℃, after indoor environment temperature reached design temperature, air-conditioner continues operation rose 1 ℃ indoor environment temperature within a certain period of time gradually, carried out according to this temperature then, if new moisture signal input is arranged, then entered program 6..
As shown in Figure 5, during heating mode: if design temperature is 16~23 ℃, after indoor environment temperature reaches design temperature, air-conditioner continues operation makes indoor environment temperature rise 2 ℃ within a certain period of time, air-conditioner is according to this temperature operation then, if new moisture signal input is arranged, then enters step procedure 6.; If design temperature is 24~29 ℃, after indoor environment temperature reached design temperature, air-conditioner continues operation rose 1 ℃ indoor environment temperature within a certain period of time gradually, and air-conditioner is according to this temperature operation then, if new moisture signal input is arranged, then enters program 6.; If design temperature is 30 ℃, after indoor environment temperature reached design temperature, air-conditioner was failure to actuate, and then according to this temperature operation, if new moisture signal input is arranged, then entered program 6., finished up to the running time of setting.
The certain hour of mentioning in said process is the best lunch break 30min that everybody generally believes, also can change other times as required into.The difference of cooling and warming is the temperature range difference, specifically embodies in the program of afternoon nap pattern.
Night, the sleep pattern detailed process was as follows: (be example with the refrigeration) user selects can to select after the sleep pattern oneself to set operational factor or according to the parameter operation of acquiescence.As select oneself to set operational factor: the user sets air-conditioner running temperature T
If, temperature increment Delta T and operation of air conditioner time.Be divided into three phases the running time here: phase I---human body enters the stage of sleep; Second stage---the stage of human body deep sleep; The stage that phase III---human body is waken up soon; According to the sleep habit of human body, the duration ratio of setting this three phases at the master controller of air-conditioning is 1: 5: 1 in advance.After the user had set, 10. air-conditioner carried out according to program, as Figure 15.In the first running time section, air-conditioner temperature is from T
If-Δ T rises to design temperature T gradually
If, air-conditioner is according to design temperature T in the second running time section
IfOperation, indoor temperature rises to T=T gradually in the 3rd running time
If+ Δ T.In this pattern in case new signal 2 input is arranged, air-conditioning then working procedure 6., shown in Fig. 8,10, up to the air-conditioner power cut-off.Move according to default parameters as selecting: the temperature when air-conditioner reads and moved last time also makes it equal design temperature T
If, judge T then
If9. 8. 7. affiliated scope carry out according to program, as Figure 12~14.
As shown in Figure 6, during refrigeration mode: when (1) is 16~23 ℃ when design temperature, after indoor environment temperature reaches design temperature, air-conditioner continue operation make running temperature per hour temperature raise 1 ℃, raises and keeps this temperature after 3 ℃, after moving 7 hours, temperature reduces by 1 ℃, under this temperature, move ever since, if new moisture signal input is arranged, then enter program 6.; (2) when initial temperature is set to 24~27 ℃, after indoor environment temperature reaches design temperature, air-conditioner continue operation make running temperature per hour temperature raise 1 ℃, raise and keep this temperature after 2 ℃, after operation 7 hours, temperature reduces by 1 ℃, moves under this temperature ever since, if new moisture signal input is arranged, then enters program 6.; (3) when initial temperature is set to 28~29 ℃, after indoor environment temperature reaches design temperature, air-conditioner continue operation make running temperature per hour temperature raise 1 ℃, raise and keep this temperature after 1 ℃, after operation 7 hours, temperature reduces by 1 ℃, moves under this temperature ever since, if new moisture signal input is arranged, then enters program 6.; (4) when initial temperature is set to 30 ℃, under this temperature, move, after operation 7 hours, temperature reduces by 1 ℃, moves under this temperature ever since, if new moisture signal input is arranged, then enters program 6..
As shown in Figure 7, during heating mode: when (1) is set to 16 ℃ when initial temperature, under this temperature, move always, if new moisture signal input is arranged, then enter program 6.; (2) when initial temperature is set to 17~20 ℃, after indoor environment temperature reaches design temperature, air-conditioner continue operation make running temperature per hour temperature reduce by 1 ℃, keep this temperature after reducing by 1 ℃, if the input of new moisture signal is arranged, then enter program 6.; (3) when initial temperature is set to 21~27 ℃, after indoor environment temperature reaches design temperature, air-conditioner continue operation make running temperature per hour temperature reduce by 1 ℃, keep this temperature after reducing by 2 ℃, if the input of new moisture signal is arranged, then enter program 6.; (4) when initial temperature is set to 28~30 ℃, after indoor environment temperature reaches design temperature, air-conditioner continue operation make running temperature per hour temperature reduce by 1 ℃, keep this temperature after reducing by 3 ℃, if the input of new moisture signal is arranged, then enter program 6..
The novel part of this patent be exactly program 6.---humiture interlock curve.Below the detailed description program 6., see also Fig. 8~11.When freezing or heating: 2 inputs of new signal are arranged, and program is transferred temperature sensor and is read up-to-date temperature value, reads the temperature output of the best in conjunction with the humiture interlock curve of refrigeration or heating mode.
6. this program can independently go out to be arranged in the air-conditioning, this program can only be regulated temperature by reading moisture signal, and then make the room reach the humiture of best (the most suitable sleep quality), design temperature refers to the running temperature of air-conditioning, and described raising once or reduce once all can Infinite Cyclic.Refrigeration all can enter regional c2 at last, heats at last and all can enter regional b1.
The above is preferred embodiment of the present invention only, and protection scope of the present invention is not limited thereto, and anyly all belongs within the protection domain of the present invention based on the equivalent transformation on the technical solution of the present invention.
Claims (11)
1. air-conditioner humiture inter-linked controlling method is characterized in that it comprises step:
(1) formulates the humiture curve as required, and formulate each the scope temperature control of this curve and regulate formula, enter step (2);
(2) read the moisture signal of humidity sensor and the temperature signal of temperature sensor, according to scope under curve judgement institute's humidity that reads and the temperature, enter step (3);
(3) regulate formula according to scope temperature control under it and carry out adjustment, then return step (2) if any new moisture signal input, otherwise air-conditioning is by the running temperature operation after regulating.
2. air-conditioner humiture inter-linked controlling method as claimed in claim 1 is characterized in that this method also comprises:
Set humidity acquiescence minimum and peak, when the humidity value that reads is then opened humidifier until reaching peak less than minimum.
3. air-conditioner humiture inter-linked controlling method as claimed in claim 1 is characterized in that this method also comprises:
CO is set
2Sensor, and CO is set
2Content default maximum and minimum of a value read CO
2The signal value of sensor is as the CO that reads
2Content value is just moved ventilatory until CO greater than default maximum
2Content value reaches minimum of a value.
4. air-conditioner humiture inter-linked controlling method as claimed in claim 1 is characterized in that, under the air-conditioning heating mode, divides a1, b1, four humiture control scopes of c1, d1 according to the humiture curve, and formulates each scope temperature control and regulate formula, a1 scope: T
0=T+1, b1 scope: T
0=T, c1 scope: T
0=T-1, d1 scope: T
0=T-2, wherein T is current indoor environment temperature value, T
0Be the set temperature value behind the temperature adjusting.
5. air-conditioner humiture inter-linked controlling method as claimed in claim 1, it is characterized in that, under the air conditioner refrigerating pattern, divide a2, b2, c2, d2, five humiture control scopes of e2 according to the humiture curve, and formulate each scope temperature control and regulate formula, a2 scope: T
0=T+2, b2 scope: T
0=T+1, c2 scope: T
0=T, d2 scope: T
0=T-1, e2 scope: T
0=T-2, wherein T is current indoor environment temperature value, T
0Be the set temperature value behind the temperature adjusting.
6. air-conditioner humiture inter-linked controlling method as claimed in claim 1 is characterized in that it is provided with the afternoon nap pattern, can select User Defined control model or default mode after entering this afternoon nap pattern.
7. air-conditioner humiture inter-linked controlling method as claimed in claim 6 is characterized in that, described User Defined control model arranges the operation of air conditioner temperature T by the user
If, temperature increment Δ T and operation of air conditioner time t1, air-conditioner is according to the operation of user's design temperature and gradually running temperature is adjusted to T in the time t1 that the user sets
If+ Δ T keeps this temperature operation then; If new moisture signal input is arranged, then enter step (2), if there is not the moisture signal input, then running temperature remains T
If+ Δ T finished up to the running time of setting.
8. air-conditioner humiture inter-linked controlling method as claimed in claim 6 is characterized in that, described default mode makes it equal design temperature T by the temperature that reads air-conditioning operation last time
If, the running time of adopting the air-conditioning acquiescence,
When air-conditioner is in refrigeration mode: temperature is divided a3, b3, three modification scopes of c3, if design temperature is in the a3 scope, after indoor environment temperature reaches design temperature, the running temperature of air-conditioner rises 2 ℃ within a certain period of time, then according to this temperature operation, if new moisture signal input is arranged, then enters step (2);
If design temperature is in the b3 scope, after indoor environment temperature reached design temperature, air-conditioner continues operation rose 1 ℃ indoor environment temperature within a certain period of time gradually, then according to this temperature operation, if new moisture signal input is arranged, then entered step (2);
If design temperature is c3, after indoor environment temperature reached design temperature, air-conditioner was failure to actuate, and then according to this temperature operation, if new moisture signal input is arranged, then entered step (2), finished up to the running time of setting;
When air-conditioner is in heating mode: temperature is divided a4, b4, three modification scopes of c4, if design temperature is in the a4 scope, after indoor environment temperature reaches design temperature, air-conditioner continues operation makes indoor environment temperature rise 3 ℃ within a certain period of time, air-conditioner is according to this temperature operation then, if new moisture signal input is arranged, then enter step (2), finish up to the running time of setting;
If design temperature is in the b4 scope, after indoor environment temperature reaches design temperature, air-conditioner continues operation rises 2 ℃ indoor environment temperature within a certain period of time gradually, air-conditioner is according to this temperature operation then, if new moisture signal input is arranged, then enter step (2), finish up to the running time of setting;
If design temperature is in the c4 scope, after indoor environment temperature reaches design temperature, air-conditioner continues operation rises 1 ℃ indoor environment temperature within a certain period of time gradually, air-conditioner is according to this temperature operation then, if new moisture signal input is arranged, then enter step (2), finish up to the running time of setting.
9. air-conditioner humiture inter-linked controlling method as claimed in claim 1 is characterized in that it is provided with the sleep pattern at night, enters this night and can select User Defined control model or default mode after the sleep pattern.
10. air-conditioner control method as claimed in claim 9 is characterized in that, described User Defined control model is set air-conditioner running temperature T by the user
If, temperature increment Delta T and operation of air conditioner time t2, be divided into three phases running time, in the first running time section, the running temperature of air-conditioning is from T
If-Δ T rises to design temperature T gradually
If, air-conditioner is according to design temperature T in the second running time section
IfOperation, the operation of air conditioner temperature rises to T=T gradually in the 3rd running time
If+ Δ T;
11. air-conditioner humiture inter-linked controlling method as claimed in claim 9 is characterized in that, described default mode, air-conditioner read the design temperature when moving last time and make it equal design temperature T
If,
When air-conditioner is in refrigeration mode: temperature is divided a5, b5, four modification scopes of c5, d5, when design temperature during in the a5 scope, after indoor environment temperature reaches design temperature, the running temperature of air-conditioner per hour temperature raises 1 ℃, raises to keep this temperature after 3 ℃, after moving 7 hours, temperature reduces by 1 ℃, under this temperature, move ever since, if new moisture signal input is arranged, then enter step (2);
When initial temperature is arranged on the b5 scope, after indoor environment temperature reaches design temperature, the running temperature of air-conditioner per hour temperature raises 1 ℃, raise and keep this temperature after 2 ℃, after operation 7 hours, temperature reduces by 1 ℃, moves under this temperature ever since, if new moisture signal input is arranged, then enters step (2);
When initial temperature is arranged on the c5 scope, after indoor environment temperature reaches design temperature, the running temperature of air-conditioner per hour temperature raises 1 ℃, raise and keep this temperature after 1 ℃, after operation 7 hours, temperature reduces by 1 ℃, moves under this temperature ever since, if new moisture signal input is arranged, then enters step (2);
When initial temperature is arranged on the d5 scope, under this temperature, move, after operation 7 hours, temperature reduces by 1 ℃, moves under this temperature ever since, if new moisture signal input is arranged, then enters step (2);
During heating mode: temperature is divided a6, b6, four modification scopes of c6, d6, when initial temperature is arranged on the a6 scope, after indoor environment temperature reaches design temperature, air-conditioner continue operation make running temperature per hour temperature reduce by 1 ℃, keep this temperature after reducing by 1 ℃, if new moisture signal input is arranged, then enters step (2);
When initial temperature is set to b6, after indoor environment temperature reaches design temperature, air-conditioner continue operation make running temperature per hour temperature reduce by 1 ℃, keep this temperature after reducing by 2 ℃, if the input of new moisture signal is arranged, then enter step (2);
When initial temperature is arranged on the c6 scope, after indoor environment temperature reaches design temperature, air-conditioner continue operation make running temperature per hour temperature reduce by 1 ℃, keep this temperature after reducing by 3 ℃, if the input of new moisture signal is arranged, then enter step (2);
When initial temperature is arranged on the d6 scope, under this temperature, move always.
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CN103032934B (en) * | 2011-10-08 | 2015-02-18 | 珠海格力电器股份有限公司 | Automatic control method of air conditioner |
CN103375876B (en) * | 2012-04-25 | 2015-09-16 | 珠海格力电器股份有限公司 | The dehumidification control method of air-conditioner and control method, device and air-conditioner |
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