CN110567122A - air conditioning area control method, device and system - Google Patents

air conditioning area control method, device and system Download PDF

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Publication number
CN110567122A
CN110567122A CN201910872087.4A CN201910872087A CN110567122A CN 110567122 A CN110567122 A CN 110567122A CN 201910872087 A CN201910872087 A CN 201910872087A CN 110567122 A CN110567122 A CN 110567122A
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China
Prior art keywords
area
control
air valve
current
parameter value
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CN201910872087.4A
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CN110567122B (en
Inventor
刘智荣
杨华生
李志逢
黄向聪
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Gree Electric Appliances Inc of Zhuhai
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Gree Electric Appliances Inc of Zhuhai
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Priority to CN201910872087.4A priority Critical patent/CN110567122B/en
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/50Control or safety arrangements characterised by user interfaces or communication
    • F24F11/61Control or safety arrangements characterised by user interfaces or communication using timers
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/62Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
    • F24F11/63Electronic processing
    • F24F11/64Electronic processing using pre-stored data
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/70Control systems characterised by their outputs; Constructional details thereof
    • F24F11/80Control systems characterised by their outputs; Constructional details thereof for controlling the temperature of the supplied air
    • F24F11/83Control systems characterised by their outputs; Constructional details thereof for controlling the temperature of the supplied air by controlling the supply of heat-exchange fluids to heat-exchangers
    • F24F11/84Control systems characterised by their outputs; Constructional details thereof for controlling the temperature of the supplied air by controlling the supply of heat-exchange fluids to heat-exchangers using valves

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Signal Processing (AREA)
  • Physics & Mathematics (AREA)
  • Fuzzy Systems (AREA)
  • Mathematical Physics (AREA)
  • Human Computer Interaction (AREA)
  • Air Conditioning Control Device (AREA)

Abstract

The invention relates to an air conditioning area control method, device and system, comprising the following steps: acquiring theoretical time required by each control area in the area control terminal to change a preset value from a given environmental parameter value; all the theoretical times are different from each other; acquiring the running time required by the area of each air valve, which is changed from the current actual environmental parameter value to the same preset value; all the operation times are different from each other; when the theoretical time of one control area is matched with the running time of one air valve, the current air valve is matched with the current control area; the parameter type of the given ambient parameter value is the same as the parameter type of the current actual ambient parameter value. When the theoretical time of one control area is matched with the running time of one air valve, the current air valve is matched with the current control area, so that the matching relation between the air valve and the control area is obtained, manual matching of the air valve and the control area is avoided, and the air valve and the control area are convenient to use and are not prone to error.

Description

Air conditioning area control method, device and system
Technical Field
the invention relates to the technical field of intelligent control, in particular to a method, a device and a system for controlling an air conditioner area.
Background
With the development of economy and the progress of society, people are pursuing quality of life, for example, people have higher and higher requirements on living and working environments, and thus a plurality of areas are often arranged to meet different living and working requirements of people. The traditional multi-split air conditioner can control the temperature regulation of each area, but as the installation cost increases, many users choose to install one air duct machine and then match with an area control system to achieve the purpose of regulating the temperature in each area.
the regional control system is realized by adding an air pipe pipeline, an air valve controller, a regional control terminal and a temperature controller on the basis of one-to-one unit (such as an air pipe machine), and the independent control of a plurality of small regions can be realized by controlling the opening and closing of an air valve through the regional control terminal. However, the above operation control is premised on: accurate pairing is needed among each control signal on the regional control terminal, the air valve of each region and the temperature controller of each region.
in the traditional technology, pairing among the three is completed manually, a plurality of control areas are required to be newly built on a regional control terminal and named, then the serial number of an air valve connected with each control area is checked through checking wiring and is input into the regional control terminal, and then the addresses of temperature controllers in the control areas are checked and input into the regional control terminal, so that a series of matching operations are completed, the work is complex, and mistakes are easy to make.
Disclosure of Invention
therefore, it is necessary to provide a method, an apparatus, and a system for controlling an air conditioning area, which can reduce the complexity of pairing a control area with an air valve in a local control terminal and prevent errors, in order to solve the problems of complicated pairing work and easy errors of the control area and the air valve in a traditional local control terminal.
An air conditioning zone control method comprises the following steps:
acquiring theoretical time required by each control area in the area control terminal to change a preset value from a given environmental parameter value; wherein all of the theoretical times are different from each other;
acquiring the running time required by the area of each air valve, which is changed from the current actual environmental parameter value to the same preset value; wherein all of the run times are different from each other;
when the theoretical time of one control area is matched with the running time of one air valve, the current air valve is matched with the current control area;
wherein the parameter type of the given environmental parameter value is the same as the parameter type of the current actual environmental parameter value.
In one embodiment, the parameter type of the given environmental parameter value and the parameter type of the current actual environmental parameter value are selected from one or more of temperature, humidity and cleanliness.
In one embodiment, after obtaining the theoretical time required for each control area in the area control terminal to change from the given environmental parameter value by the preset value, the method further includes the following steps:
All the theoretical time is sequentially distributed according to a preset rule;
After the running time required by the current actual environment parameter value change of the area of each air valve to be equal to the preset value is obtained, the method further comprises the following steps:
sequentially arranging all the running times according to the same preset rule;
When the theoretical time of one control area is matched with the running time of one air valve, the current air valve is matched with the current control area, and the method comprises the following steps:
And when the theoretical time of one control area corresponds to the arrangement sequence of the running time of one air valve, matching the current air valve with the current control area.
In one embodiment, the sequentially arranging all the theoretical times according to a preset rule includes:
all the theoretical times are arranged in sequence according to the time length;
And sequentially arranging all the running times according to the same preset rule, comprising the following steps:
All the running times are sequentially arranged according to the time length;
When the theoretical time of one control area corresponds to the arrangement sequence of the running time of one air valve, the current air valve is matched with the current control area, and the method comprises the following steps:
When the theoretical time of one control area corresponds to the operating time of one air valve, the current air valve is matched with the current control area.
In one embodiment, when the theoretical time of one of the control areas matches the operating time of one of the dampers, the current damper matches the current control area, including the steps of:
And when the running time of one air valve is within the upper and lower preset ranges of the theoretical time of one control area, matching the current air valve with the current control area.
in one embodiment, the obtaining of the theoretical time required by each control area in the area control terminal to change from the given environmental parameter value to the preset value includes:
Acquiring theoretical time required by each control area in the area control terminal from a given first environmental parameter value to a given second environmental parameter value, wherein the preset value is changed from the given first environmental parameter value;
the method for acquiring the running time required by the current actual environment parameter value change equal preset value of the area where each air valve is located comprises the following steps:
And acquiring the running time required by changing the current environmental parameter value of the area of each air valve from the same first environmental parameter value to the preset value to the same second environmental parameter value.
in one embodiment, before the theoretical time required for obtaining the preset value of the environmental parameter value of each control area in the area control terminals, the method further includes the following steps:
Newly building at least two control areas in the area control terminal;
each of the control regions is named separately.
an air conditioning zone control apparatus comprising:
the first data acquisition module is used for acquiring theoretical time required by each control area in the area control terminal to change a preset value from a given environmental parameter value; wherein all of the theoretical times are different from each other;
The second data acquisition module is used for acquiring the running time required by the area of each air valve, which is changed from the current actual environment parameter value to the same preset value; wherein all of the run times are different from each other;
and the matching module is used for matching the current air valve with the current control area when the theoretical time of one control area is matched with the running time of one air valve.
In one embodiment, the method further comprises the following steps:
The first arrangement module is used for sequentially arranging all the theoretical time according to a preset rule;
the second arrangement module is used for sequentially arranging all the running times according to the same preset rule;
when the theoretical time of one control area corresponds to the arrangement sequence of the running time of one air valve, the current air valve is matched with the current control area.
in one embodiment, the method further comprises the following steps:
The area establishing module is used for newly establishing at least two control areas in the area control terminal;
And the naming module is used for naming each control area.
an air conditioning zone control system comprises a zone control terminal, air valves, a temperature controller and an air valve controller, wherein the air valves and the temperature controller are arranged in corresponding control zones of the zone control terminal, the air valve controller is connected with the zone control terminal, the air valves and the temperature controller, and each control zone in the zone control terminal is matched with each air valve according to any one of the methods.
According to the air conditioner area control method, device and system, when the theoretical time of one control area is matched with the running time of one air valve, the current air valve is matched with the current control area, so that the matching relation between the air valve and the control area is obtained, manual matching of the air valve and the control area is avoided, and the air conditioner area control method, device and system are convenient and not prone to error.
drawings
Fig. 1 is a flowchart of an air conditioning area control method according to an embodiment of the present invention;
Fig. 2 is a block diagram of an air conditioning area control apparatus according to an embodiment of the present invention;
fig. 3 is a schematic structural diagram of an air conditioning area control system according to an embodiment of the present invention.
first data acquisition Module 110 second data acquisition Module 120 matching Module 130
Detailed Description
in order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.
Referring to fig. 1, in one embodiment, there is provided an air conditioning zone control method including the steps of:
S110: and acquiring theoretical time required by each control area in the area control terminal to change a preset value from a given environmental parameter value.
wherein all the theoretical times are different from each other. Specifically, the area control terminal has two control areas, three control areas, or three or more control areas, and the number of control areas included in the area control terminal is not limited, and the area control terminal is applicable as long as the area control terminal includes two or more control areas.
Further, the parameter type of the given environmental parameter value is selected from one or more of temperature, humidity and cleanliness. If the parameter type of the given environmental parameter value is temperature, acquiring theoretical time required by the temperature value of each control area in the area control terminal to change the preset value; when the parameter type of the given environmental parameter value is humidity, acquiring theoretical time required by the preset value of the humidity value change of each control area in the area control terminal; when the parameter type of the given environmental parameter value is cleanliness, acquiring theoretical time required by changing the preset value of the cleanliness value of each control area in the area control terminal; when the parameter types of the given environmental parameter values are three types, namely temperature, humidity and cleanliness, the time required for changing preset values of the temperature value, the humidity value and the cleanliness value of each control area in the area control terminal is obtained respectively, and then the theoretical time is obtained through calculation.
S120: and acquiring the running time required by the area of each air valve to change from the current actual environmental parameter value to the same preset value.
Wherein all the operation times are different from each other. It should be noted here that all dampers are in an open state before the above-mentioned running time is obtained, and the parameter type of the given environmental parameter value is the same as that of the current actual environmental parameter value. That is, when the parameter type of the given environmental parameter value of each control area in the area control terminal is temperature, the parameter type of the current actual environmental parameter value of the area where each air valve is located is also temperature; when the parameter type of the given environmental parameter value of each control area in the area control terminal is humidity, the parameter type of the current environmental parameter value of the area where each air valve is located is also humidity; when the parameter type of the given environmental parameter value of each control area in the area control terminal is acquired as the cleanliness, the parameter type of the current actual environmental parameter of the area where each air valve is located is acquired as the cleanliness; when the parameter types of the given environmental parameter values of each control area in the area control terminal are temperature, humidity and cleanliness, the parameter types of the current actual environmental parameter values of the area where each air valve is located are also temperature, humidity and cleanliness.
In particular, the above-mentioned operating times can be recorded by the temperature controller of the area in which each damper is located.
s130: when the theoretical time of a control area is matched with the running time of an air valve, the current air valve is matched with the current control area.
according to the air conditioner area control method, when the theoretical time of one control area is matched with the running time of one air valve, the current air valve is matched with the current control area, so that the matching relation between the air valve and the control area in the area control terminal is obtained (namely, which air valve is matched with which control area of the area control terminal is judged), the air valve and the control area are prevented from being matched manually, and the air conditioner area control method is convenient and is not prone to making mistakes.
In one embodiment, before step S110, the method further comprises the steps of:
At least two control areas are newly established in the area control terminal.
Specifically, corresponding to the above description, the number of the control areas newly created in the area control terminal may be two, three, or more than three, which is not limited herein.
Each control region is named separately for easy differentiation. For example, when four control areas are newly built in the area control terminal, the four control areas can be named as a living room, a master bed, a kitchen and a study room. If five control areas are newly established in the area control terminal, the five control areas can be named as a living room, a main bed, a secondary bed, a kitchen and a study room respectively.
in one embodiment, step S110 includes:
And acquiring theoretical time required by the preset value of the given environmental parameter value of each control area in the area control terminal according to the size of the control area, the whole air conditioner capacity and the current windshield.
In one embodiment, in step S120:
the running time comprises actual testing time which is obtained through an environment parameter controller (at the moment, each air valve and each environment parameter controller are matched in advance, and all the air valves are in an open state) arranged in the area where the air valve is located, namely the actual testing time required by the environment parameter controller in the area where the air valve is located to record the current actual environment parameter value change preset value in the area is recorded.
Specifically, when the parameter type of the current actual environment parameter value is temperature, the environment parameter controller is a temperature controller; and when the parameter type of the current actual environment parameter value is humidity, the environment parameter controller is a humidity controller.
in another embodiment, in step S120:
the running time also comprises a compensation time, the running time is the sum of the actual test time and the compensation time, and the compensation time can be a positive value or a negative value.
the reason why the setting of the operation time further includes the compensation time is that: the actual testing time is measured by the environment parameter controller, if the parameter type of the current actual environment parameter value is temperature, the actual testing time of the preset value of the current actual temperature value of the area where each air valve is located is measured by the temperature controller, but because the installation height of the temperature controller and the distance between the temperature controller and the air port in the area where each air valve is located are different, the factors can influence the actual testing time measured by the temperature controller, namely, the standards for obtaining each actual testing time are not uniform.
For example, in the cooling mode, since the cold air flows downward, under the condition that other conditions are the same (for example, the space size and the obtained air volume of the two areas are the same), the time required for the current actual temperature value of the area where the air valve with the higher installation position of the temperature controller to change the preset value is longer than the time required for the current actual temperature value of the area where the air valve with the lower installation position of the temperature controller to change the preset value, and at this time, the compensation time needs to be added, so as to ensure that the standards for obtaining the operation time are uniform.
In the cooling mode, the temperature controller of the area where one air valve is located is close to the air port, the temperature controller of the area where the other air valve is located is far from the air port, under the condition that other conditions are the same, the time required for the current actual temperature value of the area where the air valve, where the temperature controller is close to the air port, to change the preset value is smaller than the time required for the current actual temperature value of the area where the air valve, where the temperature controller is far from the air port, to change the preset value, and at the moment, the compensation time needs to be added, so that the standard of the obtained operation time is unified.
in one embodiment, step S110 includes:
and acquiring theoretical time required by each control area in the area control terminal from a given preset value of the first environmental parameter value to a second environmental parameter value.
Step S120 includes:
And acquiring the running time required by changing the current actual environmental parameter value of the area of each air valve from the same first environmental parameter value to the same second environmental parameter value.
because, if the initial value and the final value of the given environmental parameter value and the current actual environmental parameter value are different when the theoretical time and the running time are obtained, a deviation will occur. Taking the parameter type as an example of the temperature, when the theoretical time is obtained, if the theoretical time required for changing from 10 ℃ to 2 ℃ (preset value) to 12 ℃ is obtained, and when the running time is obtained, the running time required for changing from 12 ℃ to 14 ℃ is obtained, although when the theoretical time and the running time are obtained, the preset value of the temperature value change is 2 ℃, the time required for changing from 10 ℃ to 12 ℃ is different from the time required for changing from 12 ℃ to 14 ℃, and if the time required for changing from 10 ℃ to 12 ℃ is different, the matching deviation of the air valve and the control area can occur.
In one embodiment, after step S110, the method further includes:
all the theoretical time is sequentially distributed according to a preset rule;
After step S120, the method further includes:
And sequentially arranging all the running times according to the same preset rule.
the step S130 includes:
and when the theoretical time of one control area corresponds to the arrangement sequence of the running time of one air valve, the current air valve is matched with the current control area.
specifically, the preset rule is a time duration, and it is understood that in some other embodiments, the preset rule may also be another rule, for example, another rule calculated according to the time duration, and is not limited herein.
When the preset rule is the time length, all the theoretical time is sequentially distributed according to the time length, all the operation time is sequentially distributed according to the time length, and when the theoretical time of one control area corresponds to the operation time of one air valve, the current air valve is matched with the current control area.
when the area control terminal has four control areas, which are respectively defined as a living room, a main bed, a kitchen and a study room, four theoretical times respectively corresponding to the living room, the main bed, the kitchen and the study room are respectively defined as a first theoretical time, a second theoretical time, a third theoretical time and a fourth theoretical time, and if the third theoretical time is less than the fourth theoretical time and less than the second theoretical time and less than the first theoretical time, the area control terminal can obtain the first theoretical time and the second theoretical time.
the four air valves are respectively defined as a first air valve, a second air valve, a third air valve and a fourth air valve, the running time required by the current actual environmental parameter value change preset value of the area where the first air valve is located is defined as first running time, the running time required by the current actual environmental parameter value change preset value of the area where the second air valve is located is defined as second running time, the running time required by the current actual environmental parameter value change preset value of the area where the third air valve is located is defined as third running time, the running time required by the current actual environmental parameter value change preset value of the area where the fourth air valve is located is defined as fourth running time, and if the first running time is less than the second running time and less than the third running time and less than the fourth running time, the fourth.
then, according to the size relationship, the first air valve is matched with a kitchen, the second air valve is matched with a study room, the third air valve is matched with a master bed, and the fourth air valve is matched with a living room.
in one embodiment, the control area, the name of the control area, and the size of the control area are expressed as follows:
The order of the theoretical time required for obtaining the change of the given temperature value of each control area in the area control terminal by 2 ℃ is as follows:
(the third theoretical time is 5min) < (the fourth theoretical time is 7min) < (the second theoretical time is 11min) < (the first theoretical time is 15 min).
the sequence of the operation time required for obtaining the change of the current actual temperature value of the area where each air valve is located by 2 ℃ is as follows:
(the first operation time is 6min) < (the second operation time is 8min) < (the third operation time is 13min) < (the fourth operation time is 17 min).
The first air valve is matched with a kitchen, the second air valve is matched with a study room, the third air valve is matched with a master bed, and the fourth air valve is matched with a living room.
It is understood that, in another embodiment, step S130 includes:
and when the running time of one air valve is within the upper and lower preset ranges of the theoretical time of one control area, the current air valve is matched with the current control area.
Still taking the example that the area control terminal has four control areas as an example for explanation, when the area control terminal has four control areas, which are respectively defined as the living room, the main bed, the kitchen and the study room, four theoretical times respectively corresponding to the living room, the main bed, the kitchen and the study room are obtained, which are respectively defined as a first theoretical time, a second theoretical time, a third theoretical time and a fourth theoretical time.
The four air valves are respectively defined as a first air valve, a second air valve, a third air valve and a fourth air valve, the running time required by the current environmental parameter value change preset value of the area where the first air valve is located is defined as first running time, the running time required by the current environmental parameter value change preset value of the area where the second air valve is located is defined as second running time, the running time required by the current environmental parameter value change preset value of the area where the third air valve is located is defined as third running time, and the running time required by the current environmental parameter value change preset value of the area where the fourth air valve is located is defined as fourth running time.
If the first theoretical time is 15min, setting the vertical floating for 1min on the basis of the first theoretical time, and if the fourth operation time is 16min, enabling the fourth operation time to be within the vertical preset range of the first theoretical time, and enabling the fourth air valve to be matched with the living room; if the second theoretical time is 11min, floating up and down for 1min on the basis of the second theoretical time, and if the third operation time is 12min, enabling the third operation time to be within the up-down preset range of the second theoretical time, wherein the third air valve is matched with the main sleeper; if the fourth theoretical time is 7min, floating up and down for 1min on the basis of the fourth theoretical time, and if the second running time is 7min, enabling the second running time to be within the upper and lower preset range of the fourth theoretical time, and enabling the second air valve to be matched with the study room; and when the third theoretical time is 4min, the air valve floats up and down for 1min on the basis of the third theoretical time, and when the first running time is 5min, the first running time is within the up-down preset range of the third theoretical time, and the first air valve is matched with the kitchen.
Referring to fig. 2, in another embodiment, an apparatus for controlling an air conditioning area is provided, which includes a first data obtaining module 110, a second data obtaining module 120, and a matching module 130.
the first data obtaining module 110 is configured to obtain a theoretical time required by each control area in the area control terminal to change from a given environmental parameter value to a preset value. Wherein all the theoretical times are different from each other.
The second data acquisition module 120 is configured to acquire a running time required by the area of each damper to change from the current actual environmental parameter value to an equivalent preset value. Wherein all the operation times are different from each other.
the matching module 130 is configured to match the current damper to the current control area when the theoretical time of one control area matches the operating time of one damper.
In one embodiment, the air conditioning area control device further includes a first arrangement module and a second arrangement module, which are configured to sequentially arrange all the theoretical times according to a preset rule, the second arrangement module is configured to sequentially arrange all the operation times according to the same preset rule, and when the theoretical time of one control area corresponds to the arrangement sequence of the operation times of one air valve, the current air valve is matched with the current control area.
in another embodiment, the air conditioning zone control device further comprises a zone establishing module and a naming module, wherein the zone establishing module is used for newly establishing at least two control zones in the zone control terminal, and the naming module is used for naming each control zone.
For specific definition of the air conditioning area control device, reference may be made to the above definition of the air conditioning area control method, which is not described herein again. Each module in the aforementioned air-conditioning zone control device may be wholly or partially implemented by software, hardware, and a combination thereof. The modules can be embedded in a hardware form or independent from a processor in the computer device, and can also be stored in a memory in the computer device in a software form, so that the processor can call and execute operations corresponding to the modules.
Above-mentioned regional controlling means of air conditioner, when the theoretical time of a control area matches with the operating time of an air valve, current air valve and current control area phase-match to reacing air valve and control area's matching relation, thereby avoided artifical matching air valve and control area, it is comparatively convenient and difficult for makeing mistakes.
referring to fig. 3, in one embodiment, the system comprises a zone control terminal, air valves, a temperature controller and air valve controllers, wherein the air valves and the temperature controller are arranged in corresponding control zones of the zone control terminal, the air valve controllers are connected with the zone control terminal, the air valves and the temperature controller, and each control zone in the zone control terminal is matched with each air valve according to any one of the methods.
Specifically, the number of the control areas is n (n is greater than or equal to 2), and each control area is internally provided with an air valve and a temperature controller. And the air valve of each control area is connected with an air valve interface of an air valve controller, and the temperature controller of each control area is in communication connection with the RF module of the air valve controller. The air valve controller is connected with the regional control terminal through a terminal interface, and is also connected with a regional control system interface of an inner machine in an air conditioning system (the air conditioning system comprises the inner machine and an outer machine) through an air conditioning interface.
above-mentioned regional control system of air conditioner, when the theoretical time of a control area matches with the operating time of an air valve, current air valve and current control area phase-match to reacing air valve and control area's matching relation, thereby avoided artifical matching air valve and control area, it is comparatively convenient and difficult for makeing mistakes.
the technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.
the above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (11)

1. an air conditioning area control method is characterized by comprising the following steps:
Acquiring theoretical time required by each control area in the area control terminal to change a preset value from a given environmental parameter value; wherein all of the theoretical times are different from each other;
Acquiring the running time required by the area of each air valve, which is changed from the current actual environmental parameter value to the same preset value; wherein all of the run times are different from each other;
When the theoretical time of one control area is matched with the running time of one air valve, the current air valve is matched with the current control area;
Wherein the parameter type of the given environmental parameter value is the same as the parameter type of the current actual environmental parameter value.
2. the climate zone control method of claim 1, wherein the parameter type of the given environmental parameter value and the parameter type of the current actual environmental parameter value are selected from one or more of temperature, humidity and cleanliness.
3. The air-conditioning area control method according to claim 1, wherein after the theoretical time required for each control area in the area control terminal to change from the given environmental parameter value by the preset value is acquired, the method further comprises the steps of:
All the theoretical time is sequentially distributed according to a preset rule;
after the running time required by the current actual environment parameter value change of the area of each air valve to be equal to the preset value is obtained, the method further comprises the following steps:
Sequentially arranging all the running times according to the same preset rule;
When the theoretical time of one control area is matched with the running time of one air valve, the current air valve is matched with the current control area, and the method comprises the following steps:
and when the theoretical time of one control area corresponds to the arrangement sequence of the running time of one air valve, matching the current air valve with the current control area.
4. the air-conditioning area control method according to claim 3, wherein the step of sequentially arranging all the theoretical time according to a preset rule comprises the steps of:
all the theoretical times are arranged in sequence according to the time length;
And sequentially arranging all the running times according to the same preset rule, comprising the following steps:
All the running times are sequentially arranged according to the time length;
When the theoretical time of one control area corresponds to the arrangement sequence of the running time of one air valve, the current air valve is matched with the current control area, and the method comprises the following steps:
when the theoretical time of one control area corresponds to the operating time of one air valve, the current air valve is matched with the current control area.
5. The air conditioning zone control method according to claim 1, wherein when the theoretical time of one of the control zones matches the operating time of one of the dampers, the current damper matches the current control zone, comprising the steps of:
And when the running time of one air valve is within the upper and lower preset ranges of the theoretical time of one control area, matching the current air valve with the current control area.
6. the air-conditioning area control method according to claim 1, wherein the obtaining of the theoretical time required for each control area in the area control terminal to change from a given environmental parameter value to a preset value comprises the steps of:
Acquiring theoretical time required by each control area in the area control terminal from a given first environmental parameter value to a given second environmental parameter value, wherein the preset value is changed from the given first environmental parameter value;
the method for acquiring the running time required by the current actual environment parameter value change equal preset value of the area where each air valve is located comprises the following steps:
and acquiring the running time required by changing the current environmental parameter value of the area of each air valve from the same first environmental parameter value to the preset value to the same second environmental parameter value.
7. the air-conditioning zone control method according to claim 1, characterized by comprising, before the theoretical time required for each control zone in the zone control terminal to change from a given environmental parameter value by a preset value, the steps of:
Newly building at least two control areas in the area control terminal;
Each of the control regions is named separately.
8. An air conditioning zone control apparatus, comprising:
the first data acquisition module (110) is used for acquiring theoretical time required by each control area in the area control terminal to change a preset value from a given environmental parameter value; wherein all of the theoretical times are different from each other;
The second data acquisition module (120) is used for acquiring the running time required by the current actual environment parameter value change of the area of each air valve to be equal to the preset value; wherein all of the run times are different from each other;
A matching module (130) for matching the current damper to the current control area when the theoretical time of one of the control areas matches the operating time of one of the dampers.
9. the air conditioning zone control apparatus of claim 8, further comprising:
The first arrangement module is used for sequentially arranging all the theoretical time according to a preset rule;
The second arrangement module is used for sequentially arranging all the running times according to the same preset rule;
When the theoretical time of one control area corresponds to the arrangement sequence of the running time of one air valve, the current air valve is matched with the current control area.
10. The air conditioning zone control apparatus of claim 8, further comprising:
the area establishing module is used for newly establishing at least two control areas in the area control terminal;
and the naming module is used for naming each control area.
11. an air conditioning zone control system, characterized by comprising a zone control terminal, air valves, a temperature controller and an air valve controller, wherein the air valves and the temperature controller are arranged in corresponding control zones of the zone control terminal, the air valve controller is connected with the zone control terminal, the air valves and the temperature controller, and each control zone in the zone control terminal is matched with each air valve according to the method of any one of claims 1-7.
CN201910872087.4A 2019-09-16 2019-09-16 Air conditioning area control method, device and system Active CN110567122B (en)

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