CN111550903A - Air conditioner control method - Google Patents

Abstract

The invention provides an air conditioner control method which comprises the steps of obtaining the current indoor temperature in real time, entering refrigeration control when the current indoor temperature meets a first condition, exiting the refrigeration control and entering a forced ventilation mode when the current indoor temperature meets a second condition under the refrigeration control, wherein the forced ventilation mode is implemented to carry out forced ventilation within a fixed time. Therefore, the forced ventilation strategy is carried out within a fixed time, the energy consumption increase caused by frequent compressor starting and stopping or frequency conversion due to the change of the indoor temperature in the traditional control method is avoided, the indoor temperature change can be ignored within the fixed time through limiting the ventilation time, and the better energy consumption economy is obtained under the energy-saving requirement.

Description

Air conditioner control method

Technical Field

The invention relates to the field of air conditioning, in particular to an air conditioner control method.

Background

The air conditioner is an electric appliance with high energy consumption, and the comfort and the energy conservation of the air conditioner generally form a contradiction. If the user prefers cooler air conditioning temperatures in summer, more energy is required. However, each different user has a different experience with respect to temperature, and some users prefer a slightly higher temperature, which tends to be more energy-saving. Particularly, the air conditioner is not suitable for the people with low household income, and even has the special behavior of turning off the air conditioner in the middle of the night, and the aim is to save power consumption. But this in turn affects the quality of the user's sleep.

Disclosure of Invention

In order to solve the above problems, the present invention provides an air conditioner control method, which can balance the comfort and energy saving of a user by designing an air conditioner capable of providing a plurality of automatic control means of energy saving operation modes for the user.

According to an aspect of an embodiment of the present invention, there is provided an air conditioner control method, including acquiring a current indoor temperature in real time, entering a cooling control when the current indoor temperature satisfies a first condition, exiting the cooling control when the current indoor temperature satisfies a second condition under the cooling control, and entering a forced ventilation mode, where the forced ventilation mode is implemented to perform forced ventilation for a fixed duration. Therefore, the forced ventilation strategy is carried out within a fixed time, the energy consumption increase caused by frequent compressor starting and stopping or frequency conversion due to the change of the indoor temperature in the traditional control method is avoided, the indoor temperature change can be ignored within the fixed time through limiting the ventilation time, and the better energy consumption economy is obtained under the energy-saving requirement.

Preferably, the forced ventilation mode determines a ventilation wind speed based on a current indoor temperature in the forced ventilation mode.

Preferably, the method further comprises the steps of acquiring a body sensing temperature and adjusting the forced ventilation mode based on the body sensing temperature.

Preferably, when the operation duration of the forced ventilation mode exceeds the fixed duration, the current indoor temperature is acquired, when the current indoor temperature meets a third condition, the forced ventilation mode is exited and the refrigeration control is entered, otherwise, the forced ventilation mode is maintained.

Preferably, the first condition is that the current indoor temperature is higher than the sum of the sensible temperature and the additional temperature value.

Preferably, the second condition is that the current indoor temperature is less than a difference between the sensible temperature and the additional temperature value.

Preferably, the third condition is that the current indoor temperature is not less than the sum of the sensible temperature and the additional temperature value.

Preferably, the cooling control is implemented to adjust an air conditioner operation frequency and a fan rotation speed based on a current indoor temperature.

Preferably, an energy saving level is further included, and the fixed time period corresponds to the energy saving level.

According to another aspect of the embodiments of the present invention, there is provided a storage medium including a stored program, wherein when the program is executed, an apparatus in which the storage medium is located is controlled to execute the aforementioned air-conditioning control method.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

FIG. 1 is a schematic diagram of an air conditioner control method according to the present invention;

FIG. 2 is a schematic diagram of the forced draft mode control logic of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

According to an aspect of an embodiment of the present invention, there is provided an air conditioner control method, as shown in fig. 1, including obtaining a current indoor temperature in real time, entering a cooling control when the current indoor temperature satisfies a first condition, exiting the cooling control when the current indoor temperature satisfies a second condition under the cooling control, and entering a forced ventilation mode, where the forced ventilation mode is implemented to perform forced ventilation for a fixed duration. Therefore, the forced ventilation strategy is carried out within a fixed time, the energy consumption increase caused by frequent compressor starting and stopping or frequency conversion due to the change of the indoor temperature in the traditional control method is avoided, the indoor temperature change can be ignored within the fixed time through limiting the ventilation time, and the better energy consumption economy is obtained under the energy-saving requirement.

The air conditioner control method further comprises the step of obtaining the body sensing temperature T0, and adjusting the forced ventilation mode based on the body sensing temperature T0. The first condition is that the current indoor temperature is greater than the sum of the sensible temperature T0 and the temperature added value dT. The second condition is that the current indoor temperature is smaller than the difference between the sensible temperature T0 and the temperature added value dT. The sensible temperature T0 can be set by a user, can be automatically set based on the user's habit, and can be automatically set based on the indoor and outdoor ambient temperatures. The sensible temperature T0 is a temperature sensed by the end user and is different from the set temperature of the air conditioner. The temperature added value dT is a temperature correction amount in the control process, and is preferably 1 ℃. Through additional value correction, the final temperature control effect can be more in line with the expectation of the customer requirements.

The energy-saving control logic of the air conditioner is based on the selected sensible temperature T0, when the air conditioner operates in the mode, the air conditioner detects the indoor temperature Ti, if the Ti is more than T0+ dT, the refrigeration mode is started, and otherwise, the air conditioner does not act when the room temperature changes. After the refrigeration mode is started, the room temperature is reduced to T0-dT by a conventional temperature control means, then the refrigeration is stopped, the ventilation mode is switched to, and the refrigeration is not started again according to the change of the room temperature Ti in the ventilation mode.

And the refrigeration mode is an operation mode for adjusting the operation frequency of the air conditioner and the rotation speed of the fan based on the current indoor temperature Ti. Obviously, if a user has a strong power saving requirement at night, the start/stop or the running frequency of the compressor can be frequently adjusted in real time according to the indoor temperature change in the refrigeration mode, so that the energy consumption expenditure can be increased to a certain extent. On the contrary, the control method of the invention carries out forced ventilation control after the room temperature is reduced to T0-dT, namely the indoor temperature is lower than the expected value of a user, the forced ventilation time is set, so that the air conditioner can not start refrigeration again due to small amplitude rise of the indoor temperature within the fixed time, the forced ventilation time which is long enough can greatly avoid frequent compressor start-stop or energy consumption increase caused by frequency conversion due to the change of the indoor temperature, and the ventilation time can be limited to disregard the change of the indoor temperature within the fixed time, thereby obtaining better energy consumption economy under the requirement of energy saving.

In some embodiments, the current indoor temperature Ti is obtained when the forced ventilation mode operation duration exceeds a fixed duration, and when the current indoor temperature Ti satisfies a third condition, the forced ventilation mode is exited and refrigeration control is entered, otherwise the forced ventilation mode is maintained. The third condition is that the current indoor temperature Ti is not less than the sum of the sensible temperature T0 and the temperature added value dT. Thus, when the ventilation time is reached, the air conditioner detects the indoor temperature, and if the indoor temperature Ti > T0+ dT, the cooling is started again, otherwise, the ventilation is continued, and at the same time, the cooling is controlled by Ti. Therefore, the influence of indoor temperature change is comprehensively considered, the refrigeration mode is not directly switched back to the refrigeration mode even after the forced ventilation is finished for a long time, the forced ventilation mode is continuously maintained when the indoor temperature Ti is judged not to meet the third condition based on the detection of the indoor temperature Ti, and the energy consumption economy is further improved while the comfort degree of the room temperature is ensured. Thus, the above steps are repeated in a circulating way to form energy-saving control.

In some embodiments, the forced draft mode determines the ventilation wind speed based on the current indoor temperature in the forced draft mode. Specifically, in the forced ventilation mode, the wind speed needs to correspond to the indoor temperature Ti, when the room temperature Ti is low, the wind speed is low, otherwise, the user experiences discomfort, and when the wind speed is high, the user is given high wind speed, so that the phenomenon that the wind speed is used for compensating when the temperature is too high is avoided, the evaporation and heat absorption of the body surface of the user are enhanced, and the cool feeling is increased.

The correlation between the set windshield and the room temperature is as follows. The wind speed can be divided into DL5, DL4, DL3, DL2, DL1 and DL0 by the fan on average in a grading mode, wherein DL0 is the wind speed of 0, namely the wind blowing stop gear, and DL5 is the maximum wind speed. Wind speed control logic as shown in fig. 2, in the forced draft mode, the wind speed F is controlled according to this logic, and if not, the wind speed F is not controlled according to this mode.

The air temperature is used for detecting the indoor temperature and corresponds to five temperature control points Ti5, Ti4, Ti3, Ti2 and Ti 1. When the indoor temperature Ti is less than or equal to Ti1, the wind speed F is DL0, and Ti1 is selected to be 24 ℃. When Ti > Ti1 and Ti ≦ Ti2, the wind speed F is DL1, preferably Ti2 ≦ 26 ℃. When Ti > Ti2 and Ti ≦ Ti3, the wind speed F is DL2, preferably Ti3 ≦ 28 ℃. When Ti > Ti3 and Ti ≦ Ti4, the wind speed F is DL3, preferably Ti4 ≦ 29 ℃. When Ti > Ti4 and Ti ≦ Ti5, the wind speed F is DL4, preferably Ti5 ≦ 30 ℃. When Ti > Ti5, the wind speed F is DL5, preferably Ti4 ═ 30 ℃. And when the ventilation time is up, the forced ventilation mode is exited and is not controlled in the mode.

Through the correspondence of wind speed and temperature, can ensure that even just under the mode of ventilation, the user still can take away the body surface heat through heat convection and the endothermic mode of evaporation, in considering the use scene of air conditioner, most users are mostly to sleep the scene at night under energy-conserving demand and give first place to, and the user is in air conditioner refrigeration operation at present, and is comparatively counter-productive to cold wind direct-blow. In the ventilation mode, the air outlet temperature of the air conditioner is higher than that in the refrigeration mode, so that the discomfort of a user caused by direct blowing of cold air is reduced. In addition, the flow rate of indoor air can be adjusted in different room temperature environments through the correspondence between the wind speed and the temperature, and when the indoor temperature is low, the wind outlet is reduced or stopped, so that the phenomenon that the sensible temperature of a user is too low due to convection heat exchange is avoided; when the indoor temperature is higher, the wind speed is increased, the flow rate of indoor air can be accelerated, and therefore even if the air is not refrigerated for a long time, the sensible temperature of a user can be maintained at a relatively comfortable level through the adjustment of the wind speed

In some embodiments, the air conditioner control method further includes an energy saving level setting, and the fixed time period corresponds to the energy saving level. And setting an energy-saving operation mode on the air conditioner remote controller, and setting the energy-saving operation mode to be energy-saving control modes of different levels according to an energy-saving mode for a user to select. In the energy-saving control mode, different substances are set by applying different sensitivities to the temperature, and preferably 24-DEG C body sensing control, 25-DEG C body sensing control, 26-DEG C body sensing control, 27-DEG C body sensing control, 28-DEG C body sensing control, 29-DEG C body sensing control and 30-DEG C body sensing control are set. There are again N kinds of wind sense control, preferably 3 kinds of wind sense control at each temperature. Preferably, there are 21 energy saving modes for the user to select. The energy-saving control method is characterized in that ventilation time is increased by means of a conventional constant temperature control program of the air conditioner, for example, a 24 ℃ somatosensory control mode is as follows, when the temperature is reduced to 24 ℃, a compressor is stopped, a ventilation mode is switched to be controlled according to different wind senses of ventilation time, and preferably, modes such as 10-minute ventilation operation, 20-minute ventilation operation, 30-minute ventilation operation and the like are adopted. When a user designs a specific energy-saving control mode, the air conditioner firstly reduces the temperature to the selected sensible temperature T0, then switches to a ventilation mode, and does not refrigerate any more no matter how the indoor temperature changes in the ventilation time. However, the ventilation air speed has a corresponding relation with the room temperature, the air conditioner still detects the indoor temperature, and the ventilation air speed is selected according to the indoor temperature, and the higher the indoor temperature is, the higher the ventilation speed is. And after the ventilation time is up, judging whether the indoor temperature Ti meets Ti & gt T0, if the indoor temperature Ti & gt T0, refrigerating, switching to the ventilation mode again after the temperature is reduced to T0, and circulating the steps.

Therefore, an energy-saving operation mode is newly added under the air conditioner remote controller, in the energy-saving operation mode, firstly, the somatosensory temperature control is selected, and then, 3 energy-saving grade operation modes are selected, wherein the most energy-saving mode corresponds to 30-minute ventilation time, the second energy-saving mode corresponds to 20-minute ventilation time, and the third energy-saving mode corresponds to 10-minute ventilation time. By the embodiment, different physical requirements of users can be met practically, and the users do not need to be waken up or uncomfortable to sleep as long as the temperature and the air volume can ensure that the users do not get warm. If some users do not actually affect the sleep of the users even if the temperature is not higher than a certain temperature point, the users can feel what way to meet the sleep requirement and save energy through various body sensing choices, and optimization of energy saving and user experience is achieved. After the user finds out the mode which is most suitable for the physique of the user and can save energy, the user can subsequently enter the mode control again.

According to another aspect of the embodiments of the present invention, there is provided a storage medium including a stored program, wherein the apparatus where the storage medium is located is controlled to execute the aforementioned air conditioner control method when the program runs.

The air conditioner control method provided by the embodiment of the invention can be realized in the form of a software functional module, can be sold or used as an independent product, and can be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention may be embodied in the form of a software product, which is stored in a storage medium and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes.

Although the invention has been described in detail above with reference to a general description and specific examples, it will be apparent to one skilled in the art that modifications or improvements may be made thereto based on the invention. Accordingly, such modifications and improvements are intended to be within the scope of the invention as claimed.

Claims (10)

1. An air conditioner control method is characterized by comprising

Acquiring the current indoor temperature in real time, entering refrigeration control when the current indoor temperature meets a first condition,

under the refrigeration control, when the current indoor temperature meets a second condition, the refrigeration control is exited, a forced ventilation mode is entered,

wherein the forced ventilation mode is implemented such that forced ventilation is performed for a fixed period of time.

2. The air conditioning control method according to claim 1,

the forced ventilation mode determines a ventilation wind speed based on a current indoor temperature in the forced ventilation mode.

3. The air conditioning control method according to claim 1,

and further comprising acquiring the body sensing temperature and adjusting the forced ventilation mode based on the body sensing temperature.

4. The air conditioning control method according to claim 3,

and when the operation time length of the forced ventilation mode exceeds the fixed time length, acquiring the current indoor temperature, when the current indoor temperature meets a third condition, exiting the forced ventilation mode and entering the refrigeration control, otherwise, maintaining the forced ventilation mode.

5. The air conditioning control method according to claim 3,

the first condition is that the current indoor temperature is greater than the sum of the sensible temperature and the temperature added value.

6. The air conditioning control method according to claim 3,

the second condition is that the current indoor temperature is smaller than the difference between the sensible temperature and the temperature added value.

7. The air conditioning control method according to claim 4,

the third condition is that the current indoor temperature is not less than the sum of the sensible temperature and the temperature added value.

8. The air conditioning control method according to claim 1,

the refrigeration control is implemented by adjusting the operating frequency of the air conditioner and the rotational speed of the fan based on the current indoor temperature.

9. The air conditioning control method according to claim 1,

the system also comprises an energy-saving grade, and the fixed time length corresponds to the energy-saving grade.

10. A storage medium characterized in that,

the storage medium includes a stored program, wherein the apparatus on which the storage medium is located is controlled to perform the air-conditioning control method according to any one of claims 1 to 9 when the program is executed.

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