CN210292207U - Temperature compensation system of air conditioner and air conditioner - Google Patents

Abstract

The utility model provides a temperature compensation system and air conditioner of air conditioner, temperature compensation system includes: the system comprises an acquisition module, a control module and a control module, wherein the acquisition module is configured to acquire the current environment temperature of the current environment of an indoor unit of the air conditioner and the current air supply state of the indoor unit; the processor is connected with the acquisition module and is configured to determine a temperature compensation value of the air conditioner according to the air supply state and correct the ambient temperature according to the temperature compensation value; the air supply state comprises an air supply mode and an air supply speed of the air conditioner. The processor of the temperature compensation system determines a temperature compensation value suitable for the current state of the air conditioner by integrating the current air supply mode and the air supply speed of the air conditioner, so that the accuracy of the temperature compensation effect is improved.

Description

Temperature compensation system of air conditioner and air conditioner

Technical Field

The utility model relates to an air conditioning technology especially relates to a temperature compensation system of air conditioner and have this temperature compensation system's air conditioner.

Background

The existing air conditioner generally adjusts the ambient temperature of a space where the air conditioner is located to a desired temperature according to the desired temperature set by a user, thereby providing a comfortable activity environment for the user. However, due to the position limitation of the temperature sensor, the existing air conditioner has an error in the judgment of whether the ambient temperature is adjusted to the expected temperature, and the comfort level of the user using the air conditioner is affected.

In order to improve the comfort of the user using the air conditioner, the conventional air conditioner sets a fixed temperature compensation value to compensate for a temperature judgment error which may occur. However, the fixed temperature compensation value has poor compensation effect and accuracy, which results in poor comfort for users using the air conditioner.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a temperature compensation system of air conditioner to the temperature compensation system inaccuracy of solving current air conditioner at least leads to the not high technical problem of user's use comfort.

The utility model discloses a further purpose improves temperature compensation system's stability.

Another object of the present invention is to provide an air conditioner with the above temperature compensation system.

Particularly, the utility model provides a temperature compensation system of air conditioner, its characterized in that includes:

the acquisition module is configured to acquire the ambient temperature of the current environment of the indoor unit of the air conditioner and the current air supply state of the indoor unit;

the processor is connected with the acquisition module and is configured to determine a temperature compensation value of the air conditioner according to the air supply state and correct the ambient temperature according to the temperature compensation value; wherein the content of the first and second substances,

the air supply state comprises an air supply mode and an air supply speed of the air conditioner.

Further, the air supply mode includes at least one of a wind people avoiding mode, a wind people blowing mode and a normal wind mode, wherein in the wind people avoiding mode, the air supply direction of the indoor unit is a direction avoiding a human body, in the wind people blowing mode, the air supply direction of the indoor unit is a direction directly facing the human body, and in the normal wind mode, the air supply direction of the indoor unit is a direction intermittently avoiding and facing the human body; and

the temperature compensation value includes a mode compensation value, and any one of the blowing modes has one of the mode compensation values tm corresponding thereto.

Further, the temperature compensation system further comprises:

the human detection module is configured to detect position parameters of a human body in the environment where the indoor unit is located;

the obtaining module is further configured to obtain the current air supply mode of the indoor unit according to the position parameter.

Further, the air supply speed comprises at least one of a high speed, a medium speed and a low speed, wherein the air supply speed of the indoor unit in the high speed state is greater than the air supply speed of the indoor unit in the medium speed state, and the air supply speed of the indoor unit in the medium speed state is greater than the air supply speed of the indoor unit in the low speed state; and

the temperature compensation value also comprises a wind speed compensation value, and any one of the air supply wind speeds has one corresponding wind speed compensation value ts.

Further, the correction degree of the mode compensation value corresponding to the wind avoiding mode to the ambient temperature is greater than that of the mode compensation value corresponding to the normal wind mode to the ambient temperature, and the correction degree of the mode compensation value corresponding to the normal wind mode to the ambient temperature is greater than that of the mode compensation value corresponding to the wind blowing mode to the ambient temperature; and

the correction degree of the air speed compensation value corresponding to each air supply speed to the environment temperature is inversely proportional to the size of each air supply speed.

Further, the temperature compensation value also comprises a calibration compensation value T; and is

The processor is further configured to obtain a calibration compensation value T according to the mode compensation value tm and the wind speed compensation value ts, and correct the ambient temperature according to the calibration compensation value T.

Further, the temperature compensation system further comprises:

a memory for storing the calibration compensation value T of the indoor unit in advance; wherein

Each calibration compensation value T has a set of the blowing mode and the blowing wind speed corresponding to the calibration compensation value T; and

the processor is also configured to retrieve the corresponding calibration compensation value T from the memory according to the current air supply mode and the air supply speed of the indoor unit.

Further, the calculation formula for obtaining the calibration compensation value T is T- α ts + β tm, wherein

α is the wind speed coefficient of the wind speed compensation value ts, and β is the mode coefficient of the mode compensation value tm.

Further, the wind speed coefficient α and the mode coefficient β satisfy the calculation formula of α + β ═ 1.

Further, the utility model also provides an air conditioner, its characterized in that includes aforementioned arbitrary temperature compensation system of air conditioner.

The utility model discloses a temperature compensation system's treater is through synthesizing the current air supply mode of air conditioner and air supply wind speed, confirms the temperature compensation value that is fit for the air conditioner current state, has improved the precision of temperature compensation effect.

Further, the utility model discloses a temperature compensation system carries out the weighted average to wind speed compensation value and mode compensation value in order to obtain final calibration compensation value T, can avoid calibration compensation value T to exceed the great value between mode compensation value tm and the wind speed compensation value ts, perhaps is less than the less value between mode compensation value tm and the wind speed compensation value ts, and then guarantees temperature compensation system's stability.

The above and other objects, advantages and features of the present invention will become more apparent to those skilled in the art from the following detailed description of specific embodiments thereof, taken in conjunction with the accompanying drawings.

Drawings

Some specific embodiments of the present invention will be described in detail hereinafter, by way of illustration and not by way of limitation, with reference to the accompanying drawings. The same reference numbers in the drawings identify the same or similar elements or components. Those skilled in the art will appreciate that the drawings are not necessarily drawn to scale. In the drawings:

fig. 1 is a schematic diagram of a temperature compensation system according to an embodiment of the present invention;

fig. 2 is a schematic view of an air supply state of an air conditioning indoor unit according to an embodiment of the present invention.

Detailed Description

Fig. 1 is a schematic and schematic diagram of a temperature compensation system 100 of an air conditioner 1 according to an embodiment of the present invention. As shown in fig. 1, in one embodiment of the present invention, the temperature compensation system 100 may include an acquisition module 110 and a processor 120. The obtaining module 110 is configured to obtain an ambient temperature of an environment where the indoor unit 10 of the air conditioner 1 is currently located and a current air supply state of the indoor unit 10. The blowing state may include a blowing mode and a blowing wind speed of the air conditioner 1. The processor 120 is connected to the obtaining module 110, and is configured to determine a temperature compensation value of the air conditioner 1 according to the air supply state, and correct the ambient temperature according to the temperature compensation value. Specifically, the processor 120 and the obtaining module 110 may be connected by wire or wirelessly for communication or data transmission, etc. The indoor unit 10 of the air conditioner 1 may be a cabinet unit or a wall-mounted unit installed indoors as a whole, or may be an indoor unit portion of the air conditioner 1 located indoors.

That is, the air conditioner 1 generally has different heat exchange effects in different air supply modes, and the difference of the heat exchange effects in different air supply modes can be further increased or decreased due to the difference of the air supply speeds. Therefore, the processor 120 of the temperature compensation system 100 in this embodiment determines a temperature compensation value suitable for the current state of the air conditioner 1 by integrating the current air supply mode and the air supply speed of the air conditioner 1, so as to improve the accuracy of the temperature compensation effect.

In some embodiments, the acquisition module 110 may include a variety of sensors. For example, the obtaining module 110 may obtain an ambient temperature of an environment through the temperature sensor 210, and obtain a current supply wind speed through the wind speed sensor 220. The temperature sensor 210 and the wind speed sensor 220 may be selectively arranged according to specific situations, which are not limited by the present disclosure.

In some embodiments, the acquisition module 110 further comprises a human detection module 130. The human detection module 130 is configured to detect a position parameter of a human body in an environment where the indoor unit 10 is located. The obtaining module 110 may be further configured to obtain a current air supply mode of the indoor unit 10 according to the position parameter. Specifically, the air supply mode may include at least one of a wind avoiding mode, a wind blowing mode, and a normal wind mode according to a difference in a position parameter of the human body.

Specifically, in the wind avoiding mode, the air supply direction of the indoor unit 10 is a direction avoiding the human body. That is, the human body is located at a position where the wind cannot reach. In the blowing mode, the air blowing direction of the indoor unit 10 is directed toward the human body. That is, the human body is located at a position where it can continuously feel the wind. In the normal wind mode, the air supply direction of the indoor unit 10 is a direction intermittently avoiding and facing the human body, and the indoor unit 10 supplies air uniformly to the current environment without a specific target. That is, the human body is located at a position where it can not continuously feel the wind.

Fig. 2 is a schematic diagram of an air supply state of the indoor unit 10 of the air conditioner 1 according to an embodiment of the present invention. To further illustrate, if the air blowing state of the indoor unit 10 at this time is as shown in fig. 2, the user moves in the area B in the wind avoiding mode. The indoor unit 10 in the wind avoiding mode supplies air to the area a to avoid the wind from blowing to the area B. If the indoor unit 10 in fig. 2 is operated in the blowing mode, the user moves in the area a and is always located in the blowing area. If the indoor unit 10 is operated in the normal wind mode, fig. 2 shows the blowing direction of the indoor unit 10 at a certain moment, and the indoor unit 10 will then supply air back and forth between the area a and the area B to uniformly change the temperature of the indoor environment C.

Further, the temperature compensation value includes a mode compensation value based on the blowing modes, and any blowing mode has one mode compensation value tm corresponding thereto. Specifically, the correction degree of the mode compensation value corresponding to the wind avoiding mode to the ambient temperature is greater than that of the mode compensation value corresponding to the normal wind mode, and the correction degree of the mode compensation value corresponding to the normal wind mode to the ambient temperature is greater than that of the mode compensation value corresponding to the wind blowing mode to the ambient temperature.

That is, the temperature compensation value should match the corrected ambient temperature with the ambient temperature actually felt by the user as much as possible to improve the comfort of the user. In the wind avoiding mode, the user does not directly feel the wind, and the ambient temperature change felt by the user is relatively smooth, so a mode compensation value with a relatively large correction effect needs to be set to eliminate the difference between the ambient temperature actually felt by the user and the ambient temperature acquired by the temperature sensor 210 as much as possible. Accordingly, in the blowing mode, the ambient temperature sensed by the user changes abruptly, and thus a mode compensation value having a relatively small correction effect needs to be set. In the normal wind mode, the ambient temperature of the entire indoor space changes at a uniform speed, and therefore a mode compensation value with a relatively moderate correction effect needs to be set. For example, in one particular embodiment, the mode compensation values for the wind evasion mode, the normal wind mode, and the blowing mode may be 6 ℃, 4 ℃, and 2 ℃, respectively.

In the present disclosure, the magnitude of the correction effect refers to the magnitude of the variation width of the ambient temperature before and after the correction, which may correspond to the magnitude of the absolute value of the mode compensation value. Since the temperature sensor 210 is generally disposed on the indoor unit 10, when the ambient temperature detected by the temperature sensor 210 reaches the set temperature, the ambient temperature of a user activity area relatively distant from the indoor unit 10 (here, the user activity area is distant from the indoor unit 10 than the temperature sensor 210) does not reach the set temperature. If the indoor unit 10 is still operating in the wind avoiding mode, the temperature of the environment where the user is located may deviate from the set temperature relatively greatly, and therefore, a mode compensation value with a large absolute value is required to correct the environment temperature. If the indoor unit 10 is operated in the blowing mode, the temperature of the environment where the user is located may deviate from the set temperature by a relatively small amount, and therefore, a mode compensation value with a small absolute value is required to correct the environment temperature. In addition, if the air conditioner 1 is in the cooling mode at this time, the mode compensation value is required to be a positive value to correct the ambient temperature to a higher temperature, so that the indoor unit 10 continues to operate in the current cooling mode. If the air conditioner 1 is in the heating mode at this time, the mode compensation value is required to be a negative value to correct the ambient temperature to a lower temperature, so that the indoor unit 10 continues to operate in the current cooling mode.

In some embodiments, the supply air velocity comprises at least one of a high velocity, a medium velocity, and a low velocity. The air supply speed of the indoor unit 10 in the high-speed state is greater than the air supply speed thereof in the medium-speed state, and the air supply speed of the indoor unit 10 in the medium-speed state is greater than the air supply speed thereof in the low-speed state.

Furthermore, the temperature compensation value also comprises a wind speed compensation value, and any wind speed of the supplied wind has a corresponding wind speed compensation value ts. The correction degree of the air speed compensation value corresponding to each air supply speed to the environment temperature is inversely proportional to the size of each air supply speed.

That is, when the air conditioner 1 supplies air at a high speed, since the lift of the heat exchange air is large and the heat exchange air supplied per unit time is also large during high-speed air supply, the indoor ambient temperature changes relatively quickly, and therefore, it is necessary to set an air speed compensation value having a relatively small correction effect. When the air conditioner 1 is blowing air at a low speed, since the lift of the heat exchange air is small and the heat exchange air is discharged in a unit time, the indoor environment temperature changes relatively slowly, and therefore, a wind speed compensation value having a relatively large correction effect needs to be set. When the air conditioner 1 supplies air at a medium speed, the air speed compensation value with a relatively moderate correction effect needs to be set because the lift of the heat exchange air during medium-speed air supply is moderate and the heat exchange air supplied in unit time is moderate, so the indoor environment temperature change is also relatively moderate. For example, in one specific embodiment, the wind speed compensation values for the high-speed wind, the medium-speed wind, and the low-speed wind may be 2 ℃, 4 ℃, and 6 ℃, respectively.

Similarly to the mode compensation value, the magnitude of the correction effect of the wind speed compensation value refers to the magnitude of the variation amplitude of the ambient temperature before and after the correction, which may correspond to the magnitude of the absolute value of the wind speed compensation value. If the air conditioner 1 is in the cooling mode, the wind speed compensation value is required to be a positive value to correct the ambient temperature to a higher temperature, so that the indoor unit 10 continues to operate in the current cooling mode. If the air conditioner 1 is in the heating mode, the wind speed compensation value is required to be a negative value, so as to modify the ambient temperature to a lower temperature, and thus the indoor unit 10 continues to operate in the current cooling mode.

In some embodiments, the temperature compensation value further comprises a calibration compensation value T. The processor 120 is further configured to obtain a calibration compensation value T based on the mode compensation value tm and the wind speed compensation value ts, and to correct the ambient temperature based on the calibration compensation value T. That is, the control system of the present disclosure may further improve the accuracy of the temperature compensation system 100 by integrating the influence of the air supply mode and the air supply speed on the ambient temperature of the location where the user is located.

Specifically, the calibration compensation value T is obtained by the formula T- α ts + β tm, where α is the wind speed coefficient of the wind speed compensation value ts and β is the mode coefficient of the mode compensation value tm.

Further, in some embodiments, the wind speed coefficient α and the mode coefficient β satisfy the calculation formula α + β equals 1, thereby avoiding the calibration compensation value T from exceeding the larger value between the mode compensation value tm and the wind speed compensation value ts or falling below the smaller value between the mode compensation value tm and the wind speed compensation value ts, and further ensuring the stability of the temperature compensation system 100.

The values of the wind speed coefficient α and the mode coefficient β can be set according to the specific type of the air conditioner.

In some embodiments, if the wind speed difference of the air conditioner has a more significant effect on both the total amount of heat exchange wind and the heat exchange rate per unit time, and the correction based on the wind speed compensation value has a greater effect on the accuracy of the ambient temperature actually sensed by the user, for the air conditioner in this embodiment, the weight of the wind speed compensation value ts may be set to be greater than that of the mode compensation value tm, that is, the wind speed coefficient α is greater than the mode coefficient β, in some embodiments, the wind speed coefficient α may range from 0.6 to 0.8, the mode coefficient β may range from 0.2 to 0.4, in some more specific embodiments, the wind speed coefficient α may range from 0.7, and the mode coefficient β may range from 0.3, and at this time, the calculation formula for obtaining the calibration compensation value T is T ═ 0.7 × ts +0.3 × tm.

In other embodiments, if the difference of the air supply modes of the air conditioner has a more significant effect on the ambient temperature of the local area where the user is located, and the correction based on the mode compensation value has a greater effect on the accuracy of the ambient temperature actually sensed by the user, for the air conditioner in this embodiment, in the process of obtaining the calibration compensation value T, the weight occupied by the wind speed compensation value ts may be set to be smaller than that occupied by the mode compensation value tm, that is, the wind speed coefficient α is smaller than the mode coefficient β.

In other embodiments, if the air conditioner has substantially the same effect on the ambient temperature of the local area where the user is located due to the difference in the air supply mode and the difference in the wind speed, then for the air conditioner in this embodiment, the wind speed compensation value ts may be weighted equal to the mode compensation value tm during the process of obtaining the calibration compensation value T, i.e., the wind speed coefficient α is equal to the mode coefficient β, and the wind speed coefficient α and the mode coefficient β may both be set to 0.5.

In some embodiments, the temperature compensation system 100 further includes a memory 140. The memory 140 is used to store the calibration offset value T of the internal unit 10 in advance. Each calibrated offset value T has a set of supply air modes and supply air speeds corresponding thereto. Further, the processor 120 is configured to retrieve the corresponding calibration compensation value T from the memory 140 according to the current supply mode and the supply air speed of the indoor unit 10. Therefore, when the indoor unit 10 changes the blowing mode and/or the blowing wind speed, the processor 120 can acquire the calibration compensation value T by merely retrieving the corresponding data without performing a calculation operation, thereby reducing the functional requirements on the processor 120.

In a specific embodiment, when the temperature compensation system 100 adopts the calculation formula T of 0.7 × ts +0.3 × tm in the foregoing specific embodiment, the mode compensation values corresponding to the wind avoiding mode, the normal wind mode, and the blowing mode are 6 ℃, 4 ℃, and 2 ℃ respectively, and the wind speed compensation values corresponding to the high-speed wind supply, the medium-speed wind supply, and the low-speed wind supply are 2 ℃, 4 ℃, and 6 ℃ respectively, the calibration compensation value T and the wind speed of the wind supply mode and the wind speed of the wind supply corresponding thereto may be as shown in table 1.

TABLE 1

	Wind sheltering human	Normal wind	Wind blowing man
				High speed air supply	3.2	2.6	2
Medium speed air supply	4.6	4	3.4
				Low speed air supply	6	5.4	4.8

Continuing with the example, when the air conditioner 1 is blowing air at a high speed in the wind avoiding mode, the mode compensation value tm is 6 ℃ and the wind speed compensation value ts is 2 ℃. In this case, the calibration offset value T is 0.7 × 2 ℃ +0.3 × 6 ℃, i.e., 3.2 ℃. When the air conditioner 1 supplies air at a low speed in the normal wind mode, the mode compensation value tm is 4 deg.c and the wind speed compensation value ts is 6 deg.c. In this case, the calibration offset value T is 0.7 × 6 ℃ +0.3 × 4 ℃, i.e., 5.4 ℃. When the air conditioner 1 supplies air at a medium speed in the blowing mode, the mode compensation value tm is 2 deg.c and the wind speed compensation value ts is 4 deg.c. In this case, the calibration offset value T is 0.7 × 4 ℃ +0.3 × 2 ℃, i.e., 3.4 ℃.

The utility model also provides an air conditioner 1, air conditioner 1 include indoor set part and off-premises station part to and the temperature compensation system 100 in the aforesaid arbitrary embodiment. In this embodiment, the air conditioner 1 can determine a temperature compensation value suitable for the current state of the air conditioner 1 by integrating the current air supply mode and the air supply speed of the air conditioner 1 through the processor 120 of the temperature compensation system 100, so as to improve the accuracy of the temperature compensation effect.

Thus, it should be appreciated by those skilled in the art that while a number of exemplary embodiments of the invention have been shown and described in detail herein, many other variations and modifications can be made, consistent with the principles of the invention, which are directly determined or derived from the disclosure herein, without departing from the spirit and scope of the invention. Accordingly, the scope of the present invention should be understood and interpreted to cover all such other variations or modifications.

Claims (10)

1. A temperature compensation system of an air conditioner, characterized by comprising:

the acquisition module is configured to acquire the ambient temperature of the current environment of the indoor unit of the air conditioner and the current air supply state of the indoor unit;

the processor is connected with the acquisition module and is configured to determine a temperature compensation value of the air conditioner according to the air supply state and correct the ambient temperature according to the temperature compensation value; wherein the content of the first and second substances,

the air supply state comprises an air supply mode and an air supply speed of the air conditioner.

2. The temperature compensation system of an air conditioner according to claim 1,

the air supply mode comprises at least one of an air people avoiding mode, an air people blowing mode and a normal air mode, wherein in the air people avoiding mode, the air supply direction of the indoor unit is the direction avoiding the human body, in the air people blowing mode, the air supply direction of the indoor unit is the direction directly facing the human body, and in the normal air mode, the air supply direction of the indoor unit is the direction avoiding and facing the human body intermittently; and

the temperature compensation value includes a mode compensation value, and any one of the blowing modes has one of the mode compensation values tm corresponding thereto.

3. The temperature compensation system of an air conditioner according to claim 2, further comprising:

the human detection module is configured to detect position parameters of a human body in the environment where the indoor unit is located;

the obtaining module is further configured to obtain the current air supply mode of the indoor unit according to the position parameter.

4. The temperature compensation system of an air conditioner according to claim 2,

the air supply speed comprises at least one of a high speed, a medium speed and a low speed, wherein the air supply speed of the indoor unit in the high speed state is greater than the air supply speed of the indoor unit in the medium speed state, and the air supply speed of the indoor unit in the medium speed state is greater than the air supply speed of the indoor unit in the low speed state; and

the temperature compensation value also comprises a wind speed compensation value, and any one of the air supply wind speeds has one corresponding wind speed compensation value ts.

5. The temperature compensation system of an air conditioner according to claim 4,

the correction degree of the mode compensation value corresponding to the wind avoiding mode to the environment temperature is greater than that of the mode compensation value corresponding to the normal wind mode to the environment temperature, and the correction degree of the mode compensation value corresponding to the normal wind mode to the environment temperature is greater than that of the mode compensation value corresponding to the wind blowing mode to the environment temperature; and

the correction degree of the air speed compensation value corresponding to each air supply speed to the environment temperature is inversely proportional to the size of each air supply speed.

6. The temperature compensation system of an air conditioner according to claim 4,

the temperature compensation value further comprises a calibration compensation value T; and is

The processor is further configured to obtain a calibration compensation value T according to the mode compensation value tm and the wind speed compensation value ts, and correct the ambient temperature according to the calibration compensation value T.

7. The temperature compensation system of an air conditioner according to claim 6, further comprising:

a memory for storing the calibration compensation value T of the indoor unit in advance; wherein

Each calibration compensation value T has a set of the blowing mode and the blowing wind speed corresponding to the calibration compensation value T; and

the processor is also configured to retrieve the corresponding calibration compensation value T from the memory according to the current air supply mode and the air supply speed of the indoor unit.

8. The temperature compensation system of an air conditioner according to claim 6,

the calculation formula for obtaining the calibration compensation value T is that T is α ts + β tm, wherein

α is the wind speed coefficient of the wind speed compensation value ts, and β is the mode coefficient of the mode compensation value tm.

9. The temperature compensation system of an air conditioner according to claim 8,

the wind speed coefficient α and the mode coefficient β satisfy the calculation formula of α + β being 1.

10. An air conditioner characterized by comprising the temperature compensation system of the air conditioner of any one of claims 1 to 9.

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