ES2573466T3 - Air conditioner and method to control it - Google Patents

Abstract

An air conditioner comprising: an inlet unit (20) that receives an inlet cooling or heating temperature for an interior space; an air conditioning unit (10) that generates a cold wind that has the inlet cooling temperature or a hot wind that has the inlet heating temperature; a wind direction adjustment unit (30) that adjusts a cold or hot wind direction generated by the air conditioning unit (10); a location detection unit (40) that detects a user located in one of a plurality of air conditioning sections defined by dividing the interior space; and a control unit (50) that controls the wind direction adjustment unit (30) so that the cold or hot wind is generated as a direct or indirect wind depending on whether the user leaves any of the conditioning sections of air, which is determined by a user location detected by the location detection unit (40) and characterized in that the control unit (50) controls the wind direction adjustment unit (30) so that the wind cold that has the inlet cooling temperature or the hot wind that has the inlet heating temperature is generated as an indirect wind when it is determined that the user does not leave any of the air conditioning sections and the control unit controls the wind direction adjustment unit (30) such that the cold wind having a corrected cooling temperature or the hot wind having a heating temperature Corrected entity is generated as indirect wind when the user does not leave any of the air conditioning sections for a preset detection time or more.

Description

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DESCRIPTION

Air conditioner and method to control the same technical field

The present description relates to an air conditioner and, more particularly, to an air conditioner and a method for controlling the air conditioner.

Background of the technique

An air conditioner is an appliance that cools or heats an interior space. The air conditioner includes a compressor, an expansion device, an internal heat exchanger and an external heat exchanger that constitute a heat exchange cycle. The interior space is cooled or heated by the exchange of heat between a refrigerant and the indoor or outdoor air that passes through the indoor or outdoor heat exchangers.

With reference to Figure 1, an indoor heat exchanger for air conditioning of an indoor space is provided in an indoor unit 1. The indoor unit 1 is provided with an air inlet 2 to introduce indoor air and an outlet of air 3 to discharge the air introduced through the air inlet 2 and exchange heat with the internal heat exchanger. An input unit 4 for receiving manipulation signals for the indoor air conditioning is provided in the indoor unit 1. In addition, the air outlet 3 is provided with vertical and horizontal adjustment units to adjust a discharge direction of the air discharged into the interior space.

Meanwhile, the components for indoor air conditioning, such as a compressor and an outdoor heat exchanger, are provided in the outdoor unit 7.

EP-A-1985936 describes an air conditioner and a control method thereof.

Description of the Invention Solution to the problem

The embodiments provide an air conditioner and a method for controlling the air conditioner, which can economically control air in an interior space according to a user's location.

An air conditioner may include: an input unit that receives an input air conditioning temperature for an indoor space; an air conditioning unit that generates a hot or cold wind that has the inlet air conditioning temperature; and a location detection unit to detect a user location in the interior space, where a direction or temperature of the cold or hot wind generated by the air conditioning unit is adjusted according to whether a user is detected in the interior space and the user location by the location detection unit.

In one embodiment, an air conditioner as defined by independent claim 1 includes: an inlet unit that receives an inlet cooling or heating temperature for an interior space; an air conditioning unit that generates a cold wind that has the inlet cooling temperature or a hot wind that has the inlet heating temperature; a wind direction adjustment unit that adjusts a cold or hot wind direction generated by the air conditioning unit; a location detection unit that detects a user located in one of a plurality of air conditioning sections defined by dividing the interior space; and a control unit that controls the wind direction adjustment unit so that the cold or hot wind is generated as a direct or indirect wind and corrects the inlet cooling and heating temperatures according to whether the user leaves one of the air conditioning sections, which is determined by the user location detected by the location detection unit and a time during which the user leaves one of the air conditioning sections.

In another embodiment, a method of controlling an air conditioner is defined by independent claim 6, which comprises an air conditioning unit that generates a hot or cold wind having an inlet air conditioning temperature for an interior space; a wind direction adjustment unit to adjust a cold or hot wind direction generated by the air conditioning unit, a location detection unit for detecting a user location in the interior space and a control unit is provided that controls the air conditioning unit, the method that includes: determining whether the location detection unit detects the user in the interior space; allow the control unit to determine if the user leaves the interior space according to whether the user is detected in the indoor unit by the location detection unit; and allow the control unit to control the air conditioning unit and the wind direction adjustment unit so that a cold or hot wind direction is adjusted according to whether the user leaves the interior space.

Advantageous Effects of the Invention

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According to the embodiments, the interior space can be air conditioned more pleasantly.

Brief description of the drawings

Figure 1 is a view of a typical air conditioner.

Figure 2 is a block diagram of an air conditioner according to an embodiment. Figure 3 is a view illustrating air conditioning sections according to an embodiment.

Figure 4 is a flow chart illustrating an air conditioning process by an air conditioner control method of one embodiment.

Best way to carry out the Invention

The details of one or more embodiments are set forth in the accompanying drawings and the description below. Other features will be apparent from the description and drawings and from the claims.

Reference will now be made in detail to the embodiments of the present description, examples of which are illustrated in the accompanying drawings.

Figure 2 is a block diagram of an air conditioner according to one embodiment and Figure 3 is a view illustrating air conditioning sections according to one embodiment.

With reference first to Figure 2, an air conditioner includes an air conditioning unit 10, an input unit 20, a wind direction adjustment unit 30, a localization detection unit 40 and a control unit 50 The air conditioning unit works to control indoor air. The input unit 20 receives manipulation signals from the air conditioning unit 10 and the wind direction adjustment unit 30 adjusts the directions of cold winds and hot winds generated from the air conditioning unit 10. The detection unit Location 40 detects a location of a user (that is, an apprentice) located in the interior space. In addition, the control unit 50 controls the air conditioning unit 10 and the wind adjustment unit 30 according to the signals introduced to the input unit 20 and the location of the apprentice detected by the location detection unit 40.

In more detail, the air conditioning unit 10 includes a variety of components for controlling indoor air, that is, generating hot and cold winds. That is, the air conditioning unit 10 includes components that constitute a heat exchange cycle, such as a compressor, a condenser, an expansion unit and an evaporation unit. The air conditioning unit 10 includes an indoor unit and an outdoor unit, which can be provided separately or integrated with each other.

The input unit 20 receives a manipulation signal to set the cooling and heating temperatures and a manipulation signal for a quantity of hot and cold winds. Particularly, the inlet unit 20 receives inlet air conditioning temperatures such as an inlet cooling temperature and an inlet heating temperature.

The wind direction adjustment unit 30 includes a vertical adjustment unit 31 and a horizontal adjustment unit 33. The vertical adjustment unit 31 adjusts a vertical direction of the hot and cold winds generated from the air conditioning unit 10. In addition, the horizontal adjustment unit 33 adjusts a horizontal direction of the hot and cold winds. For example, streaks can be used as the vertical adjustment unit 31 and the slats can be used as the horizontal adjustment unit 33.

The location detection unit 40 can be installed, for example, on one side of the air conditioning unit 10. Therefore, when the air conditioning unit 10 includes the indoor and outdoor units, the location detection unit 40 can be installed in the indoor unit. It goes without saying that the location detection unit 40 can be installed in locations other than the air conditioning unit 10. An infrared sensor can be used as the location detection unit 40.

In this embodiment, the location detection unit 40 determines if the user is located in one of the air conditioning sections Z1 to Z9 that are defined by dividing the interior space according to a distance from the air conditioning unit 10 and an angle with respect to the air conditioning unit 10. With reference to Figure 3, the air conditioning sections Z1 to Z9 are defined by dividing the interior space along a plurality of imaginary latitude lines that are separated from each other. by predetermined radii from a center of the air conditioning unit 10 and extending in a circular direction and longitudinal lines extending in a radial direction and separated from each other by predetermined central angles with respect to the center of the conditioning unit of air 10. In Figure 3, the interior space is divided into nine air conditioning sections Z1 to Z9. However, the present invention is not limited to this.

Meanwhile, the control unit 50 controls so that the air conditioning unit 10 cools or heats the interior space in response to the input cooling and heating temperatures introduced

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to the input unit 20. Especially, the control unit 50 determines if the user leaves the interior space, that is, from one of the air conditioning sections Z1 to Z9 according to the user location detected by the detection unit of location 40. The control unit 50 adjusts the trio and hot winds as direct and indirect winds according to whether the user leaves one of the air conditioning sections Z1 to Z9. In addition, the control unit 50 corrects the inlet and heating temperatures of the inlet when the user leaves one of the air conditioning sections Z1 to z9 for a predetermined time or more.

That is, when it is determined that the user leaves the interior space, the control unit 50 controls the wind direction adjustment unit 30 so that the direct wind having the inlet temperature or inlet heating can be directed directly to one of the air conditioning sections Z1 to Z9 where the user is detected by the location detection unit 40. However, when it is determined that the user does not leave the interior space, the control unit 40 controls the adjustment unit of wind direction 30 so that the indirect wind having the inlet temperature and inlet heating can indirectly be directed towards at least three of the air conditioning sections Z1 to Z9.

In addition, when it is detected that the user leaves one of the air conditioning sections Z1 to Z9 for a predetermined time or more, the control unit 50 corrects the inletting and inlet heating temperatures to pre-set inletting and heating temperatures. In addition, the control unit 50 controls the wind direction adjustment unit 30 so that the hot wind having the corrected heating temperature or the three-way wind having the corrected inletting temperature is directed towards at least three of the sections of air conditioning Z1 to Z9 as indirect wind. At this point, the corrected inletting temperature is pulled to be greater than the inlet inlet temperature at 2 ° C and the corrected heating temperature is pulled to be less than the inlet heating temperature in 2 ° C.

The following will describe a method for controlling the air conditioner according to an embodiment in more detail.

Figure 4 is a flow chart illustrating an air conditioning process by an air conditioner control method of one embodiment. Figure 4 illustrates a case of intruder mode. However, the present invention can be applied identically to a case of heating mode.

With reference to Figure 4, the input inlet temperature is first introduced to the input unit 20 (S11). It goes without saying that other manipulation signals can also be introduced to the input unit 20 such as a wind volume.

The air conditioning unit 10 begins the air conditioning with the input inlet temperature introduced to the input unit 20 (S13). That is, the air conditioning unit 10 generates a three-way wind that has the inlet cooling temperature and sends the three-way wind to the interior space.

Next, the location detection unit 40 detects if the user is located in the interior space (S15). In more detail, the location detection unit 40 detects if the user leaves one of the air conditioning sections Z1 to Z9.

Meanwhile, the control unit 50 determines whether or not the user leaves one of the sections of

air conditioning Z1 to Z9 according to the user location detected by the detection unit of

location 40 (S17). The control unit controls the trio wind generated by the air conditioning unit 10 as direct or indirect wind according to the existence of the user in one of the sections of

air conditioning Z1 to Z9 or corrects the inlet tempering temperature to the temperature of

preset corrected training.

In more detail, when it is determined that the user leaves one of the air conditioning sections Z1 to Z9, the control unit 50 controls the wind direction adjustment unit 30 so that the trio wind having the temperature of input and generated inlet from the air conditioning unit 10 is directed directly to one of the air conditioning sections Z1 to Z9 where the user leaves (S19). Therefore, the user leaving one of the air conditioning sections Z1 to Z9 may feel more comfortable.

Next, the control unit 50 determines if the air conditioning is tinalized (S21). It can be determined if the air conditioning is tinalized according to the tinalization of the air conditioning time that is thrown by a handling signal introduced to the input unit 20 or if a handling signal is put by the user to finalize the air conditioning air. When it is determined that the air conditioning is not finished, step 15 and following are performed.

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Meanwhile, when it is determined in Step 17 that the user does not leave one of the air conditioning sections Z1 to Z9, the control unit 50 controls the wind direction adjustment unit 30 so that the wind chills that it has the inlet cooling temperature and generated by the air conditioning unit 10 is formed in the indirect wind that is directed towards at least three of the air conditioning sections Z1 to Z9 (S23). At this point, the control unit 50 can control the wind direction adjustment unit 30 so that the indirect wind is directed substantially to all air conditioning sections Z1 to Z9.

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Furthermore, in the state where the cooling mode is performed by indirect wind 'in Step 23, the localization detection unit 40 detects the user localization (S25). In addition, the control unit 50 determines whether the user leaves the interior space according to the user location detected by the location detection unit 40 S27.

When it is determined that the user leaves the interior space, the control unit 50, Step 19 and the following steps are performed. However, when it is determined that the user does not leave the interior space, the control unit determines whether a predetermined detection time has elapsed (S29). When it is determined that the predetermined detection time has elapsed, the control unit 50 corrects the inlet cooling temperature to the predetermined corrected cooling temperature and controls the wind direction adjustment unit 30 so that the conditioning sections of air Z1 to Z9 are cooled according to the predetermined corrected cooling temperature (S31). However, when it is determined that the predetermined detection time has not elapsed, Step 23 and the following steps are performed.

Although the embodiments have been described with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that fall within the scope of the appended claims. More particularly, various variations and modifications are possible in the component parts and / or dispositions of the object combination arrangement within the scope of the description, the drawings and the appended claims. In addition to the variations and modifications in the component parts and / or arrangements, alternative uses for those skilled in the art will also be apparent.

Industrial applicability

According to the air conditioner described above and the method of controlling the same of the claims, the following effects can be expected.

The hot and cold winds generated by the air conditioning unit are formed in direct or indirect wind according to whether the user leaves the interior space. Therefore, user comfort can be improved. In addition, the inlet cooling and heating temperature is corrected when it is detected that the user does not leave the interior space for a predetermined time. Therefore, when the user does not leave the interior space, the cooling or heating load can be substantially reduced and thus cooling or heating can be performed more economically.

Claims (9)

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An air conditioner comprising: an input unit (20) that receives an input cooling or heating temperature for an interior space; an air conditioning unit (10) that generates a cold wind that has the inlet cooling temperature or a hot wind that has the inlet heating temperature; a wind direction adjustment unit (30) that adjusts a cold or hot wind direction generated by the air conditioning unit (10); a location detection unit (40) that detects a user located in one of a plurality of air conditioning sections defined by dividing the interior space; Y a control unit (50) that controls the wind direction adjustment unit (30) so that the cold or hot wind is generated as a direct or indirect wind according to whether the user leaves any of the air conditioning sections , which is determined by a user location detected by the location detection unit (40) and characterized in that the control unit (50) controls the wind direction adjustment unit (30) so that the cold wind having the inlet cooling temperature or the hot wind having the inlet heating temperature are generated as an indirect wind when it is determined that the user does not leave any of the air conditioning sections and The control unit controls the wind direction adjustment unit (30) so that the cold wind having a corrected cooling temperature or the hot wind having a corrected heating temperature is generated as the indirect wind when the user does not leaves any of the air conditioning sections for a preset detection time or more. 2. The air conditioner according to claim 1, characterized in that the air conditioning sections are defined according to a distance and an angle with reference to the air conditioning unit (10). 3. The air conditioner according to claim 1 or 2, characterized in that the air conditioning sections are defined by dividing the interior space along a plurality of imaginary latitude lines that are separated from each other by predetermined radii from a center of the air conditioning unit (10) and extend in a circular direction and longitudinal lines that extend in a radial direction and separated from each other by predetermined central angles with respect to the center of the air conditioning unit (10 ). 4. The air conditioner according to any one of claims 1 to 3, characterized in that the corrected cooling temperature is greater than the inlet cooling temperature at a temperature that is greater than or equal to 1 ° C and less than 5 ° C ; Y The corrected heating temperature is less than the inlet heating temperature at a temperature that is greater than or equal to 1 ° C and less than 5 ° C. 5. The air conditioner according to any of the preceding claims, characterized in that the predetermined detection time is 10-30 minutes. 6. A method of controlling an air conditioner comprising an air conditioning unit (10) that generates a hot or cold wind having an inlet air conditioning temperature for an interior space; a wind direction adjustment unit (30) to adjust a cold or hot wind direction generated by the air conditioning unit (10), a location detection unit (40) to detect a user location in space interior and a control unit (50) that controls the air conditioning unit, characterized in that the method comprises: determine if the location detection unit (40) detects the user in the interior space; allow the control unit (50) to determine if the user leaves the interior space according to whether the user in the interior space by the location detection unit (40); Y allow the control unit (50) to control the air conditioning unit (10) and the wind direction adjustment unit (30) so that a cold or hot wind direction is adjusted according to whether the user leaves the space interior and characterized in that the cold or hot wind is generated as a direct wind that has the inlet air conditioning temperature when it is determined that the user leaves one of the air conditioning unit and the hot or cold wind is generated as a Indirect wind that has the inlet air conditioning temperature when it is determined that the user does not leave any of the air conditioning sections and The cold or hot wind that has a corrected air conditioning temperature is generated as the indirect wind when the user does not leave any of the air conditioning sections during a time of preset detection or more, in a state where cold or hot wind is generated as the indirect wind that has the inlet air conditioning temperature. 7. The method according to claim 6, characterized in that the location detection unit determines if the user is located in one of the air conditioning sections defined by dividing the space inside. The method according to claims 6 or 7, characterized in that the corrected air conditioning temperature of the cold wind is greater than the inlet air conditioning temperature and the temperature of 10 corrected air conditioning of the hot wind is lower than the inlet air conditioning temperature. 9. The method according to any of the preceding claims, characterized in that the temperature of the corrected air conditioning of the cold wind is greater than the air conditioning temperature of 15 input at 2 ° C and the corrected air conditioning temperature of the hot wind is lower than the input conditioning temperature at 2 ° C.