ES2319479B1 - AIR CONDITIONER. - Google Patents

Abstract

Air conditioner that expels air evenly, with finished heat exchange, to a space interior and maximum capacity. It includes main body that includes two suction holes formed in the upper parts and bottom of it; a heat exchanger installed in the main body to exchange heat with air drawn through of the first and second suction holes; and a diaphragm that divide the inside of the main body into two zones: upper e lower, to separate the flow of the sucked air through the two suction holes. The diaphragm satisfies the expression Relational S1 greater than or equal to S2. S1 represents an area in which the air sucked through the first suction hole, and S2 represents an area in which the air drawn through the second suction hole exchanges heat in both cases with the heat exchanger.

Description

Air conditioner.

       \ global \ parskip0.900000 \ baselineskip
    

Reference to related request

This request claims the benefit of the Korean patent application No. 2006-0000706, deposited on January 3, 2006 at the Property Office Korea Intellectual, whose description is incorporated in the Present document for reference.

Background of the invention 1. Field of the invention

The present invention relates to a air conditioner with a plurality of fans air injection and a plurality of discharge holes, and more specifically, to an air conditioner that expels evenly the air, with heat exchange finished, at a interior space and presents maximum capacity even when the vertical distribution of heat in the interior space is not uniform.

2. Description of the related technique

The Japanese patent open for consultation by the Public No. 2003-156232 describes a conditioner of air with a plurality of air injection fans and a plurality of discharge holes.

This air conditioner comprises holes suction formed on the front and top surfaces of the main body and a first and second discharge hole formed on the lower surface of the main body. It forms a first air channel and a second air channel in the body main, and a first heat exchanger and a second heat exchanger respectively in the first channel of air and in the second air channel. A first one is installed air injection fan and a second fan air injection respectively in the first air channel and in The second air channel. Then, fans of cross flow as a first and second injection fan air.

In the air conditioner, air is discharged, that exchanges heat with the first heat exchanger by operating the first injection fan of air, air is discharged into the first discharge hole, which exchange heat with the second heat exchanger by the operation of the second air injection fan, in The second discharge hole.

Since the suction holes are located on the front and upper body surfaces main and first and second discharge hole are located on the lower surface of the main body, the expulsion of discharged air into the area in front of the Air conditioner is limited. In addition, since it concentrates a stream of air in the lower area of the interior space, When the air conditioner runs continuously, the vertical temperature distribution in the interior space is not uniform. That is, there is a temperature difference between the lower part of the interior space under the conditioner of air, in which the discharged air is concentrated, and the upper zone of the interior space of the air conditioner, which does not reach Directly discharged air. This difference deteriorates the pleasant atmosphere of the interior space, and reduces an efficiency of heating / cooling of the air conditioner.

Summary of the Invention

Therefore, one aspect of the invention is provide an air conditioner, which ejects evenly air discharged throughout the area of an interior space.

Another aspect of the present invention is provide an air conditioner, which presents the maximum capacity even when the vertical distribution of heat in the Interior space is not uniform.

According to one aspect, the present invention provides an air conditioner comprising a body main comprising a first suction hole and a second suction hole formed respectively in the upper and lower parts thereof; a heat exchanger installed in the main body to exchange heat with air aspirated through the first and second suction holes; and a diaphragm that divides the inside of the main body into a upper zone and lower zone to separate air flow sucked through the first suction hole and the flow of air drawn through the second suction hole in the that the diaphragm satisfies the following relational expression,

S1 \ geq S2,

in which S1 represents an area in that the air sucked through the first suction hole exchange heat with the heat exchanger, and S2 represents an area in which the air sucked through the second orifice of suction exchanges heat with the heat exchanger hot.

Preferably, the diaphragm is installed in position that satisfies the following relational expression,

1.0? S1 / S2 \ leq 2.3.

The first suction hole may be formed at the top of a rear surface of the main body, and the second suction hole can be formed at the bottom of the back surface of the body principal.

The main body can also comprise a first discharge hole formed on the top of a front surface of the main body, and a second hole of discharge formed at the bottom of the front surface of the main body; and the air conditioner can also comprise a first installed air injection fan above the diaphragm to expel air into the first hole of  discharge, and a second air injection fan installed under the diaphragm to expel air into the second hole Download

The air conditioner can also understand a first guide and a first stabilizer to guide the  air expelled by the first air injection fan at first discharge hole; and a second guide and a second stabilizer to guide the air expelled by the second air injection fan to the second hole of discharge.

Preferably, the angles of inclination descending from the first guide and the first stabilizer are respectively smaller than the angles of inclination descending from the second guide and the second stabilizer.

According to another aspect, the present invention provides an air conditioner comprising: a body main comprising a first suction hole and a second suction hole formed respectively in the upper and lower parts thereof; a heat exchanger installed in the main body to exchange heat with air aspirated through the first and second suction holes; and a diaphragm that divides the inside of the main body into a upper zone and lower zone to separate air flow sucked through the first suction hole and the flow of air drawn through the second suction hole in the that the diaphragm is rotatably installed in the body principal so that the relationship between Yes can vary, which represents an area in which the air that passes through the first suction hole exchanges heat with the heat exchanger heat and S2, which represents an area in which the air that passes to through the second suction hole it exchanges heat with the heat exchanger.

One end of the diaphragm may be located at a front internal surface of the main body and the other diaphragm end may be located near the exchanger of heat so that the ratio can vary by rotating the diaphragm, which centers around the end located in the front internal surface of the main body.

The air conditioner can also comprise a first temperature sensor installed around the first suction hole to measure air temperature sucked into the first suction hole; and a second sensor of temperature installed around the second hole of suction to measure the temperature of the air sucked into the second suction hole.

The angle of rotation of the diaphragm can determined in proportion to a difference between the temperature of the air measured by the first temperature sensor and the air temperature measured by the second sensor temperature.

According to another aspect, the present invention provides an air conditioner comprising: a body main comprising a first suction hole and a second suction hole formed respectively in the upper and lower parts thereof; a diaphragm that divides the interior of the main body in an upper zone and a zone lower; a first heat exchanger installed in the area upper to exchange heat with air sucked in the first suction hole; and a second heat exchanger installed in the lower area to exchange heat with air aspirated through the second suction hole, in which the diaphragm satisfies the following relational expression,

S1 \ geq S2,

in which S1 represents an area in that the air sucked through the first suction hole exchange heat with the heat exchanger, and S2 represents an area in which the air sucked through the second orifice of suction exchanges heat with the heat exchanger hot.

Brief description of the drawings

These and / or other aspects and advantages of the invention will come off and be appreciated more quickly from of the following description of the embodiments, taken together with the accompanying drawings in which:

Fig. 1 is a perspective view that illustrates the back of an air conditioner according to the present invention;

       \ global \ parskip1.000000 \ baselineskip
    

Fig. 2 is a longitudinal section view of an air conditioner according to a first form of embodiment of the present invention;

Fig. 3 is a graph to compare air conditioner capabilities with the condition that it modify a ratio of heat exchange areas (S1: S2);

Fig. 4 is a longitudinal section view of an air conditioner according to a second form of embodiment of the present invention; Y

Fig. 5 is a longitudinal section view of an air conditioner according to a third form of embodiment of the present invention.

Detailed description of the embodiments preferred

Reference will now be made in detail to the form of embodiment of the present invention, of which a example in the accompanying drawings, in which the same reference numbers always refer to the same elements. TO the embodiment is described below to explain the present invention with reference to the attached drawings.

Fig. 1 is a perspective view that illustrates the back of an air conditioner according to the present invention, and Fig. 2 is a sectional view length of an air conditioner according to a first form of embodiment of the present invention.

As shown in Figs. 1 and 2, the air conditioner according to the first embodiment of the present invention comprises a main body 10 with a first suction hole 13 and a second suction hole 14 formed in it to aspirate indoor air, an exchanger of heat 20 installed in the main body 10 to exchange heat with air sucked through the first and second holes suction 13 and 14, air injection fans 31 and 32 arranged in front of heat exchanger 20, and a diaphragm 50 that divides the interior of the main body 10 into an area upper and lower area to separate the flow of aspirated air through the first suction hole 13 and the air flow aspirated through the second suction hole 14.

The first suction hole 13 is formed at the top of a rear surface 11 of the body main 10, and the second suction hole 14 is formed at the bottom of the rear surface 11 of the body main 10. A first discharge hole 15 and a second discharge hole 16 to discharge the air, with exchange of heat finished, in the interior space are formed in the parts upper and lower of a front surface 12 of the body main 10. Preferably, the top and bottom of the rear surface 11 of the main body 10, in which the first suction hole 13 and the second are formed suction hole 14, are inclined. In this case, when the main body 10 of the air conditioner is fixed to a wall of a structure, the first suction hole 13 and the second suction hole 14 are separated from the wall by a designated distance so that air can be aspirated without problems in the first suction hole 13 and the second suction hole 14.

The heat exchanger 20 is located in the  back of the inside of the main body 10 and is divided into a first heat exchange part 21, which exchange heat with the air sucked through the first hole suction 13, and a second heat exchange part 22, that exchanges heat with the air sucked through the second suction hole 14, by diaphragm 50.

The first air injection fan 31 and the second air injection fan 32 are arranged respectively above and below diaphragm 50. The first air injection fan 31 sucks air from the first hole suction 13 and expels the air into the first hole of discharge 15, and the second air injection fan 32 sucks air from the second suction hole 14 and expels the air towards the second discharge hole 16. The flow fans Conventional crusaders are like the first and second fans of air injection 31 and 32. The first and the second fan of air injection 31 and 32 work respectively with engines drive (not shown), which are installed separately. Therefore, a controller (not shown) of the air conditioner controls the drive motors for operate the first and second injection fans of air 31 and 32, thus allowing the first and second air injection fan 31 and 32 operate simultaneously or selectively

In the main body 10 a first guide 41 and a first stabilizer 42 to guide the air ejected by the first air injection fan 31 at first discharge hole 15, and a second guide 43 and a second stabilizer 44 to guide the air expelled by the second air injection fan 32 to the second discharge hole 16.

The first guide 41 extends from the end top of the first discharge hole 15 towards the top of the first air injection fan 31, and surrounds the part upper of the first air injection fan 31. The first stabilizer 42 extends from the lower end of the first discharge hole 15 to near the first fan of air injection 31. In the same way, the second guide 43 is extends from the upper end of the second discharge hole 16 towards the top of the second injection fan of air 32, and surrounds the upper part of the second fan of air injection 32. The second stabilizer 44 extends from the lower end of the second discharge hole 16 until close of the second air injection fan 32.

The angle of downward inclination (α1) of the first guide 41 is less than the angle of downward inclination (α2) of the second guide 43, and the angle of downward inclination (β1) of the first stabilizer 42 is smaller than the tilt angle (? 2) of the second stabilizer 44. The reason is that the air expelled through the first discharge orifice 15 is discharge in a remote area and the air expelled through the second discharge hole 16 is discharged in a nearby area.

From now on, it will be briefly described the operation of the previous air conditioner.

When the first air injection fan 31 and the second air injection fan 32 are in operation, indoor air is sucked above the air conditioner in the first suction hole 13 and it sucks indoor air located under the air conditioner in the second suction hole 14. The indoor air sucked selectively passes through the first exchange part of heat 21 and the second exchange part 22 of the heat exchanger heat 20, and is discharged into the interior space through the first and from the second discharge port 15 and 16. Then, the air discharged from the first discharge hole 15 reaches a further zone far away than the air discharged from the second discharge hole 16. Accordingly, the air conditioner of the present invention evenly distributes a stream of air throughout the interior space area, and maintains the pleasant state of everything the interior space

However, although the air flow is ejects evenly as described above, the air discharged through the first discharge hole 15 and the air discharged through the second discharge hole 16 are directed towards the bottom of the interior space. As a result, there are a difference between the temperature (t1) of the air drawn in the first suction hole 13 formed in the upper part of the main body 10 and the temperature (t2) of the air sucked into the second suction hole 14 formed in the lower part of the main body 10. Consequently, the air sucked into the first upper suction hole 13 has a heat load greater than that of the air sucked in the second lower suction hole 14. For example, in a cooling operation, since the temperature (t_ {{}}) of the air sucked into the first suction hole 13 is higher than the temperature (t2) of the air sucked into the second suction hole 14, to match the temperature of the air discharged from the first discharge port 15 and the temperature of the air discharged from the second discharge port 16, the air sucked into the first suction hole 13 must be cooled for longer than the air sucked into the second hole of suction 14. In a heating operation, the same procedure

In consideration of the previous aspect, the Diaphragm 50 of the air conditioner must be installed so that satisfies the following relational expression. In this one, S1 represents an area in which the air drawn through the first suction hole 13 exchanges heat with the exchanger of heat 20, and S2 represents an area in which the air aspirated to through the second suction hole 14 exchanges heat with the heat exchanger 20.

S1 \ geq S2

When S1 and S2 are determined in consideration of heat loads due to the difference between the temperature (t_ {{}}) and the temperature (t_ {{}}), the exchange of heat in heat exchanger 20 is performed more effective, and thus increases the capacity of the air conditioner.

Fig. 3 is a graph to compare air conditioner capabilities with the condition that it modify a ratio of heat exchange areas (S1: S2). As shown in Fig. 3, when S1 ≥ S2, the capacity of the Air conditioner is generally high. Specifically, as I know shown in Fig. 3, when S1: S2 = 6: 4 or S1: S2 = 7: 3, the capacity of the air conditioner is relatively high. Therefore, it is preferable that the diaphragm 50 is located in a position noted, satisfying the expression, 1.0 \ leq S1 / S2 \ leq 2.3.

Under heat exchanger 20 is installed a container of condensed water 23 to collect and discharge condensed water flowing down from the heat exchanger 20, and inside the first and the second suction hole 13 and 14 are installed respectively filters 13a and 14a to eliminate foreign substances of the air sucked into the first and second suction holes 13 and 14.

Fig. 4 is a longitudinal sectional view. of an air conditioner according to a second form of embodiment of the present invention. The air conditioner of the second embodiment differs from the air conditioner of the first embodiment as shown in Fig. 2 in that the air conditioner of the second embodiment it comprises a mobile diaphragm 60. From now on, some parts in this embodiment, which are essentially the same as in the first embodiment, they are indicated with the same reference numbers even if they are represented in different drawings, and a detailed description of these will be omitted parties because it is considered not necessary.

Diaphragm 60 of the air conditioner according to the second embodiment is rotatably installed in the main body 10 so that the ratio of S1: S2 can to vary. An end 61 of the diaphragm 60 is located in the front surface 12 of the main body 10, and the other end 62 of diaphragm 60 is located near the heat exchanger 20. Since the end 61 of the diaphragm 60 is connected to the drive motor 63, when drive motor 63 is in operation, diaphragm 60 rotates focusing around the end 61, and thus varies the ratio of S1: S2.

A first temperature sensor 71 to measure the  sucked air temperature in the first suction hole 13 is installed around the first suction hole 13, and a second temperature sensor 72 to measure the temperature of air sucked into the second suction hole 14 is installed around the second suction hole 14. The angle of rotation (the) of diaphragm 60 is determined in proportion to the difference between the temperature (T1) of the air measured by the first temperature sensor 71 and the temperature (T2)  of the air measured by the second temperature sensor 72. That is, when the difference between temperature (Ti) and temperature (T2) is large, diaphragm 60 rotates down at an angle relatively large, and when the difference between the temperature (T1) and the temperature (T2) is small, diaphragm 60 rotates towards down at a relatively small angle. Turning angle (the) of diaphragm 60 is determined according to temperatures (T1 and T2) of air measured by the first and second sensor of temperature 71 and 72, thus allowing the air conditioner present the maximum capacity according to the state of a space inside.

Fig. 5 is a longitudinal section view of an air conditioner according to a third form of embodiment of the present invention. The air conditioner of the third embodiment differs from the air conditioner of the first embodiment as shown in Fig. 2 in that the air conditioner of the third embodiment it comprises a diaphragm 80 that completely divides the interior of the main body 10 in an upper zone (A) and a lower zone (B) and a first heat exchanger 24 and a second 25 heat exchanger installed separately in the zones upper and lower (A and B). In this case, the exchange zone of heat of the first heat exchanger 24 located in the area upper (A) is greater than or equal to the heat exchange zone of the second heat exchanger 25 located in the lower zone (B). Under the first and second heat exchanger 24 and 25 condensed water containers are installed respectively 26 and 27.

As is evident from the description. above, the present invention provides a conditioner of air, which comprises a first air injection fan, a second air injection fan, a first hole of discharge, and a second discharge hole, which are located vertically separately, thus ejecting evenly air discharged throughout the area of an interior space.

In addition, the air conditioner of the present  invention adjusts the heat exchange zones of a heat exchanger in consideration of heat loads according to sucked air temperatures, thus effectively performing cooling and heating operations even when the vertical distribution of heat in the interior space is not uniform.

Although ways have been shown and described embodiment of the invention, those skilled in the art will value that changes can be made to these embodiments without deviate from the principles and spirit of the invention, whose scope is defined in the claims and their equivalents.

Claims (5)

1. An air conditioner comprising: a main body comprising a first suction hole and a second suction hole formed  respectively in the upper and lower parts thereof; a heat exchanger installed in the main body to exchange heat with sucked air to through the first and second suction holes; a diaphragm that divides the inside of the body main in an upper zone and a lower zone to separate the flow of the sucked air through the first suction hole and the flow of the sucked air through the second orifice of aspiration, in which the diaphragm satisfies the expression following relational, S1 \ geq S2, in which S1 represents an area in that the air sucked through the first suction hole exchange heat with the heat exchanger, and S2 represents an area in which the air sucked through the second orifice of suction exchanges heat with the heat exchanger and in the that the diaphragm is installed in a position that satisfies the next expression relational, 1.0 \ leq S1 / S2 \ leq 2.3. 2. The air conditioner as established by the  claim 1, wherein the first suction hole is formed on the upper part of a posterior body surface main, and the second suction hole is formed in the lower part of the back surface of the main body. 3. The air conditioner as established by the  claim 1, wherein: the main body also comprises a first discharge hole formed on top of a surface front of the main body, and a second discharge hole formed in the lower part of the front surface of the body principal; Y the air conditioner also comprises a first air injection fan installed above the diaphragm to expel air into the first discharge hole, and a second air injection fan installed under the diaphragm to expel air into the second hole of discharge. 4. The air conditioner as set by the  claim 3, which also comprises: a first guide and a first stabilizer to guide the air expelled by the first injection fan of air to the first discharge port; Y a second guide and a second stabilizer for  guide the air expelled by the second injection fan of air to the second discharge hole. 5. The air conditioner as established by the  claim 4, wherein the inclination angles descending from the first guide and the first stabilizer are respectively smaller than the angles of inclination descending from the second guide and the second stabilizer.