KR102441257B1 - air conditioner having turbulent flow producing device - Google Patents

Abstract

The present invention relates to an air conditioner having a turbulence generating means, which has a new structure to effectively mix recovered indoor air with outdoor air. According to the present invention, in the air conditioner having a turbulence generating means, the turbulence generating means (40) is connected to a rear side of a bypass damper (31) to generate turbulence in the indoor return air passing through a bypass damper (31) to allow the indoor return air supplied to a second chamber (13) to generate an irregular turbulent flow, so that the indoor return air is smoothly mixed with the outdoor air introduced in the second chamber (13). Accordingly, thermal efficiency can be prevented from deteriorating as the indoor return air and the outdoor air are not mixed.

Description

Air conditioner having turbulent flow producing device

The present invention relates to an air conditioner provided with a turbulence generating means of a novel structure that effectively mixes indoor recovered air and outdoor air.

As shown in FIG. 1, an air conditioner generally used in a building includes a main body 10, a suction chamber 11, mixing chambers 12 and 13, and a heat exchange chamber provided inside the main body 10 ( 14) and the first to third partition walls 21, 22, and 23 dividing the supply chamber 15 and the mixing chambers 12 and 13 provided in the middle of the mixing chambers 12 and 13 to form the first mixing chambers 12 and 13. and a second chamber (12,13) and an auxiliary partition wall (24) having a bypass hole (24a) connecting the first and second chambers (12,13), and the bypass hole (24a) a bypass damper 31 provided, a suction blower 33 provided inside the suction chamber 11, and cooling and heating coils 34 and 35 provided inside the heat exchange chamber 14; and a discharge blower (36) provided inside the supply chamber (15).

At this time, an indoor suction port 16 for sucking the indoor recovery air is formed on one side of the suction chamber 11, and an outdoor outlet 17 through which a part of the indoor recovery air is discharged is provided on one side of the first chamber 12. An outdoor suction port 18 for sucking outdoor air is formed at one side of the second chamber 13, and an indoor outlet 19 through which the indoor supply air is discharged is formed at one side of the supply chamber 15. .

In addition, first to third communication holes 21a, 22a, and 23a passing through front and rear surfaces are formed in the first to third partition walls 21 , 22 , and 23 .

In addition, the indoor inlet 16, the outdoor outlet 17, and the outdoor inlet 18 are provided with a flow control damper 32, respectively, and the indoor inlet 16, the outdoor outlet 17, and the outdoor inlet 18 An indoor intake pipe 16a, an outdoor exhaust pipe 17a, an outdoor intake pipe 18a, and an indoor exhaust pipe 19a are respectively connected to each other.

Therefore, if the suction blower 33 and the discharge blower 36 are driven while the cooling coil 34 or the heating coil 35 is in operation, the recovered indoor air is sucked into the indoor suction port 16 and then Some of the indoor recovery air supplied to the first chamber 12 and supplied to the first chamber 12 is discharged to the outdoor outlet 17, and the remaining indoor recovered air is discharged through the bypass hole 24a in the second chamber. It is supplied to (13) and mixed with the outdoor air sucked in through the outdoor suction port (18).

At this time, the air in which the indoor recovery air and the outdoor air are mixed is called indoor supply air, and the indoor supply air is supplied to the heat exchange chamber 14 and cooled or heated while passing through the cooling and heating coils 34 and 35, It is supplied to the supply chamber (15), pressurized by the blower, and supplied to the room through the indoor outlet (19).

And, the ratio of the air discharged to the outdoor outlet (17) among the indoor recovery air supplied to the first chamber (12) is adjusted according to the opening/closing amount of the bypass damper (31), and to the outdoor outlet (17). Outdoor air equal to the amount of exhausted air is sucked in through the outdoor suction port 18 and mixed with indoor recovery air to constitute indoor supply air.

That is, the ratio of the indoor return air to the outdoor air in the indoor supply air is adjusted according to the opening/closing amount of the bypass damper 31 .

However, in this air conditioner, due to the influence of the blowing pressure of the suction blower 33 and the suction pressure of the discharge blower 36 , the indoor return air sucked into the indoor suction port 16 and the outdoor air sucked through the outdoor suction port 18 . Since the air is supplied to the heat exchange chamber 14 before it is sufficiently mixed, there is a problem in that the overall heat exchange efficiency is lowered.

In addition, when cooling the indoor supply air using the cooling coil 34 , moisture contained in the indoor supply air is condensed in the cooling coil 34 .

Accordingly, a discharge case 34a for collecting and discharging moisture condensed in the cooling coil 34 is provided under the cooling coil 34, and the moisture condensed in the cooling coil 34 is collected in the discharge case 34a. It is configured to be discharged to the outside after being made.

However, as the indoor supply air passes through the cooling coil 34 at a high speed, a part of the moisture condensed in the cooling coil 34 is blown backward by the indoor supply air, and is supplied to the room together with the indoor supply air. Accordingly, the humidity in the room increases, and in severe cases, moisture is scattered inside the room in the form of mist, and people in the room feel damp.

Therefore, there is a need for a new method to solve these problems.

Registered Patent No. 10-0580272 Registered Patent No. 10-1603904

An object of the present invention is to solve the above problems, and it is an object of the present invention to provide an air conditioner equipped with a turbulence generating means of a new structure for effectively mixing indoor recovered air and outdoor air.

The present invention for achieving the above object includes a main body 10, a suction chamber 11, a mixing chamber 12 and 13, a heat exchange chamber 14 and a supply chamber provided inside the main body 10 ( 15), the first to third partition walls 21, 22, and 23 are provided in the middle of the mixing chambers 12 and 13 to separate the mixing chambers 12 and 13 into the first and second chambers 12 . 31), a suction blower 33 provided inside the suction chamber 11, cooling and heating coils 34 and 35 provided inside the heat exchange chamber 14, and the supply chamber 15 It includes a discharge blower 36 provided in the inside of the suction chamber 11, an indoor suction port 16 for sucking the indoor recovery air is formed on one side of the suction chamber 11, and an indoor recovery port 16 is formed on one side of the first chamber 12 An outdoor outlet 17 through which a part of the air is discharged is formed, an outdoor intake 18 through which outdoor air is sucked is formed at one side of the second chamber 13, and an indoor supply is provided at one side of the supply chamber 15 An indoor outlet 19 through which air is discharged is formed, and first to third communication holes 21a, 22a, and 23a penetrating the front and rear surfaces are formed in the first to third partition walls 21, 22, and 23. In the air conditioner, the air conditioner further includes a turbulence generating means (40) connected to the rear side of the bypass damper (31) and generating turbulence in the recovered indoor air that has passed through the bypass damper (31), and the turbulence generating means (40) ) is composed of a guide tube body 41 connected to the rear side of the bypass damper 31 and a rectangular plate shape extending in the lateral direction, and both ends are rotatably coupled to both inner sides of the guide tube body 41, and first and second turbulence generating plates 42 and 43 rotated in opposite directions by a driving motor 45, and the first and second turbulence generating plates 42 and 43 are spaced apart from each other in the front and rear directions. Provided is an air conditioner provided with a turbulence generating means, characterized in that it is provided on the guide tube body (41) as much as possible. do.

According to another feature of the present invention, a fourth communication hole (24b) is further formed in the third partition wall (23) dividing the heat exchange chamber (14) and the supply chamber (15), and the third communication hole (23a) A first opening/closing damper 51 provided in the second opening/closing damper 52 provided in the fourth communication hole 24b, and a second opening/closing damper 52 provided in the second opening/closing damper 52 Further comprising a moisture removal means 60 for controlling moisture contained in the air passing through, the second opening/closing damper 52 includes a damper tube body 52a coupled to the fourth communication hole 24b, and the and a damper plate 52b coupled to the damper tube 52a and rotated by an actuator to open and close the middle portion of the damper tube 52a, and the water removal means 60 is provided below the damper tube 52a. and a drying cylinder 61 having an exhaust port 61a formed on one side thereof, a guide roller 62 provided inside the damper tube body 52a and the drying cylinder 61, and the periphery of the guide roller 62 The absorbing sheet 63 is coupled and the intermediate portion is disposed to pass through the slit 52c formed in the damper tube body 52a, and the absorber sheet 63 is connected to the guide roller 62 so that the absorption sheet 63 is formed in the damper tube body 52a. a driving motor 64 for circulating the inside and the inside of the drying cylinder 61, an outdoor intake pipe 18a connected to the outdoor suction port 18, and an air supply pipe 65 connecting the drying cylinder 61; , an air supply pump (66) provided in the middle of the air supply pipe (65) and supplying external air passing through the outdoor intake pipe (18a) to the drying cylinder body (61). The provided air conditioner is provided.

In the air conditioner provided with the turbulence generating means according to the present invention, the turbulence generating means 40 for generating turbulence in the recovered indoor air passing through the bypass damper 31 is connected to the rear side of the bypass damper 31, The indoor return air supplied to the second chamber 13 causes irregular turbulence so that the indoor return air is smoothly mixed with the outside air introduced into the second chamber 13, so that the indoor recovery air and the outside air is not mixed, there is an advantage that can prevent a decrease in thermal efficiency.

1 is a cross-sectional side view showing a conventional air conditioner;
2 is a side cross-sectional view showing an air conditioner equipped with a turbulence generating means according to the present invention;
3 is a side cross-sectional view showing the turbulence generating means of the air conditioner provided with the turbulence generating means according to the present invention;
4 and 5 are cross-sectional side views showing the water removal means of the air conditioner provided with the turbulence generating means according to the present invention.

Hereinafter, the present invention will be described in detail based on the accompanying illustrative drawings.

2 to 5 are views illustrating an air conditioner equipped with a turbulence generating means according to the present invention. 13), first to third partition walls 21, 22, and 23 partitioning the heat exchange chamber 14 and the supply chamber 15, and the mixing chamber 12 provided in the middle of the mixing chambers 12 and 13 . A bypass damper 31 provided in the pass hole 24a, a suction blower 33 provided inside the suction chamber 11, and a cooling/heating coil provided inside the heat exchange chamber 14 ( 34 and 35) and the discharge blower 36 provided in the supply chamber 15 is the same as in the prior art.

At this time, an indoor suction port 16 for sucking the indoor recovery air is formed on one side of the suction chamber 11, and an outdoor outlet 17 through which a part of the indoor recovery air is discharged is provided on one side of the first chamber 12. An outdoor suction port 18 for sucking outdoor air is formed at one side of the second chamber 13, and an indoor outlet 19 through which the indoor supply air is discharged is formed at one side of the supply chamber 15. .

In addition, first to third communication holes 21a, 22a, and 23a passing through front and rear surfaces are formed in the first to third partition walls 21 , 22 , and 23 .

In addition, the indoor inlet 16, the outdoor outlet 17, and the outdoor inlet 18 are provided with a flow control damper 32, respectively, and the indoor inlet 16, the outdoor outlet 17, and the outdoor inlet 18 An indoor intake pipe 16a, an outdoor exhaust pipe 17a, an outdoor intake pipe 18a, and an indoor exhaust pipe 19a are respectively connected to each other.

And, according to the present invention, a fourth communication hole 24b is further formed in the third partition wall 23 that partitions the heat exchange chamber 14 and the supply chamber 15 .

And, a turbulence generating means 40 connected to the rear side of the bypass damper 31 to generate turbulence in the indoor recovered air that has passed through the bypass damper 31, and the third communication hole 23a. The first opening/closing damper 51, the second opening/closing damper 52 provided in the fourth communication hole 24b, and the second opening/closing damper 52 provided in the second opening/closing damper 52 pass through A moisture removal means 60 for controlling moisture contained in the air is further provided.

In detail, as shown in FIG. 3, the turbulence generating means 40 has a guide tube body 41 connected to the rear side of the bypass damper 31, and a rectangular plate shape extending in the lateral direction. It consists of first and second turbulence generating plates 42 and 43, both ends of which are rotatably coupled to both inner sides of the guide tube body 41 and rotated in opposite directions by a driving motor 45.

At this time, the first and second turbulence generating plates 42 and 43 are provided on the guide tube body 41 so as to be spaced apart from each other in the front-rear direction, and are connected to rotate in opposite directions by an interlocking gear (not shown).

In addition, the first and second turbulence generating plates 42 and 43 are configured in plurality and are provided to be vertically spaced apart from each other, and each of the first turbulence generating plate 42 and the second turbulence generating plate 43 is provided. are connected to each other by a belt, not shown.

The driving motor 45 is connected to the uppermost first turbulence generating plate 42, and when the driving motor 45 is driven, the plurality of first and second turbulence generating plates 42 and 43 are rotated simultaneously.

In this embodiment, the first turbulence generating plate 42 is configured to rotate counterclockwise, and the second turbulence generating plate 43 is configured to rotate clockwise.

Therefore, when the first and second turbulence generating plates 42 and 43 are rotated by the driving motor 45, the recovered indoor air passing through the bypass damper 31 is transferred to the first and second turbulence generating plates ( 42 and 43), irregular turbulence is generated, and the recovered indoor air in this way is mixed with the external air introduced into the second chamber 13 and supplied to the heat exchange chamber 14.

In particular, as the first and second turbulence generating plates 42 and 43 are continuously rotated, the recovered indoor air passing through the first and second turbulence generating plates 42 and 43 causes more irregular turbulence. , and thus more smoothly mixed with the outside air.

As shown in FIG. 4 , the first and second opening/closing dampers 51 and 52 are coupled to the damper pipes 51a and 52a coupled to the third and fourth communication holes, and to the damper pipes 51a and 52a. and is composed of damper plates 51b and 52b that are rotated by an actuator not shown to open and close the middle part of the damper tube bodies 51a and 52a, and according to the operation of the actuator, the third communication hole 23a and the fourth communication hole It is configured to open and close the ball 24b in reverse.

That is, the first opening/closing damper 51 and the second opening/closing damper 52 allow the fourth communication hole 24b to be closed when the third communication hole 23a is opened, and the fourth communication hole 24b to be opened. If so, the third communication hole (23a) is sealed.

As shown in FIGS. 2 and 4, the moisture removing means 60 includes a drying cylinder 61 provided below the damper tube 52a and having an exhaust port 61a on one side thereof, and the damper tube 52a. ) and a guide roller 62 provided inside the drying cylinder 61, coupled to a periphery of the guide roller 62, and a middle portion disposed to pass through a slit 52c formed in the damper tube body 52a an absorbent sheet 63 and a driving motor 64 connected to the guide roller 62 so that the absorbent sheet 63 circulates inside the damper tube body 52a and the inside of the drying cylinder 61; An air supply pipe (65) connecting the outdoor intake pipe (18a) and the drying cylinder (61), is provided in the middle of the air supply pipe (65), and external air passing through the outdoor intake pipe (18a) is dried. It is composed of an air supply pump (66) for supplying to the cylinder (61).

The drying tubular body 61 is configured in a rectangular tubular shape with an open upper surface and is hermetically coupled to the rear lower surface of the damper tubular body 52a.

At this time, the slits 52c are configured as a pair spaced apart in the front and rear and are formed to penetrate the upper and lower surfaces on the rear lower surface of the damper tube body 52a, and the inner space of the damper tube body 52a and the drying cylinder ( 61) to be interconnected.

The absorbent sheet 63 is constituted by combining a sheet having excellent breathability and absorbency, such as a nonwoven fabric, in a ring shape.

Therefore, in the state in which the cooling coil 34 is driven, as shown in FIG. 4 , when the first opening/closing damper 51 is opened and the second opening/closing damper 52 is closed, the cooling coil 34 is The indoor supply air cooled while passing through is supplied to the supply chamber 15 through the first opening/closing damper 51 and supplied to the room through the discharge blower 36 .

Conversely, as shown in FIG. 5 , when the first opening/closing damper 51 is closed and the second opening/closing damper 52 is opened, the indoor supply air cooled while passing through the cooling coil 34 is opened and closed to the second opening/closing damper 52 . It is supplied to the supply chamber 15 after passing through the absorbent sheet 63 extending into the damper 52 .

At this time, as the indoor supply air passes through the absorption sheet 63, moisture contained in the indoor supply air is absorbed and removed by the absorption sheet 63, and the dry indoor supply air from which the moisture has been removed is transferred to the supply chamber ( 15) and supplied to the room through the discharge blower (36).

At this time, when the driving motor 64 and the air supply pump 66 of the water removal means 60 are driven, as the guide roller 62 rotates, the damper tube body 52a of the second opening/closing damper 52 is rotated. The upper portion of the absorbent sheet 63, which has absorbed moisture from the inside of the It is supplied to the drying chamber through 65, and after drying the absorbent sheet 63, it is discharged to the outside through the exhaust port 61a.

Therefore, when the lower end of the absorbent sheet 63 located inside the drying cylinder 61 is dried and the guide roller 62 is continuously rotated by the driving motor 64, the drying cylinder 61 is dried. The absorbed sheet 63 is raised inside the second opening/closing damper 52 to absorb and remove moisture contained in the indoor supply air passing through the second opening/closing damper 52 .

In the air conditioner provided with the turbulence generating means configured as described above, the turbulence generating means 40 for generating turbulence in the recovered indoor air passing through the bypass damper 31 is connected to the rear side of the bypass damper 31, The indoor return air supplied to the second chamber 13 causes irregular turbulence so that the indoor return air is smoothly mixed with the outside air introduced into the second chamber 13, so that the indoor recovered air and the outside air Since they are not mixed, there is an advantage in that thermal efficiency can be prevented from being lowered.

In addition, a fourth communication hole 24b is further formed in the third partition wall 23 that divides the heat exchange chamber 14 and the supply chamber 15 from the first opening/closing hole provided in the third communication hole 23a. The damper 51, the second opening/closing damper 52 provided in the fourth communication hole 24b, and the second opening/closing damper 52 provided in the air passing through the second opening/closing damper 52 A moisture removal means 60 for controlling the accumulated moisture is further provided, if necessary, by controlling the first and second opening/closing dampers 51 and 52, the air passing through the heat exchange chamber 14 is The moisture condensed in the cooling coil 34 is supplied into the room together with the indoor supply air by allowing it to pass through the second chamber 13 so that the moisture contained in the air is removed by the moisture removing means 60. It has the advantage of preventing the humidity from rising.

10. Body 31. Bypass Damper
32. Flow control valve 40. Turbulence generating means

Claims (2)

The body 10 and
First to third partition walls 21 , 22 , 23 provided inside the main body 10 to partition the suction chamber 11 , the mixing chamber 12 , 13 , the heat exchange chamber 14 , and the supply chamber 15 . )class,
It is provided in the middle of the mixing chambers 12 and 13 to divide the mixing chambers 12 and 13 into first and second chambers 12 and 13, and connect the first and second chambers 12 and 13 to each other. and an auxiliary bulkhead 24 having a bypass hole 24a formed therein;
a bypass damper 31 provided in the bypass hole 24a;
a suction blower 33 provided in the suction chamber 11;
cooling and heating coils 34 and 35 provided in the heat exchange chamber 14;
and a discharge blower (36) provided inside the supply chamber (15),
An indoor suction port 16 for sucking indoor recovery air is formed at one side of the suction chamber 11,
An outdoor outlet 17 through which a part of the indoor recovery air is discharged is formed on one side of the first chamber 12,
An outdoor suction port 18 through which outdoor air is sucked is formed at one side of the second chamber 13,
An indoor outlet 19 through which indoor supply air is discharged is formed on one side of the supply chamber 15,
In the air conditioner in which first to third communication holes (21a, 22a, 23a) passing through front and rear surfaces are formed in the first to third partition walls (21, 22, 23),
and a turbulence generating means (40) connected to the rear side of the bypass damper (31) to generate turbulence in the recovered indoor air that has passed through the bypass damper (31);
The turbulence generating means 40 is
a guide tube body 41 connected to the rear side of the bypass damper 31;
First and second turbulence generating plates configured in the shape of a rectangular plate extending in the lateral direction, both ends rotatably coupled to both inner sides of the guide tube body 41 and rotated in opposite directions by a driving motor 45 (42,43);
The first and second turbulence generating plates 42 and 43 are provided on the guide tube body 41 so as to be spaced apart from each other in the front-rear direction,
A fourth communication hole (24b) is further formed in the third partition wall (23) dividing the heat exchange chamber (14) and the supply chamber (15),
a first opening/closing damper 51 provided in the third communication hole 23a;
a second opening/closing damper 52 provided in the fourth communication hole 24b;
It further comprises a water removal means (60) provided in the second opening/closing damper (52) to control the moisture contained in the air passing through the second opening/closing damper (52),
The second opening/closing damper 52 is
a damper tube body 52a coupled to the fourth communication hole 24b;
and a damper plate 52b coupled to the damper tube 52a and rotated by an actuator to open and close the middle part of the damper tube 52a,
The moisture removal means 60 is
a drying cylinder 61 provided on a lower side of the damper tube body 52a and having an exhaust port 61a on one side thereof;
a guide roller 62 provided in the damper tube body 52a and the drying cylinder 61;
an absorbent sheet 63 coupled to the periphery of the guide roller 62 and disposed to pass through the slit 52c formed in the damper tube body 52a;
a driving motor 64 connected to the guide roller 62 so that the absorption sheet 63 circulates between the inside of the damper pipe body 52a and the inside of the drying cylinder body 61;
an air supply pipe (65) connecting the outdoor intake pipe (18a) connected to the outdoor suction port (18) and the drying cylinder (61);
The turbulence generating means comprising an air supply pump (66) provided in the middle of the air supply pipe (65) and supplying external air passing through the outdoor intake pipe (18a) to the drying cylinder body (61) Equipped with air conditioner. delete

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