DE69103727T2 - Air conditioner. - Google Patents

Description

The invention relates to an air conditioning device, in particular to an air conditioning device that can prevent the temperature distribution near an indoor floor from becoming uneven.

A conventional outlet structure in an air conditioner is disclosed, for example, in Japanese Unexamined Utility Model Publication No. 196041/1988. Fig. 9 is a side sectional view of the indoor unit in a conventional air conditioner. Fig. 10 is an exploded perspective view of the indoor unit. Fig. 11 is a perspective view showing details of the outlet of the indoor unit.

In Figs. 9-11, reference numeral 41 denotes the casing of the indoor unit. Reference numeral 42 denotes an inlet formed in the casing 41. Reference numeral 43 denotes a heat exchanger housed in the casing 41. Reference numeral 44 denotes an outlet. Reference numeral 45 denotes a cross-flow fan which blows conditioned air, which has been introduced into the casing 41 through the inlet 42 and passed through the heat exchanger 43, into the indoor space from the outlet 44. Reference numeral 46 denotes an auxiliary flap which is rotatably supported at its opposite ends in the outlet 44 and which has five passage openings 47 formed longitudinally therein. The reference number 48 designates a main flap which is rotatably mounted in the outlet 44 so that it has the same axis as the auxiliary flap 47 on the interior side.

Now, the operation of the conventional air conditioner constructed as described above will be explained.

In heating, when the power is turned on, when the main flap 48 is inclined at about 45 degrees and the auxiliary flap 46 is substantially vertical, indoor air is introduced into the casing 41 through the inlet 42 by rotation of the cross-flow fan 45. The introduced air is heated to a high temperature by the heat exchanger 43 and blown into the indoor space from the outlet 44. When the air is blown out through the outlet 44, a part X of the discharged air flows along the main flap 48. The blowing angle of another part Y of the discharged air is directed downward through the auxiliary flap 46. The other part Z of the discharged air, which has passed through the outlet openings 47 in the auxiliary flap 46, flows along the main flap 48 like the part X. In this way, the two flaps 46 and 48 divide the discharged air into that which is directed directly under the indoor unit and that which is directed to a location away from the indoor unit, which causes the temperature distribution near the indoor floor to be more uniform.

The outlet structure of the conventional air conditioner as explained above can make the temperature distribution near the floor uniform at a location directly under the indoor unit, but it creates a problem that the discharged air directed to a location away from the indoor unit rises and that the temperature away from the indoor unit tends to be lower compared to the temperature directly under the indoor unit. The temperature distribution near the floor was not satisfactory over an entire space to be air-conditioned.

Although located away from the indoor unit If directed hot air hits the feet of a resident, it rises and reaches a spot near the hand, which is not quite ideal for comfort.

It is an object of the invention to eliminate the disadvantage of the conventional air conditioning device and to provide a new and improved air conditioning device which is able to equalize the temperature distribution near the floor throughout the room to be air-conditioned and to achieve ideal heating in such a way that the head of an occupant remains cool and the feet are warm.

The above and other objects of the invention have been achieved by providing an air conditioning apparatus comprising: a plurality of heat exchangers connected in series; a plurality of outlets arranged to correspond to the respective heat exchangers; air supply means for blowing out conditioned air having passed through the heat exchangers through the outlets; and blowing direction control means arranged to correspond to the respective outlets and capable of separately adjusting the blowing direction of the conditioned air.

According to the invention, a refrigerant compressed by a compressor for heating is circulated in the respective heat exchangers to increase the temperature of the heat exchangers. A heat exchanger closer to the compressor is kept at a higher temperature by the heat of the refrigerant, and the respective heat exchangers have different temperatures. As a result, the discharged air as blown out of the outlets by the air supply device has different temperatures depending on its different parts.

The air conditioner according to the invention can separately adjust the blowing direction of different parts of the discharged air by the blowing direction control means. A hotter portion of the discharged air can be blown to a location near the floor, and a cooler portion of the discharged air can be blown to a location near the head of an occupant to equalize the temperature distribution near the floor over the entire space to be air-conditioned and to carry out ideal heating in such a way that the occupant's head remains cool and his feet become warm.

An embodiment of the invention will now be described by way of example with reference to the accompanying drawings, in which:

Fig. 1 is a perspective view showing an indoor unit of an air conditioner according to an embodiment of the invention;

Fig. 2 is a refrigeration cycle diagram showing the air conditioner of the embodiment;

Fig. 3 is a perspective view showing details of the outlet in the indoor unit of the air conditioner according to the embodiment;

Fig. 4 is a block diagram showing the electrical structure of the air conditioner of the embodiment;

Fig. 5 is a Mollier diagram of the air conditioner of the embodiment;

Fig. 6 is a flow chart illustrating the process performed by the control circuit of the air conditioner of the embodiment is performed;

Figs. 7 and 8 are schematic diagrams helpful in explaining the blowing directions of discharged air from the air conditioner of the embodiment;

Fig. 9 is a side sectional view of an indoor unit in a conventional air conditioner;

Fig. 10 is an exploded perspective view of the indoor unit of the conventional air conditioner; and

Fig. 11 is a perspective view showing details of the indoor unit outlet in the conventional air conditioner.

Reference is now made to the drawings, in which like reference numerals designate identical or corresponding parts throughout the several views, and particularly to Fig. 2 thereof, there is shown a refrigerant circuit diagram showing the air conditioning apparatus according to an embodiment of the invention.

In Fig. 2, reference numeral 1 denotes a compressor arranged in an outdoor unit to compress a refrigerant. Reference numeral 2 denotes an indoor unit arranged in a house. Reference numeral 3 denotes a heat exchanger in the indoor unit 2 connected to the compressor 1. Reference numeral 4 denotes a second heat exchanger in the indoor unit 2 connected in series to the first heat exchanger. Reference numeral 5 denotes an expansion valve connected to the second heat exchanger 4. Reference numeral 6 denotes an evaporator connected to the expansion valve 5.

It will Reference is now made to Fig. 1, which is a perspective view illustrating the indoor unit 2 of the air conditioning device.

In Fig. 1, reference numeral 7 denotes the casing of the indoor unit 2, which accommodates the first and second heat exchangers 3 and 4. Reference numeral 8 denotes an inlet formed in the front part of the indoor unit 2. Reference numeral 9 denotes a first outlet formed in the lower part of the casing so as to correspond to the first heat exchanger 3. Reference numeral 10 denotes a second outlet formed in the lower part of the casing 7 so as to correspond to the second heat exchanger 4.

The reference number 11 denotes a first cross-flow fan, which is arranged between the first heat exchanger 3 and the first outlet 9 in the housing 7. The reference number 12 denotes a first fan drive motor for rotating the first cross-flow fan 11. The reference number 13 denotes a second cross-flow fan, which is arranged between the second heat exchanger 4 and the second outlet 10 in the housing 7. The reference number 14 denotes a second fan drive motor for rotating the second cross-flow fan 13.

In the embodiment, the first cross-flow fan 11 and the second cross-flow fan 13 form an air supply device.

Reference is now made to Fig. 3, which is a perspective view showing details of the outlets 9 and 10 in the indoor unit 2.

In Fig. 3, reference numeral 15 denotes a first group of six louvers 15 supported in the first outlet 9 so that they can swing horizontally. Reference numeral 16 denotes a pair of first louver motors for performing the swinging operation of one set of three louvers via link levers 17 independently of the other set of three louvers. Reference numeral 18 denotes a first louver supported in the first outlet 9 in front of the first louvers 15 so that it can swing vertically. Reference numeral 19 denotes a first discharge air temperature measuring sensor which measures the temperature of discharged air in the first outlet 9.

Reference numeral 20 denotes a second group of six louvers supported in the second outlet 10 so as to be horizontally pivotable. Reference numeral 21 denotes a pair of second louver motors for performing the pivoting operation of one set of three louvers 20 via link levers 22 independently of the other set of three louvers 20. Reference numeral 23 denotes a second louver supported in the second outlet 10 in front of the second louvers 20 so as to be vertically pivotable. Reference numeral 24 denotes a second discharge air temperature measuring sensor which measures the temperature of discharged air in the second outlet 10.

In the embodiment, the first and second ventilation flaps 15 and 20 as well as the first and second flaps 18 and 23 form a blow-out direction control device.

Reference is now made to Fig. 4, which is a block diagram showing the electrical structure of the air conditioner according to the embodiment.

In Fig. 4, reference numeral 25 denotes an air conditioner control circuit, whose input side is connected to the first discharge air temperature measuring sensor 19 and the second discharge air temperature measuring sensor 24, and whose output side is connected to the first fan drive motor 12, the second fan drive motor 14, the first louver motors 16 and the second louver motors 21 via driver circuits 26-29. Reference numeral 30 denotes a first louver motor which can be connected to the output side of the control circuit 25 via a driver circuit 31 in order to carry out the pivoting movement of the first louver 18. Reference numeral 32 denotes a second louver motor which can be connected to the output side of the control circuit 25 via a driver circuit 33 in order to carry out the pivoting operation of the second louver 23.

In the control circuit 25, a table is stored in advance which can output stable durations Ta, desired output air temperature differences Δt, air volume differences ΔQ and time-stable total air volumes Qs so as to correspond to different operation modes and which controls the motors 12, 14, 16, 21, 30 and 32 depending on selected values.

The operation of the air conditioner with the embodiment constructed as described above will now be explained.

When the air conditioner according to the embodiment performs a heating operation, the refrigerant compressed by the compressor 1 is first introduced into the heat exchanger 3 to release part of its heat, and then it is introduced into the second heat exchanger 4 to release another part of its heat. Fig. 5 shows a Mollier diagram for this case, which shows that the refrigerant at the first heat exchanger 3 undergoes heat exchange in a region of superheat and a two-phase flow or a temperature range indicated by reference character A to be kept at a high temperature, and this shows that the refrigerant at the second heat exchanger 4 undergoes heat exchange in a region of two-phase flow and subcooling or a low temperature range indicated by reference character B to be kept at a low temperature at the second heat exchanger 4. As a result, the discharge air U at the first heat exchanger 3 has a high temperature, while the discharge air V at the second heat exchanger 4 has a low temperature.

Reference is now made to Fig. 6, which is a flow chart illustrating the process performed by the control circuit 25 when the power to the air conditioner is turned on.

Now, the operation of the air conditioner will be explained with reference to this flow chart. The program shown in the flow chart is called during the execution of a main program not shown.

The control circuit 25 determines whether or not the power in the air conditioner is turned on in a step S1. If the answer is affirmative, the operation mode selected by a resident is input in a step S2. The stable period Ta corresponding to the selected operation mode is read out from the table in a step S3. It is determined in a step S4 whether or not the stable period Ta has elapsed since the power was turned on. If the stable period Ta has elapsed, data concerning the discharge air temperatures t1 and t2 are input from the first discharge air temperature measuring sensor 19 and the second discharge air temperature measuring sensor 24 in a step S5, respectively.

The stable periods Ta are determined to be long enough for the temperatures of the heat exchangers 3 and 4 to be raised to the equilibrium state by the coolant. After the temperatures of the heat exchangers 3 and 4 have reached the equilibrium state to cause the discharge air temperatures t1 and t2 to be stable, blow-out direction control, which will be explained later, is carried out.

Thereafter, in a step S6, the desired blow-out air temperature difference Δt corresponding to the selected operation mode is read out from the table stored in advance in the control circuit. In a step S7, the desired blow-out air temperature difference Δt is compared with a value obtained by subtracting the blow-out air temperature t2 from the blow-out air temperature t1. If (t1 - t2) is smaller than Δt (which means that the actual temperature difference is small), a corresponding air volume difference ΔQ is read out from the table in a step S8, and the program proceeds to a step S9. In step S9, the rotation speeds of the first fan motor 12 and the second fan motor 14 are adjusted so that the air volume Q1 of the first blow-out air U and the air volume Q2 of the second blow-out air V are adjusted so that the air volume Q1 is larger than the air volume Q2 by ΔQ. In addition, as shown in Figs. 3 and 7, the first flap motor 30 is driven to direct the first flap 18 downward, and the second flap motor 32 is driven to direct the second flap 23 to face forward. The first louver motors 16 and the second louver motors 21 are driven to direct both groups of louvers 15 and 20 inward with respect to each other, causing the discharge air flows U and V flow in a crossing manner. The respective sets of the first ventilation flaps 15 are opened with respect to each other to make the air supply area for the first discharge air U larger.

In a step S10, it is determined whether (t1 - t2) is equal to Δt or not. If this is affirmative, the program ends. If it is negative, the program returns to step S7 and (t1 - t2) is again compared with Δt .

If (t1 - t2) is larger than Δt in step S7 (which means that the actual temperature difference is large), the program proceeds to a step S11 in which the rotation speeds of the first fan motor 12 and the second fan motor 14 are adjusted so that the air volume Q1 of the first discharge air U and the air volume Q2 of the second discharge air V are adjusted so that both air volumes are equal. At the same time, the first damper motor 30 and the second damper motor 32 are driven to direct both dampers 18 and 23 downward, and the first louver motors 16 and the second louver motors 21 are driven to direct both sets of louvers 15 and 20 in the same direction.

If (t1 - t2) is equal to Δt in step S10, the program ends. If the value is negative, the program returns to step S7 and (t1 - t2) is compared with Δt.

If in step S7 (t1 - t2) corresponds to Δt, in step S12 the time-stable total air volume Qs is read from the card and the program continues to a step S13. In step S13, the speeds of the first fan motor 12 and the second fan motor 14 are adjusted so that both air volumes Q1 and Q2 are adjusted so that the air volume Q1 of the first discharge air U and the air volume Q2 of the second discharge air V are each half of Qs. Moreover, as shown in Figs. 3 and 7, the first damper motor 30 is driven to direct the first damper 18 downward, and the second damper motor 32 is driven to direct the second damper 3 to face forward. The first louver motors 16 and the second louver motors 21 are controlled to direct both sets of louvers 15 and 20 inward with respect to each other, causing the discharge air flows U and V to flow crossing each other. The respective sets of first louvers 15 are slightly closed with respect to each other to make the air supply area of the first discharge air U smaller, and the program ends.

As explained in detail, when the actual temperature difference (t1 - t2) is smaller than Δt in step S7, the air volume Q1 of the first discharge air U is set larger than the air volume Q2 of the second discharge air V in step S9 to cause the temperature t1 of the first discharge air to gradually increase, allowing the temperature difference (t1 - t2) to increase to approach Δt. When the actual temperature difference (t1 - t2) is larger than t, the air volume Q1 of the first discharge air U is reduced until the air volume Q1 becomes equal to the air volume Q2 of the second discharge air V in step S11. In this way, the temperature t1 of the first discharge air is gradually reduced to cause the temperature difference (t1 - t2) to decrease, allowing the temperature difference to approach Δt.

Accordingly, the temperature difference between the temperature t1 of the first discharge air and the temperature t2 of the second discharge air can always be kept close to the predetermined Air temperature difference Δt. In step S13, the first discharge air U having a high temperature is blown out through the first flap 18 downward or to a location near the floor of the room R, and the second discharge air V having a low temperature is blown out through the second flap 23 forward or to the head of an occupant as shown in Fig. 8. Moreover, the blown air V formed by two cooler portions prevents the first blown air U from rising, allowing the temperature distribution near the floor in the room R to be balanced.

As explained in detail, the air conditioner according to the embodiment includes: the first and second heat exchangers 3 and 4 connected in series with each other; the first and second outlets 9 and 10 arranged to correspond to the respective heat exchangers 3 and 4; the first and second cross-flow fans 11 and 14 which blow conditioned air into the interior through the outlets 9 and 10 as the first and second discharge air, respectively, the conditioned air having passed through the respective heat exchangers 3 and 4; and the first and second louvers 15 and 20 and the first and second flaps 18 and 23 arranged to correspond to the outlets 9 and 10, respectively, and which can separately adjust the blowing direction of the first and second discharge air.

The arrangement of the embodiment can separately adjust the blowing directions of the high-temperature discharge air from the first heat exchanger 3 and the low-temperature discharge air from the second heat exchanger 4 using the first and second louvers 15 and 20 and the first and second louvers 18 and 23.

As a result, the first high-temperature discharge air U can be blown out to a location near the floor, and the second low-temperature discharge air V can be blown out to a location near the head of a resident to keep the resident's head cool and the resident's feet warm. In addition, the second low-temperature discharge air V can prevent the first high-temperature discharge air U from rising to equalize the temperature distribution near the floor.

Although the heat exchanger unit in the embodiment is constituted by two heat exchangers, i.e., the first and second heat exchangers 3 and 4, the invention is not limited to such an arrangement, but is also applicable to cases where the number of heat exchangers is three or four. However, providing at least two kinds of discharge air having different temperatures can keep a resident's head cool and his feet warm. When two heat exchangers are used to realize the invention, there is an advantage that the manufacturing cost is reduced compared with the case where three or four heat exchangers are used.

Although the flow direction control means in the embodiment is constituted by the first and second louvers 15 and 20 for adjusting the blowing direction horizontally and the first and second louvers 18 and 23 for adjusting the blowing direction vertically, the invention is not limited to this case, but is also applicable to a case where the blowing direction control means is constituted by a blowing direction control louver for adjusting the blowing direction in an oblique direction, insofar as the flow direction of the discharge air can be adjusted as desired.

Although the blowing direction control means in the embodiment is constituted by the louvers 15 and 20 and the flaps 18 and 23 by which the blowing direction of the discharge air can be automatically adjusted using the motors 16, 21, and 32 as controlled by the control unit 25, the invention is not limited to this case, but is also applicable to a case in which the louvers 15 and 20 and the flaps 18 and 23 are operated manually.

Claims (9)

1. Air conditioning device, characterized in that it has the following: - several heat exchangers (3, 4) connected in series ; - a plurality of outlets (9, 10) arranged to correspond to the respective heat exchangers (3, 4); - an air supply device (11, 13) for blowing out conditioned air which has passed through the heat exchangers (3, 4) through the outlets (9, 10); - Blow-out direction control devices (15, 18, 20, 23) which are designed to correspond to the respective outlets (9, 10) and which are capable of separately adjusting the blow-out direction of the conditioned air. 2. Air conditioning device according to claim 1, wherein the blow-out direction control devices (15, 18, 20, 23) are capable of adjusting the blow-out direction of the conditioned air in several ways simultaneously. 3. Air conditioning device according to claim 1, in which the blow-out direction control devices (15, 18, 20, 23) are able to adjust the blow-out direction at the respective outlets (9, 10) in a vertical or horizontal manner. 4. Air conditioning device according to claim 3, in which the blow-out direction control devices (15, 18, 20, 23) have flaps (18, 23) and ventilation flaps (15, 20) at the respective outlets (9, 10), the flaps (18, 23) being vertically adjustable and the ventilation flaps (15, 20) being horizontally adjustable. 5. An air conditioning device according to claim 1, wherein the blow direction control means (15, 18, 20, 23) blow the conditioned air downward from the outlet (9) arranged to correspond to the heat exchanger (3) closer to the compressor (1), and blow the conditioned air upward from the outlet (10) arranged to correspond to the heat exchanger (4) further away from the compressor (1). 6. An air conditioner according to claim 5, wherein the downwardly discharged air is adjusted so that it is discharged evenly in the horizontal direction. 7. Air conditioning device according to claim 1, wherein the blow direction control devices (15, 18, 20, 23) adjust the blow direction depending on the temperatures as measured by temperature sensors (19, 24) arranged near the outlets (9, 10). 8. Air conditioning device according to claim 7, in which the blow-out direction serves to direct the outlet (9 or 10) downwards, the temperature of which is measured as high by the associated temperature sensor. 9. Air conditioning device according to one of claims 5, 7 or 8, in which the blowing direction control devices (15, 18, 20, 23) adjust the blowing direction when a predetermined period of time has elapsed since the start of operation.