ES2222652T3 - METHOD OF CONTROL OF THE DIRECTION OF THE AIR FLOW IN A CLIMATE CONTROL DEVICE. - Google Patents

Abstract

An air conditioner including: - an outdoor unit that has a variable capacity compressor, a four-way valve, an external heat exchanger, and an expansion valve; - an indoor unit having an indoor heat exchanger and connected to said outdoor unit, said indoor unit also having a direction change flap pivotally mounted thereon to selectively open and close an outlet hole defined therein; and - putting said air direction change fin in a closed position, in which said exit hole is closed, or a position adjacent to it during operation in dehumidification mode.

Description

Method of controlling the flow direction of air in an air conditioning device.

Background of the invention Field of the Invention

The present invention generally relates to control of an air conditioner and, in particular, although not exclusively, to a method of air direction control to control air direction or air flow during operation in dehumidification mode to increase the degree of dehumidification or to improve the feeling of cold.

Description of the related technique

During operation in dehumidification mode of a conventional air conditioner, air is introduced dehumidified inside by means of a change flap direction of the air directed downwards which is mounted in a indoor unit

However, when the change fin of air direction goes down, cold air collides directly in a resident or residents within the room and It makes them feel cold or feel upset. To make the air cold does not shock residents, it has been proposed to regulate horizontally the air direction change fin (see, For example, Japanese Patent published number 10-61999).

Although in this air conditioner the air cold does not collide directly with residents, the cold air that flows on the upper side of the room falls later and makes Feel something cold.

Recently, a conditioner has been proposed of air that uses a short circuit system where cold air coming out through an air outlet of an indoor unit is sucked directly to an air inlet by setting the change flap of air direction up. This air conditioner has the purpose of achieving a comfortable dehumidification without feeling of cold causing cold air not to crash directly into residents (see, for example, the published Japanese Patent number 9-72599).

Although this air conditioner almost eliminates the feeling of cold during operation in dehumidification, the amount of moisture that is removed with it is relatively small and its dehumidifying efficiency is low, resulting in a relatively high ultimate humidity.

Summary of the Invention

The present invention has been developed to overcome the disadvantages described above.

Therefore, an object of the present invention is to provide a method of controlling the direction of the air for an air conditioner capable of improving performance dehumidification and minimize the feeling of air flow or A feeling of cold

In carrying out the above and other objects, The air conditioner according to the present invention includes a outdoor unit that has a variable capacity compressor, a four-way valve, an external heat exchanger, and a expansion valve, and an indoor unit that has a indoor heat exchanger and connected to the outdoor unit. The indoor unit also has a direction change fin air pivotally mounted on it to open and close selectively a defined exit hole in it. Fin change of air direction is put in a closed position, in the that the exit hole is closed, or a position adjacent to during operation in dehumidification mode.

Through this construction, since the cold air or refrigerated does not crash directly into a person or people inside from the room, the feeling of cold and performance is eliminated Dehumidification can be improved at a low cost.

It is preferred to put an indoor fan mounted in the indoor unit at an average air flow or lower when the air direction change fin is put in position closed or the position adjacent to it, making it possible to eliminate The feeling of cold.

Advantageously, before the exchange fin air direction is put in the closed position or position adjacent to it, the indoor fan is set to a minimum flow of air and turns on and off. Doing so, no drops form of frost around an exit hole of the indoor unit during dehumidification.

Again advantageously, when the fin of change of air direction is put in the closed position or the position adjacent to it, the compressor frequency of variable capacity, leading to a reduction in input.

Conveniently, before the exchange fin air direction is put in the closed position or position adjacent to it, when the intake temperature detected is greater than the temperature setting, the operation is carried out in cooling mode, therefore performing a dehumidification effective and preventing frost drops from forming around the exit hole when closed. In addition, the use of operation in cooling mode and operation in mode dehumidification extends the range of use, making it possible for the Air conditioner operate efficiently.

Preferably, before the exchange fin air direction is put in the closed position or position adjacent to it, when the intake temperature detected is greater than the temperature setting, the air flow of the indoor fan and variable capacity compressor will Increase in frequency. In doing so, a effective dehumidification before closing the exit hole, thus avoiding the creation of frost drops around the hole Exit during closing.

Again preferably, when the humidity detected is less than the humidity setting, the change fin of air direction is put in the closed position or the position adjacent to her. In this case, drops are unlikely to adhere of frost to the indoor unit near the exit hole and then fall to the ground, thus making it possible to perform Desirably the operation in dehumidification mode during the exit hole closure.

The humidity setting is changed according to at least one of the intake temperature and the tube temperature.

When the detected tube temperature is higher than the default temperature, the direction change fin of the air is put in the closed position or the position adjacent to her, thereby avoiding the creation of frost drops around of the exit hole.

The default temperature is changed according to the intake temperature

Immediately after putting the fin of change of air direction in the closed position or position adjacent to it, the angle of inclination of the change fin of air direction is maintained for a predetermined time, thus avoiding the screeching of the change of direction fin from air.

Although the temperature of the tube varies due to obstruction of the indoor unit due to dust, the amount of refrigerant, or the total length of the pipes, the indoor unit can be stably controlled by determining the desired temperature of the tube according to the detected intake temperature and humidity detected

Advantageously, when the temperature detected of the tube is higher than the desired temperature of the tube, the expansion valve opening, or the frequency is increased of the variable capacity compressor. In contrast, when the tube detected temperature is lower than desired temperature of the tube, the opening of the expansion valve is increased, or The frequency of the variable capacity compressor is reduced. By doing so, the operation in dehumidification mode is performed  efficiently.

Brief description of the drawings

The above and other objects and features of the present invention will be more apparent from the description following of your preferred embodiments with reference to annexed drawings, in which all similar parts are designated with similar reference numbers, and where:

Figure 1 is a circuit diagram that shows a refrigeration cycle of an air conditioner in which is used a method of air direction control according to the present invention.

Figure 2 is a block diagram of a control circuit in the air conditioner of figure 1 by which controls the frequency of the compressor and the opening of the expansion valve.

Figure 3 is a schematic sectional view. vertical of an indoor unit.

Figure 4 is a flow chart indicating the control during operation in dehumidification mode.

Figure 5 is a schematic view showing the movements of an air direction change fin in a cooling region during operation in mode dehumidification

Figure 6 is a schematic view showing the movements of the air direction change fin in a drying region during operation in mode dehumidification

Figure 7 is a flow chart indicating the control when any of the conditions to lead to carry out a "No breeze and dry" operation in the region of dried

Figure 8 is a flow chart indicating the control of a motor-driven expansion valve when meets any of the conditions to perform an operation of "No breeze and dry."

Figure 9 is a flow chart indicating the compressor frequency control when any of the the conditions to carry out an operation of "No breeze and dry".

Figure 10 is a timing chart. when the air direction control method is used according to the present invention.

Figure 11A is a schematic view that shows a flow of cold air in the "drying region 1" when "Auto Air Direction" has been set during Operation in dehumidification mode.

Figure 11B is a view similar to Figure 11A, showing a cold air flow in the "Drying Region 2 "when an indoor fan is turned on and off during Dehumidification mode operation.

And Figure 11C is a view similar to Figure 11 A, showing a cold air flow in the "Drying Region 2 "during" No breeze and dry "operation.

Detailed description of the preferred embodiments

This request is based on request number 10-354195 filed on December 14, 1998 in Japan, whose content is incorporated here by reference.

Figure 1 shows a refrigeration cycle of an air conditioner that employs a method of controlling the air direction according to the present invention. This conditioner of air includes an outdoor unit 2 and an indoor unit 4 connected to each other by connecting pipes 6.

As shown in Figure 1, the unit exterior 2 includes a variable capacity (frequency) compressor 8 moved by inverter, a four way valve 10 for selection heating and cooling mode, a heat exchanger outside 12, an auxiliary choke 14, and a valve expansion moved by motor 16, while indoor unit 4 includes an internal heat exchanger 18. In this figure, the reference numbers 20 and 22 denote an outside fan and a indoor fan, respectively, and reference numbers 24, 26 and 28 denote a tube temperature sensor, a sensor intake air temperature, and a humidity sensor, respectively, all of which are mounted on the unit interior 4.

With the refrigeration cycle set as represented in figure 1, the refrigerant from the compressor 8 during operation in cooling or dehumidification mode flows through the four-way valve 10 and reaches the external heat exchanger 12, in which heat is exchanged with the outside air and the refrigerant condenses. Coolant condensate then goes through auxiliary choke 14, so that the refrigerant pressure is reduced and the refrigerant is converts to an easily evaporable state. Coolant low pressure condensate then passes through the expansion valve driven by engine 16, so that the coolant pressure is reduce more. The opening of the motor-driven expansion valve 16 is controlled by pulses, for example, by a stepper motor depending on the load of the room to cool or dehumidify, and so low pressure refrigerant flows to indoor unit 4 a through the connecting tube 6 at a flow proportional to the load of the room. The refrigerant then evaporates in the internal heat exchanger 18, and the gasified refrigerant returns thus by the connecting tube 6, by the four-way valve 10, and re-enters compressor 8.

A method of controlling the frequency of compressor and motor-driven expansion valve opening described below with reference to figure 2, a block diagram of the corresponding control circuit. Note that the differential temperature ΔT is the temperature Ambient Tr minus temperature setting Ts.

In the indoor unit 4, first a output (ambient temperature) of the air temperature sensor intake 26 in a temperature sensing circuit of the room 40, which in turn sends a temperature signal (Tr) to a differential temperature calculator 42. So substantially simultaneous, an adjustment discriminator 44 determines the temperature (Ts) and the operating mode set by a circuit of operation selection 38, and supplies this information to the differential temperature calculator 42. The calculator differential temperature 42 thus calculates the differential temperature ΔT (= Tr-Ts), and sends a signal of differential temperature to a signal transmission circuit fifty.

A discriminator on / off 46 Determine whether the indoor unit 4 has been turned on or off. The regime capacity of indoor unit 4 is stored in a regime capacity memory 48.

A signal of memory capacity speed rating 48, the differential temperature signal of the differential temperature calculator 42, and a mode signal operating and discriminator on / off status signal on / off 46 are passed through the transmission circuit of signal 50 from indoor unit 4 to a signal receiving circuit 52 of the outdoor unit 2. The signals received by the circuit signal reception 52 are sent to a frequency calculator from compressor 54 and to a valve opening calculator 56.

Based on the regime capacity signal, the differential temperature signal, the operating mode signal and the on / off status signal from the unit inside 4, the frequency calculator of the compressor 54 performs a default operation to calculate the frequency value (nº) (for example, an integer from 0 to 8).

Based on the regime capacity signal, the differential temperature signal, the operating mode signal, and the on / off status signal from the unit inside 4, the valve opening calculator 56 performs also another predetermined operation to determine the aperture of the motor-driven expansion valve 16.

The result of the operation performed by the frequency calculator of compressor 54 and operation performed by the valve opening calculator 56 apply as a frequency signal and a valve opening signal a a compressor excitation circuit (not shown) and a valve excitation circuit (not shown), respectively, to control the frequency of the compressor 8 and the motor valve expansion valve opening 16.

Since then, the frequency N1 of the compressor 8 and the valve opening of the motor-driven expansion valve 16 are calculated for each predetermined cycle, based on the signal of regime capacity, the differential temperature signal, the operating mode signal, and on / off status signal so that the frequency of the compressor 8 and the opening of the 16 motor driven expansion valve can be controlled properly.

The operation in heating mode is not a main objective of the present invention and, therefore, its Description is omitted.

Figure 3 illustrates the indoor unit 4, in the that a plurality of intake holes 30 have been formed in a upper portion and a front portion of the main body, while an exit hole 32 has formed in a portion lower main body.

The intake holes 30 and the hole outlet 32 communicate with each other by an air passage 34, in which the inner heat exchanger 18 and the fan are arranged inside 22. An air direction change fin 36 is pivotally mounted on the main body in its portion bottom to selectively open and close the outlet hole 32. The temperature sensor of the tube 24 is mounted and kept in contact with the bottom of a plurality of blocks heat exchanger of the internal heat exchanger 18, while that the intake air temperature sensor 26 and the sensor moisture 28 are juxtaposed with each other in a front portion of the main body.

The air direction control method according to the present invention during operation in the mode of Dehumidification is explained later.

Figure 4 illustrates the control method during Operation in dehumidification mode. In step S1, you first calculate the differential temperature ΔT between the temperature environment detected by the air temperature sensor of intake 26 and the Ts temperature setting set by the user, and then the frequency of the compressor and the valve opening based on differential temperature ΔT, as described above. In step S2, the temperature differential ΔT is compared with t1 (for example, + 0.5 ° C). Yes the differential temperature ΔT is greater than t1, it takes perform an operation in cooling mode in step S3, and if the differential temperature ΔT is less than or equal to t1, the procedure proceeds to step S4, in which the temperature differential ΔT is compared with t2 (for example, -0.5 ° C). Yes the differential temperature ΔT is greater than t2, it takes perform an operation for "drying region 1" in step S5. In contrast, if the differential temperature ΔT is less than or equal to t2, the procedure proceeds to step S6, in the that the differential temperature ΔT is compared with t3 (for example, -2.5 ° C). If the differential temperature ΔT is higher than t3, an operation is carried out for the "drying region 2 "in step S7, and if the differential temperature ΔT is less than or equal to t3, compressor 8 stops in step S8. Then, it is determined in step S9 if a predetermined time t4 (for example, approximately three minutes) has elapsed or not after compressor stop 8. If the decision in step S9 is YES, the differential temperature ΔT is again compared to T3 in step S10. If the differential temperature ΔT is higher that t3, compressor 8 starts again in step S11

It should be noted that the temperature sampling of the intake air is performed during each predetermined cycle (for example, about a second), and the conditions operating conditions are determined by repeatedly calculating the temperature differential ΔT.

During a cooling operation in mode dehumidification, when the user says "Address of the Air-Auto "using a remote controller (no represented), the air direction change fin 36 scales between the upper limit position and the limit position lower, as depicted in figure 5, except when the indoor fan 22 is stopped. It is also possible that the user set the angle of inclination of the change flap of air direction 36 at one of the five different angles with the Use of the remote controller. In a region near the "region of drying 1 ", when the intake air temperature detected by the intake air temperature sensor 26 approaches the temperature setting, compressor frequency is reduced extremely (the number of frequency is, for example, 1), while the indoor fan 22 is set to an air flow that goes from "Hi (high speed) "to" Lo (low speed) ".

In the "drying region 1", overlooking the absolute humidity reduction, compressor frequency number 8 it is set, for example, to 3, while the indoor fan 22 it is put at an average air flow or "Super Wind" less than "The". If you put "Address of Auto-air ", the direction change fin of the air 36 is generally directed horizontally, as depicted in figure 6, to reduce the feeling of cold. By other part, if "Adjusting the address of the air ", the user may select one of five angles different inclination of the direction change fin of the air 36 using the remote controller, as in the operation of cooling in dehumidification mode.

In the "Drying Region 2", overlooking the relative humidity reduction, the compressor frequency number 8 is set, for example, to 2, while the operation is set "Super wind and dry" or a "No breeze and dry" operation depending on the operating conditions, as explained more ahead.

As depicted in Figure 6, during "Super wind and dry" operation, the indoor fan 22 creates a stream of light or loose air to provide a flow of Extremely low air and turns on and off. When selected "Air-Auto Direction", the change flap of air direction 36 is put in a position (this position is later called the position directed down) directed further down from the lower limit position in the operation for "drying region 1", thus making cold air or Refrigerated does not directly crash into the resident or residents. Yes "Air direction adjustment" is selected, it is possible that the user put the air direction change fin 36 on one of five different positions between the limit position top and downward position using the controller remote. The on / off operation of the indoor fan 22 is, for example, such that the indoor fan 22 is turned on and turn off to repeat a 15 minute operation and a 10 stop minutes, alternatively.

On the other hand, during the operation of "Without breeze and dry ", the indoor fan 22 creates a stream of light or loose air to provide extremely high airflow under, and in any of "Address of Auto-air "and" Adjusting the direction of the air ", the air direction change fin 36 is set to one position (reset position) to close the hole of exit 32 or other position in its proximity. The operation of "Sin breeze and dry "has the following characteristics.

(1) Provide comfort without imparting a cold feeling to the resident or residents (a feeling of absence of air flow).

(2) Reduce heat exchange to reduce the temperature of the tubes, thereby improving the ability to dehumidification (high power dehumidification).

(3) Minimize the cooling capacity to limit the ambient temperature reduction to a minimum (continuous dehumidification performance).

The "No breeze and dry" operation is performed when the decision in step S6 is YES and when one of the conditions set forth in Table 1 continues, for example, during more than five minutes in "Drying Region 2" (step S7).

TABLE 1

one

When approximately ten have elapsed minutes after none of the conditions are met above, it is determined whether or not any of they.

The conditions to exit the operation "Without breeze and dry "are explained below with reference to a graph represented in figure 7.

After fulfilling any of the conditions "No breeze" and after setting the direction change fin of air 36 in the reset position or a position near it for a predetermined time (for example, approximately five minutes), it is determined in step S21 if the temperature of the tube detected by the tube 24 temperature sensor is lower or not at (the desired temperature of the tube (A) minus three). If the decision in step S21 is YES, the operation of "No breeze and dry "is terminated immediately in step S22, and if the decision in step S21 is No, the procedure proceeds to step S23, in the which determines whether the temperature of the tube is lower or not than (the desired tube temperature (A) minus two). If the decision in the step S23 is YES, the "No breeze and dry" operation continues for thirty minutes and then stop at step S24. In as opposed, if the decision in step S23 is NO, the procedure proceeds to step S25, in which the operation of "Without breeze and dry "continues for sixty minutes and then it for.

The desired tube temperature (A) is determined based on Table 2 below using the air temperature of intake detected by the air temperature sensor of intake 26 and relative humidity detected by the sensor humidity 28.

TABLE 2

2

During the operation of "No breeze and dry ", if the condition to determine the desired temperature of the tube (A) has changed and if any condition is maintained, by example, for about two minutes, said condition for determining the desired temperature of the tube (A).

The control of the valve opening motor-driven expansion 16 is explained later with reference to a flow chart represented in figure 8.

After an interval of a time default after receipt of a signal indicating that the condition to control the operation of "No breeze and dry" has been completed in step S31, it is determined in step S32 if the tube temperature detected by the tube temperature sensor 24 is or not greater than (the desired temperature of the tube (A) plus one). If the detected tube temperature is higher than (the temperature desired tube (A) plus one), the expansion valve moved by motor 16 is controlled so that it is closed, for example, with four pulses in step S33, and the determination of the opening of valve is made in step S34. At this time, if the opening of valve is greater than or equal to the established minimum pulses (for example, 60 pulses), the procedure returns to step S32, and if the valve opening is lower than the minimum set pulses, it is set to the minimum pulses established in step S35. For other part, if the detected temperature of the tube is less than or equal to (the desired temperature of the tube (A) plus one) in step S32, is determine in step S36 if the detected tube temperature is or not greater than (the desired temperature of the tube (A) minus one). If the tube detected temperature is less than or equal to (the desired temperature of the tube (A) minus one), the valve motor-driven expansion 16 is controlled so that it opens, by  example, for eight pulses in step S37. In contrast, if the tube detected temperature is higher than (the desired temperature of tube (A) minus one), the motor-driven expansion valve 16 is locked in the opening present in step S38.

The frequency control of compressor 8 is explain below with reference to a flowchart represented in figure 9.

After an interval of a time default after receipt of a signal indicating that the condition to control the operation of "No breeze and dry" has been completed in step S41, it is determined in step S42 if the tube temperature detected by the tube temperature sensor 24 is or not greater than (the desired temperature of the tube (A) plus one). If the detected tube temperature is higher than (the temperature desired from tube (A) plus one), the frequency of compressor 8 is increases 1 Hz in step S43, and it is determined in step S44 if a Compressor frequency increase is or not less than 5 Hz. If the increase in compressor frequency is less than 5 Hz, the procedure returns to step S42 after a while default (for example, approximately three minutes), and if the increase is greater than or equal to 5 Hz, the procedure proceeds to the step S48 in which the frequency 8 is locked to the present frequency. On the other hand, if the detected temperature of the tube is lower or equal to (the desired temperature of the tube (A) plus one) in the step S42, it is determined in step S45 if the detected temperature of the tube is or not greater than (the desired temperature of the tube (A) less one). If the detected tube temperature is less than or equal to (the desired tube temperature (A) minus one), the frequency of the Compressor 8 is reduced by 1 Hz in step S46, and the procedure proceeds to step S47 in which it is determined whether a decrease in the compressor frequency is less than 5 Hz. Whether the decrease Compressor frequency is less than 5 Hz, the procedure return to step S45 after a predetermined time has elapsed (for example, approximately three minutes). In contrast, yes the decrease is greater than or equal to 5 Hz, the compressor 8 is locked at the frequency present in step S48. On the other hand, if the tube detected temperature is higher than (the desired temperature of the tube (A) minus one) in step S45, the procedure advances to step S48 in which the compressor 8 is also locked to the present frequency

Figure 10 illustrates an example of diagrams of timing when the address control method is used of the air according to the present invention.

Figures 11A, 11B and 11C illustrate flows of cold air during operation in dehumidification mode when the air direction control method is used according to the present invention In particular, Figure 11A illustrates the flow of cold air in the "drying region 1" when set "Air-Auto Direction", Figure 11B the cold air flow in the "Drying Region 2" when the indoor fan turns on and off, figure 11C the flow of cold air in the "Drying Region 2" during the operation of "No breeze and dry."

In the "drying region 1", although it is removed relatively high humidity, cold or refrigerated air flows horizontally on the upper side inside the room, as is depicted in figure 11. Therefore, the resident feel cold from above, but the feeling of cold is reduced considerably. When the indoor fan turns on and turn off in "Drying Region 2", the resident feels cold for down to some extent, but there is little cold air flow. During "No breeze and dry" operation, the resident has no feeling cold below.

Although the present invention has been described in connection with your preferred embodiments with reference to attached drawings, it should be noted that several changes and modifications They will be apparent to those skilled in the art.

Claims (14)

1. An air conditioner including: an outdoor unit that has a compressor of variable capacity, a four-way valve, a external heat exchanger, and an expansion valve; an indoor unit that has a indoor heat exchanger and connected to said outdoor unit, said indoor unit also having a change flap of air direction pivotally mounted on it to open and selectively close a defined exit hole in it; Y putting said direction change fin of the air in a closed position, in which said exit hole is closed, or a position adjacent to it during the operation in dehumidification mode. 2. The air conditioner according to the claim 1, further including a mounted indoor fan in said indoor unit, where said indoor fan is set to an average air flow or less when said change fin of air direction is put in the closed position or the position adjacent to her. 3. The air conditioner according to the claim 1, further including a mounted indoor fan in said indoor unit, where before said exchange fin air direction is put in the closed position or position adjacent to it, said indoor fan is put to a flow minimum air and turns on and off. 4. The air conditioner according to the claim 1, further including a mounted indoor fan in said indoor unit, where said frequency is reduced variable capacity compressor when said change fin of air direction is put in the closed position or the position adjacent to her. 5. The air conditioner according to the claim 1, wherein before said change fin of air direction is put in the closed position or position adjacent to it, when the intake temperature detected is greater than a temperature setting, an operation is carried out in cooling mode. 6. The air conditioner according to the claim 1, further including a mounted indoor fan in said indoor unit, where before said exchange fin air direction is put in the closed position or position adjacent to it, when the intake temperature detected is greater than a temperature setting, the air flow of said indoor fan and said variable capacity compressor It increases in frequency. 7. The air conditioner according to the claim 1, wherein when the detected humidity is less than one humidity adjustment, said air direction change fin is puts in the closed position or the position adjacent to it. 8. The air conditioner according to the claim 7, wherein the humidity setting is changed according to the minus one of the intake temperature and the temperature of the tube. 9. The air conditioner according to the claim 1, wherein when the detected tube temperature is greater than the predetermined temperature, said change fin of air direction is put in the closed position or the position adjacent to her. 10. The air conditioner according to the claim 9, wherein the predetermined temperature is changed according to the intake temperature. 11. The air conditioner according to the claim 1, wherein immediately after said fin of air direction change has been put in the closed position or the position adjacent to it, the angle of inclination of said air direction change fin is maintained for a while predetermined. 12. The air conditioner according to the claim 1, wherein the desired tube temperature is determined according to the detected intake temperature and humidity detected 13. The air conditioner according to the claim 1, wherein when the detected tube temperature is greater than the desired tube temperature, the opening of said expansion valve, and when the detected temperature of the tube is lower than the desired tube temperature, it increases the opening of said expansion valve. 14. The air conditioner according to the claim 1, wherein when the detected tube temperature is higher than the desired tube temperature, the frequency of said variable capacity compressor, and when the tube detected temperature is lower than desired temperature of the tube, the frequency of said capacity compressor is reduced variable.