JP2010151398A - Air conditioner, method of controlling air conditioner, and program for controlling air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air conditioner reflecting user's feeling even in an energy-saving operation, and expecting sufficient energy-saving effect without degrading comfort. <P>SOLUTION: This air conditioner is provided with: a temperature control part 3 for controlling an indoor temperature to a target temperature; a target temperature receiving part 4 for receiving a user set temperature T<SB>u</SB>as the target temperature T; and a target temperature changing part 5 for setting the target temperature T higher than the user set temperature T<SB>u</SB>by a first value T<SB>c</SB>in cooling, and setting the target temperature lower than the user set temperature by a second value T<SB>h</SB>in heating, after the lapse of a first prescribed time t<SB>1</SB>in a state that the indoor temperature is stabilized near the user set temperature T<SB>u</SB>. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an air conditioner having an energy saving operation function.

  In recent years, air conditioners such as air conditioners having energy saving functions have been developed in order to save electricity charges and consider the environment.

For example, Patent Document 1 stores in advance a reference temperature for performing an energy saving operation during cooling or heating, and the user set temperature is lower than the reference temperature during cooling or higher than the reference temperature during heating. In this case, there is a description that the target temperature is changed from the user set temperature to the reference temperature when the state is continued for a certain time.
JP 2005-55144 A

  However, with such a configuration, the target temperature during energy saving operation is changed to a predetermined reference temperature regardless of the user set temperature set by the user, and the user's feeling is not reflected.

  Therefore, when the difference between the user set temperature and the reference temperature is large, the user's comfort during energy saving operation may be greatly impaired.

  On the other hand, when the difference between the user set temperature and the reference temperature is small, there is a possibility that the energy saving effect cannot be expected much.

  Further, once the energy saving operation is started, the energy saving operation is continued unless the user arbitrarily operates, and the above-described problems are not solved.

  The present invention has been made in view of the above-described problems. The user's feeling is reflected even during energy-saving operation, comfort is not impaired, and a sufficient energy-saving effect can be expected. It aims at providing the air conditioner which can be performed.

  That is, the air conditioner of the present invention includes a temperature control unit that controls a room temperature to a target temperature, a target temperature reception unit that receives a user set temperature as a target temperature, and a room temperature that is stably near the user set temperature. A target temperature changing unit configured to increase the target temperature by a first value than the user set temperature during cooling and to decrease the target temperature by a second value during heating after the first predetermined time has elapsed; It is characterized by having.

  In addition, the air conditioner control method of the present invention includes a temperature control step for controlling the room temperature to a target temperature, a target temperature reception step for receiving the user set temperature as the target temperature, and the room temperature being stable near the user set temperature. Then, after the first predetermined time has passed, the target temperature is changed by a first value higher than the user set temperature during cooling and by a second value lower than the user set temperature during heating. And a step.

  Furthermore, the air conditioner control program of the present invention includes a temperature control unit that controls a room temperature to a target temperature, a target temperature receiving unit that receives a user set temperature as a target temperature, and a room temperature that is stable near the user set temperature. Then, after the first predetermined time has passed, the target temperature is changed by a first value higher than the user set temperature during cooling and by a second value lower than the user set temperature during heating. It is characterized by having the computer function as a part

  If it is such, since the target temperature at the time of energy saving operation is determined based on the user set temperature, it can be set to the target temperature reflecting the user's sense even at the time of energy saving operation. Since the difference between the set temperature and the target temperature during operation can be set to a sufficient magnitude regardless of the user set temperature, the energy saving effect can be made sufficient.

  In the case where priority is given to the user's comfort, the target temperature is changed by the target temperature changing unit from the user set temperature by a first value or by a second value, and after a second predetermined time has elapsed. A target temperature return unit that returns the target temperature to the user set temperature may be further provided, and the target temperature change unit and the target temperature return unit may be configured to change the target temperature alternately.

  As described above, according to the present invention, since the target temperature at the time of energy saving operation is determined based on the user set temperature, temperature control suitable for the user's sense is possible, and energy saving operation can be achieved. .

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows an air conditioner 100 according to this embodiment that includes a refrigeration cycle circuit RC and a control device S that acquires and controls information from various devices constituting the refrigeration cycle circuit RC.

  The refrigeration cycle circuit RC includes a compressor (not shown), a heat exchanger (condenser), an expansion valve, and a heat exchanger (evaporator) that are connected in an annular shape in this order, and a refrigerant is circulated therein. It is configured to operate a refrigeration cycle. Each device constituting the refrigeration cycle circuit RC is housed inside the outdoor unit 1 and the indoor unit 2.

  As shown in FIG. 2, the control device S is composed of an operating device and a control device main body MS. In addition, although the said control apparatus main body MS is attached to the indoor unit 1 in this embodiment, it may be provided separately.

The operating device is, for example, a remote controller R for exchanging information by the controller body and the infrared communication, at least, a user setting temperature input unit R1 for the user to input a desired user-set temperature T _u, the freezing An energy-saving operation switching unit (not shown) that switches whether to operate the cycle circuit RC with energy-saving operation is provided.

  The control device main body is a so-called computer having a CPU, a memory, an I / O channel, an AD converter, a timer, a display, etc., and the CPU and its peripheral devices operate according to a program stored in the memory, thereby It functions as the control unit 3, the target temperature receiving unit 4, the target temperature changing unit 5, the target temperature returning unit 6, and the like. The memory exhibits a function as the user set temperature storage unit 7.

Each part will be described.
The temperature control unit 3 reduces the deviation between the set target temperature T and the measured temperature measured by a temperature measuring means (not shown) provided in the room, so that the room temperature is stabilized at the target temperature T. The refrigeration cycle circuit RC is controlled.

The target temperature accepting unit 4 accepts the user set temperature Tu input by the user on the user set temperature input unit R1, it is intended to convey the target temperature T of the user set temperature T _u to the temperature controller 3 . The target temperature receiving unit 4 is also configured to store the received user set temperature _Tu in the user set temperature storage unit 7.

The target temperature changing unit 5, the temperature controlled user set temperature T _u as the target temperature T by the temperature control unit 3, the first predetermined time in the timer from the room temperature is stable and the user set temperature T _u after t ₁ has elapsed, and changes the target temperature T from the user set temperature T _u. More specifically, the target temperature changing unit 5 is in the cooling high as the first value T _c than the user set temperature T _u, during heating by a second value T _h than the user set temperature T _u It is configured to be low.

Here, the first predetermined time t ₁ , the first value T _c , and the second value _Th will be described. The user stored in the user set temperature storage unit 7 is the target temperature changing unit 5. refers to the setting temperature T _u, it is those that are selected on the basis of the respective user set temperature T _u, a first predetermined time of t _1, a first value T _c, the second value T _h is A value that does not impair the user's comfort obtained by the subject test or the like is set. In this embodiment, the first predetermined time _{t 1,} the first value _{T c,} the second value _{T h} is constant are selected. Therefore, the target temperature T during the energy saving operation is different for each different user set temperature _Tu . Further, the length of the first predetermined time t ₁ will be described more specifically. The length is such that the user has become accustomed to the cooling / heating operation at the user set temperature _Tu when the first predetermined time t ₁ ends. Is determined by subject test. For example, after evaluating the temperature by a subject test in five stages and starting the cooling / heating operation at the user set temperature _Tu , many subjects do not feel hot or cold and begin to feel that the room temperature is just right. The time up to may be the first predetermined time.

The target tempering unit 6, after the target temperature changing section 5 has elapsed the second predetermined time t ₂ is in the timer changes the target temperature T from the user set temperature T _u, the said target temperature T user The temperature is returned to the user set temperature _Tu stored in the set temperature storage unit 7. The second predetermined time t ₂ also have selected the value of improving the comfort of the more user by the subject test, and the like. In this embodiment, the second predetermined time t ₂ also constant has been set.
If it will be described more specifically a second length of the predetermined time t _2, and cooling and heating operations only different set temperatures first value T _c or a _second value T _h from the user set temperature T _u is started, the user It is set to the time until the body is about to stabilize at room temperature. Also, we evaluated in 5 steps by the subject tested cold-warm, the time to start feeling a lot of hot or cold subject from the start of the energy-saving operation may be set as the second predetermined time t _2.
The target temperature changing unit 5 and the target temperature returning unit 6 are configured to change the target temperature T alternately. Therefore, the temperature control unit 3 alternately performs normal operation and energy saving operation with the user set temperature _Tu .

  Next, the operation at the time of temperature control of the air conditioner 100 according to the present embodiment will be described with reference to the flowchart of FIG.

FIG. 2 is a flowchart showing the overall flow of temperature control during cooling operation. After the power is turned on by the user and the cooling operation is started, the user set temperature _Tu is input by the remote controller R by the user. Here, when there is no user input, the previously set user set temperature _Tu is used as it is (step S1).

Then, the target temperature reception section 4 is transmitted to the temperature controller 3 user set temperature T _u received from the user as the setting temperature T. Here, the user set temperature _Tu at this time is also stored in the user set temperature storage unit 7 (step S2).

Temperature control unit 3, so that the room temperature at the user set temperature T _u stabilized, the difference between the user set temperature T _u and the indoor temperature is direction to begin the control of the refrigeration cycle circuit RC to be smaller (step S3).

From this point, it is considered a normal operation is started, the normal operation time measurement t _n is started by the timer (step S4).

If the user of the energy saving mode has not been selected by the remote controller R, the normal operation time measurement t _n does not shift to the energy-saving operation for continuously reset (step S5).

When the room temperature is stable at a temperature lower than the user set temperature + 1 ° C. (step S6), and the measured normal operation time t _n exceeds the first predetermined time t ₁ of 20 minutes Shifts to the energy saving operation mode (step S7).

  Next, description will be made with reference to FIG. 3 which is a flowchart showing the flow of the operation in the energy saving operation mode.

When energy-saving operation is started, the target temperature changing unit 5, to raise the target temperature T used in the temperature control unit 3 from the user set temperature T _u by a first value T _c (step S8). In this example, the first value _Tc is set to 2 ° C., and is changed by 2 ° C. higher than the respective user set temperature _Tu . That is, the target temperature T during the energy saving operation is different for each user set temperature _Tu .

When energy-saving operation by the temperature controller 3 is started, energy-saving operation time t _e the measurement is started by the timer (step S9).

After the energy saving operation is started, special control such as cooling freezing prevention control, oil recovery control, and oil leveling control is performed on the refrigeration cycle circuit RC (step S10), or the user sets a new user set temperature _Tu. Is input (step S11), the energy saving operation mode is terminated and the normal operation mode is restored (step S13).

When there is no special control or new input of the user set temperature T _u as described above, when the energy saving operation time t _e exceeds the second predetermined time t ₂ of 20 minutes (step S12), the target temperature return portion 6 is returned to the user set temperature T _u stored target temperature T in the user set temperature storing unit 7, shifts again to the normal operation mode (step S13).

Therefore, unless exceptional processing occurs, normal operation and energy saving operation are alternately performed as shown in the flowcharts of FIGS. A temperature control by the user set temperature T _u, a temperature control by only high temperature first value T _c from the user set temperature T _u are alternately performed in other words.

At the time of heating, the determination of whether at room temperature is stable in terms and S6 is set only to a temperature lower second value T _h to the user set temperature T _u, rt user set temperature Tu-1 The only difference is that it is determined depending on whether it is stable at a temperature higher than ° C. The temperature control operation is substantially the same as that during cooling.

Thus, according to the air conditioner 100 of the present embodiment, the target temperature T during energy saving operation is determined based on the user set temperature _Tu set by the user, and the target used during energy saving operation is determined. Even at the temperature T, temperature control reflecting the user's feeling is possible, and the user's comfort can be maintained. In addition, by setting the first value _Tc and the second value _Th to a value having a sufficiently large value, the target temperature T during energy saving operation can be obtained at any user set temperature _Tu . Since the difference can be increased, a sufficient energy saving effect can be expected.

Further, when the target temperature return unit 6 performs a long-time energy saving operation, the target temperature T is returned to the original user set temperature _Tu , so that the user's Comfort can be further improved.

In addition, after the temperature is stabilized by the user set temperature _Tu by the target temperature return unit 6 and the temperature is stabilized and the first predetermined time t _{1 has} elapsed, the target temperature changing unit 5 again sets the target temperature. Since the temperature T is changed from the user set temperature _Tu , the normal operation and the energy saving operation are performed alternately. Therefore, since driving with emphasis on the user's comfort and driving with emphasis on energy saving are performed alternately, driving with both comfort and energy saving driving can be achieved.

  Other embodiments will be described.

  In the embodiment, the first value and the second value are constants, but may be variables that change according to the user set temperature. For example, when the user set temperatures are 28 ° C., 27 ° C., and 26 ° C. during cooling, the first values are 4 ° C., 3 ° C., and 3 ° C., respectively, and the target temperatures during energy saving operation are 24 ° C., respectively. , 24 ° C, 23 ° C. That is, the first value may be set based on the user set temperature set to a different value so that the set temperature during energy saving operation is partially or entirely different. The same applies to the second value.

  In the embodiment, the first predetermined time and the second predetermined time are constants. However, the first predetermined time and the second predetermined time may be variables that change the values depending on the user set temperature, the operation duration, or the like.

  In order to determine whether the room temperature is stable, for example, it may be determined based on the fact that the room temperature fluctuates by several percent above and below the set temperature. In other words, it may be determined that the room temperature is stable for a long time at a temperature in the vicinity of the set temperature.

  The position where the control device main body is mounted is not particularly limited. It may be incorporated in the indoor unit or provided in the remote control.

  In addition, various modifications and combinations can be made without departing from the spirit of the present invention.

Schematic which shows one Embodiment of the air conditioner of this invention. The functional block diagram which shows the control apparatus in the embodiment. The flowchart which shows the whole flow of the air_conditionaing | cooling operation in the same embodiment. The flowchart which shows the flow of the energy saving operation of the air_conditionaing | cooling operation in the embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 ... Air conditioner 4 ... Target temperature reception part 5 ... Target temperature change part 6 ... Set temperature return part T ... Set temperature _Tu ... User set temperature _Tc ... first value _T h · · · second value _t 1 · · · first predetermined time _t 2 · · · second predetermined time

Claims (4)

A temperature control unit for controlling the room temperature to a target temperature;
A target temperature receiving unit that receives a user set temperature as a target temperature;
After the first predetermined time has elapsed after the room temperature has stabilized in the vicinity of the user set temperature, the target temperature is set higher than the user set temperature by a first value during cooling, and from the user set temperature during heating. An air conditioner comprising a target temperature changing unit that lowers only the second value. A target temperature at which the target temperature is returned to the user set temperature after the second predetermined time has elapsed after the target temperature is changed by the target temperature changing unit by a first value higher or lower by a second value than the user set temperature. A return part,
The air conditioner according to claim 1, wherein the target temperature changing unit and the target temperature returning unit are configured to change the target temperature alternately. A temperature control step for controlling the room temperature to a target temperature;
A target temperature receiving step for receiving the user set temperature as the target temperature;
After the first predetermined time has elapsed after the room temperature has stabilized in the vicinity of the user set temperature, the target temperature is set higher than the user set temperature by a first value during cooling, and from the user set temperature during heating. And a target temperature changing step for lowering the second value by a second value. A temperature control unit for controlling the room temperature to a target temperature;
A target temperature receiving unit that receives a user set temperature as a target temperature;
After the first predetermined time has elapsed after the room temperature has stabilized in the vicinity of the user set temperature, the target temperature is set higher than the user set temperature by a first value during cooling, and from the user set temperature during heating. A program for controlling an air conditioner that causes a computer to function as a target temperature changing unit that lowers the second value by a second value.