ES2441355T3 - Air conditioner - Google Patents

Abstract

An air conditioner, comprising: a ventilation part (6) for ventilating a room; a first non-volatile memory (11) that stores operating information representing an operating state of the ventilation part (6) at a previous operating time; a control part (7) that controls the operation of the ventilation part (6) on a basis of the operating information stored in the first non-volatile memory (11) at a current defunction moment; an indoor unit (1) having the first non-volatile memory (11), a receiving part (13) that receives a command signal to command the operational state of the ventilation part (6) and a transmission part (13) which transmits an operating information signal representing the operating information stored in the first non-volatile memory; and characterized in that the air conditioner further comprises a wireless remote controller (3) that has a transmission part (31) that transmits the confusing signal and a reception part (31) that receives the operation information signal, whereby the controller Wireless remote (3), when the operating state is restored to the initial state, it obtains the operating information stored in the first non-volatile memory (11), so as to avoid that the operating information differs between the wireless remote controller (3 ) and the indoor unit (1).

Description

Air conditioner

5 Technical field

The present invention relates to air conditioners, and in particular, to an air conditioner having a ventilation part that ventilates a room.

Prior art

Conventionally, an air conditioner is disclosed, where an indoor unit and an outdoor unit are connected to each other through a ventilation tube, and one end of the ventilation tube is connected to the inlet side and the outlet side of a fan. of air supplied to the outdoor unit switchable

15 using a shock absorber (JP 2003-176944 A).

In the conventional air conditioner, the ventilation tube is connected to the inlet side of the air fan, and the air fan introduces the indoor air through the ventilation tube and the indoor unit and discharges the air to the outside of the room in a first position of the damper switch. On the other hand, in a second position of the damper switch, the ventilation tube is connected to the outlet side of the air fan, and the air fan supplies the outside air to the interior of the room through the ventilation tube and the indoor unit In this way, by discharging the indoor air to the outside of the room or supplying the outside air to the interior of the room by means of the air conditioner, the indoor air ventilation operation is performed.

The air conditioner also includes a remote controller that receives a command from an operating state of an operator and transmits a signal corresponding to the command of the indoor unit, and a control part that controls the operating status of the air conditioner in accordance with The signal from the remote controller. When the operator instructs the remote controller to perform the ventilation operation, the control part that receives the signal from the remote controller controls the damper and the air fan to perform the ventilation operation.

However, in a case where a power failure occurs while the ventilation operation is taking place, the conventional air conditioner enters a stop state, even if the power failure is recovered

35 electrical and sometimes fails to return to the ventilation operation before the power failure. On the other hand, when the battery of the remote controller is replaced while the ventilation operation is performed, the remote controller is set back to its initial state, and a signal of the initial state is transmitted to the indoor unit, sometimes stopping the conditioner of air.

Recently, all buildings have the obligation to be equipped with a mechanical ventilation installation, in principle, as a countermeasure to the so-called sick house syndrome due to the revision of the Construction Standards Act.

However, there is a problem with conventional air conditioners, which sometimes stop the operation of

45 ventilation even though they have not received the command to stop the ventilation operation by the operator, as described above, and therefore, are not able to function as a mechanical ventilation installation provided by the Law on Construction Standards

In addition, EP 0837 289 A2 refers to an air conditioner and JP 2001 099477A refers to a ventilation fan.

Description of the invention

An object of the present invention is to provide an air conditioner capable of avoiding the disadvantage that

The ventilation operation is stopped even if no stop command of the ventilation operation has been received from the operator.

In order to achieve the above object, an air conditioner according to claim 1 is provided.

According to the previous construction, when the ventilation part was in the operational state at the previous operating time, the operation of the ventilation part is controlled in the operational state by the control part at the current operating time on the basis of the operating information which is the operating information stored in the first non-volatile memory and represents the operational state. For example, by controlling the ventilation part so that the operating state becomes identical to the operating state at the previous operating time, even when the ventilation operation stops due to, for example, a power failure, the ventilation operation can be resumed at the current time

of operation after recovery of the power failure. Therefore, the disadvantage of the ventilation operation being stopped even if no command has been received to stop the ventilation operation as in the conventional case can be avoided.

5 According to the invention, the air conditioner also comprises:

an indoor unit having the first non-volatile memory, a receiving part that receives a command signal to command the operating state of the ventilation part and a transmission part that transmits an operating information signal representing the operating information stored in the first non-volatile memory; and a wireless remote controller that has a transmission part that transmits the command signal and a reception part that receives the operation information signal.

According to the embodiment, the command signal is transmitted from the transmission part of the remote controller over

15 the base of the input to the remote controller by the operator. The command signal is received by the receiving part of the indoor unit, and the ventilation part is controlled to the operating state corresponding to the command signal.

On the other hand, the operating information signal representing the operating information stored in the first non-volatile memory of the indoor unit is transmitted by the transmission part of the indoor unit. The operating information signal is received by the receiving part of the remote control. Therefore, as the wireless remote controller can obtain information identical to the operating information stored in the first non-volatile memory of the indoor unit, even when the operating state is adjusted back to the initial state due to, for example, the remote control battery replacement, it

25 can prevent the operating information from differing between the remote controller and the indoor unit. Therefore, the disadvantage can be avoided that the initial state command signal is transmitted from the remote controller returns to the initial state of the indoor unit and the operation of the ventilation part stops even if there is no stop command. the ventilation operation that is entered into the remote controller.

In an embodiment of the invention, the air conditioner further comprises:

an outdoor unit that has a second non-volatile memory that stores the operating information of the ventilation part at the previous operating time.

In accordance with the previous embodiment, the operating information of the ventilation part at the previous time of operation is stored in the second non-volatile memory of the outdoor unit. Therefore, the operating information of the ventilation part can be saved as a backup in the preparation of the lack of operating information in the first non-volatile memory due to, for example, failure or replacement of the unit inside.

In one embodiment of the invention, the remote control comprises:

a third non-volatile memory that stores the operating information of the ventilation part at the previous operating time, and

The transmission part transmits the operating information signal representing the operating information stored in the third non-volatile memory of the indoor unit.

According to the previous embodiment, the operating information of the ventilation part at the previous time of operation is stored in the third non-volatile memory of the remote control. The operating information signal representing the operating information stored in the third non-volatile memory is transmitted to the indoor unit through the transmission part. Through this operation, the operating information of the ventilation part at the previous time of operation can be made as a backup in preparation for the lack of operating information in the first or second memories not

55 volatile due to, for example, replacement or other cause of electrical components.

In one embodiment of the invention, when the receiving part of the indoor unit does not receive the command signal for the execution of the ventilation command of the ventilation part at the current operating time and the operational state of the ventilation part at the previous operation it is represented by the operating information stored in the first non-volatile memory, the second non-volatile memory or the third non-volatile memory executes the ventilation, the control part controls the operation of the ventilation part on a basis of the stored operating information, so that the operational state becomes identical to the operational state at the time of previous operation.

65 According to the previous embodiment, when the receiving part does not receive the command signal that orders the ventilation execution of the ventilation part at the current operating time, reference is made to the operating information stored in the first memory not volatile, the second non-volatile memory or the third non-volatile memory. When the operating state of the ventilation part at the previous operating time, represented by the operating information stored in the first non-volatile memory, the second non-volatile memory or the third non-volatile memory indicates the execution of the ventilation, controlling the

5 operation of the ventilation part to enter the operating state identical to the operating state at the previous operating time based on the stored operating information. Therefore, when, for example, the previous operation has stopped due to, for example, a power failure, the ventilation operation can be resumed as in the previous operation, even if the ventilation execution command is not received from the operator at the time of resuming the current operation. It is noted that the control part can control the operation of the ventilation part at the current operating time to enter the operating state identical to at least part of the operating state at the previous operating time.

As described above, the air conditioner of the present invention includes the ventilation part.

15 that ventilates the room, the first non-volatile memory that stores the operating information that represents the operating state of the ventilation part at the time of previous operation, and the control part that controls the operation of the ventilation part on the basis to the operating information stored in the first non-volatile memory at the current operating time. Therefore, even if the ventilation operation is stopped due to, for example, a power failure, the ventilation operation can be resumed at the current operating time after the recovery of the power failure. Therefore, the disadvantage of the ventilation operation being stopped after the power failure recovery can be avoided, as in the conventional case.

Brief description of the drawings

The present invention will be more fully understood from the detailed description given below and from the accompanying drawings given by way of illustration only, and therefore, are not intended to limit the present invention, and where:

Figure 1 is a schematic view showing an air conditioner according to a first embodiment of the present invention; Figure 2 is a flow chart showing the processing performed by a control part of the air conditioner of the first embodiment; Figure 3 is a schematic view showing an air conditioner according to a second

Embodiment of the present invention; Figure 4A is a flow chart showing the processing performed by a control part of the air conditioner of the second embodiment; Figure 4B is a flow chart showing the processing performed by a control part of the air conditioner of the second embodiment.

Detailed description of the invention

The present invention will now be described in detail by the embodiments shown in the drawings.

45 (First embodiment)

Figure 1 is a schematic view showing an air conditioner according to a first embodiment of the present invention.

The air conditioner includes an indoor unit 1 placed on a wall or similar surface of a room, and an outdoor unit 2 that is placed outside the room, and the indoor unit 1 and the outdoor unit 2 are connected to each other through of a refrigerant pipe 5, a vent pipe 6 and a connection wiring 8.

55 The indoor unit 1 has an indoor heat exchanger (not shown) to which a refrigerant is supplied from the outdoor unit 2 through the refrigerant pipe 5 and a cross-circulation fan that guides the wind to the indoor heat exchanger. On the other hand, an opening is provided that communicates with the ventilation tube 6 in an air passage generated by the cross flow fan, forming a structure where the outside air is supplied to the interior of a room and the indoor air is discharged. outside the room through the opening.

On the other hand, the indoor unit 1 has an infrared ray transmission and reception part 13 that transmits and receives an infrared signal between the part and a wireless remote controller 3, such as a remote controller described below. In detail, the infrared ray transmission and reception part 13 receives signals from

65 command for the command of operating states of an operating mode, a preset temperature, a preset air volume, a wind direction, etc., from the wireless remote controller 3 and transmits an operation information signal representing the state operating from the air conditioner to the wireless remote controller 3. As described above, the infrared transmission and reception part 13 functions as a reception part and a transmission part.

5 Wireless remote controller 3 has an input part to which the operating states of the programmed temperature, preset air volume, wind direction, etc. are commanded and entered. by an operator in the room. The wireless remote controller 3 also has an infrared transmitting and receiving part 31 that transmits and receives an infrared signal between the part and the indoor unit 1 to transmit a command signal corresponding to the input to the input part to the indoor unit 1 and receiving an operation information signal relating to the operation information of the indoor unit 1. As described above, the infrared ray transmitting and receiving part 31 functions as a receiving part and a part of transmission.

Indoor unit 1 also includes a first EEPROM memory (electrically read-only memory

15 programmable and erasable) 11 as a first non-volatile memory that stores the operating information that represents the operating status of the air conditioner at the current operating time.

The indoor unit 1 also includes a communication information part that performs information communication between the unit and the outdoor unit 2 to transmit the command signal received from the wireless remote controller 3 to the outdoor unit 2. The information communication part transmits an operating information signal representing the operating information (information identical to the information stored in the first EEPROM memory 11) at the time of operation to the outdoor unit 2 and receives the operating information signal relating to the conditioner of air at the previous time of operation of the outdoor unit 2.

25 The outdoor unit 2 includes an outdoor unit 21 and a humidifying unit 22. A compressor that compresses a refrigerant, an expander that reduces the pressure by adiabatic expansion of the refrigerant, an outdoor heat exchanger that exchanges heat between the refrigerant and the outside air and a four-way switching valve for switching between the cooling operation and the heating operation by changing the direction of the refrigerant flow are housed in the outdoor unit 21. Moreover, the electrical components are housed in the unit exterior 21, and the electrical components include a power circuit of the air conditioner and a control part 7 constructed of a CPU. The CPU reads a control program stored in a ROM and executes the control of the air conditioner. The refrigerant pipe 5 is connected to the outdoor unit 21 and is supplied with the refrigerant at the temperature and pressure prescribed by

35 four-way switching valve change control and compressor control capability.

On the other hand, a humidification rotor formed of a moisture adsorbent material such as zeolite, an air fan to which the humidification rotor is selectively connected at the inlet side, and a connection damper that connects the ventilation tube 6 to the inlet side or to the outlet side of the air fan in a switching manner are housed in the humidification unit 22 of the outdoor unit 2. In a first position of the switch of the connection damper, the ventilation tube 6 is connected to the Inlet side of the air fan, and the air fan takes the indoor air through the vent tube 6 and the indoor unit 1 and discharges the air out of the room. On the other hand, in a second position of the connection damper switch, the vent tube 6 is connected to the outlet side of the air fan, and the

The air fan supplies the humidified air outdoors through the humidification rotor or the outside air that does not pass through the humidification rotor to the room through the ventilation tube 6 and the indoor unit 1.

The operation of ventilation of the indoor air is therefore carried out by discharging the indoor air to the outside of the room through the indoor unit 1, the ventilation tube 6 and the outdoor unit 2 or by supplying the outdoor air to the room. That is, a ventilation part is constructed of an opening formed in the ventilation duct of the indoor unit, the ventilation tube 6 communicating with the opening, the air fan connected to the ventilation tube 6 and the connection damper which changes the connection of the vent tube 6 to the air fan.

55 The outdoor unit 2 further includes an information communication part that performs the information communication between the unit and the indoor unit 1 to receive the command signal, which has been transmitted from the wireless remote controller 3 and received by the party transmission and reception 13 of the indoor unit 1, from the information communication part of the indoor unit 1. A second EEPROM 23 that stores the operating information at the current operating time is also provided for the information communication part that received from indoor unit 1.

The control part 7 provided for the electrical components of the outdoor unit 21 performs the capacity control and the start / stop of the compressor, the change of the four-way switching valve, the capacity control and the start / stop of the air fan and the change of the shock absorber connection on the base 65 of the command signal from the indoor unit 1. On the other hand, the control part 7 controls the storage and reading to and from the first EEPROM memory 11 , transmission and reception to and from the controller

Wireless remote 3 and storage and reading to and from the second EEPROM 23 regarding the operating information of the air conditioner.

The ventilation operation by means of the air conditioner of the previous construction is described with reference to the flowchart of Figure 2. The flowchart shows the processing executed by the control part 7.

First, the energy of the air conditioner is activated to start the air conditioner (step S1). The control part 7 is started by activating the energy and determines if the command signal of the contents to turn on the ventilation operation has been received from the wireless remote controller 3 (step S2). When it is determined that the command signal to turn on the ventilation operation has been received from the wireless remote controller 3, the information representing the ignition state of the ventilation operation is stored in the first EEPROM memory 11 of the indoor unit 1 (step S3). Subsequently, the information representing the ignition status of the ventilation operation is stored in the second

15 EEPROM memory 23 of outdoor unit 2 (step S4).

Subsequently, it is determined whether the command signal from the wireless remote control 3 has the contents that represent the on state of the ventilation operation or of the contents that represent the off state of the ventilation operation (step S5).

When it is determined that the command signal to turn on the ventilation operation is not received from the wireless remote controller 3 in step S2, the information stored in the first EEPROM memory 11 of the indoor unit 1 is read to determine whether the operation of ventilation has been at the previous time of the operation or not (step S7). When the information stored in the first EEPROM memory 11 is the

25 information on the state of ignition of the ventilation operation and it is determined that the ventilation operation has been at the previous operating time, the program flow passes to step S5.

When the information stored in the first EEPROM memory 11 is the shutdown status information of the ventilation operation in step S7, the information stored in the second EEPROM memory 23 is read to determine if the ventilation operation has been in the previous one. Moment of operation (step S10) or not. When it is determined that the information stored in the second EEPROM memory 23 is the information on the ignition status of the ventilation operation and the ventilation operation has been at the previous operating time, the information representing the ignition status of the operation ventilation is stored in the first EEPROM memory 11 (step S11). Subsequently, the operating information that

35 represents the on state of the ventilation operation is transmitted to the wireless remote controller 3 (step S12). Next, the program flow advances to step S5.

When the information stored in the second EEPROM memory 23 is the information of the shutdown status of the ventilation operation in step S10, the program flow advances to step S5.

When the command signal from the wireless remote controller 3 has the contents that represent the power state of the ventilation operation in step S5, the ventilation operation is executed (step S6). That is, the connection damper of the outdoor unit 2 is switched to connect the vent tube 6 to the inlet side or to the outlet side of the air fan, and the air fan starts up.

45 When the command signal from the wireless remote controller 3 has the contents that represent the shutdown state of the ventilation operation in step S5, it is determined whether the information stored in the first EEPROM memory 11 represents the power on state of the ventilation operation or not (step S8). When the information stored in the first EEPROM memory 11 represents the on state of the ventilation operation, the program flow advances to step S6 to execute the ventilation operation.

When the information stored in the first EEPROM memory 11 is the shutdown state of the ventilation operation in step S8, the ventilation operation is set to a stop state (step S9).

55 After step S6 and step S9, the program flow returns to step S2 to determine whether or not the command signal of the ignition status of the ventilation operation has been received from the wireless remote controller 3.

As described above, when the command to perform the ventilation operation is entered in the remote controller by the operator, in the air conditioner of the present embodiment, the ventilation operation is performed in accordance with the command signal from the remote controller Even in a case where the command to perform the ventilation operation is not entered in the remote controller by the operator, the ventilation operation can be resumed based on the information on the power state of the operation stored in the first memory EEPROM 11 or in the second EEPROM 23 when the ventilation operation 65 has been performed at the previous operating time. Therefore, even if the ventilation operation stops, for example, due to a power failure, the ventilation operation identical to

the operation at the previous time of the operation before the power failure at the current operation after the recovery of the power failure, even if the operator does not introduce the ignition of the ventilation operation. Therefore, the conventional disadvantage that the ventilation operation cannot be resumed after recovery from a power failure is effectively avoided and

5 puts in the stop state, even if no command has been received to stop the ventilation operation. It is observed that the state of adjustment of the air volume, wind direction, etc. other than the operating state can be adjusted back, at the current time of operation, to its initial state or to the state at the previous time of operation by also storing the adjustment state of the previous operating moment in the first EEPROM memory eleven.

On the other hand, as the signal representing the operating information stored in the first EEPROM memory 11 that is transmitted to the wireless remote controller 3 with respect to the operating information of the ventilation part, it is possible to prevent the operating information from differing between the indoor unit 1 and the wireless remote controller 3, even when the wireless remote controller 3 adjusts again to the state

15 initial due to, for example, battery replacement. Therefore, the disadvantage can be avoided that the command signal in the initial state is transmitted to the indoor unit 1 and the operation of the ventilation part stops even if there is no command to stop the ventilation operation being introduced by the operator on the wireless remote controller 3.

In addition, since a backup is made by storing the operating information that is stored in the first EEPROM memory 11 of the indoor unit 1 and also in the second EEPROM memory 23 of the outdoor unit 2, the ventilation operation is it can continue on the basis of the operating information stored in the second EEPROM 23, even if the operating information of the first EEPROM memory 11 disappears due to, for example, a problem or replacement of the indoor unit 1.

25 As described above, the air conditioner of the present embodiment can continue the execution of the ventilation operation under the on condition until receiving the command to turn off the ventilation operation by the operator, even when there is a power failure, indoor unit 1 problems, initialization of wireless remote controller 3 or similar. As a result, the air conditioner can function as a fan prescribed in the provision of the Building Regulations Act.

(Second embodiment)

Figure 3 is a schematic view showing an air conditioner according to another embodiment of the present invention.

As shown in Figure 3, an indoor unit 1 and an outdoor unit 2 are connected to each other through a refrigerant pipe 5, a vent tube 6 and a connection wiring 8 in the air conditioner of the second embodiment , as in the air conditioner of the first embodiment.

In the air conditioner of the present embodiment, the operating information at the current operating time is stored in a third EEPROM 33, in addition to the first EEPROM memory 11 and the second EEPROM memory 23. With this arrangement, even if the operating information stored in the first and second EEPROMs 11 and 23 disappear due to a problem with the indoor unit and the unit

Outside, the replacement of electrical components or the like, a ventilation operation similar to that of the previous operating moment can be performed based on the operating information stored in the third EEPROM memory 33.

In the present embodiment, components similar to the components of the first embodiment are designated with the same reference numbers as those used in the first embodiment, and a detailed description thereof is not provided.

In the air conditioner of the present embodiment, the wireless remote controller 3 has the third EEPROM 33. The operating information received from the indoor unit 1 is written to the third memory.

55 EEPROM 33, and the operating information to be transmitted to the indoor unit 1 is read from the third EEPROM memory 33. The wireless remote controller 3 transmits the operating information read from the third EEPROM 33 to the indoor unit 1, in addition to the command signal corresponding to the input to the input part by the operator by means of an infrared transmitting and receiving part 31 that transmits and receives an infrared signal between the controller and the indoor unit 1. Moreover, the information of operation to be written in the third EEPROM memory 33 is received from the indoor unit 1 by means of the infrared ray transmission and reception part 31. The wireless remote controller 3 also includes an input part to be introduced by the operator into the room, as in the case of the wireless remote controller 3 of the first embodiment.

65 On the other hand, the infrared ray transmission and reception part 13 of the indoor unit 1 receives the operation information signal representing the operating information stored in the third EEPROM memory 33 from the wireless remote controller 3, in addition to the command signal that emits operating mode commands, preset temperature, preset air volume, wind direction, etc., or operating conditions of the air conditioner. On the other hand, the infrared ray transmission and reception part 13 of the indoor unit 1 transmits an operation information signal, which represents the

5 air conditioner operating information to be stored in the third EEPROM memory 33, to the wireless remote controller 3.

Figures 4A and 4B are flow charts showing the processing executed in the control part 7 of the air conditioner of the present embodiment. The ventilation operation of the air conditioner of the present embodiment is described with reference to the flow charts of Figures 4A and 4B.

First, the energy of the air conditioner is turned on to start the air conditioner (step S1) and turn on the control part 7, and it is determined whether or not the command signal of the ignition contents has been received. of the ventilation operation from the wireless remote controller 3 (step S2).

15 When it is determined that the command signal to turn on the ventilation operation has been received from the wireless remote controller 3, the information representing the power state of the ventilation operation is stored in the first EEPROM memory 11 of the indoor unit 1 (step S3). Subsequently, the information representing the ignition state of the ventilation operation is stored in the second EEPROM memory 23 of the outdoor unit 2 (step S4). In addition, the information representing the on state of the ventilation operation is transmitted to the wireless remote controller 3, and the information representing the on state of the ventilation operation is stored in the third EEPROM memory 33 of the wireless remote controller ( step S5).

Subsequently, it is determined whether the command signal from the wireless remote control 3 has the contents that

25 represent the on state of the ventilation operation or the contents representing the off state of the ventilation operation (step S6).

When it is determined that the command signal to turn on the ventilation operation has not been received from the wireless remote controller 3 in step S2, the information stored in the first EEPROM memory 11 of the indoor unit 1 is read to determine if it is on or not the ventilation operation at the previous operating time (step S8). When the information stored in the first EEPROM memory 11 is the information on the state of ignition of the ventilation operation and it is determined that the ventilation operation was on at the previous operating time, the program flow proceeds to step S6.

35 When the information stored in the first EEPROM memory 11 is the shutdown status information of the ventilation operation in step S8, the information stored in the second EEPROM memory 23 is read to determine whether or not the ventilation operation was on at the previous time of operation (step S11). When it is determined that the information stored in the second EEPROM memory 23 is the information on the ignition status of the ventilation operation and the ventilation operation was turned on at the previous operating time, the information representing the ignition status of the operation ventilation is stored in the first EEPROM memory 11 (step S12). Subsequently, the operating information representing the on state of the ventilation operation is transmitted to the wireless remote controller 3, and the information representing the on state of the ventilation operation is stored in the third EEPROM memory 33 of the remote controller. wireless (step S13). Then the

45 program flow advances to step S6.

When the information stored in the second EEPROM memory 23 is the shutdown status information of the ventilation operation in step S11, the wireless remote controller 3 is commanded to read the information stored in the third EEPROM memory 33 and transmit the information to the indoor unit, and it is determined whether or not the ventilation operation was on at the previous operating time based on the information received by the indoor unit (step S14). When the information stored in the third EEPROM memory 33 is the information on the state of ignition of the ventilation operation and it is determined that the ventilation operation was on at the time of previous operation, the information representing the state of ignition of the operation ventilation is stored in the first EEPROM memory 11

55 (step S15). Subsequently, the information representing the ignition state of the ventilation operation is stored in the second EEPROM memory 23 of the outdoor unit 2 (step S16). Next, the program flow advances to step S6.

When the information stored in the third EEPROM memory 33 represents the shutdown state of the ventilation operation and it is determined that the ventilation operation was turned off at the previous operating time in step S14, the program flow advances to step S6 .

When the command signal from the wireless remote controller 3 has the contents that represent the ignition state of the ventilation operation in step S6, the ventilation operation is executed (step

65 S7).

When the command signal from the wireless remote controller 3 has the contents that represent the shutdown state of the ventilation operation in step S6, it is determined whether or not the information stored in the first EEPROM memory 11 represents the power on state of the ventilation operation (step S9). When the information stored in the first EEPROM 11 represents the power-on status of the operation

5 of ventilation, the program flow returns to step S7 to execute the ventilation operation.

When the information stored in the first EEPROM memory 11 is the shutdown state of the ventilation operation in step S9, the ventilation operation is put into a stop state (step S10)

After step S7 and step S10, the program flow returns to step S2 to determine whether the command signal of the on state of the ventilation operation has been received or not from the wireless remote controller 3.

As described above, when the command to perform the ventilation operation is entered into the

The operator remote control, in the air conditioner of the present embodiment, the ventilation operation is performed according to the command signal from the remote controller. Even in a case where the command to perform the ventilation operation is not entered in the remote control by the operator, the ventilation operation can be resumed on the basis of the information on the status of the operation stored in the first EEPROM 11, the second EEPROM 23 or the third EEPROM 33 when the ventilation operation was performed at the previous operation. Therefore, even if the information stored in the first EEPROM 11 and the second EEPROM 23 disappears due to, for example, the replacement, malfunction or the like of the electrical components, the air conditioner of the present embodiment may resume ventilation operation similar to that of the previous operating moment at the current operating time, regardless of an operator input.

25 Although the information representing the on state of the ventilation operation is stored in the third EEPROM 33 by receiving the command signal to turn on the ventilation operation from the wireless remote controller 3 and to subsequently transmit the information that represents the ignition state of the ventilation operation to the wireless remote controller 3 (step S5) in the second embodiment, it is acceptable to store the information representing the ignition state of the ventilation operation in the third EEPROM 33 when the input of the switching on the ventilation operation by the operator to the wireless remote controller 3. In this case, step S5 can be eliminated.

On the other hand, when the information on the state of ignition of the ventilation operation is stored in the

35 second EEPROM 23 or in the third EEPROM 33, once the information is stored in the first EEPROM 11 and, subsequently, the ventilation operation is executed by reading the information stored in the first EEPROM 11 in the first and second realizations However, the ventilation operation can be executed immediately by reading the ignition status information of the ventilation operation stored in the second EEPROM 23 or in the third EEPROM 33.

On the other hand, although the first EEPROM 11 is intended as a first non-volatile memory for the indoor unit 1, the first non-volatile memory need not be provided for the indoor unit 1, but must be provided for the outdoor unit 2 or in the controller wireless remote 3. For example, it is acceptable to remove the first EEPROM 11 from the indoor unit 1 and make the second EEPROM 23 from the outdoor unit 2 or the

45 third EEPROM 33 of the wireless remote controller 3 function as the first EEPROM 11.

On the other hand, in the first and second embodiments, the ventilation means at least supply outside air to a room and discharge indoor air to the outside of the room. On the other hand, the supply of outside air to a room and the discharge of indoor air to the outside of the room can be performed alternatively on the basis of the operator's entry condition or another condition.

On the other hand, although the information of the on and off status of the ventilation operation at the previous operating time is stored in the first, second and third EEPROMs 11, 23 and 33 in the first and second embodiments, it is acceptable to store the distinction information between the

55 air inlet and discharge, air volume, wind direction, presence or absence of humidification operation, preset temperature, etc. of the ventilation operation, in addition to the information on the on or off status of the ventilation operation.

On the other hand, although the ventilation tube 6 is connected to the humidification unit 22 which has the humidification rotor in the outdoor unit 2, the ventilation tube 6 can be connected to an air fan unit that does not have any rotor humidifier

On the other hand, the ventilation part may be constructed of a ventilation tube, from which one end communicates with the indoor unit and the other end opens towards the outside of the room and a fan that is

65 provides for the indoor unit and discharges indoor air to the outside of the room or guides the outside air into the interior of the room through the ventilation tube.

On the other hand, non-volatile memory can be provided by a RAM or a magnetic recording device, such as a hard disk, in addition to EEPROM and, in summary, it is required to be a memory that can maintain the storage state, even When the power goes out.

5 On the other hand, even if the air conditioner is constituted by connecting the indoor unit 1 with the outdoor unit 2 through the ventilation pipe 6, the refrigerant pipe 5 and the connection wiring 8, it is acceptable to form integrally the indoor unit 1 with the outdoor unit 2.

Having described the embodiments of the invention in this way, it will be obvious that they may vary from

10 many ways. Such variations should not be considered as a deviation from the scope of the invention, provided that the variations are made in accordance with the following claims.

Claims (3)

1. An air conditioner, comprising: 5 a ventilation part (6) to ventilate a room; a first non-volatile memory (11) that stores operating information representing an operating state of the ventilation part (6) at a previous operating time; a control part (7) that controls the operation of the ventilation part (6) on a basis of the operating information stored in the first non-volatile memory (11) at a time of 10 current operation; an indoor unit (1) having the first non-volatile memory (11), a receiving part (13) that receives a command signal to command the operational state of the ventilation part (6) and a transmission part (13) that transmits an operating information signal representing the operating information stored in the first non-volatile memory; and characterized in that the conditioner of The air further comprises a wireless remote controller (3) that has a transmission part (31) that transmits the command signal and a reception part (31) that receives the operation information signal, whereby the wireless remote controller (3), when the operating state is restored to the initial state, it obtains the operating information stored in the first non-volatile memory (11), so that it is avoided 20 that the operating information differs between the wireless remote controller (3) and the indoor unit (1). 2. The air conditioner according to claim 1, comprising: an outdoor unit (2) having a second non-volatile memory (23) that stores the operating information of the ventilation part (6) at the previous operating time. 3. The air conditioner according to claim 2, wherein the wireless remote controller (3) comprises: 30 a third non-volatile memory (33) that stores the operating information of the ventilation part (6) at the previous operation time, and the transmission part (31) transmits the operation information signal representing the operating information stored in the third non-volatile memory (33) to the indoor unit (1). The air conditioner according to claim 3, wherein, when the receiving part (13) of the indoor unit does not receive the command signal for the command of the execution of the ventilation of the ventilation part (6 ) at the current operating time and the operating status of the ventilation part (6) at the previous operating time, represented by the operating information stored in the first non-volatile memory (11), the second non-volatile memory (23 ) or the third non-volatile memory (33) is the execution of the 40, the control part (7) is arranged to control the operation of the ventilation part (6) on the basis of the stored operating information, so that the operational state becomes identical to the operational state at the time of previous operation