JP2014109385A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner which enables a user to realize energy saving performance.SOLUTION: An air conditioner 10 has: an operation part 30 for a user to set an operating condition of the air conditioner 10; an input part 34 where upper limit electricity charges or electric energy used for operating the air conditioner 10 is inputted by the user; a residual quantity calculation part 16 for calculating a residual quantity of available electricity charges or electric energy on the basis of the upper limit electricity charges or electric energy inputted to the input part and an electric energy consumed by the air conditioner 10 in operation; an operable time calculation part 18 for calculating an operable time when operation by using the residual quantity of available electricity charges or electric power calculated by the residual quantity calculation part 16 is possible; and a display part 36 for displaying the operable time calculated by the operable time calculation part 18 when operation starts or during operation of the air conditioner 10.

Description

  The present invention relates to an air conditioner in which operating conditions can be set by a user.

  In recent years, it has been desired to perform energy-saving operation of air conditioners. For example, in the case of the air conditioner described in Patent Document 1, information necessary for executing the energy saving operation is displayed on the display screen of a remote controller for remotely operating the air conditioner. If the operating condition is set via the remote controller based on this information, the user can execute the energy saving operation.

JP 2011-33285 A

  However, in the case of the air conditioner described in Patent Document 1, the air conditioner can execute the energy-saving operation, but the user does not satisfy the operating condition so that the air conditioner executes the energy-saving operation according to the instruction of the air conditioner. Because the settings are made, it is difficult for the user to obtain satisfaction that contributed to energy-saving operation, that is, it is difficult to realize energy saving.

  Then, this invention makes it a subject to provide the air conditioner with which an air conditioner can perform an energy saving operation, and a user can realize energy saving.

In order to solve the above problems, according to an aspect of the present invention,
An air conditioner,
An operation unit for the user to set the operating conditions of the air conditioner;
An input unit in which an upper limit electricity cost or electric energy used for operation of the air conditioner is input by the user;
A remaining amount calculation unit that calculates the remaining available electricity cost or electric energy based on the upper limit electricity cost or electric energy input to the input unit and the electric energy consumed by the operating air conditioner;
A drivable time calculating unit that calculates a drivable time that can be operated using the remaining available electricity cost or power amount calculated by the remaining amount calculating unit;
An air conditioner is provided that includes a display unit that displays the drivable time calculated by the drivable time calculation unit at the start or during operation of the air conditioner.

  According to the present invention, the air conditioner can perform energy saving operation, and the user can realize energy saving.

The figure which shows schematically the air conditioner which concerns on one embodiment of this invention. Diagram showing the configuration of the air conditioner and remote controller The figure which shows the display screen of the display section of the remote controller which displays the upper limit electricity bill Diagram for explaining how to calculate the driveable time The figure which shows the display screen of the display section of the remote controller which displays the operation possible time The figure which shows the display screen of the display part of the remote controller which displays the time until an air conditioner stops operation.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 schematically shows an air conditioner according to an embodiment of the present invention.

  As shown in FIG. 1, the air conditioner 10 of this Embodiment has the remote controller 30 as an operation part for a user to set the operating condition of the air conditioner 10. As shown in FIG. The air conditioner 10 and the remote controller 30 are configured to be capable of bidirectional communication.

  For example, a signal for setting the operating condition of the air conditioner 10 (for example, a signal for starting or stopping the operation, a signal for changing the set temperature, a signal for changing the operation mode such as cooling or heating) Are output from the remote controller 30 to the air conditioner 10. On the other hand, for example, information on the current operating state (for example, set temperature, wind direction, air volume, etc.) of the air conditioner 10 is output from the air conditioner 10 to the remote controller 30.

  Moreover, the air conditioner 10 of this Embodiment is comprised so that a user can drive the air conditioner 10 with little power consumption. That is, the air conditioner 10 supports the user so that the user can perform energy-saving operation.

  Specifically, the air conditioner 10 is configured so that a user can determine an upper limit electricity cost until the operation stops at the start of the operation or during the operation.

  In addition, the air conditioner 10 calculates the remaining electricity bill that can be used based on the amount of power consumed by the air conditioner 10 (power consumption amount) after the user determines the upper limit electricity bill. It is configured to present to the user a time during which operation can be performed using the remaining electricity bill (operable time).

  The structure of the air conditioner 10 and the remote controller 30 for that is shown by FIG. The air conditioner 10 includes a communication unit 12 for two-way communication with the remote controller 30, a power consumption detection unit 14 that detects the power consumption of the air conditioner 10, and a remaining amount calculation unit 16 that calculates the remaining electricity cost. And a drivable time calculation unit 18 that calculates a drivable time, and a storage unit 20. On the other hand, the remote controller 30 includes a communication unit 32 for two-way communication with the air conditioner 10, an input unit 34 to which an upper limit electric charge desired by the user is input, and an operating time for presenting to the user. And a display unit 36.

  The input unit 34 of the remote controller 30 to which the upper limit electricity bill is input by the user has an input button 40 provided on the main body 38 of the remote controller 30, for example, as shown in FIG. The display unit 36 includes a display screen 42 provided on the front surface of the main body 38 of the remote controller 30, for example.

  When the user inputs a desired upper limit electricity bill to the remote controller 30, for example, as shown in FIG. 3, the upper limit electricity bill 42 a is displayed on the display screen 42 of the display unit 36 of the remote controller 30. In FIG. 3, for example, “100 yen” is displayed on the display screen 42 as the upper limit electricity bill 42 a. When the user operates the up and down buttons 40a and 40b of the input button 40, the upper limit electricity bill 42a displayed on the display screen 42 increases or decreases. When the user presses the enter button 40c of the input button 40 in a state where the desired upper limit electricity bill 42a is displayed on the display screen 42, the upper limit electricity bill 42a displayed on the display screen 42 is input to the remote controller 30. Input to the unit 34. In addition, the upper limit electricity bill 42a displayed on the display screen 42 is an approximate electricity bill for one operation.

  The remote controller 30 transmits to the air conditioner 10 via the communication unit 32 a signal corresponding to the upper limit electricity bill desired by the user, which is input to the input unit 34.

  When the communication unit 12 of the air conditioner 10 receives a signal corresponding to the upper limit electricity bill from the remote controller 30, the power consumption detection unit 14 of the air conditioner 10 starts detecting the power consumption. That is, the power consumption detection unit 14 starts detecting the power consumption amount of the air conditioner 10 after the user determines the upper limit electricity bill.

  When the power consumption detection unit 14 starts detecting the power consumption, the remaining amount calculation unit 16 of the air conditioner 10 uses the remaining power charges that can be used based on the power consumption detected by the power consumption detection unit 14. Is calculated.

  Specifically, the remaining amount calculation unit 16 of the air conditioner 10 is a signal that the air conditioner 10 corresponds to the upper limit electricity bill from the remote controller 30 based on the power consumption detected by the power consumption detection unit 14. The electricity bill used after receiving is calculated. For example, the air conditioner 10 holds information on the electricity cost per unit power in the storage unit 20 and calculates an electricity cost corresponding to the power consumption based on the information.

  Further, the remaining amount calculation unit 16 is configured to calculate the remaining usable electricity bill by subtracting the electricity bill corresponding to the power consumption from the upper limit electricity bill desired by the user.

  The operable time calculation unit 18 of the air conditioner 10 calculates an operable time during which the air conditioner 10 can be operated using the remaining usable electricity cost calculated by the remaining amount calculation unit 16. It is configured.

  Specifically, as shown in FIG. 4, the drivable time calculation unit 18 calculates the drivable time for each timing T (n) (n is an integer) that repeats after a certain period (for example, 1 hour). To do.

  A case where the driveable time is calculated at the timing T (n) will be described as an example. In order to facilitate the explanation, the electric charge in the period P (n) between the timing T (n) and the timing T (n−1) immediately before the timing T (n), that is, the period P (n) immediately after the end is expressed as C ( n), and the electricity bill per unit time in the period P (n) is Cs (n). Further, the remaining usable electricity bill at timing T (n) is Cr (n).

  The electricity bill C (n) in the period P (n) is the remaining calculated at the timing T (n) from the remaining electricity bill Cr (n−1) calculated by the remaining amount calculator 16 at the timing T (n−1). It can be calculated by subtracting the electricity bill Cr (n). The electricity bill Cs (n) per unit time in the period P (n) can be calculated by dividing the electricity bill C (n) in the period P (n) by the time in the period P (n).

  The driveable time calculation unit 18 calculates the electricity bill Cs (n) per unit time calculated by smoothing the electricity bill Cs (n) per unit time in the period P (n) immediately after the end at the timing T (n). ) Is calculated by dividing the remaining available electricity bill Cr (n) by the smooth value Cs (n) ′.

Formula 1 is a formula for calculating a smooth value Cs (n) ′ of the electricity bill Cs (n) per unit time in the period P (n).

  Each of α and β in Equation 1 is a weighting factor (first and second weighting factors) and is a number such that the sum thereof is 1. For example, α and β are each 0.5.

  As shown in Equation 1, the smooth value Cs (n) ′ of the electricity bill Cs (n) per unit time in the period P (n) is the electricity bill Cs (n) per unit time in the period P (n). And the weighting coefficient α are integrated to calculate a first integrated value (first term on the right side), and the electric charge Cs (n−1) per unit time in the previous period P (n−1). Calculated by adding the smoothed value Cs (n−1) ′ and the weighting coefficient β to calculate the second integrated value (second term on the right side) and summing the first and second integrated values. The

As shown in Formula 2, the operable time t (n) at the timing T (n) is calculated by taking the remaining electricity bill Cr (n) at the timing T (n) per unit time in the period P (n) immediately after the end. It is calculated by dividing by the smooth value Cs (n) ′ of the electricity bill.

  The electricity bill Cr (n) in the period P (n) corresponds to the operating state of the air conditioner 10 in the period P (n), that is, corresponds to the operating condition of the air conditioner 10 in the period P (n). Therefore, the operable time t (n) at the timing T (n) is calculated taking into account the recent operating conditions. In addition, the operable time t (n) is calculated in consideration of the operating conditions of the air conditioner 10 in the past period from the period P (n). Therefore, for example, even if the operating condition of the air conditioner 10 is changed by the user operating the remote controller 30 (for example, the set temperature is increased or decreased by the user), the operation possible time t (n) is highly accurate. Can be calculated.

  The electricity bill C (s), the electricity bill Cs (n) per unit time, and the smooth value Cs (n) ′ in each period P (n) are stored in the storage unit 20 of the air conditioner 10. .

  When the drivable time calculation unit 18 calculates the drivable time, the air conditioner 10 transmits a signal corresponding to the drivable time to the remote controller 30 via the communication unit 12.

  When the remote controller 30 receives a signal corresponding to the operable time via the communication unit 32, the remote controller 30 displays the operable time 42b on the display screen 42 of the display unit 36 as shown in FIG. In FIG. 5, “about 8 hours” is displayed as the operable time 42b. Thereby, the user can know the operation possible time of the air conditioner 10 which can be drive | operated using the upper limit electricity bill which he determined.

  During the operation of the air conditioner 10, the operable time 42b on the display screen 42 of the display unit 36 of the remote controller 30 is updated. That is, every time the operable time calculation unit 18 of the air conditioner 10 calculates a new operable time (every timing T (n)), the operable time 42b on the display screen 42 of the remote controller 30 is updated. . Thereby, the user can know the highly accurate operation possible time of the air conditioner 10 currently being performed.

  Only when the user requests, the operable time 42b may be displayed on the display screen 42 of the display unit 36 of the remote controller 30.

  In this case, for example, when the operable time calculation unit 18 of the air conditioner 10 calculates the operable time, the calculated operable time is stored in the storage unit 20. For example, when the user requests the remote controller 30 to provide the operable time by operating the input button 40, the remote controller 30 transmits a request signal for requesting the provision of the operable time to the air conditioner 10. . Upon receiving the request signal, the air conditioner 10 transmits a response signal corresponding to the operable time stored in the storage unit 20 to the remote controller 30. Then, the remote controller 30 displays the operable time 42 b on the display screen 42 based on the response signal received from the air conditioner 10. Thereby, the power consumption of the remote controller 30 can be suppressed as compared with the case where the always operable time 42 b is displayed on the display screen 42. For example, when the remote controller 30 is driven by a battery (not shown) that is detachably incorporated, it is possible to suppress consumption of the battery.

  Regarding the power consumption of the remote controller 30, the remaining amount calculator 16 that calculates the remaining electricity cost and the operable time calculator 18 that calculates the operable time of the air conditioner 10 are provided to the remote controller 30. Although it is possible to provide, it is preferable to provide in the air conditioner 10, as shown in FIG. As a result, the remote controller 30 does not consume power to calculate the remaining electricity cost and the operable time. As a result, power consumption of the remote controller 30 is suppressed.

  When the drivable time calculation unit 18 calculates a drivable time of zero, the remote controller 30 may display on the display screen 42 of the display unit 36 that the drivable time is zero. Thereby, the user can know that the electricity bill of the air conditioner 10 in operation has reached the upper limit electricity bill determined by the user.

  Instead of or in addition to displaying that the operable time is zero on the display screen 42 of the display unit 36 of the remote controller 30, the air conditioner 10 has an operable time when the operable time calculation unit 18 is zero. If calculated, the operation may be stopped. Thereby, it is suppressed that the electricity bill of the air conditioner 10 exceeds the upper limit electricity bill determined by the user. Furthermore, when the drivable time calculation unit 18 calculates zero drivable time, by not displaying the upper limit electricity bill on the display unit 36, the user is notified that the electricity bill has reached the upper limit. You can also. That is, when the driveable time calculation unit 18 calculates zero driveable time, the display unit 36 displays that the driveable time is zero, and the display of the upper limit electricity bill on the display unit 36 is turned off. By configuring the air conditioner 10 to perform at least one of an operation or an operation in which the operation of the air conditioner 10 is stopped, the user can be notified that the upper limit of the electricity bill has been reached.

  In this connection, the air conditioner 10 is configured so that the user can select whether or not the operation of the air conditioner 10 is stopped when the operable time calculation unit 18 calculates zero operable time. Also good. For example, when the user operates the input button 40 of the remote controller 30, whether the operation of the air conditioner 10 stops as the operation of the air conditioner 10 after the zero operable time is calculated is determined by the user. Selected by. Thereby, according to a user preference, the operation | movement of the air conditioner 10 after the driving | operation possible time calculation part 18 calculates zero driving | operation possible time can be determined.

  In addition, when the operation of the air conditioner 10 is stopped when the operable time calculation unit 18 calculates zero operable time, the user may be notified before the operation is stopped.

  For example, when the drivable time calculation unit 18 calculates a first predetermined time (different from zero, for example, 45 minutes) as the drivable time, a second predetermined time (which is shorter than the first predetermined time) ( For example, 30 minutes) 42c is displayed on the display screen 42 of the display unit 36 of the remote controller 30 as the time until the air conditioner 10 stops operating, as shown in FIG. Thereafter, when the second predetermined time has elapsed since the second predetermined time was displayed, the air conditioner 10 stops its operation. Thereby, the user can know the time until the air conditioner 10 stops before the operation of the air conditioner 10 stops. For example, it is suppressed that the air conditioner 10 stops suddenly and the user is surprised.

  Supplementally, since the drivable time calculated by the drivable time calculation unit 18 includes an error, the drivable time can be increased or decreased. Therefore, when the air conditioner 10 is configured to inform the user via the display unit 36 as the time until the air conditioner 10 stops as it is, the time until the air conditioner 10 stops. May increase or decrease. As a result, the user may be confused. Therefore, after notifying the user of the second predetermined time until the air conditioner 10 stops via the display unit 36, the second predetermined time from the point in time when the second predetermined time is notified. When the time has elapsed, the air conditioner 10 is stopped. Further, the remote controller 30 is configured to count down the second predetermined time after informing the user via the display unit 36 of the second predetermined time as the time until the air conditioner 10 stops. Is preferred. Thereby, after notifying the user of the second predetermined time, even if the communication connection between the air conditioner 10 and the remote controller 30 cannot be established due to a change in the location of the remote controller 30 or the like, the air conditioner 10 stops and the display of the remote controller 30 can be synchronized.

According to the present embodiment, the air conditioner 10 can perform energy saving operation, and the user can realize energy saving.

  Specifically, as shown in FIG. 5, the operating time is displayed on the display screen 42 of the display unit 36 of the remote controller 30, so that the user determines the operating conditions of the air conditioner 10 and the user himself / herself. The correlation between the upper limit electricity cost and the operable time of the air conditioner 10 can be known empirically.

  In other words, the user can efficiently and empirically know under what operating conditions the operation can be performed for a long time with a small electricity bill (ie, a small amount of electricity). In other words, it is possible to know empirically the operation conditions that can realize the energy-saving operation.

  For example, when the user operates the remote controller 30 to change the operating condition of the air conditioner 10, the power consumption of the air conditioner 10 changes (that is, the remaining usable electricity calculated by the remaining amount detection unit 16). As a result, the drivable time calculated by the drivable time calculation unit 18 changes. Therefore, the user can know that the operating condition after the change by the user does not contribute to energy saving when the operating time is reduced, while the operating time after the change is increased, You can know that the conditions contribute to energy saving.

  As described above, when the user knows the operating condition that contributes to energy saving empirically and the user sets the operating condition of the air conditioner 10, the air conditioner 10 can execute the energy saving operation. As a result, the user can get a sense of satisfaction that he / she contributes to energy-saving operation, that is, can realize energy saving.

  Although the present invention has been described with reference to the above-described embodiments, the present invention is not limited to the above-described embodiments.

  For example, in the case of the above-described embodiment, the air conditioner is configured so that the user can determine the upper limit electricity cost until the operation stops at the start of the operation or during the operation. However, the present invention is not limited to this. In other words, the air conditioner may be configured so that the user can determine the upper limit electricity bill in a plurality of consecutive operations. However, in this case, if the operation stop period between each of the plurality of operations becomes too long, it may be difficult for the user to know empirically the operation conditions that can realize the energy-saving operation.

  Further, for example, the calculation method of the operable time by the operable time calculation unit 18 of the air conditioner 10 is not limited to the above-described method, that is, the method using the mathematical expressions 1 and 2.

  The drivable time calculation unit of the air conditioner according to another embodiment is configured to calculate the drivable time for each timing repeated with a certain period. The operable time is calculated based on the remaining electricity cost at the timing for calculating the operable time and the operating condition of the air conditioner at the same timing.

  For example, the correspondence between various operating conditions of the air conditioner and the electricity cost per unit time when the air conditioner is operated under each operating condition is obtained in advance experimentally or theoretically, and the correspondence data Is stored in the storage unit of the air conditioner.

  The operable time calculation unit calculates the operable time by dividing the remaining electricity cost by the electricity cost per unit time corresponding to the operation condition.

  Thus, the present invention does not ask | require the calculation method, if the driving | operation possible time can be calculated using the remaining usable electric bill calculated by the residual amount calculation part. However, the calculation method of the above-described embodiment (that is, the method using the mathematical formulas 1 and 2) is preferable because the drivable time can be calculated with high accuracy.

  Furthermore, it is clear that the electricity bill of the air conditioner uniquely corresponds to the amount of power used by the air conditioner. Therefore, the air conditioner may be configured to calculate the operable time using the electric energy instead of the electricity bill.

  In this case, instead of the electricity bill, the input unit of the remote controller of the air conditioner is configured so that the upper limit power amount that uniquely corresponds to the upper limit electricity bill is inputted by the user. That is, the user inputs a desired upper limit power amount to the input unit of the remote controller.

  In addition, the remaining amount calculation unit of the air conditioner includes an upper limit power amount desired by the user (upper limit power amount input to the input unit) and an energy amount consumed by the operating air conditioner (power consumption amount). Based on the above, it is configured to calculate the remaining amount of power that can be used. That is, the remaining power amount that can be used is calculated by subtracting the power consumption amount from the upper limit power amount.

  Furthermore, the operable time calculation unit of the air conditioner is configured to calculate an operable time that can be operated using the remaining usable electric energy calculated by the remaining amount calculation unit.

  Furthermore, the present invention provides an air conditioner in which an operation unit for operating the air conditioner is configured separately from the main body of the air conditioner, like the air conditioner 10 and the remote controller 30 of the above-described embodiment. Not limited to. For example, it may be an air conditioner that can be placed on a floor surface in a room and can be moved, and further provided with an operation unit, an input unit, and a display unit integrally with the main body.

  The present invention is applicable to any air conditioner in which operating conditions can be set by a user.

DESCRIPTION OF SYMBOLS 10 Air conditioner 12 Communication part 14 Power consumption detection part 16 Remaining amount calculation part 18 Operation possible time calculation part 20 Storage part 30 Operation part (remote controller)
32 communication unit 34 input unit 36 display unit 42a upper limit electric charge 42b operable time 42c predetermined time P (n) period T (n) timing Cr (n) remaining electric charge Cs (n) electric charge per unit time Cs (n) 'Smooth value of electricity bill per unit time

In order to solve the above problems, according to an aspect of the present invention,
An air conditioner,
An operation unit for the user to set the operating conditions of the air conditioner;
An input unit in which an upper limit electricity cost or electric energy used for operation of the air conditioner is input by the user;
A remaining amount calculation unit that calculates the remaining available electricity cost or electric energy based on the upper limit electricity cost or electric energy input to the input unit and the electric energy consumed by the operating air conditioner;
A drivable time calculating unit that calculates a drivable time that can be operated using the remaining available electricity cost or power amount calculated by the remaining amount calculating unit;
The have been operable time calculated by the operating time computation unit have a display unit for displaying during operation start or during operation of the air conditioner,
When the drivable time calculation unit calculates drivable time within a first predetermined time different from zero, the display unit displays the second predetermined time,
Thereafter, an air conditioner is provided in which the operation of the air conditioner stops when the second predetermined time has elapsed from the time when the second predetermined time is displayed .

Claims (8)

An air conditioner,
An operation unit for the user to set the operating conditions of the air conditioner;
An input unit in which an upper limit electricity cost or electric energy used for operation of the air conditioner is input by the user;
A remaining amount calculation unit that calculates the remaining available electricity cost or electric energy based on the upper limit electricity cost or electric energy input to the input unit and the electric energy consumed by the operating air conditioner;
A drivable time calculating unit that calculates a drivable time that can be operated using the remaining available electricity cost or power amount calculated by the remaining amount calculating unit;
An air conditioner, comprising: a display unit that displays the drivable time calculated by the drivable time calculation unit at the start or during operation of the air conditioner. The operation unit consists of a remote controller capable of bidirectional communication with the air conditioner,
An input unit and a display unit are provided in the remote controller,
The air conditioner according to claim 1, wherein the remaining amount calculating unit and the operable time calculating unit are provided in the air conditioner.   The air conditioner according to claim 1 or 2, wherein the display unit is configured to display a drivable time when a user requests via the operation unit. The driving time calculation unit
It can be used with the smooth value of electricity cost or electricity consumption per unit time calculated by smoothing electricity cost or electricity consumption per unit time in the period immediately after the end at a certain time interval. Calculate the operating time by dividing the remaining electricity bill or electricity amount,
The smooth value of the electricity cost or power consumption per unit time in the period immediately after the end is obtained by integrating the electricity cost or power consumption per unit time in the period immediately after the end and the first weighting factor. A second integrated value is calculated by calculating a value, integrating a smooth value of the electricity bill or power consumption per unit time in the previous period and the second weighting factor, and calculating the first and second Calculated by summing the integrated values,
The air conditioner according to any one of claims 1 to 3, wherein the sum of the first and second weighting factors is one.   5. The input unit according to claim 1, wherein the input unit is configured to input an upper limit electricity cost or amount of electricity until the operation is stopped at the start or during operation of the air conditioner. Air conditioner as described in. When the drivable time calculator calculates a drivable time of zero,
Execute at least one of an operation in which the display unit displays that the operable time is zero, an operation to turn off the display on the display unit of the upper limit electricity bill or electric energy, or an operation to stop the operation of the air conditioner The air conditioner according to any one of claims 1 to 5.   The air conditioner of Claim 6 comprised so that a user can select whether a driving | operation of an air conditioner stops, when the driveable time calculation part calculates the zero driveable time. When the drivable time calculation unit calculates a first predetermined time different from zero as the drivable time, the display unit displays a second predetermined time shorter than the first predetermined time,
The air conditioner according to any one of claims 1 to 5, wherein after the second predetermined time is displayed, the operation of the air conditioner is stopped when the second predetermined time has elapsed. .

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