JP2005009686A - Electronic device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent erroneous receiving of standard radio wave caused by the noise of peripheral devices in an electronic device with a function of a relay device and to easily receive standard radio wave while allowing sent-out relay radio wave to easily reach a desired receiver such as a radio controlled clock. <P>SOLUTION: An air conditioner is provided with an outdoor unit 100 and an indoor unit 200 connected to the outdoor unit 100 through piping 300. The outdoor unit 100 is provided with a receiving antenna for receiving standard radio wave. When receiving the standard radio wave, the operating state (in operation/stand-by) of the air conditioner is first determined, and in the case of standing by, time data extracted from the received standard radio wave is transmitted to the indoor unit 200 through wiring 310 provided along the piping 300. The indoor unit 200 corrects the present time based on the time data received from the outdoor unit 100, and the relay radio wave including the present time data is sent out every fixed time (specifically one minute). <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic device including an indoor device and an outdoor device connected to the indoor device by a connecting member.
[0002]
[Prior art]
At present, in Japan (Japan), time data, that is, 40 kHz and 60 kHz standard radio waves including a time code are transmitted from two transmitting stations (Fukushima Prefecture and Saga Prefecture). FIG. 11 shows the format of the time code included in this standard radio wave.
[0003]
According to FIG. 11, the time code is transmitted every 60 minutes in a frame of 60 seconds per cycle. The leading marker (M) corresponds to the rise of the minute (0 seconds per minute), which is the start time of the 60-second frame. This head marker (M) is provided with a pulse width of 0.2 seconds, and the same position marker with a pulse width of 0.2 seconds is 9 seconds (P1), 19 seconds (P2), 29 seconds ( P3), 39 seconds (P4), 49 seconds (P5), and 59 seconds (P0). For this reason, two frames having a pulse width of 0.2 seconds with an interval of approximately 1 second (ie, indicated by the head marker (M) and the position marker (P0)) at the frame boundary. This means that the start of a new frame can be recognized. The head marker (M) is a frame reference marker (M), and the rising edge of the pulse indicated by the frame reference marker (M) is an accurate update of the digit of the current time. In the frame, data such as the minute, hour, total date (number of days since January 1), year (last two digits), day of the week, etc. are respectively 1 In the second, tenth and thirty to forty seconds, it is arranged in binary-coded decimal numbers. In this case, logic 1 and 0 are represented by pulses with pulse widths of 0.5 seconds and 0.8 seconds, respectively. Has been. In the frame shown in FIG. 11, data at 17:25 on the 114th day is shown.
[0004]
In recent years, so-called radio timepieces have been put to practical use that receive such standard time-code radio waves and thereby correct time data of the time counting circuit. The radio timepiece corrects the current time by receiving a standard radio wave via a built-in antenna every predetermined time, amplifying and modulating the time code, and decoding the time code.
[0005]
This type of radio-controlled timepiece is usually installed indoors, but it is often impossible to receive standard radio waves at the installation location, for example, in a steel frame house or basement. Therefore, as described in Patent Document 1, in order to eliminate restrictions on the place where the radio timepiece is installed, a standard radio wave is received, and a relay radio wave obtained by modulating the time code of the received standard radio wave with a predetermined carrier is transmitted. Proposals have been made to provide a relay device and allow the radio timepiece to receive the relay radio wave transmitted by the relay device so that the time can be reliably corrected.
[0006]
[Patent Document 1]
JP 2000-75064 A
[0007]
[Problems to be solved by the invention]
However, when the relay device is placed outdoors, there is a problem that the transmitted relay radio wave is difficult to reach indoors. On the other hand, when placing a relay device indoors, the installation location is limited, such as having to place it by the window, and it is harder to receive standard radio waves than when placing it outdoors and erroneous reception occurs. There was a problem that it was easy.
[0008]
In view of the above circumstances, an object of the present invention is to make it easy for an electronic device having a function of a relay device to easily receive a standard radio wave and to transmit a relay radio wave to be transmitted to a desired receiving device such as a radio clock.
[0009]
[Means for Solving the Problems]
In order to solve the above problem, the invention according to claim 1
An indoor unit (for example, the indoor unit 200 in FIG. 1), and an outdoor unit (for example, the outdoor unit 100 in FIG. 1) connected to the indoor unit by a connecting member (for example, the pipe 300 in FIG. 1). An electronic device (for example, an air conditioner according to an embodiment of the invention),
The outdoor device is
A first time counting means (for example, a total clock number circuit 136 in FIG. 3) for counting the reference clock signal to obtain current time data;
A receiving antenna that receives radio waves including time data (for example, the receiving antenna 110 in FIG. 2);
A determination means (for example, the CPU 131 in FIG. 3) for determining whether or not the electronic device is on standby for operation;
An extraction unit (for example, the receiving unit 120 in FIG. 2 and the CPU 131 in FIG. 3) that extracts time data from the radio wave received by the receiving antenna when the determination unit determines that the operation is on standby;
First time correcting means (for example, the CPU 131 in FIG. 3) for correcting the current time data of the first time counting means based on the time data extracted by the extracting means;
First time data transmitting means (for example, FIG. 2) for transmitting the current time data of the first time counting means to the indoor unit via a wiring (for example, the wiring 310 in FIG. 1) provided on the connecting member. Interface unit 140);
Have
The indoor device is:
A second time counting means (for example, a total clock number circuit 256 in FIG. 3) for counting the reference clock signal to obtain current time data;
Time data receiving means for receiving time data transmitted via the wiring (for example, the interface unit 260 in FIG. 2);
Second time correcting means (for example, CPU 251 in FIG. 3) for correcting the current time data of the second time counting means based on the time data received by the time data receiving means;
Second time data transmission means for wirelessly transmitting the current time data of the second time counting means (for example, the transmission unit 220 and the transmission antenna 210 in FIG. 2);
Having
It is characterized by that.
[0010]
According to the first aspect of the present invention, in the electronic device configured to include the indoor device and the outdoor device connected by the connecting member, the outdoor device is in a state where the electronic device is on standby for operation. The time data is extracted from the received radio wave, and based on the extracted time data, the time data counted by the first time counting means is corrected, and the corrected time data is transmitted via the wiring provided on the connection member. To the indoor unit. The indoor device corrects the current time data counted by the second time counting means based on the time data received from the outdoor device, and wirelessly transmits the corrected current time data. That is, an electronic device having a function as a relay device that receives a standard radio wave including time data and transmits a relay radio wave is realized.
[0011]
Therefore, since the function as a relay radio wave receiving unit is provided in the outdoor unit and the function as a relay radio wave sending unit is provided in the indoor unit, the standard radio wave is easily received and the transmitted relay radio wave is installed in the room. It is possible to realize a relay device that is easily received by a received radio timepiece or the like. In addition, since transmission / reception of data between the outdoor device and the indoor device is performed via a wiring provided on the connection member, the transmission / reception of data between the standard radio wave reception unit and the relay radio wave transmission unit is performed. Wiring is easy.
Further, the extraction of time data from the received radio wave is performed when it is determined that the electronic device is on standby. For this reason, it is possible to prevent erroneous reception of radio waves due to noise or the like generated by the operation of the electronic device.
[0012]
The invention described in claim 2
An indoor unit (for example, the indoor unit 200 in FIG. 1), and an outdoor unit (for example, the outdoor unit 100 in FIG. 1) connected to the indoor unit by a connecting member (for example, the pipe 300 in FIG. 1). An electronic device (for example, an air conditioner according to an embodiment of the invention),
The outdoor device is
A receiving antenna that receives radio waves including time data (for example, the receiving antenna 110 in FIG. 2);
Determination means (for example, CPU 131, 137 in FIG. 9) for determining whether or not the electronic device is on standby for operation;
Extraction means for extracting time data from the radio wave received by the receiving antenna (for example, the receiving unit 120 in FIG. 2 and the CPUs 131 and 137 in FIG. 9) when the determination means determines that the operation is on standby;
First time data transmission means (for example, the interface of FIG. 2) that transmits the time data extracted by the extraction means to the indoor unit via a wiring (for example, the wiring 310 of FIG. 1) provided on the connection member. Part 140),
Have
The indoor device is:
Time counting means for counting the reference clock signal to obtain current time data (for example, the total clock number circuit 256 in FIG. 3);
Time data receiving means for receiving time data transmitted via the wiring (for example, the interface unit 260 in FIG. 2);
Based on the time data received by the time data receiving means, time correcting means (for example, CPU 131, 137 in FIG. 9) for correcting the current time data of the time counting means,
Second time data transmission means (for example, the transmission unit 220 and the transmission antenna 210 in FIG. 2) for wirelessly transmitting the current time data of the time counting means;
Having
It is characterized by that.
[0013]
According to the second aspect of the present invention, in the electronic device configured to include the indoor device and the outdoor device connected by the connecting member, the outdoor device is in a state where the electronic device is on standby for operation. Then, time data is extracted from the received radio wave, and the extracted time data is transmitted to the indoor device via the wiring provided on the connection member. The indoor device corrects the current time data counted by the second time counting means based on the time data received from the outdoor device, and wirelessly transmits the corrected current time data. That is, an electronic device having a function as a relay device that receives a standard radio wave including time data and transmits a relay radio wave is realized.
[0014]
Therefore, since the function as a relay radio wave receiving unit is provided in the outdoor unit and the function as a relay radio wave sending unit is provided in the indoor unit, the standard radio wave is easily received and the transmitted relay radio wave is installed in the room. It is possible to realize a relay device that is easily received by a received radio timepiece or the like. In addition, since transmission / reception of data between the outdoor device and the indoor device is performed via a wiring provided on the connection member, the transmission / reception of data between the standard radio wave reception unit and the relay radio wave transmission unit is performed. Wiring is easy.
Further, the extraction of time data from the received radio wave is performed when it is determined that the electronic device is on standby. For this reason, it is possible to prevent erroneous reception of radio waves due to noise or the like generated by the operation of the electronic device.
[0015]
Further, as in the invention according to claim 3, in the electronic device according to claim 1 or 2,
The outdoor device is
Interrupting means (for example, the CPU 131 in FIG. 3) for interrupting the operation of the electronic device for a predetermined time when the determination means determines that the operation is not in standby.
Further comprising
The extraction means extracts time data from the radio wave received by the receiving antenna while the operation of the electronic device is interrupted by the interruption means.
It's also good.
[0016]
According to the third aspect of the present invention, the same effect as that of the first or second aspect of the invention can be achieved, and the outdoor device can be operated for a predetermined time when the electronic device is not on standby. During this time (while the operation of the electronic device is interrupted), time data can be extracted from the received radio wave. Therefore, even when the electronic device is in operation, it is possible to realize a relay device that transmits a relay radio wave quickly while preventing erroneous reception of the radio wave due to noise or the like generated by the operation of the electronic device. It should be noted that it is desirable to interrupt the operation of the electronic device as long as the original operation of the electronic device is not hindered.
[0017]
The invention according to claim 4
An indoor unit (for example, the indoor unit 200 in FIG. 1), and an outdoor unit (for example, the outdoor unit 100 in FIG. 1) connected to the indoor unit by a connecting member (for example, the pipe 300 in FIG. 1). An electronic device (for example, an air conditioner according to an embodiment of the invention),
The outdoor device is
A receiving antenna that receives radio waves including time data (for example, the receiving antenna 110 in FIG. 10);
Radio wave transmission means (for example, the transmission antenna 110 in FIG. 10) that transmits the radio wave received by the reception antenna to the indoor device via a wiring (for example, the wiring 310 in FIG. 1) provided in the connection member; ,
Have
The indoor device is:
Time counting means for counting the reference clock signal to obtain current time data (for example, the clock number circuit 256 in FIG. 3 provided in the indoor unit microcomputer 250 in FIG. 10),
Radio wave receiving means (for example, receiving unit 270 in FIG. 10) for receiving radio waves transmitted through the wiring;
A determination means for determining whether or not the electronic device is on standby (for example, the CPU 251 in FIG. 3 provided in the indoor unit microcomputer 250 in FIG. 10);
When the determination unit determines that the operation is on standby, an extraction unit that extracts time data from the radio wave received by the radio wave reception unit (for example, the CPU 251 of FIG. 3 provided in the indoor unit microcomputer of FIG. 10);
Based on the time data extracted by the extracting means, time correcting means for correcting the current time data of the time counting means (for example, the CPU 251 of FIG. 3 provided in the indoor unit microcomputer 250 of FIG. 10),
Time data transmitting means for wirelessly transmitting the current time data of the time counting means (for example, the transmission unit 220 and the transmission antenna 210 in FIG. 10);
Having
It is characterized by that.
[0018]
According to the fourth aspect of the present invention, in the electronic apparatus configured to include the indoor device and the outdoor device connected by the connecting member, the outdoor device has the received radio wave provided to the connecting member. It transmits to the indoor device via wiring. Then, when the electronic device is on standby for operation, the indoor unit extracts time data from the radio wave received from the outdoor unit, and the current time data counted by the time counting unit based on the extracted time data is extracted. At the same time, the corrected time data is wirelessly transmitted. That is, an electronic device having a function as a relay device that receives a standard radio wave including time data and transmits a relay radio wave is realized.
[0019]
Therefore, since the function as a relay radio wave receiving unit is provided in the outdoor unit and the function as a relay radio wave sending unit is provided in the indoor unit, the standard radio wave is easily received and the transmitted relay radio wave is installed in the room. It is possible to realize a relay device that is easily received by a received radio timepiece or the like. In addition, since transmission / reception of data between the outdoor device and the indoor device is performed via a wiring provided on the connection member, the transmission / reception of data between the standard radio wave reception unit and the relay radio wave transmission unit is performed. Wiring is easy.
Further, the extraction of time data from the received radio wave is performed when it is determined that the electronic device is on standby. For this reason, it is possible to prevent erroneous reception of radio waves due to noise or the like generated by the operation of the electronic device.
[0020]
Further, as in the invention according to claim 5, in the electronic device according to claim 4,
The indoor device is:
Interrupting means for interrupting the operation of the electronic device for a predetermined time (for example, the CPU 251 of FIG. 3 provided in the indoor unit microcomputer 250 of FIG. 10) when the determination means determines that the operation is not in standby.
Further comprising
The extraction means extracts time data from the radio wave received by the radio wave reception means while the operation of the electronic device is interrupted by the interruption means;
It's also good.
[0021]
According to the fifth aspect of the invention, the same effect as that of the fourth aspect of the invention can be achieved. When the electronic device is not in operation standby, the indoor device interrupts the operation for a predetermined time. During that time (while the operation of the electronic device is interrupted), time data can be extracted from the received radio waves. Therefore, even when the electronic device is in operation, it is possible to realize a relay device that transmits a relay radio wave quickly while preventing erroneous reception of the radio wave due to noise or the like generated by the operation of the electronic device. It should be noted that it is desirable to interrupt the operation of the electronic device as long as the original operation of the electronic device is not hindered.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following, the case where the present invention is applied to a home air conditioner (air conditioner) will be described, but the application of the present invention is not limited thereto.
[0023]
[Schematic configuration]
FIG. 1 is a diagram showing a schematic configuration in the present embodiment. According to the figure, the home air conditioner is configured to include an outdoor unit 100 installed outside and an indoor unit 200 installed indoors. The outdoor unit 100 and the indoor unit 200 are connected to each other by a pipe 300 through which a refrigerant or the like circulates, and can transmit and receive data to and from each other via a wiring 310 provided along the pipe 300. It has become.
[0024]
In the present embodiment, the air conditioner receives the standard radio wave transmitted from the transmitting station 500 in addition to the conventional air conditioning function (such as cooling / heating / dehumidifying function) that adjusts the indoor temperature, humidity, etc., and time data It has a function as a so-called relay device that transmits relay radio waves including
[0025]
Specifically, the outdoor unit 100 receives the standard radio wave transmitted from the transmitting station 500, and transmits the received standard radio wave or time data based on the standard radio wave to the indoor unit 200 via the wiring 310. . The indoor unit 200 transmits a relay radio wave including current time data based on the received data from the outdoor unit 100. The radio clock 700 placed in the room receives the relay radio wave transmitted from the indoor unit 200 and corrects the time based on the current time data included in the relay radio wave.
[0026]
Two embodiments of the air conditioner configured as described above will be sequentially described below. In the following description, the processes related to the basic operations of the air conditioner (for example, the air conditioning operation and the timer operation) are the same as those in the prior art, and thus illustration and description thereof are omitted.
[0027]
[First Embodiment]
First, the first embodiment will be described.
In the first embodiment, when the outdoor unit 100 receives a standard radio wave, it first determines the operating state (in operation / standby) of the air conditioner. If it is in operation, it waits until it is on standby, and then receives a standard radio wave.
[0028]
[Internal configuration]
The configuration in the first embodiment will be described.
FIG. 2 is a diagram illustrating an internal configuration of the outdoor unit 100 and the indoor unit 200 according to the first embodiment.
[0029]
As shown in the figure, the outdoor unit 100 includes a receiving antenna 110, a receiving unit 120, an outdoor unit microcomputer (microcomputer) 130-1, and an interface unit 140.
[0030]
The receiving antenna 110 can receive standard radio waves, and is configured by a bar antenna, for example. The standard radio wave received by the receiving antenna 110 is converted into an electric signal and output to the receiving unit 120.
[0031]
The receiving unit 120 detects the standard radio wave received by the receiving antenna 110 and extracts a predetermined frequency signal. Then, a time code including data necessary for a clock function such as a time code, an integrated date code, and a day code is generated from the extracted frequency signal. The generated time code is output to the outdoor unit microcomputer 130-1.
[0032]
The interface unit 140 is an interface for the outdoor unit 100 to transmit and receive data to and from the indoor unit 200 via the wiring 310.
[0033]
The outdoor unit microcomputer 130-1 controls the operation of the outdoor unit 100 related to reception of standard radio waves. Specifically, as shown in FIG. 3A, the outdoor unit microcomputer 130-1 includes a CPU 131, a ROM 132, a RAM 133, an oscillation circuit 134, a frequency dividing circuit 135, a clock count circuit 136, It is configured with.
[0034]
The CPU 131 reads various programs stored in the ROM 132 at a predetermined timing, expands them in the RAM 133, executes various processes based on the programs, and controls the operation of the outdoor unit 100. In particular, in the first embodiment, processing related to reception of standard radio waves (see FIG. 4) described later is executed according to the standard radio wave reception program 132a of the ROM 132.
[0035]
The oscillation circuit 134 includes, for example, a crystal oscillator and outputs a clock signal having a constant frequency to the frequency dividing circuit 135 at all times. The frequency divider 135 counts the clock signal input from the oscillation circuit 134 and outputs a 1-minute signal to the clock count circuit 136 every time the count value becomes a value corresponding to 1 minute. The clock count circuit 136 counts current time data such as the date of the day and the current hour and minute based on the 1-minute signal input from the frequency divider circuit 135.
[0036]
The ROM 132 stores various initial setting values and initial programs, as well as programs and data for realizing the functions of the outdoor unit 100. In particular, in the first embodiment, a standard radio wave reception program 132a for realizing processing (see FIG. 4) related to reception of standard radio waves, which will be described later, is stored.
[0037]
The RAM 133 includes a data storage area for temporarily holding various programs executed by the CPU 131 and data related to the execution of these programs. In particular, the first embodiment includes an extracted time data storage area 133a that holds time data including integrated date data, hour / minute data, day of week data, and the like extracted from standard radio waves.
[0038]
In FIG. 2, the indoor unit 200 includes a transmission antenna 210, a transmission unit 220, a display unit 230, an operation unit 240, an indoor unit microcomputer 250, and an interface unit 260.
[0039]
The transmission unit 220 generates a relay radio wave in which a predetermined carrier wave is modulated with the time code input from the indoor unit microcomputer 250, and transmits the generated relay radio wave via the transmission antenna 210. The carrier wave at this time may be the same as the received standard radio wave, or may be a dedicated radio wave as a relay radio wave. If it is the same as the long wave standard radio wave, the radio clock 700 installed indoors may be a normal one, but if it is a dedicated radio wave as a relay radio wave, the radio clock 700 receives the radio wave. A means to do this is required.
[0040]
The display unit 230 is a display device configured with, for example, an LCD (Liquid Crystal Display) or the like, and digitally displays the current time based on a display signal input from the indoor unit microcomputer 250. The display unit 230 may also be configured to serve as a display panel that displays a set temperature, a current indoor temperature, and the like in the air conditioning function of the air conditioner.
[0041]
The operation unit 240 is an input device including, for example, various operation switches, buttons, a remote controller (remote controller), and the like, and outputs an operation signal corresponding to the operation to the indoor unit microcomputer 250.
[0042]
The interface unit 260 is an interface for the indoor unit 200 to transmit / receive data to / from the outdoor unit 100 via the wiring 310.
[0043]
The indoor unit microcomputer 250 controls the operation of the indoor unit 200 related to transmission of relay radio waves. Further, as shown in FIG. 3B, the indoor unit microcomputer 250 includes a CPU 251, a ROM 252, a RAM 253, an oscillation circuit 254, a frequency dividing circuit 255, and a clock count circuit 256. Is done.
[0044]
The CPU 251 reads various programs stored in the ROM 252 at a predetermined timing, expands them in the RAM 253, executes various processes based on the programs, and controls the operation of the indoor unit 200. In particular, in the first embodiment, processing (see FIG. 6) related to transmission of relay radio waves, which will be described later, is executed according to the relay radio wave transmission program 252a of the ROM 252.
[0045]
The ROM 252 stores various initial setting values and initial programs, as well as programs and data for realizing the functions of the indoor unit 200. In particular, in the first embodiment, a relay radio wave transmission program 252a for realizing processing (see FIG. 6) related to the transmission of relay radio waves described later is stored.
[0046]
The RAM 253 includes a data storage area for temporarily holding various programs executed by the CPU 251 and data related to the execution of these programs. In particular, the first embodiment includes a reception time data storage area 253a that holds time data received from the outdoor unit 100.
[0047]
The oscillation circuit 254 includes a crystal oscillator, for example, and outputs a clock signal having a constant frequency to the frequency dividing circuit 255 at all times. The frequency dividing circuit 255 counts the clock signal input from the oscillation circuit 254 and outputs a one-minute signal to the clock count circuit 256 every time the count value becomes a value corresponding to one minute. The clock count circuit 256 counts current time data such as the date of the day and the current hour and minute based on the 1-minute signal input from the frequency divider circuit 255.
[0048]
[Operation]
The operation in the first embodiment will be described.
[0049]
4 and 5 are flowcharts for explaining the operation of the outdoor unit 100 according to the first embodiment. This process is executed when the power of the outdoor unit 100 is ON, and is continuously executed while the power is ON.
[0050]
According to FIG. 4, the CPU 131 first determines whether or not the current time indicated by the current time data counted by the counting clock circuit 136 is 3:00 am, which is a predetermined reception time of the standard radio wave. If the current time is 3:00 am (step S11: YES), the air conditioner operating state (in operation / standby) is subsequently determined.
[0051]
Here, the air conditioner being “operating” means a state in which the power supply is ON and a conventional air conditioning operation such as a cooling / heating / dehumidifying operation is performed. Further, “standby” means a state in which the power supply is ON but the above-described air conditioning operation is not performed.
[0052]
If the air conditioner is operating as a result of the determination (step S12: NO), the CPU 131 determines the operating state of the air conditioner again after a predetermined time has elapsed (step S13). If it is not in operation, that is, if it is on standby (step S12: YES), the standard radio wave reception process is then executed to receive the standard radio wave transmitted from the transmitting station 500 (step S14).
[0053]
The standard radio wave reception process executed here will be described.
FIG. 5 is a flowchart for explaining standard radio wave reception processing. According to the figure, when the standard radio wave reception process is started, the CPU 131 starts taking in the time code from the receiving unit 120 and starts counting the elapsed time T from the start time of the process. Then, the frame reference marker is searched from the fetched time code.
[0054]
When the frame reference marker is detected (step S141: YES), the CPU 131 extracts time data including accumulated date data, hour / minute data, day of the week data, and the like from the time code for one frame starting from the frame reference marker. (Step S142). Then, the extracted time data is stored in the extraction time data storage area 133a in the RAM 133 in the order of extraction (step S143).
[0055]
Next, the CPU 131 determines whether or not the time code for one frame has been correctly received. This determination can be made by, for example, an error check (parity check) based on a parity bit included in the time code.
[0056]
If the time code has been correctly received (step S144: YES), the CPU 131 subsequently determines whether or not the time code for three frames has been correctly received. If the time code for three frames is correctly received (step S145: YES), the standard radio wave receiving process is terminated, and the process returns to step S15 in FIG.
[0057]
In addition, when the frame reference marker is not detected in the captured time code (step S141: NO), when the time code for one frame cannot be correctly received (step S144: NO), or for three frames When the time code is not correctly received (step S145: NO), the CPU 131 determines the elapsed time T so far.
[0058]
If the elapsed time T is less than 10 minutes (step S146: NO), the CPU 131 proceeds to step S141 and searches for the next frame reference marker. On the other hand, if the elapsed time T is 10 minutes or more (step S146: NO), the standard radio wave reception process is terminated, and the process returns to step S15 in FIG.
[0059]
As described above, when the standard radio wave reception process is executed and the standard radio wave is received, the CPU 131 subsequently determines whether or not the standard radio wave has been successfully received. Specifically, time data for three frames that have been successfully received are stored in the extraction time data storage area 133a, and the time data for these three frames are stored in a predetermined time (predetermined minutes) in the order of storage. Judgment is made based on whether the value is delayed.
[0060]
If the reception of the standard radio wave is successful (step S15: YES), the CPU 131 corrects the current time data counted by the clock count circuit 136 based on the time data extracted from the received standard radio wave (step S16). ). Specifically, the current time data of the clock count circuit 136 is corrected from the end time of the standard radio wave reception process described above to the time data of the third frame that has been successfully received, stored in the extraction time data storage area 133a. The time data obtained by adding the elapsed time (for example, 1 minute) until completion is set in the clock count circuit 136 in accordance with the input timing of the frame reference marker.
[0061]
Then, CPU131 transmits the transmission start signal which notifies the transmission start of time data to the indoor unit 200 (step S17). When a response signal in response to this transmission start signal is received from the indoor unit 200 (step S18: YES), the current time data counted by the clock count circuit 136 is transmitted to the indoor unit 200 (step S19).
[0062]
When the above processing is performed, the CPU 131 proceeds to step S11 again and repeatedly executes the same processing.
[0063]
FIG. 6 is a flowchart for explaining the operation of the indoor unit 200 according to the first embodiment. This process is a process executed when the power of the indoor unit 200 is ON, and is continuously executed while the power is ON.
[0064]
According to FIG. 6, the CPU 251 first determines whether or not a transmission start signal has been received from the outdoor unit 100. If no transmission start signal has been received (step S21: NO), the CPU 251 counts every minute. A relay radio wave including the current time data counted by the clock number circuit 256 is generated and transmitted from the transmission antenna 210 (step S25).
[0065]
When the transmission start signal is received from the outdoor unit 100 (step S21: YES), the CPU 251 transmits a response signal to the transmission start signal to the outdoor unit 100 (step S22), and then transmitted from the outdoor unit 100. Time data is received (step S23).
[0066]
Subsequently, the CPU 251 corrects the current time data counted by the total clock number circuit 256 based on the received time data (step S24). Then, it returns to step S21 and repeats the same process.
[0067]
[Action / Effect]
As described above, according to the first embodiment, when the outdoor unit 100 receives the standard radio wave, the outdoor unit 100 determines the operation state of the air conditioner. If the outdoor unit 100 is in operation, the outdoor unit 100 does not receive the standard radio wave and the air conditioner is on standby. When waiting, the standard radio wave is received and time data extracted from the standard radio wave is transmitted to the indoor unit 200. Then, the indoor unit 200 corrects the current time based on the time data received from the outdoor unit 100, and transmits a relay radio wave including the current time data every predetermined time (specifically, one minute).
[0068]
Therefore, since the outdoor unit 100 has a function as a standard radio wave receiving unit and the indoor unit 200 has a function as a relay radio wave transmission unit, it is easy to receive the standard radio wave and the transmitted relay radio wave is indoors. The function of the relay device that can be easily received by the placed timepiece 700 can be realized. In addition, transmission / reception of data between the outdoor unit 100 and the indoor unit 200 is easily realized via the wiring 310 provided along the pipe 300.
Further, extraction of time data from the received standard radio wave is performed when the air conditioner is on standby. For this reason, it is possible to prevent erroneous reception of the standard radio wave due to noise or the like generated by the operation of the air conditioner (particularly, the operation of the outdoor unit 100).
[0069]
[Second Embodiment]
Next, a second embodiment will be described. In the following description, the same elements as those in the first embodiment described above are denoted by the same reference numerals, and detailed description thereof is omitted.
In the second embodiment, when the outdoor unit 100 receives a standard radio wave, it first determines the operating state (in operation / standby) of the air conditioner. When the air conditioner is in operation, the operation of the air conditioner is temporarily interrupted, and then the standard radio wave is received.
[0070]
[Internal configuration]
A configuration in the second embodiment will be described.
The configuration of the outdoor unit 100 in the second embodiment is the same as that of the outdoor unit microcomputer 130-1 of the outdoor unit 100 shown in FIG. This is a configuration in which the microcomputer 130-2 is replaced. The configuration of the indoor unit 200 is the same as that shown in FIG. 2 in the first embodiment described above.
[0071]
According to FIG. 7, the outdoor unit microcomputer 130-2 in the second embodiment includes a CPU 137, a ROM 138, a RAM 139, an oscillation circuit 134, a frequency divider circuit 135, and a clock count circuit 136. It is prepared for.
[0072]
The ROM 138 includes a standard radio wave reception program 138a for realizing a process (see FIG. 8) related to reception of a standard radio wave, which will be described later, and an interruptable condition 138b that is a condition that can temporarily interrupt the operation of the air conditioner. And are stored.
[0073]
The interruptable condition 138b is, for example, a temperature difference between the set temperature of the air conditioner and the indoor temperature, which is determined not to hinder the adjustment of the indoor temperature even if the operation is interrupted for a predetermined time (specifically, 10 minutes). The upper limit value of is stored. The interruptable condition 138b is not limited to a temperature condition, and may be a humidity condition.
[0074]
The RAM 139 includes an operation status storage area 139a that holds data relating to the current operation of the air conditioner, a stop flag storage area 139c that holds the value of the stop flag, and an extraction time data storage area 139b.
[0075]
Here, the data related to the operation of the air conditioner includes the current operation status (operating / standby) of the air conditioner, the indoor environment (temperature, humidity, etc.), and the like. In addition, this data is constantly updated to the latest data according to data appropriately transmitted from the indoor unit 200.
[0076]
The stop flag is a flag indicating that the operation of the air conditioner is temporarily interrupted in order to receive the standard radio wave.
[0077]
[Process flow]
The operation in the second embodiment will be described. In the following description, the same steps as those shown in FIG. 4 in the first embodiment described above are denoted by the same reference numerals (same step numbers), and the description will be simplified. The operation of the indoor unit 200 is the same as the operation shown in FIG. 6 in the first embodiment described above, although the description is omitted.
[0078]
FIG. 8 is a flowchart for explaining the operation of the outdoor unit 100 according to the second embodiment. This process is executed when the power of the outdoor unit 100 is ON, and is continuously executed while the power is ON.
[0079]
According to FIG. 8, the CPU 137 first determines whether or not the current time is 3 am, and if it is 3 am (step S11: YES), it next determines the operating state of the air conditioner. As a result, if it is in operation (step S12: YES), the CPU 137 determines whether or not the operation of the currently operating air conditioner can be temporarily interrupted. Specifically, the determination is made based on whether or not the data relating to the current operation of the air conditioner stored in the operation status storage area 139a satisfies the interruptable condition 138b.
[0080]
As a result, if the operation of the air conditioner can be interrupted (step T13; YES), the CPU 137 transmits a stop instruction signal for temporarily interrupting the operation of the air conditioner to the indoor unit 200 (step T14). The flag is set to “1” (step T15).
[0081]
Then, when the air conditioner is on standby, the CPU 137 subsequently executes the standard radio wave reception process shown in FIG. 5 (step S14), and after receiving the standard radio wave transmitted from the transmitting station 500, the standard radio wave is received. It is determined whether or not the reception is successful.
[0082]
If the reception of the standard radio wave is successful (step S15: YES), the CPU 137 corrects the current time based on the received standard radio wave (step S16). Then, a time data transmission start signal is transmitted to the indoor unit 200 (step S17), and when a response signal in response to the transmission start signal is received from the indoor unit 200 (step S18: YES), the current time data is transmitted to the indoor unit 200. (Step S19).
[0083]
Thereafter, the CPU 137 determines a stop flag, and if it is “1” (step T14: YES), transmits an operation instruction signal instructing the re-operation of the air conditioner to the indoor unit 200, and after the air conditioner is re-activated ( In step T15), the stop flag is set to “0” (step T16).
[0084]
When the above processing is performed, the CPU 137 proceeds to step S11 again and repeatedly executes the same processing.
[0085]
[Action / Effect]
As described above, according to the second embodiment, the outdoor unit 100 determines the operating state of the air conditioner when receiving the standard radio wave, and temporarily stops the operation of the air conditioner for a predetermined time when it is in operation. After being suspended for a period of time, the standard radio wave is received and time data extracted from the standard radio wave is transmitted to the indoor unit 200. Then, the indoor unit 200 corrects the current time based on the time data received from the outdoor unit 100, and transmits a relay radio wave including the current time data every predetermined time (specifically, one minute).
[0086]
Therefore, since the outdoor unit 100 has a function as a standard radio wave receiving unit and the indoor unit 200 has a function as a relay radio wave transmission unit, it is easy to receive the standard radio wave and the transmitted relay radio wave is indoors. The function of the relay device that can be easily received by the placed timepiece 700 can be realized. In addition, transmission / reception of data between the outdoor unit 100 and the indoor unit 200 is easily realized via the wiring 310 provided along the pipe 300.
Further, extraction of time data from the received standard radio wave is performed when the air conditioner is on standby. For this reason, it is possible to prevent erroneous reception of the standard radio wave due to noise or the like generated by the operation of the air conditioner (particularly, the operation of the outdoor unit 100).
[0087]
[Modification]
The application of the present invention is not limited to the above-described two embodiments, and can be appropriately changed without departing from the spirit of the present invention. For example, the following modification is mentioned.
[0088]
(1) In the two embodiments described above, the outdoor unit 100 has a clock function for measuring the current time, but may not have this.
[0089]
Specifically, as shown in FIG. 9, the outdoor unit microcomputer 130-1 shown in FIG. 3A or the outdoor unit microcomputer 130-2 shown in FIG. It replaces with the microcomputer 130-3 for outdoor units of the structure which is not provided with the circuit 135 and the clock number circuit 136. FIG.
[0090]
The outdoor unit microcomputer 130-3 transmits time data extracted from the standard radio wave to the indoor unit 200 during or after the standard radio wave reception process. In this case, the CPU 251 included in the indoor unit microcomputer 250 determines the success / reception of the standard radio wave based on the time data received from the outdoor unit 100. A correction will be made.
[0091]
Alternatively, the outdoor unit microcomputer 130-3 executes standard radio wave reception processing to determine success / failure of reception of the standard radio wave, and when it is determined to be successful, It is good also as transmitting to 200. In this case, when the reception of the standard radio wave fails, the time data is not transmitted to the indoor unit 200.
[0092]
(2) Further, the outdoor unit 100 may include only the receiving antenna 110 without including the outdoor unit microcomputers 131-1 and 131-2.
[0093]
Specifically, as shown in FIG. 10, the outdoor unit 100 is configured to include only the reception antenna 110. The standard radio wave received by the receiving antenna 110 is transmitted to the indoor unit 200 via the wiring 310.
[0094]
The indoor unit 200 includes a transmission antenna 210, a transmission unit 220, a display unit 230, an operation unit 240, an indoor unit microcomputer 250, and a reception unit 270. The receiving unit 270 detects the standard radio wave received from the outdoor unit 100 via the wiring 310 and outputs the generated time code to the indoor unit microcomputer 250.
[0095]
Then, the CPU 251 included in the indoor unit microcomputer 250 executes processing corresponding to processing related to reception of standard radio waves (see FIG. 4 or FIG. 8) and processing related to reception of relay radio waves (see FIG. 6). That is, the current time is determined, and when it is 3:00 am, which is a predetermined reception time of the standard radio wave, the standard radio wave reception process is executed to receive the standard radio wave. If the standard radio wave is successfully received, the time is adjusted based on the received standard radio wave (corresponding to steps S11 to S16 in FIGS. 4 and 8 and step S24 in FIG. 6). On the other hand, if the current time is not 3:00 am, relay radio waves including the current time data are transmitted every minute (corresponding to steps S21: NO to S25 in FIG. 6).
[0096]
【The invention's effect】
According to the present invention, since the function as a relay radio wave receiving unit is provided in the outdoor device and the function as a relay radio wave sending unit is provided in the indoor device, respectively, it is easy to receive the standard radio wave and the transmitted relay radio wave Can be easily received by a radio timepiece or the like placed in the room. In addition, since transmission / reception of data between the outdoor device and the indoor device is performed via a wiring provided on the connection member, the transmission / reception of data between the standard radio wave reception unit and the relay radio wave transmission unit is performed. Wiring is easy.
Further, the extraction of time data from the received radio wave is performed when it is determined that the electronic device is on standby. For this reason, it is possible to prevent erroneous reception of radio waves due to noise or the like generated by the operation of the electronic device.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of an embodiment.
FIG. 2 is a block diagram showing an internal configuration of the outdoor unit and the indoor unit in the first embodiment.
FIG. 3 is a block diagram showing an internal configuration of the outdoor unit microcomputer and the indoor unit microcomputer in the first embodiment.
FIG. 4 is a flowchart for explaining the operation of the outdoor unit in the first embodiment.
FIG. 5 is a flowchart for explaining standard radio wave reception processing executed in the operation of FIG. 4;
FIG. 6 is a flowchart for explaining the operation of the indoor unit in the first embodiment.
FIG. 7 is a block diagram showing an internal configuration of an outdoor unit microcomputer according to the second embodiment.
FIG. 8 is a flowchart for explaining the operation of the outdoor unit in the second embodiment.
FIG. 9 is a diagram showing another internal configuration example of the outdoor unit microcomputer.
FIG. 10 is a diagram showing another internal configuration example of the outdoor unit and the indoor unit.
FIG. 11 is a diagram showing a time code format;
[Explanation of symbols]
100 outdoor unit
110 Receiving antenna
120 receiver
130-1, Microcomputer for outdoor unit
131,137 CPU
132,138 ROM
132a, 138a Standard radio wave reception program
138b Interruptible conditions
133 RAM
133a Extraction time data storage area
134 Oscillator circuit
135 divider circuit
136 Clock circuit
140 Interface section
200 indoor unit
210 Transmitting antenna
220 Transmitter
230 Display section
240 operation unit
250 Microcomputer for indoor unit
251 CPU
252 ROM
252a Relay radio wave transmission program
253 RAM
253a Reception time data storage area
254 oscillation circuit
255 frequency divider
256 Count clock circuit
260 Interface section
300 piping
310 Wiring
500 transmitting station
700 radio clock

Claims (5)

An electronic device comprising an indoor device and an outdoor device connected to the indoor device with a connecting member,
The outdoor device is
First time counting means for counting a reference clock signal to obtain current time data;
A receiving antenna for receiving radio waves including time data;
Determining means for determining whether or not the electronic device is on standby;
An extraction means for extracting time data from the radio wave received by the receiving antenna when the determination means determines that the operation is waiting;
First time correction means for correcting current time data of the first time counting means based on the time data extracted by the extraction means;
First time data transmitting means for transmitting current time data of the first time counting means to the indoor unit via a wiring provided in the connecting member;
Have
The indoor device is:
Second time counting means for counting the reference clock signal to obtain current time data;
Time data receiving means for receiving time data transmitted via the wiring;
Second time correcting means for correcting the current time data of the second time counting means based on the time data received by the time data receiving means;
Second time data transmitting means for wirelessly transmitting current time data of the second time counting means;
Having
An electronic device characterized by that. An electronic device comprising an indoor device and an outdoor device connected to the indoor device with a connecting member,
The outdoor device is
A receiving antenna for receiving radio waves including time data;
Determining means for determining whether or not the electronic device is on standby;
An extraction means for extracting time data from the radio wave received by the receiving antenna when the determination means determines that the operation is waiting;
First time data transmitting means for transmitting the time data extracted by the extracting means to the indoor unit via wiring provided in the connecting member;
Have
The indoor device is:
Time counting means for counting the reference clock signal to obtain current time data;
Time data receiving means for receiving time data transmitted via the wiring;
Based on the time data received by the time data receiving means, time correcting means for correcting the current time data of the time counting means;
Second time data transmission means for wirelessly transmitting current time data of the time counting means;
Having
An electronic device characterized by that. The outdoor device is
Interruption means for interrupting the operation of the electronic device for a predetermined time when it is determined by the determination means that the operation is not on standby;
Further comprising
The extraction means extracts time data from the radio wave received by the receiving antenna while the operation of the electronic device is interrupted by the interruption means.
The electronic device according to claim 1, wherein An electronic device comprising an indoor device and an outdoor device connected to the indoor device with a connecting member,
The outdoor device is
A receiving antenna for receiving radio waves including time data;
A radio wave transmitting means for transmitting the radio wave received by the receiving antenna to the indoor unit via a wiring provided in the connection member;
Have
The indoor device is:
Time counting means for counting the reference clock signal to obtain current time data;
Radio wave receiving means for receiving radio waves transmitted via the wiring;
Determining means for determining whether or not the electronic device is on standby;
An extracting means for extracting time data from the radio wave received by the radio wave receiving means when it is determined by the determining means that the operation is waiting;
Based on the time data extracted by the extracting means, time correcting means for correcting the current time data of the time counting means;
Time data transmitting means for wirelessly transmitting current time data of the time counting means;
Having
An electronic device characterized by that. The indoor device is:
Interruption means for interrupting the operation of the electronic device for a predetermined time when it is determined by the determination means that the operation is not on standby;
Further comprising
The extraction means extracts time data from the radio wave received by the radio wave reception means while the operation of the electronic device is interrupted by the interruption means;
The electronic device according to claim 4.

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