JP2001305254A - Timepiece device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a timepiece device capable of continuously measuring time even if an output circuit of a base pulse signal is in failure. SOLUTION: The timepiece device comprises a waveform shaping circuit 26 for extracting to output the base pulse signal CKb based upon a predetermined frequency from a commercial alternating-current power supply 22 supplied at the predetermined frequency, and a ceramic resonator 25 for outputting a standby pulse signal CKs having a lower precision of frequency than the base pulse signal CKb. A microcomputer 21 comprises a base pulse signal detecting part 30 for detecting the presence or absence of the base pulse signal CKb outputted from the waveform shaping circuit 26, and clocking means 32 which operate based upon the base pulse signal CKb if the base pulse signal CKb may be detected by the base pulse signal detecting part 30 or operate based upon the standby pulse signal CKs if the base pulse signal CKb may not be detected by the base pulse signal detecting part 30.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a timekeeping device that measures time based on a reference pulse signal extracted from a commercial AC power supply supplied at a predetermined frequency.

[0002]

2. Description of the Related Art Conventionally, for example, in a cooking appliance operated by a commercial AC power supply having a predetermined frequency supplied from a power company, a reference pulse signal for time measurement is extracted from the commercial power supply, and cooking is performed based on the reference pulse signal. It is known to measure time.

[0003] Since the frequency of the commercial power supplied from the power company is strictly controlled, the reference pulse signal is extracted from the frequency of the commercial power and the reference pulse signal is counted. This is because the cooking time can be accurately managed.

[0004] However, in such a cooking appliance that measures time based on the reference pulse signal extracted from the commercial power supply, while the cooking time is being set and the cooking is being executed, the reference pulse signal is output. If a reference pulse signal cannot be obtained due to a failure of a circuit to be extracted or the like, cooking time cannot be managed and cooking is interrupted.

[0005] When cooking is interrupted in this way,
Particularly, in the case of a commercial cooking appliance that performs a large amount of cooking at a time, there is an inconvenience that a large amount of cooked food is generated during the cooking and a great damage is caused.

[0006]

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned inconveniences and to provide a timekeeping device capable of continuously measuring time even when a reference pulse signal cannot be obtained. And

[0007]

SUMMARY OF THE INVENTION The present invention has been made to achieve the above object, and a reference pulse for extracting and outputting a reference pulse signal based on a frequency from a commercial AC power supply supplied at a predetermined frequency. The present invention relates to an improvement of a timing device that has a signal output circuit and performs timing based on the reference pulse signal.

A preliminary pulse signal output circuit for outputting a preliminary pulse signal having a lower frequency accuracy than the reference pulse signal, and a reference pulse signal detecting means for detecting the reference pulse signal output from the reference pulse signal output circuit When the reference pulse signal is detected by the reference pulse signal detection means, time measurement is performed based on the reference pulse signal, and when the reference pulse signal is not detected by the reference pulse signal detection means, Switching timekeeping means for performing timekeeping based on the time.

According to the present invention, the reference pulse signal is output due to the failure of the reference pulse signal output circuit or the disconnection of the substrate while the switching timer measures the time based on the reference pulse signal. When the reference pulse signal detecting means detects that the switching is stopped, the switching time measuring means measures the time based on the preliminary pulse signal. Therefore, even if the reference pulse signal is no longer output, the time measurement is not interrupted. In addition, while waiting for repair such as a failure of the reference pulse signal output circuit, the time can be measured based on the preliminary pulse signal, so that the time measuring device is not disabled.

[0010] Further, the reference pulse signal and the preliminary pulse signal are inputted, and a calibration parameter is calculated to calibrate timing data measured based on the preliminary pulse signal to timing data based on the reference pulse signal. The apparatus further comprises parameter calculation means, wherein the switching timekeeping means calibrates timekeeping data timed based on the preliminary pulse signal with the calibration parameter when performing timekeeping based on the preliminary pulse signal.

According to the present invention, the switching timing means calibrates timing data based on the calibration parameters when timing is performed based on the preliminary pulse signal having lower frequency accuracy than the reference pulse signal. Thus, even when timing is performed using the preliminary pulse signal with low frequency accuracy, the switching timing unit can perform timing with high accuracy as in the case of timing based on the reference pulse signal. .

[0012] Further, the invention is characterized in that it comprises nonvolatile storage means for storing the calibration parameters.

According to the present invention, once the calibration parameters are calculated and stored in the non-volatile storage means at the first power-on, the process of calculating the calibration parameters is not required thereafter. Can be.

Further, the microcomputer is provided with a microcomputer, wherein the preliminary pulse signal is used as an operation clock of the microcomputer.

According to the present invention, the operation clock required for the operation of the microcomputer can be used as the preliminary pulse signal.

[0016] Further, the timing device is provided in a cooking appliance, and measures the cooking time of the cooking appliance.

According to the present invention, even if the reference pulse signal output circuit fails when the cooking appliance is performing cooking, the switching timer continues the cooking time based on the preliminary pulse signal. You can time it. Therefore, the cooking by the cooking appliance is not interrupted on the way.

Further, a notifying means for notifying when the fault detecting means detects a fault in the reference pulse signal output circuit is provided.

According to the present invention, the user is informed that the reference pulse signal output circuit is out of order and the time is being measured based on the preliminary pulse signal, and the user is notified of the reference pulse signal. The output circuit can be repaired.

The pulse signal detecting means may output the reference pulse signal when detecting that the pulse signal having a frequency within a predetermined range is output from the reference pulse signal output circuit. Judgment is made that the timing device is provided in a device that is normally operated by the commercial AC power supply and is operated by the AC power supply supplied from the backup power supply device when a power failure occurs.

According to the present invention, when a power failure occurs and AC power is supplied from the backup power supply to the electric device, the frequency of the pulse signal output from the reference pulse signal output circuit is changed. Is not within the predetermined range, that is, when the accuracy of the frequency of the AC power supplied from the backup power is low,
The reference pulse signal is not detected by the reference pulse signal detection means. Then, since the switching timer measures the time based on the preliminary pulse signal, when the accuracy of the frequency supplied from the backup power supply device is low, the time is measured based on the reference pulse signal based on the frequency. Thus, it is possible to prevent the accuracy of timekeeping from deteriorating.

In the case where the backup power supply is an uninterruptible power supply, even if a power failure occurs, the electric equipment can continue to operate with the AC power supplied from the uninterruptible power supply. In this case, also, when the frequency accuracy of the AC power supply is low, the switching timer means
Since the time is measured based on the preliminary pulse signal, it is possible to prevent the accuracy of the time from being deteriorated.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described with reference to FIGS. 1 is an overall configuration diagram of a gas oven including the function of the timepiece of the present invention, FIG. 2 is a control block diagram relating to timekeeping of the gas oven shown in FIG. 1, FIG. 3 is a flowchart of timekeeping processing, and FIG. FIG.

Referring to FIG. 1, gas oven 1 heats the inside of a refrigerator by a gas burner 2 to cook at a predetermined target temperature. The gas oven 1 includes a gas supply pipe 3 for supplying a fuel gas to a gas burner 2, a gas source valve 4 for opening and closing the gas supply pipe 3, a gas proportional valve 5 for adjusting a flow rate of the fuel gas supplied to the gas burner 2, Electrode 6, a flame detector 7 for detecting the presence or absence of combustion of the gas burner 2, a temperature control thermocouple 8 for detecting the temperature in the refrigerator, an igniter 9 for applying a high voltage to the ignition electrode 6, and an operation switch (shown in FIG. Operation panel 1 having a display unit (not shown) and a display unit (not shown)
0 and a controller 20 for controlling the overall operation of the gas oven 1. The controller 20 is an electronic unit including a microcomputer 21 (hereinafter, referred to as a microcomputer 21).

When the user operates the operation panel 10 to instruct the start of oven cooking, the controller 20 applies a high voltage to the ignition electrode 6 through the igniter 9 to generate a spark discharge. The gas source valve 4 is opened to perform the ignition process of the gas burner 2. And the controller 20
Is set by the gas proportional valve 5 to the gas burner 2 so that the temperature inside the refrigerator detected by the temperature control thermocouple 8 matches the target cooking temperature set by the temperature setting switch (not shown) of the operation panel 10. Temperature control is performed to control the combustion amount of the gas burner 2 by adjusting the supply amount of the fuel gas.

When the cooking time is set by a cooking time setting switch (not shown) provided on the operation panel 10, the controller 20 measures the execution time of the cooking and waits until the cooking time elapses. Execute the temperature control. Further, the controller 20 detects misfire of the gas burner 2 by the flame detector 7 during combustion of the gas burner 2.

As described above, when cooking by heating with the gas oven 1, unless the cooking time is managed accurately, the cooking will fail. In addition, if a malfunction occurs during cooking and it becomes impossible to measure the cooking time, cooking is interrupted and cooking also fails. In particular, in the case of a large-scale oven for business use, a large amount of defective products are generated due to such cooking failure, and the damage is large.

Further, if the time cannot be measured by the controller 20 due to the failure and the cooking time of the gas oven 1 cannot be managed, the cooking time is set and the cooking by the gas oven 1 is performed until the failure is repaired. Therefore, in the case of a commercial gas oven, the operation is hindered.

Therefore, the controller 20 is provided with a configuration capable of accurately measuring the cooking time and preventing the cooking time from being disabled due to a failure. Hereinafter, this configuration will be described with reference to FIGS.

Referring to FIG. 2, microcomputer 21 provided in controller 20 is operated by a DC power supply generated by a power supply circuit 23 from a commercial AC power supply 22. Also,
At the time of a power failure, the microcomputer 21 is operated by the backup battery 24 and performs a minimum necessary process such as updating a clock.

The microcomputer 21 uses a pulse signal (CKs in the figure, corresponding to the preliminary pulse signal of the present invention) output from the ceramic oscillator 25 as an operation clock. It fluctuates under the influence of individual characteristic variations and ambient temperature. Therefore, the frequency accuracy is low for use as a reference signal for timing.

Therefore, the microcomputer 21 is basically provided by a waveform shaping circuit 26 (corresponding to a reference pulse signal output circuit of the present invention) from a commercial AC power supply 22 whose frequency is strictly controlled by a power company. Time is measured based on the extracted and output pulse signal (CKb in the figure, corresponding to the reference pulse signal of the present invention).

The waveform shaping circuit 26 is connected to the commercial AC power supply 22 and detects a zero-cross point where the output voltage of the commercial AC power supply 22 changes from positive to negative or from negative to positive.
The frequency of the commercial AC power supply 22 (60H in this embodiment)
A pulse signal having the same frequency as z) (hereinafter referred to as a reference pulse signal CKb) is output.

The microcomputer 21 includes a first counter 27 for counting the reference pulse signal CKb, a second counter 28 for counting a pulse signal (hereinafter, referred to as a preliminary pulse signal CKs) output from the ceramic oscillator 25,
And comparing the count data of the first counter 27 with the count data of the second counter 28 to determine a calibration parameter for calibrating the count data of the preliminary pulse signal CKs by the second counter 28 to count data based on the reference pulse signal CKb. A comparison calculator 29 (corresponding to a calibration parameter calculator of the present invention) for calculating is provided.

The microcomputer 21 further includes a waveform shaping circuit 2
6, a reference pulse signal detecting section 30 (corresponding to a reference pulse signal detecting means of the present invention) for detecting whether or not the reference pulse signal CKb is normally output; timing unit 32 the count data of the first counter 27 when the CK _b is detected
And a counter switching unit 31 that outputs the count data of the second counter 28 to the timer 32 when the reference pulse signal CKb is not detected by the reference pulse signal detector 30. Note that the counter switching unit 31 and the timer unit 3
2 constitutes the switching timer means of the present invention.

The reference pulse signal detecting section 30 detects the number of reference pulse signals CKb counted by the first counter 27 while the second counter 28 counts the predetermined number of preliminary pulse signals CKs, It is determined whether a pulse signal having a frequency within a predetermined range is output. If the pulse signal is output, it is determined that the reference pulse signal CKb is output normally.

The calibration section 33 provided in the timer section 32 uses the calibration parameter calculated by the comparison calculation section 29 to count the count data of the preliminary pulse signal CKs by the second counter 28 based on the reference pulse signal CKb. Calibrate to data.

As described above, the timing section 32 calibrates the count data of the preliminary pulse signal CKs by the second counter 28 by the calibration section 33, thereby converting the preliminary pulse signal CKs into a preliminary pulse signal CKs having lower frequency accuracy than the reference pulse signal CKb. Even when time is measured based on the reference pulse signal CKb, the cooking time can be measured with the same accuracy as in the case where time is measured based on the reference pulse signal CKb.

The storage unit 35 stores the calibration parameters calculated by the comparison calculation unit 29. In addition, EEPRO
M40 (corresponding to the nonvolatile memory of the present invention) will be described later.

Next, according to the flowchart shown in FIG. 3, a description will be given of the cooking time measuring process by the configuration shown in FIG.

Referring to FIG. 3, when power supply to microcomputer 21 is started, microcomputer 21 determines in step 1 whether the frequency of commercial AC power supply 22 is normal.
Specifically, the second counter 28 outputs the preliminary pulse signal C
It is determined whether or not the power supply frequency is normal by checking whether or not the count number of the reference pulse signal CKb counted by the first counter 27 while the predetermined number of Ks is counted is within a specified range. I do.

When it is determined that the power supply frequency is normal, the process proceeds to STEP 2 where the comparison calculation unit 29 calculates calibration parameters. Specifically, the comparison calculation unit 29 grasps the count number of the preliminary pulse signal CKs counted by the second counter 28 while the first counter 27 counts the reference pulse signal CKb corresponding to one second. . Then, the ratio between the count numbers of the first counter 27 and the second counter 28 is calculated as a calibration parameter.

Thus, by multiplying the count number of the second counter by the calibration parameter, the preliminary pulse signal C
The count of the second counter 28 based on Ks can be calibrated to the count based on the reference pulse signal CKb. Then, in the next STEP 3, the microcomputer 21 stores the calibration parameters calculated by the comparison calculation unit 29 in the storage unit 35.
To memorize.

In the following STEP 4, the microcomputer 21 checks whether or not the reference pulse signal CKb is detected by the reference pulse signal detection section 30. When the reference pulse signal CKb is not detected, the process branches to STEP 20 and the microcomputer 21 sets an error lamp (not shown, corresponding to a notifying means of the present invention) provided on the operation panel 10 (see FIG. 1). Is turned on to notify the user that the waveform shaping circuit 26 has failed.

On the other hand, when the reference pulse signal CKb is detected by the reference pulse signal
Proceeding to P5, the microcomputer 21 turns off the error lamp if it has been turned on, and cancels the notification.

When the cooking time is set by the operation panel 10 and the cooking is started and the cooking timer is started, the microcomputer 21 proceeds from STEP 6 to STEP 7 and repeats the loop from STEP 7 to STEP 10.
It is repeatedly executed until the cooking timer times out in EP10.

In STEP 7, the counter switching section 31 checks whether or not the reference pulse signal CKb is detected by the reference pulse signal detection section 30. When the reference pulse signal CKb is detected, the process proceeds to STEP 8 to output count data of the reference pulse signal CKb by the first counter 27 to the timer 32, and the timer 32 performs cooking based on the count data. Performs timer counting.

On the other hand, if the reference pulse signal CKb is not detected by the reference pulse signal detecting means 30 in STEP 7, the process branches to STEP 30, and the counter switching section 31 sets the preliminary pulse signal CKs by the second counter 28.
Is output to the timer 32. Then, the timer 32 measures the time of the cooking timer based on the count data of the second counter 28.

That is, when the waveform shaping circuit 26 fails during the counting of the cooking timer and the reference pulse signal CKb cannot be obtained, the counter switching unit 31 causes the reference pulse signal C
The counter used for counting the cooking timer is switched from the first counter 27 for counting Kb to the second counter 28 for counting the preliminary pulse signal CKs. Therefore, even if the waveform shaping circuit 26 fails during the cooking, the counting of the cooking timer is not interrupted.
Is continued.

The next STEP 31 is processing by the calibration unit 33. The calibration unit 33 uses the calibration parameters stored in the storage unit 35 to count the number of the preliminary pulse signals CKs counted by the second counter 28. The data is calibrated to count data based on the reference pulse signal CKb. Thus, even when time is measured based on the preliminary pulse signal CKs whose frequency accuracy is lower than the reference pulse signal CKb, the cooking timer can be accurately timed in the same manner as when time is measured based on the reference pulse signal CKb. Can be.

Then, in the subsequent STEP 32, STEP 20
A failure notification similar to that described above is started, and the process proceeds to STEP 10 where ST
When the cooking timer has timed out in EP10, the microcomputer 21 ends the cooking timer clocking process.

In the present embodiment, by using the operation clock of the microcomputer 21 for the spare pulse signal CKs, it is not necessary to provide a circuit for separately outputting the spare pulse signal CKs. May be provided for exclusive use.

In this embodiment, the gas oven 1
The calibration parameters are calculated each time the power is turned on, but as shown in FIG.
(Corresponding to the nonvolatile memory of the present invention), and the EE
The calibration parameters may be stored in the PROM 40.

In this case, for example, the calibration parameters are calculated once at the time of the shipping inspection of the gas oven 1 in the factory and stored in the EEPROM 40, or the calibration parameters are calculated once at the time of installation of the gas oven 1 and the E.
By storing the data in the EPROM, it is not necessary to calculate the calibration parameters thereafter.

Further, the end of the NO branch of STEP 6 in FIG. 3 is set to STEP 1, and while waiting for the start of the cooking timer in STEP 6, the calibration parameters are calculated and stored in STEP 2 and STEP 3 to update the calibration parameters. You may.

In this embodiment, an example in which the present invention is applied to a gas oven is shown. However, the present invention can be applied to any device such as an air conditioner or a hot water device that sets the operation time using a timer. It is possible.

In this embodiment, the ratio between the count of the first counter 27 and the count of the second counter 28 per second is used as the calibration parameter.
The number of counts of the second counter 28 per count of the counter 27 may be used as a calibration parameter.
The average may be obtained by performing the calculation of the calibration parameter a plurality of times.

As shown in FIG. 4A, the gas oven 1 (corresponding to the device of the present invention) can be used even when the supply of the commercial AC power supply 50 is interrupted due to a power failure. In addition, the AC generator 52 for private power generation and the contact 53 when a power failure occurs are connected to the commercial AC power supply side (ac side in the figure).
And a power supply switching device 54 for switching the power supply to the AC generator side (bc side in the figure). The AC power generator 52 and the power supply switching device 54 constitute a backup power supply device of the present invention.

In this case, when a power failure occurs, the AC generator 52 is added to the waveform shaping circuit 26 of the gas oven 1 (see FIG. 2).
, But the frequency of the AC power supply is not as accurate as the commercial AC power supply 50.

Therefore, the pulse signal having the frequency within the above-mentioned predetermined range is not detected by the reference pulse signal detecting section 30, and it is determined that the reference pulse signal CKb is not output. Therefore, counter switching unit 31 outputs the count data of the preliminary pulse signal CK _s the second counter 28 to the clock unit 32. Then, the calibration unit 33 provided in the clock unit 32 calibrates the count data of the second counter 28 with the calibration parameters. As a result, it is possible to prevent the reference pulse signal from being extracted from the AC power supply whose frequency output from the AC generator 52 is not accurate, and to perform inaccurate timing based on the reference pulse signal.

Further, as shown in FIG. 4B, an uninterruptible power supply 60 may be added. The uninterruptible power supply 60
When an AC voltage is supplied from the commercial AC power supply 50, the AC voltage is rectified by the charger 61 to charge the battery 62. Then, when a power failure occurs and the power supply from the commercial AC power supply 50 is cut off, the DC voltage output from the battery 62 is converted into AC by the inverter 63 and supplied to the gas oven 1 via the contactless switch 64.

Here, from the commercial AC power supply side (df side) by the non-contact switch 64 to the uninterruptible power supply unit 60 side (e-
Switching to the f) side is performed instantaneously when a power failure occurs. Then, before all the electric charges charged in the battery 62 are consumed, the supply of the AC power from the AC generator 52 is started. Therefore, even if a power failure occurs during cooking, the gas oven 1 can continue cooking without stopping the operation, and can prevent cooking failure due to the power failure.

In this case, too, the uninterruptible power supply 60
When the frequency accuracy of the AC power supplied from
Since the timer 32 performs time counting based on the preliminary pulse signal CKs counted by the second counter 28, the reference pulse signal CKb is extracted from the AC power supply whose frequency output from the uninterruptible power supply 60 is not accurate, It is possible to prevent inaccurate timing from being performed based on the reference pulse signal CKb.

In the present embodiment, the gas oven 1 is exemplified as the device of the present invention. However, as long as the device has a timer function, it can be used for other types of cooking devices, air conditioners, hot water appliances, and the like. The present invention can also be applied to this.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of a gas oven including a function of a timing device of the present invention.

FIG. 2 is a control block diagram relating to timing of the gas oven shown in FIG.

FIG. 3 is a flowchart of a timing process.

FIG. 4 is a configuration diagram when a backup power supply device is provided.

[Explanation of symbols]

1. Gas oven, 2. Burner, 10. Operation panel, 2.
0: controller, 21: microcomputer, 22
... commercial AC power supply, 23 ... power supply circuit, 24 ... backup battery, 25 ... ceramic oscillator, 26 ... waveform shaping circuit,
27 first counter, 28 second counter, 29 comparison calculation unit, 30 reference pulse failure detection unit, 31 counter switching unit, 32 clock unit, 33 calibration unit, 35 storage unit,
52: AC generator, 60: Uninterruptible power supply

Claims (8)

[Claims] 1. A timing device having a reference pulse signal output circuit for extracting and outputting a reference pulse signal based on a frequency from a commercial AC power supply supplied at a predetermined frequency, and performing timekeeping based on the reference pulse signal. A preliminary pulse signal output circuit that outputs a preliminary pulse signal whose frequency accuracy is lower than that of the reference pulse signal; a reference pulse signal detection unit that detects the reference pulse signal output from the reference pulse signal output circuit; When the reference pulse signal is detected by the pulse signal detection means, time measurement is performed based on the reference pulse signal.When the reference pulse signal is not detected by the reference pulse signal detection means, time measurement is performed based on the preliminary pulse signal. A switching time counting means for performing the switching. 2. A calibration for inputting the reference pulse signal and the preliminary pulse signal and calculating a calibration parameter for calibrating timing data measured based on the preliminary pulse signal to timing data based on the reference pulse signal. 2. The apparatus according to claim 1, further comprising a parameter calculating unit, wherein the switching timer unit calibrates the timing data measured based on the preliminary pulse signal using the calibration parameter when performing the clocking based on the preliminary pulse signal. Timing device as described. 3. The timekeeping device according to claim 2, further comprising a non-volatile storage unit that stores the calibration parameter. 4. The timekeeping device according to claim 1, further comprising a microcomputer, wherein the spare pulse signal is used as an operation clock of the microcomputer. 5. The timekeeping device according to claim 1, wherein the timekeeping device is provided in the cooking appliance and measures the cooking time of the cooking appliance. 6. The timekeeping device according to claim 1, further comprising a notifying unit for notifying when the reference pulse signal is not detected by the reference pulse signal detecting unit. apparatus. 7. The pulse signal detecting means, when detecting that a pulse signal having a frequency within a predetermined range is output from the reference pulse signal output circuit, determines that the reference pulse signal is output. When the commercial AC power is supplied, the timing device is operated by the commercial AC power, and when a power failure occurs and the commercial AC power is not supplied, the AC power supplied from the backup power supply is The timekeeping device according to any one of claims 1 to 4, wherein the timekeeping device is provided in a device that operates according to (1). 8. The timekeeping device according to claim 7, wherein the backup power supply is an uninterruptible power supply.