JP2006275571A - Digital clock - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To facilitate reading of digital indication of time in a digital clock by turning on a light source with proper brightness. <P>SOLUTION: In a digital clock indicating time in digital by turning on a light source, a controller circuit 50 making variable duty ratio which is a ratio of turn-on time of the light source to total indication time of digital indication. By changing the duty ratio of the light source with the controller circuit according to various conditions, the brightness of the digital indication is made to be proper. For example, a dial plate 24 digital-indicating time by transmitting the light when turning on the light source is provided based on time data 52 and the output signal of a provided light sensor 55. When each figure indication digitally indicating, is turned on by shifting in turn for a light source outage time X based on the light transmission of the dial plate and based on the voltage detection data 58, the downtime of the light source is changed so that the duty ratio is made variable in the controller circuit. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a digital timepiece, in particular, a wristwatch, which digitally displays a time using a number or the like by turning on a light source such as an LED.

  Conventionally, in a digital wristwatch, for example, as shown in FIG. 7, two-digit number display DIG1, DIG2, DIG3, DIG4 formed by using a light source such as an LED on the display surface 1 two by two with a colon 2 in between. They were arranged side by side, and the time was digitally displayed as a whole.

  Then, as shown in FIG. 8, each number display DIG1, DIG2, DIG3, DIG4 is lit intermittently every b hours at a constant interval a, and each number display DIG1, DIG2, DIG3, DIG4 is sequentially turned on by c hours. It was switched and turned on and displayed for d hours as a whole.

Japanese Utility Model Publication No. 54-172766 JP-A-8-122468

  However, conventionally, the light source lighting interval a, the light source lighting time b, and the light source pause time c are all constant, and the duty ratio, which is the ratio of the lighting time b during which the light source is lit, to the entire display time d for digital display is It was constant. The duty ratio is set to be large so that it is as bright as possible.

  If the light source is used for a liquid crystal backlight, a peripheral illumination that illuminates the surroundings, or a dial illumination that illuminates the dial, the brighter the better. However, when it is used for number display DIG1, DIG2, DIG3, and DIG4 for digital display, there is a problem that the digital display becomes difficult to read if it is too bright.

  SUMMARY OF THE INVENTION An object of the present invention is to facilitate reading of a digital display with appropriate brightness in a digital timepiece that lights a light source and digitally displays time.

In order to achieve such an object, the present invention provides a digital timepiece that digitally displays a time by turning on a light source.
And a control circuit that varies a duty ratio, which is a ratio of a lighting time during which the light source is lit to a total display time during which digital display is performed.

  Then, according to various conditions, the control circuit changes the duty ratio of the light source so that the digital display has an appropriate brightness.

  For example, based on time data, equipped with a light sensor and based on the output signal of the light sensor, and equipped with a dial that transmits the light when the light source is turned on and digitally displays the time, and transmits the light through the dial. Based on the rate, and based on the voltage detection data, when the number display to be digitally displayed is switched in order by shifting the light source pause time in order, the duty cycle can be made variable by changing the light source pause time, etc. To do.

  According to the present invention, in the digital timepiece that lights the light source and digitally displays the time, the digital display is adjusted to an appropriate brightness by changing the duty ratio of the light source by the control circuit according to various conditions. It is easy to read and saves power without unnecessary power consumption.

  For example, the digital display is bright during bright days, dark during dark nights, bright when indoor environments are bright, dark when dark, or digitally displays the time through the dial when the light source is turned on. In the case of a digital watch, use a dial with low light transmittance to brighten, use a dial with high light transmittance to darken it, or darken it when the battery is not depleted. When you are doing it, make it brighter.

The best mode of the present invention will be described below with reference to the drawings.
FIG. 1 shows an analog-driven digital wrist watch that is analog-driven and can digitally display the time by turning on a light source as necessary.

  In the illustrated wristwatch, a windshield glass 11 is fixed to the front side of the watch case 10 and a back cover 12 is screwed to the back side. The back cover 12 is made of a non-magnetic material such as plastic or a metal that is not a ferromagnetic material.

  In the watch case 10, an analog movement 13 is fixed and stored with a resin inner frame 14. The movement 13 is provided with a hand movement shaft 15 for the hour hand, the minute hand, and the second hand concentrically at the center. A disc-shaped circuit board 16 is overlaid on the movement 13. For example, a plurality of thin chip LEDs (digital display LEDs) 17 having a length of 1.6 mm, a width of 0.8 mm, and a thickness of 0.5 mm or less are attached to the circuit board 16.

  Then, as shown in FIG. 2, one number display DIG11, DIG12, DIG13, DIG14 is configured using seven LEDs 17, and the number display DIG11, DIG12, DIG13, DIG14 forming the figure 8 is a plane. Line up four. In the circuit board 16, a central hole a is formed at the center, and a colon 19 is configured by using LEDs 17 provided one by one above and below the central hole a. Then, two numbers DIG11, DIG12, DIG13, and DIG14 are distributed and arranged on the left and right with the colon 19 in between.

  As shown in FIG. 1, the circuit board 16 is attached to the light shielding plate 22 that is slightly thicker than the circuit board 16 and supported by the light shielding plate 22. As shown in FIG. 3, a plurality of light transmission holes 23 are formed in the light shielding plate 22 so as to penetrate the front and back surfaces. The light transmission holes 23 are opened to face the respective thin chip LEDs 17 of the circuit board 16, the LEDs 17 are provided corresponding to the light transmission holes 23, respectively, and the circuit board 16 is provided on the back side of the light shielding plate 22. When attached, the thin chip LED 17 is inserted. And even if the circuit board 16 is overlaid on the light shielding plate 22, the thickness is 1.5 mm or less.

  As shown in FIG. 1, on the light shielding plate 22, a dial plate 24 having a time display such as a time numeral or a time character is superimposed on the surface. The dial 24 is formed, for example, by attaching ink to the surface of a transparent material made of plastic, glass, or the like by printing or using a colored translucent material made of plastic, glass, or the like. Only when the display LED 17 is turned on, a digital display of the LED 17 is formed with a light transmittance that can be seen through the dial 24. Preferably, the light transmittance is 30 to 70%. Then, the entire periphery of the dial 24 is placed in the watch case 10 with the peripheral edge of the dial 24 being applied to the parting portion of the watch case 10.

  In this way, the light shielding plate 22 is provided on the back side of the dial plate 24, the circuit board 16 is disposed on the back side of the light shielding plate 22, and the movement 13 is provided on the back side of the circuit board 16. Thereby, the LED 17 for digital display on the circuit board 16 is arranged on the back side of the dial plate 24.

  The hand movement shaft 15 penetrates from the center hole a of the circuit board 16 to the center hole of the dial plate 24 (indicated by reference numeral c in FIG. 1) through the central hole of the light shielding plate 22 (indicated by reference numeral b in FIG. 3). The front end is exposed to the front side of the dial plate 24. Then, the hour hand 25, the minute hand 26, and the second hand 27 are attached to the tip.

  A charging circuit is provided on the back cover 12 side of such a movement 13, and a coin-type secondary battery 30 is arranged so as to overlap the movement 13, and the coil bobbin 31 is annularly surrounded so as to surround the secondary battery 30. And the secondary coil 32 is attached. That is, in the illustrated example, the secondary battery 30 and the secondary coil 32 are arranged on the same plane in the watch case 10.

  In the wristwatch case 10, an LED drive circuit 33 that drives the LEDs 17 is attached to the back side of the circuit board 16 in the same plane as the movement 13.

  On the other hand, in the illustrated wristwatch, a winding stem 36 for attaching the crown 35 to the outer end is inserted through the wristwatch case 10 and placed in the movement 13. Although not shown, an operation shaft for attaching a switch to the outer end is similarly inserted through the watch case 10 and placed in the movement 13.

  In the illustrated digital wristwatch, normally, the digital display LED 17 is not lit, the movement 13 is driven by the secondary battery 30 to rotate the hands 25 to 27, and the time display on the dial 24 is indicated. Analog display. If necessary, the LED 17 is turned on by appropriate external operation, the light of the LED 17 is guided through the light transmission hole 23 of the light shielding plate 22 and is transmitted through the dial plate 24, and the time, month, day of the week, etc. are digitally displayed. .

FIG. 4 shows a block diagram of the above-described wristwatch.
The wristwatch shown in the figure includes a light source duty variable control circuit 50 that varies a duty ratio that is a ratio of a lighting time during which the light source is lit to a total display time during which digital display is performed. Then, according to various conditions, the control circuit 50 changes the duty ratio of the light source to make the digital display appropriate brightness.

  For example, information obtained from an analog or digital timekeeping function is reserved in the microcomputer 51 as time data 52, and the time data 52 is input to the light source duty variable control circuit 50, and the duty ratio of the light source is varied based on the time data 52. Then, the light source driving circuit 53 is driven, and the display unit 54 performs digital display.

FIG. 5 shows the drive timing of each number display DIG11, DIG12, DIG13, and DIG14 on the display unit 54.
As shown in the figure, each number display DIG11, DIG12, DIG13, DIG14 is lit intermittently every B hours at regular intervals A, and each number display DIG11, DIG12, DIG13, DIG14 is sequentially turned on for X hours. The lights are switched and shifted, and the display unit 54 displays the D time as a whole.

  In the illustrated wristwatch, for example, by changing the light source pause time X, the control circuit 50 makes the duty ratio variable. Then, the time data 52 is used to determine whether it is daytime or nighttime. During bright daytime, the light source pause time X is reduced to lighten the digital display, and during dark nighttime, the light source pause time X is increased to digitally Darken the display and make the digital display easier to see. Naturally, if the light source pause time X is 0, the duty ratio is 100%, and the digital display is brightest.

  For example, as shown in FIG. 6, an optical sensor 55 is provided on the circuit board 16 on the back side of the dial plate 24. Then, the output signal of the optical sensor 55 is input to the microcomputer 51 as shown in FIG. 4 and held as optical sensor data 56, and the optical sensor data 56 is input to the light source duty variable control circuit 50. Based on the above, the duty ratio of the light source is varied to drive the light source driving circuit 53, and the display unit 54 performs digital display.

  Then, the indoor environment is detected using the built-in optical sensor 55, the indoor brightness is determined by the optical sensor data 56, and when it is bright, the light source pause time X is reduced to brighten the digital display, and when it is dark Increases the light source pause time X to darken the digital display and make the digital display easier to see.

  Further, the light transmittance of the dial 24 is inputted and stored as dial light transmittance data 57 in the microcomputer 51 as shown in FIG. 4, and the dial light transmittance data 57 is inputted to the light source duty variable control circuit 50. Then, based on the dial light transmittance data 57, the duty ratio of the light source is varied to drive the light source driving circuit 53, and the display unit 54 performs digital display.

  Then, the light transmittance of the dial 24 being used is determined from the dial light transmittance data 57, and when using a dial with a low light transmittance, the light source pause time X is reduced to brighten the light source. When using a dial plate with high light transmittance, the light source pause time X is increased to darken the digital display and make the digital display easier to see.

  Further, the voltage of the secondary battery 30 is detected by a voltage detection element built in the circuit, the detected voltage is stored in the microcomputer 51 as voltage detection data 58, and the voltage detection data 58 is stored in the light source duty variable control circuit 50. The light source duty circuit 53 is changed based on the voltage detection data 58 to drive the light source driving circuit 53 and digitally displayed on the display unit 54.

  When the battery voltage is low, that is, when the battery is exhausted below the detected battery voltage, the light source pause time X is reduced to brighten the digital display, and when the battery voltage is high, that is, the battery is exhausted. If not, the light source pause time X is increased to darken the digital display to make the digital display easier to see. At the same time, current consumption is reduced.

  In the illustrated example described above, the case where the digital display has four digits including the number displays DIG11, DIG12, DIG13, and DIG14 has been described. Needless to say, the digital display is not limited to four digits. In addition, the duty ratio can be determined by combining conditions such as time data, photosensor data, dial light transmittance data, voltage detection data, and the like, and the digital display can have appropriate brightness.

1 is a schematic longitudinal sectional view of an analog-led digital wrist watch according to the present invention capable of performing digital display. It is a top view of the circuit board used with the wristwatch. It is a top view of the light-shielding plate used with the wristwatch. It is a block diagram of the wristwatch. It is a drive timing chart of each number display in a digital display part. It is a top view of the circuit board of other examples. It is a top view of the conventional circuit board. It is a drive timing chart of each number display in the conventional display part.

Explanation of symbols

24 Dial 30 Secondary Battery 50 Light Source Duty Variable Control Circuit 51 Microcomputer 52 Time Data 53 Light Source Drive Circuit 54 Display Unit 55 Photosensor 56 Photosensor Data 57 Dial Light Transmittance Data 58 Voltage Detection Data

Claims (6)

In a digital clock that lights the light source and displays the time digitally,
A digital timepiece comprising a control circuit that varies a duty ratio that is a ratio of a lighting time during which the light source is turned on with respect to an entire display time during which digital display is performed.   The digital timepiece according to claim 1, wherein the duty ratio is made variable by the control circuit based on time data.   The digital timepiece according to claim 1, further comprising an optical sensor, wherein the duty ratio is made variable by the control circuit based on an output signal of the optical sensor.   A dial plate that transmits light when the light source is turned on and digitally displays time is provided, and the duty ratio is variable in the control circuit based on the light transmittance of the dial plate. The digital timepiece according to any one of 1 to 3.   5. The digital timepiece according to claim 1, wherein the duty ratio is made variable by the control circuit based on voltage detection data.   The number of digitally displayed numbers are changed in order by shifting the light source pause time in order to change the light source pause time, thereby changing the duty ratio in the control circuit. 5. The digital timepiece according to any one of 5 above.

Images