DE2641972A1 - Combined electronic watch and cigarette lighter - has digital LED display in side of electronically ignited gas lighter with common battery - Google Patents

Abstract

The digital electronic watch is combined with a gas cigarette lighter, the watch display module (7) positioned adjacent the lighter flame. A battery is incorporated in the gas lighter (31) and is also used as the supply battery for the watch circuit. The watch display module (7) uses a liquid crystal display and is inserted in the front face of the lighter beneath the flame source, at the top of the lighter. An oscillator may be coupled to both the watch circuit and via a transformer to the HF ignition circuit for the lighter flame.

Description

Electronic clock with digital display

The invention relates to an electronic watch with a digital display. In recent years, mechanical watches are gradually and at a considerable rate Extent has been replaced by semi or fully electronic timers that take place a pen have a traction battery and also a digital display. Such electronic clocks with digital displays and quartz crystal oscillators as precision time bases can be divided into two main groups. One includes clocks with liquid crystal displays, the other with an LED display. The former are hereinafter referred to as the "LCD" type marked0 The display is not without the human eye on these clocks further recognizable when the background is dark. Usually there is a switch provided to turn on a small electric lamp covering the display area enlightened. The switch is activated either by finger pressure or by gravity or directly closed indirectly by touching the skin. Even when using such switching means cannot prevent the valuable battery energy from being used up quickly will. In this case, an electrical switching surge or impulse is also applied to the the part containing the precision time base is transmitted where it is disturbed by its work will. The same goes for electronic watches with an analog display that also have a have such a precision time base. Again, the frequent involvement of a specially provided electrical lighting to that contained in the clockwork Battery is used up quickly.

In the second group of clocks, referred to here as the "LED" type no electrical lighting is provided, as the display is self-sufficient shines. In this case, however, care must also be taken to ensure that the transmission of switching shocks or pulses is prevented.

The invention aims to provide watches, in particular SCD watches, with an effective Equip flame light source.

The invention further aims to provide a battery-powered electronic Combine clock with a gas lighter that ignites one from a battery Having fed high-voltage spark gap.

According to the invention, the electrical lighting of the clock display is through an on and off switchable flame light source replaced, so that the energy consumption the battery is reduced.

A device according to the invention accordingly has an electronic one Clockwork with digital display, designed as a clockwork module and SCD digital display and is combined with a flame light source fed by liquid gas, which lights up the display instead of an electric bulb.

According to the invention, there is a common battery for both parts of the device provided, i.e. as an energy source for the electronic clock and source for the Ignition energy of the flame light source.

The flame is generated by igniting a gas stream that is emitted by a LPG container is dispensed.

The clock module, the flame light source and a common battery for both parts are housed in one housing, with the display in or on a wall of the housing is formed. A blocking oscillator is electrical on the one hand with the clock module and on the other hand with a high-voltage spark ignition circuit connected for the flame light source. The latter connection is via a step-up transformer.

The clock module, the lock oscillator and the spark circle are with provided a positive earth connection to prevent switching pulses from the flame light source side to the clock module side. Further a diode is provided in the spark ignition circuit for this purpose.

A second step-up transformer provides the necessary for the ignition sparks High voltage and is located directly in front of the spark gap, Further Advantages and features of the invention emerge from the claims as well as from The following description and drawings, in which the invention is exemplified is explained and illustrated. 1 shows a block diagram of a device according to the invention Combination of clock and flame light source, Fig. 2 a more detailed Circuit diagram of a device according to the invention, Fig. 3 shows a series of voltage pulse or waveforms appearing at different points in the circuit of FIG. 2, 4 shows a circuit modified from FIG. 2, FIGS. 5-6 show the sequence over time control operation diagrams for the embodiment of FIG FIGS. 4 and 7-9 show the arrangement of different parts of the combination according to the invention within the common housing.

The arrangement shown in Fig. 1 as a block diagram has a Voltage source 1 in the form of a 3-volt battery. The one delivered by this source Current goes to a branch point 100 and from there to the input 104 of a voltage regulator 2 and further to the first input 101 of a crystal oscillator 4. The output voltage of the voltage regulator 2 becomes a flame generator via a branch point 103 3 supplied. The point 103 can be through a power 13 with an input 102 of the Oscillator 4 be connected. If the second input 102 is used is, can on the branch line 15, here the first connection point 100 and the Input 101 connects, can be omitted.

The crystal oscillator 4 is electrically connected to a frequency divider 14, a power amplifier 5, a driver circuit 6 and a display device? connected in the order shown.

These devices 4, 14, 5, 6 and 7 are in the movement part or Clock module included, which is shown in Fig. 1 by the dash-dotted block line w is.

In the more detailed illustration of Figure 2, the clock module is again shown as block W. The voltage regulator has a blocking oscillator in this case BO, which has a switch SW-1, a voltage source 1, a transistor Tr-1, a variable resistor WR, a coil element L1 and connection points 100, 106 and 107 contains 0 Point 107 is grounded.

The module W has a time display reading switch SW-2 and a time correction switch SW-3, which are actually known. The two switches SW-2 and SW-3 can also be found on conventional electronic clockworks, especially on wristwatches. On the switch SW-2 can, however, be dispensed with if the clock or the movement has a liquid crystal display (LCD) is equipped.

The output signal of the block oscillator circuit BO, or more precisely that of the oscillator transistor Tr-1, at 10 volts, 2.5 kHz, becomes a coil element L2 supplied, which is a primary winding Step-up transformer T 1 is used, which has a secondary winding L3.

The secondary winding L3 is contained in an ignition circuit IG to which a rectifier diode 20, connection points 21, 22 and 23, a charging capacitor 24, a second transformer T2 with primary and secondary winding Ii4 and L5 and one Spark gap SP are formed between a pair of spark electrodes 25, 26 and was usually about 2 to 3 mm. One bidirectional and two connections having thyristor SS is between the two connections 21 and 22. The connection 23 is grounded.

The first or main transformer T1 is to step up its Primary voltage of 10 V is provided on the secondary voltage of 100 V. The second or spark transformer T2 is used to step up its primary voltage from 100 V to the secondary voltage of around 8,000 V.

In Fig. 3 different voltage curves are shown, which at the with 108 to 112 designated points of the circuit 2 occur.

Even if the ignition switch SW-1 is opened as shown is, the clock module W can work in a regular manner, since via the connection 107, the ground and the terminal 113 of the module current can flow.

It is assumed that 1 module \ with liquid crystal display (LCD) Is provided. If then the time display can be viewed in the dark the ignition switch SW-1 is closed and thereby the lock oscillator circuit BO excited. In this way, a high ignition voltage of around 8,000 V is generated and bridges the ignition spark gap SP, which is present in section 3 and tightly is adjacent to the gas outlet nozzle. Therefore, it becomes the flame light generating portion 3 ignited, and the flame used to display the liquid crystals enlighten. This spark excitation and ignition process is repeated until the switch SW-1 is opened again. The thyristor SS is designed in such a way that it becomes conductive, when the input voltage reaches 100V. In this way, otherwise become possible Prevents misfire.

According to the present invention, a common battery for the clockwork and section 3 used. As mentioned, Section 3 has a Pair of spark electrodes that form a relatively large spark gap, usually approx. 2 - 3 mmO Therefore, a high ignition voltage, approx. 8 - 10 kV, must be applied to the spark gap forming electrodes are applied. These ignition voltages are therefore essential higher than the battery voltage, which is only around 3V. To prevent that High voltage switching surges on the precision time base, i. here the crystal oscillator 4, special means are provided. Serves as the first safety device for this purpose the diode 20.

Other safety devices for this purpose are the positive earth connections are provided at 23, 107 and 113.

A modified circuit is shown in FIG. The clockwork and the gas lighter ignition, see the upper left part of Fig. 4, are essentially as shown in Fig. 2 is formed. Therefore, in Fig. 4, this is part of the device shown only in simplified form. In the modified circuit there is also a time constant circle TC and a thermistor UM included. The parts TC and UM are designed and arranged in such a way that that they interrupt the spark generation in the spark gap SP when the flame of section 3 has been ignited.

The circuit TC includes a transistor Tr-2, a resistor 27 and a capacitor 28 which together form a timing element. The Elements and the thermistor TM are connected to each other as shown in FIG.

When the switch SW-1 is open as shown, will occasionally electric charge accumulated in the capacitor 28 via the resistor 27 completely discharged, If the switch SW-1 is on, the capacitor 28 is over a resistor 29 charged, which lies between the points 107 and 115, and the Resistance at thermistor sensor TM held at normal temperature.

If the charge voltage is dimensioned so that it is slightly smaller than the terminal voltage of the base-emitter path of the transistor Tr-2, measured in the forward direction, this transistor cannot work normally, while the blocking oscillator BO continues to work to generate the required operating current to be fed to the spark pulse generation circuit. Therefore, sparks are periodically sent to the Spark gap generated in time intervals of e.g. 0.45 seconds.

One that flows out of a gas nozzle of the gas lighter under these circumstances This ignites the gas flow. The thermistor sensor UM, which is immediately adjacent to the flame and at least to a lowest temperature of 70 - 800C responds, senses the presence of the ignited gas flame.

Due to this perception, the resistance of the thermistor is decreased and increases the electrical charge in capacitor 28 up to a predetermined value, which must be above the base-emitter voltage, WBE, of transistor Tr-2.

When the capacitor charge voltage becomes higher than the WBE voltage, the transistor Tr-2 is set in operation, so that thereby the blocking oscillator BO ceases its oscillation activity.

These processes are explained further with reference to FIG. 5.

In Fig0 5, the curves (1) correspond to the operating conditions that occur when the gas ignition has been carried out with the first spark pulse. The curves (2) correspond to a slightly delayed ignition with the second spark pulse. The one with (3) designated curves correspond to a misfire condition, although a spark pulse or pulses have been generated. If there is a misfire the next or more spark pulses are used for ignition purposes.

When the gas is ignited, the oscillator ceases to function; Transistor Tr-1 is interrupted, and the electric current is then partially passed through the resistor WR transferred to the collector-emitter path of the transistor Tr-2 and at the same time part of the current then flows through the resistor 29 and the thermistor TM to Base electrode of the same transistor Tr-2. Due to the dimensioning of the associated Switching elements can reduce the last-mentioned current to a tenth to a twentieth of the operating current can be set in the operating state of the blocking oscillator BO occurs.

The time constant of the circuit TC defines a certain period of time, about 5 - 10 seconds. During this period of time, counting from the extinction of a previously ignited gas flame, the thermistor sensor TM reaches the resistance value again its cold state. After this period of time has elapsed, it is sufficient for a new ignition of the lighter actuation of the switch SW-1, after its closure the aforementioned Operating steps are repeated.

Another possibility for renewed gas ignition can be provided immediately after opening the switch SW-1 after using the once ignited Gas flame. In this case the thermistor sensor TM has a resistance value for the hot state, which is considerably lower than that for the cold state is. By interrupting the switch SW-1, the charge on the capacitor 28 becomes discharged through the parallel resistor 27. If the time constant of the circuit TC set to a value that is less than the length of time required for a On-Off actuation of the switch is required, e.g. about 0.5 seconds, sets the blocking oscillator BO continues its activity, despite the short time interruption SW-1. Therefore, in this case, one or two sparks will be generated at the spark gap SP, and the gas flow is ignited immediately. In this embodiment, the die works Gas flame generating part is good even if the thermistor sensor TM is not yet has returned to its cold state. This operating characteristic is schematic in Fig.

illustrated.

If the thermistor sensor TM and the lighter operating resistance are omitted the circuit shown in Fig. 4 to a higher value than that of the voltage WBE of the transistor Tr-2 is set instead of the lower value As mentioned above, spark pulses can still occur at the spark gap SP after closure of the switch SW-1 can be continuously generated for a predetermined period of time. In this way, a flame ignition working with a spark gap is created, which is equipped with a kind of timer.

FIGS. 7-9 show a preferred practical embodiment the invention. 7 and 8 show vertical sections and Figo 9 is a perspective view of a device according to the invention. The device has a housing 31 with a pivotably arranged cap 30, which is shown in FIG. 9 is open. The time display 7 is a digital display in the front of the Housing 31 formed.

7 and 8, when the cap 30 is held in its closed position a thumb or pusher 32 fixedly attached to the cap applies pressure on one end of a toggle lever 33 which is pivotably arranged at 34, so that the end of the other lever arm acts on a gas burner nozzle 35 to this hold in the closed position. The uppermost end of the nozzle 35 forms the one spark gap electrode 26. The other spark electrode 25 can also be seen in FIG. 7 and lies close together adjacent to the upper end of the nozzle, i.e. its movable valve member.

When the cap 30 is brought into its open position, see Fig. 9 is from the fuel tank 36, which contains a quantity of liquid gas in the usual way, delivered a gas stream. By pressing the switch button SW-1, the gas flow in in the manner described above by the electrical spark discharge between the electrodes 25 and 26 ignited.

The switch SW-1 can either be a spring-loaded one Be a push button or a slide that can be moved up and down. A slide switch SW-1 can be arranged to fire when the switch is in its uppermost position Has. And the Indicator 7 can be turned on when the switch from above via a middle "off" position into a second, lower 'IEin' 'position is brought. In this way, the two switches shown in FIG SW-1 and SW-2 are combined in a double switch.

The slide switch SW-1 can be further modified and connected that is turned off in its uppermost position, while in the middle and the lowest position for the ignition or display is switched on. Instead of this can also be the middle position for the display and the lowest position for the ignition be used.

In Figure 2, switches SW-2 and SW-3 are grounded at 116. In Fig. 4, the connection point 117 of the second transistor Tr-2 is immediately adjacent provided to the base electrode of the first transistor Tr-1

Claims (9)

REQUIREMENTS: 1. Electronic clock with a clockwork module and digital display, in particular of the LCD type, characterized in that the display device (?) and a gas flame light source (35) are disposed adjacently. 2. Clock according to claim 1, characterized in that the clockwork module (W), the gas flame light source (35) and a battery common to both parts (1) are arranged in a common housing (31,30), on one wall of which the Display device (7) is arranged. 3O clock according to claim 1 - 2, characterized in that a blocking oscillator (Bo) electrically on the one hand with the movement module (W) and on the other hand via a Step-up transformer (T1) with a high voltage spark ignition circuit (IG) of the gas flame light source connected is. 4O clock according to claim 3, characterized in that the clockwork module (W), the blocking oscillator (Bo) and the spark ignition circuit (IG) with means for Prevention of the transmission of a switching shock from the switching of the gas flame light source are equipped on the clockwork module. 5. Clockwork according to claim 4, characterized in that the clockwork module (W), the blocking oscillator (B0) and the spark ignition circuit (IG) each with one positive earth connection (113,107,23) are provided. 6. Movement according to claim 4-5, characterized in that the spark ignition circuit (IG) contains a diode (20). 7. Clock according to claim 6, characterized in that a second step-up transformer (T2) by the first transformer (T1) further increased, the diode (20) and the Grounding (23) between the secondary winding of the first and the primary winding of the second transformer, 8. Clock according to claim 7, characterized by a Thyristor (SS) in parallel with the primary winding of the second transformer (T2). 9. Clock according to one of the preceding claims, characterized in that that the blocking oscillator has a thermistor (UM) in conjunction with a time constant defining transistor circuit (TC) for the automatic control of the gas flame light source has igniting spark gap (SP).