KR930008050Y1 - Lantern - Google Patents

Abstract

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Description

Lantern with thermometer

The accompanying drawings are circuit diagrams of a lantern with a thermometer according to the present invention.

* Explanation of symbols for main parts of the drawings

2: transformer 10A: relay coil

10B: relay switch SW: lantern power switch

16: recording circuit 18: digital / analog converter

40: speaker 44: timer

60: mercury thermometer 61: reverse current prevention diode

62: alarm signal oscillator

The present invention relates to a combination of AC and DC power supply lanterns, in particular to provide an alarm function to notify the emergency situation in the event of a fire, as well as to use as an emergency light, and to perform a function that can check the usual ambient temperature with the naked eye. It is about a lantern with a thermometer attached.

Conventional portable lanterns use only batteries and rechargeable batteries are most commonly used. The method of using batteries has a short lifespan, and the method of using rechargeable batteries is for single-color charging and operation. Although each of the light emitting diodes was attached, it was not easy to distinguish them visually, and there was a problem in that an expensive rechargeable battery was destroyed due to overcharging because no means for controlling the state of charge completion was provided.

In order to solve this problem, the Korean Utility Model Registration Application No. 89-8104 of the present applicant uses one tricolor LED which can generate three colors, and the LED emits green light during normal operation. When charging the battery, red light is generated, and when the available voltage of the battery drops below a predetermined voltage level, yellow light is generated, which is a mixed color of green light and red light, so that the user can easily check each operation state visually. Although a lantern has been described, this lantern also has a problem that it is not possible to visually easily identify the operating state of the lantern at a slightly spaced distance.

In order to solve this problem, the Korean Utility Model Registration Application No. 91-7245 of the present applicant warns with a voice signal that the rechargeable battery should be charged when the voltage of the rechargeable battery falls below a predetermined level. A talking lantern has been described for easily identifying the operating state.

However, this lantern also has a function to use as an emergency light at the same time as an alarm to inform the emergency situation in the event of a fire, and in order to solve the above problems because it is not possible to check the ambient temperature as usual, There was an uncomfortable problem of having a lantern separately.

Therefore, the present invention has been devised to solve such a problem, and if the temperature of the mercury thermometer is set to an arbitrary temperature at which a fire occurs in a state where the battery is fully charged, the temperature of the thermometer rises to an arbitrary temperature when a fire occurs. The object of the present invention is to provide a lantern with a thermometer that enables the alarm state and emergency light to easily recognize that a fire has occurred when the temperature is reached.

The present invention for achieving the above object is a rectifying circuit for converting an AC voltage into a DC voltage, a charge control circuit for controlling the voltage rectified in the rectifying circuit to charge a voltage in the battery, and the discharge voltage of the battery is less than a predetermined level A discharge voltage detection circuit for detecting a case of falling down and a data signal indicating that the rechargeable battery should be charged by inputting a signal generated by the discharge voltage detection circuit when the rechargeable battery is discharged, and a charging control circuit when the rechargeable battery is fully charged. Inputs a signal generated from the to generate a data signal indicating the charge completion state of the rechargeable battery, recording circuit for generating a data signal indicating the power failure state by inputting the signal of the rectifier circuit when the AC power is outage And other for generating data signals respectively output from the recording circuits for a predetermined time. The digital circuit, the digital / analog conversion circuit for converting the data signal outputted from the recording circuit into an analog signal, and the digital / analog converted signal, and amplifying the discharge, full charge and blackout of the rechargeable battery as sound signals. In a lantern having a voice output circuit for outputting to the outside, an alarm for outputting an alarm signal by a mercury thermometer for detecting a predetermined temperature in the event of a fire in the discharge voltage detection circuit and a signal output from the thermometer The signal oscillator is configured.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a circuit diagram of a lantern with a thermometer according to the present invention, first, when the user wants to charge the rechargeable battery, the user turns on the power supply voltage (110V / 220V) switching switch 10 and the power switch SW is off. It can be used at 220V when the switch 1 is located at the a-contact and 110V when it is located at the b-contact.

When the power supply voltage is selected by the switch 1, the AC voltage 110V or 220V is applied to the primary coil Lp of the power transformer 2, where the secondary coil Ls of the power transformer 2 is used. ), An AC voltage stepped down to a predetermined voltage is induced and applied to a bridge circuit composed of a plurality of rectifying diodes (3, 4, 5, 6).

Then, the bridge converts the AC voltage into a DC voltage and outputs the DC voltage. Since the output signal includes some noise, the noise can be eliminated by the capacitor 7.

The voltage converted into direct current is applied to the base of the transistor 9 via the resistor 8 and simultaneously to the collector of the transistor 9. At this time, since the transistor 9 is turned on by the bias voltage of the high state via the resistor 8, the DC voltage passing through the collector-emitter of the transistor 9 is applied to the relay coil 10A. As the current flows through 10A, an electromagnetic force is generated so that the relay switch 10B is connected to the a-contact.

On the other hand, the DC voltage past one end of the relay coil 10A is applied to the base of the transistor 12 via the resistor 11, but the transistor 12 is not turned on once by the action of the resistors 11 and 13. Do not. However, the transistor 15 is turned on via the resistor 14 having the negative value characteristic. When the transistor 15 is turned on, a high state signal is applied to the input port A of the recording circuit 16.

Therefore, in this operation, since the DC current is applied to the rechargeable battery 17 via the relay switch 10B, the rechargeable battery 17 is charged.

When the rechargeable battery 17 is charged, the recording circuit 16 recognizes a high state signal to which the input port A is applied, and outputs a digital data signal through its output terminals D1 to D8. The digital data signal generated in this way is applied to the input terminals IN1 to IN8 of the digital / analog converter 18. At this time, the digital / analog converter 18 transmits a signal having a predetermined level through its output terminals Q1 to Q8. Will print This output signal is applied to the differential amplifier 39 via a plurality of resistors 19 to 35, capacitors 36 and 37, and variable resistor 38, amplified, and then output to the outside through the speaker 40. . Herein, the fact that the rechargeable battery 17 is charged is pre-recorded in the recording circuit 16. The recording circuit 16 is preferably a digital RAM.

On the other hand, as the rechargeable battery 17 is charged, the current supplied to the rechargeable battery 17 gradually decreases. For example, when the battery 17 is charged to 7 V, it is bypassed to the current zener diode 41, and thus the zener diode 41 Is turned on so that the current flowing through the variable resistor 42 increases, so that the transistor 43 is turned on. Then, the current through the resistor 8 is bypassed to the ground through the collector-emitter of the transistor 43, so that the transistor 9 is turned off, so that no charge flow is supplied to the rechargeable battery 17, so that further charging It doesn't work.

However, before the transistor 9 is turned off, while the voltage of the rechargeable battery 17 is gradually charged, the current flowing through the resistor 14 decreases while the current flowing through the resistor 11 increases. Accordingly, since the voltage level of the resistor 11 and the variable resistor 13 increases, the transistor 12 is gradually turned on. At this time, since the transistor 15 is turned off, the input port A of the recording circuit 16 is turned off. The low signal is input. Then, the recording circuit 16 recognizes a signal in a low state and outputs a digital data signal indicating that the rechargeable battery 17 is fully charged. The digital data signal is analogized by the digital / analog converter 18. After the signal is converted to the outside through the speaker 40 as described above, the user can easily identify the state of completion of charging of the rechargeable battery 17.

On the other hand, a case where a power failure occurs at the time of charging such a rechargeable battery 17 will be described. In the normal AC power supply, the DC voltage generated in the bridge circuit is applied to the input port B of the recording circuit 16 in a high state. In this case, the recording circuit 16 recognizes this and does not generate an output signal. When the input port B changes from high to low, that is, when the Brit circuit does not operate due to a power failure, the recording circuit 16 generates a data signal indicating that power failure has occurred.

By the way, in the recording circuit 16 of FIG. 1, when the rechargeable battery 17 is being charged and at the completion of the charging, the rechargeable battery 17 is being charged and generates a voice signal indicating a charging completion state or generating a voice signal indicating a power failure state. The time is during the operation time of the timer 44. Thus, upon power failure or charging and charging of the rechargeable battery 17, the recording circuit 16 generates a data signal through its output terminals D1 to D8 during the operation time of the timer 44.

The data signals D1 to D8 are different from each other at the time of power failure, charging of the rechargeable battery 17, and completion of charging, and this state can be stored in advance.

When the charging of the rechargeable battery 17 is completed, no current flows through the relay coil 10A, so the relay switch 10B is located at the b-contact point. Therefore, the direct current voltage discharged from the rechargeable battery 17 turns on the transistor 47 through the resistors 45 and 46. In this case, the current through the resistor 48 does not turn on the transistor 49. A low state signal may be input to the input port C of the circuit 16.

In addition, when the power switch SW is turned on, the lamp 50 is operated and the light emitting diode 52 is turned on via the resistor 51.

Therefore, the light by the lamp 50 is emitted in all directions, and the light by the light emitting diode 52 is generated. However, when only the light emitting diode 52 is operated and the lamp 50 does not operate, the user can easily know that an abnormal state has occurred in the lamp 50.

At this time, the alarm signal oscillator 62, the differential amplifier 39, and the speaker 40 to sound the alarm in the event of a fire are not operated by the reverse current prevention diode 61.

On the other hand, it is necessary to have a means for detecting when the voltage of the rechargeable battery 17 drops below a predetermined voltage, for example, 4V due to the long time use of the lantern, as shown in FIG. In the case where the resistor 46 is provided to change the value of the variable resistor 46, the operating voltage of the storage battery 17 that can be used can be arbitrarily adjusted.

If the variable resistance value 46 is set to turn off the transistor 47 when the discharge voltage of the battery 17 is 4V or less, the transistor 17 is 4V or less while the lantern is in use. Since the bias voltage applied to the base of 47 is also reduced, the transistor 47 is turned off. In other words, the bias of the low state is applied to the base of the transistor 47 according to the voltage ratio set by the resistors 45 and 46, and the transistor 47 is turned off.

When the transistor 47 is turned off, the base voltage of the transistor 49 via the resistor 48 increases, so that the transistor 49 is turned on. At this time, a high voltage signal is applied to the input port C of the recording circuit 16. The recording circuit 16 recognizes this and generates a data signal for outputting an acoustic signal indicating that the rechargeable battery is to be charged. Thus, the user can easily identify that the current rechargeable battery 17 must be charged.

In addition, when a fire occurs in a state where the battery is fully charged, when the temperature rises and reaches a temperature set to a certain temperature, a predetermined alarm is generated and at the same time, it is used as an emergency light. There needed to be a means.

To this end, as shown in FIG. 1 of the present invention, a mercury thermometer 60, a reverse current prevention diode 61, and an alarm signal oscillation unit 62 are attached to operate the thermometer switch 60A when a fire occurs.

For example, it is assumed that the set temperature at the time of fire occurs at 60 ° C., and when the temperature of the mercury thermometer reaches 60 ° C., the reverse current prevention diode 61 operates because the thermometer switch 60A is turned on. 50 is activated and the light emitting diode 52 is turned on via the resistor 51.

Therefore, the light by the lamp 50 is radiated in all directions as in the state of turning on the power switch SW described above, and the light by the light emitting diode 52 is generated. However, when only the light emitting diode 52 is operated and the lamp 50 does not operate, the user can easily know that an abnormal state has occurred in the lamp 50.

On the other hand, the oscillation signal output from the alarm signal oscillator 62 at the same time as the operation of the lamp 50 is amplified by the differential amplifier 39 to output the alarm signal through the speaker 40 to the outside.

As shown in FIG. 1, when the power switch SW is turned off and when no fire occurs, that is, when the thermometer switch 60A is turned off, the ambient temperature can be easily judged as related. To make it possible.

The present invention, which operates as described above, can not only visually identify these states by sounding the charging state, the discharge state of the rechargeable battery and the power outage state of the AC power, but also generates an alarm sound in case of fire. At the same time, it functions as an emergency light and can be used as a normal thermometer.

Claims (1)

A rectifier circuit for converting an AC voltage into a DC voltage, a charge control circuit for controlling a voltage rectified in the rectifier circuit to charge a battery, and a discharge voltage for detecting when the discharge voltage of the battery falls below a predetermined level. A sensing circuit and a signal generated by the discharge voltage sensing circuit are inputted when the rechargeable battery is discharged to generate a data signal indicating that the rechargeable battery needs to be charged, and a signal generated by the charge control circuit is inputted when the rechargeable battery is fully charged. Generates a data signal indicating the charge completion state, and outputs from the recording circuit and the recording circuit for generating a data signal indicating the power failure state by inputting the signal of the rectifier circuit when the AC power is outage A timer circuit for generating a predetermined data signal for a predetermined time, and outputting from the recording circuit A digital / analog conversion circuit for converting a data signal into an analog signal, and an audio output circuit for amplifying the digital / analog converted signal and outputting a discharged, fully charged, or blackout state of a rechargeable battery to an external device as an acoustic signal. In the lantern, the discharge voltage detection circuit comprises a mercury thermometer for detecting a predetermined temperature in the event of a fire, and an alarm signal oscillator for outputting a predetermined alarm signal by the signal output from the thermometer. Lantern with thermometer.