KR200357576Y1 - Rechargeable Emergency Lantern - Google Patents

Abstract

Regarding the lantern which can be recharged when the power supply is cut off in an emergency, it is a rechargeable emergency lantern that does not require battery replacement due to the use of a secondary battery that can be used as a battery and can stand by while the secondary battery is fully charged. In order to provide, to prevent the overcharge or over-discharge of the lamp, the first power supply means, the second power supply means, the second power supply means capable of charging and discharging when the first power supply means is cut off Preventing means, sensing means for detecting the interruption state when the first power supply means is cut off, automatically detecting the second power supply means, charging checking means for displaying the state of charge of the second power supply means; An overvoltage limiting means for limiting the overvoltage applied to the lamp at the time of initial supply of power from the first power supply means is set.

When the secondary battery is in a fully charged state, it automatically detects this and changes the charging mode.It operates to maintain the full charge state from the self discharge of the battery at all times. The effect is that the ability to respond to changes in ambient temperature is safer without damage, and this configuration makes it possible to use semi-permanently by using a secondary battery capable of charging and discharging more than 500 times, and supplying a first power supply. Even if the means are not blocked, it is possible to check whether the system is abnormal due to the means to inspect the system itself.

Description

Rechargeable Emergency Lantern

The present invention relates to a lantern that can be recharged when the power supply is cut off in an emergency, and more particularly to an incandescent light fixture used in a ship.

That is, the present invention relates to a system for charging a secondary battery when power is supplied, and driving a lamp with a secondary battery when power is cut off.

Currently, the ship uses incandescent lamps with AC115V and 60Hz. In such a device, the general conditions required should be operable at an ambient temperature of -30 ° C to 40 ° C, seawater temperature of -2 ° C to 30 ° C, an internal temperature of 0 ° C to 50 ° C, and a relative humidity of 0 to 95%. Considerations due to hull motion include: 15 ° permanent inclination in any chord, 5 ° permanent inclination in the horizontal plane, 45 ° rolling in any chord from the vertical plane, and 10 ° pitching in the water direction from the horizontal plane. It should work satisfactorily.

Under the conditions as described above, the conventional incandescent light fixture was configured to sense the power supply state when the main power supply voltage is interrupted, and to operate the lamp automatically by the primary battery.

However, a conventional incandescent lamp using a primary battery as described above should be used after replacing the discharged battery, the use time of the first battery replacement is only about 8 hours, once used batteries according to the extra capacity Due to the different discharge capacity, the incandescent lamp cannot be operated normally in an emergency, and the battery has to be replaced at any time, which causes a considerable waste of money.

An object of the present invention is to solve the problems of the prior art described above, by replacing the use of a rechargeable battery with a rechargeable battery rechargeable battery does not need to replace the secondary battery is a rechargeable emergency lantern that can wait in a fully charged state To provide.

In order to achieve the above object, the rechargeable emergency lantern of the present invention is a second power supply means that is capable of charging and discharging when the lamp, the first power supply means, the first power supply means is shut off, Prevention means for preventing overcharging or overdischarging of the power supply means of 2; detecting means for automatically detecting the shut-off state when the first power supply means is cut off and automatically operating the second power supply means; Charging checking means for indicating a state of charge of the power supply means of the second and means for protecting against overvoltage and tube current applied to the second power supply means when the power is initially supplied from the first power supply means, the second And transient inrush current limiting means for limiting the transient inrush current applied to the lamp when the initial power is supplied from the power supply of the power supply.

When the secondary battery is in a fully charged state, it automatically detects this and changes the charging mode.It operates to maintain the full charge state from the self discharge of the battery at all times. It does not damage and the effect that the ability to respond to changes in ambient temperature is more secured is obtained, and semi-permanent use is possible by using a rechargeable battery capable of charging and discharging. In the rechargeable emergency lantern of the present invention, the second power supply means is a secondary battery.

In addition, in the rechargeable emergency lantern of the present invention, if the over-discharge prevention voltage is reached after the power supply from the second power supply means lasts for a predetermined time, the over-discharge of the second power supply means As an prevention means for preventing the over-discharge prevention portion.

Further, in the rechargeable emergency lantern of the present invention, the sensing means is a transistor that is turned on or off according to the difference between the reference voltage and the applied divided voltage and the second power supply means according to the conduction or non-conduction of the transistor. A relay for determining whether to apply voltage from the circuit.

Further, in the rechargeable emergency lantern of the present invention, a constant voltage means for rectifying and smoothing the power supplied from the first power supply means and a current suitable for the second power supply means according to the voltage output from the constant voltage means. It further comprises a constant current means for charging with.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, like reference numerals denote like parts, and repetitive description thereof will be omitted.

1 is a block diagram showing the overall circuit configuration of a rechargeable emergency lantern according to the present invention. FIG. 1 is a 115 V / 60 Hz power supply unit supplied from the power supply unit 1 to the lantern. (2) is a power supply rectifying section, which is composed of a bridge rectifying circuit suitable for voltage rectification. Denoted at 3 is a constant voltage circuit section, and smoothes the pulsating voltage rectified by the power supply rectifying section 2. (4) is a charge check unit for visually confirming the state of charge of the secondary battery (110), (5) is an overcharge prevention unit to prevent excessive charging of the secondary battery (110), (6) is 2 The constant current circuit unit protects the voltage of the battery from affecting other circuits during operation of the battery 110. Denoted at 7 is a reference voltage generator for generating a reference voltage of the voltage supplied from the power rectifier 2, and at 8, the secondary battery 110 is over-discharged according to the output from the reference voltage generator 7. It is an over-discharge prevention part to prevent it. Denoted at 9 is a power supply voltage detection unit, which detects whether the power supplied to the lamp 100 is cut off and controls the supply of the secondary battery as an emergency power source.

100 is a lamp which is an incandescent lamp driven by the power supply of the power supply unit 1 or the supply voltage from the secondary battery 110.

The 110 is a rechargeable battery that can be reused after being recharged, and can be used for about 30 hours after being charged for about 30 hours (discharge time), and is always charged when the power is supplied from the power supply unit 1. Ready to wait in full state.

Secondary battery 110 according to the present invention is a secondary battery made of nickel-cadmium without gas generation, 4. 8V / 4500mAh so that 4 of the 2V is connected in series to one packing, a large discharge current 31. 5A (148W) takes about 0.3 seconds to discharge to 0.65V / Cell per cell.

120 is a lamp protection circuit for protecting the lamp 100.

Hereinafter, the configuration and operation of specific circuits of the respective parts shown in FIG. 1 will be described in detail with reference to FIGS. 2 to 9.

Fig. 2 is a specific circuit diagram of the constant voltage circuit section 3, which is composed of constant voltage IC U2, resistor R5, capacitors C2, C4, diodes D5, D6, and zener diode ZD2. The pulsating voltage rectified by the power supply rectifying unit 2 is supplied through the node V1, and the supplied pulsating current is first output as a voltage containing ripple through the capacitor C4.

The constant voltage IC U2 varies the output voltage according to the magnitude of the voltage supplied to terminal 1, and the constant voltage circuit unit 3 is used to prevent the overcharge by interlocking with the overcharge preventing unit 5. The output voltage is determined by resistor R5, diode D11, zener diode ZD2, and capacitor C2, and the presence or absence of output depends on the state of cathode potential and anode potential of diode D6. In the constant voltage circuit section 3, the output voltage of U2 is set to a predetermined potential during charging, the cathode potential of the diode D6 is higher than the anode potential, and when the cathode potential of the diode D6 is lower than the anode potential, the output of U2 is output. The voltage is below a predetermined potential.

3 is a specific circuit diagram of the charging confirmation unit (4). In FIG. 3, when the LED1, which is a light emitting diode, is a green LED and the secondary battery 110 is fully charged, the LED2, which is a light emitting diode, is a red LED, and the operator can check the state of the charging operation and the completion of charging of the secondary battery 110. It is designed for visual confirmation.

4 is a specific circuit diagram of the overcharge preventing unit 5, which is composed of a comparator UIC and a resistor R10.

In general, overcharging rechargeable batteries may shorten their life or make them unusable. In the present invention, in order to compensate for these disadvantages, an overcharge protection circuit is used, and the operation principle of the overcharge prevention part 5 is as follows. As charging progresses, the potential of the S3 node is increased so that the cathode potential is lower than the anode potential of the reference voltage REF1 (2.5V), and the output voltage of the IC U2 is lowered to enter the trickle charge mode. In the present invention, the potential setting of the S3 node sets the resistor R2 to be 2.5V at the end of charge.

5 is a specific circuit diagram of the constant current circuit unit 6. In Fig. 5, the constant current circuit section 6 is composed of IC U3, resistors R2, R6 to R9, and diodes D7 and D8. The voltage output from the constant voltage circuit section 3 is supplied to terminal 3 of the IC U3 through the V2 node, the charging current is varied by the resistances of the resistors R6 and R7, and the constant current circuit section 6 uses the battery for the longest time. It is set to make permanent charge below 225mA which is full current. Diodes D7 and D8 are used for protection against battery voltage from affecting the circuit during full charge or when driving the lamp with batteries.

6 is a specific circuit diagram of the reference voltage generator 7. In Fig. 6, the reference voltage generator 7 is composed of a comparator U1D, resistors R1, R4, R15, R20, capacitors C1, C3, diodes D10, D12, and shunt regulation diode Q2.

The reference voltage generator 7 generates a reference voltage and supplies it to the comparator U1B of the overdischarge prevention unit 8. The voltage supplied to node V1 is smoothed by capacitors C1 and C3 through diode D10, and is supplied to Q2, a shunt-controlled diode that can be programmed as an output voltage as three terminals, through diode Q2 protection resistor R15. Q2, set to output a 5V voltage, only outputs a constant reference voltage of 2.5V to the reference voltageREF1 node. This voltage is divided by resistors R1 and R20 and outputs a comparable voltage to reference voltage REF2 through a buffer using IC U1. Here, the reference voltage REF1 is used as the comparison voltage of the over-discharge prevention unit 8, and the reference voltage REF2 is used as the comparison voltage of the power supply voltage detection unit 9. In addition, diodes D10 and D12 are used to eliminate power loss during battery operation in circuits connected to the nodes of resistors R4 and anode of diode D10.

Fig. 7 is a specific circuit diagram of the overdischarge prevention section 8, which is composed of a comparator U1B, resistors R11, R12, R13 and a capacitor C5.

The overdischarge prevention unit 8 is used to protect the secondary battery 110 by preventing the secondary battery 110 from being over discharged when the lantern is driven by the secondary battery 110 in an emergency.

When the two voltages are compared in the comparator U1B composed of OP Amp, when the voltage is applied from the power supply unit 1, a voltage of about 18 V is output to VCC, and a voltage of 2.5 V is output to the reference voltage REF1 so that the -terminal voltage of the comparator is output. Since the voltage is higher than the + terminal voltage, the output voltage of the comparator U1B becomes 0V or less. When the output voltage is 1.5 V or more, the output of the power supply voltage detection unit 9 is affected. However, when the output voltage is 0 V or less, the output voltage is independent of the power supply voltage detection unit 9.

When the circuit is driven by the secondary battery 110, the VCC voltage in the circuit is the output voltage of the secondary battery 110, the reference voltage with the reference voltage REF1, that is, the voltage of the secondary battery 110 is less than 2.5V To prevent discharge. The operation of the comparator U1B compares the voltage of the reference voltage REF1, which is the voltage of the + terminal of the comparator U1B, with the VCC voltage and the voltage of the secondary battery 110 is lower than 2. 5V. The output is cut off the power source of the battery 110 to the power supply voltage detection unit 9 to prevent the secondary battery 110 from overdischarging. The resistor R14 connected to the + terminal of the comparator U1B creates a hysteretic characteristic in the comparator U1B to prevent hunting during voltage comparison.

8 is a specific circuit diagram of the power supply voltage detection unit 9. In Fig. 8, the power supply voltage detection unit 9 is composed of differential amplifiers U1A, resistors R3, R16 to R19, diodes D9, D13 to D15, transistors Q1, and relays RELAY1. When the power is applied to the lantern, voltage is also applied to the node V1, and the voltage divided by the resistors R3 and R19 is higher than the comparison voltage of the reference voltage REF2 (1.5V), so the output of the differential amplifier U1A becomes 0V or less, and Q1 is not conducting and therefore relay RELAY1 is not turned on.

When the lantern is powered off, the voltage applied to the V1 node also drops sharply, while the divided voltages of the resistors R3 and R19 are also 1. Lower below 5V. At this time, while the capacitors C1, C3 and C4 discharge the charged voltage while the power is being supplied, the output of the differential amplifier U1A instantly rises by the discharge voltage of the capacitor to electrically conduct the transistor Q1, and the relay RELAY1 is also turned on. The voltage of the battery 110, which is an emergency voltage source, is applied to each circuit unit, and the lamp 100 is also turned on at the same time.

9 is a detailed circuit diagram of the lamp protection circuit unit 120 and includes an inductor L1 and a diode D18.

When the voltage of the battery 110 that is initially fully charged is directly applied to the lamp, the life of the filament may be drastically reduced or the filament may burn due to the transient inrush current. However, by connecting the inductor L1 in series with the lamp 100, the initial transient inrush current is limited to the lamp limit current or less, and the diode D18 inserted in series is used to protect the lamp from the overvoltage of the initial discharge.

As described above, in the present invention, since the secondary battery capable of charging and discharging 500 times or more is used, it can be used semi-permanently, and even if charged with a current less than the normal charging current in a fully charged state, the battery is not damaged. Therefore, the ability to respond to changes in ambient temperature becomes safer.

In addition, in the present invention, since the overcharge preventing unit 5 and the overdischarge preventing unit 8 are provided, the secondary battery 110 can be used semi-permanently by preventing overdischarging and overcharging.

That is, in the present invention, the battery starts to discharge the fully charged battery at 0.5 A (0.111 C), depending on the characteristics of the lamp, and after 10 hours of operation, the battery is 1 V / Cell x 4, which is the cutoff voltage for each cell. When = 4V is reached, the cutoff voltage is sensed by the power supply voltage detection unit and the overdischarge prevention unit 8 prevents the battery from being overdischarged.

As mentioned above, although the invention made by this inventor was demonstrated according to the said Example, this invention is not limited to the said Example, Of course, it can be variously changed in the range which does not deviate from the summary.

1 is a block diagram of the overall circuit configuration of the rechargeable emergency lantern according to the present invention,

2 is a specific circuit diagram of the constant voltage circuit unit shown in FIG. 1;

3 is a detailed circuit diagram of the charging check unit shown in FIG. 1;

Figure 4 is a specific circuit diagram of the overcharge protection shown in Figure 1,

5 is a specific circuit diagram of the constant current circuit unit shown in FIG. 1;

6 is a detailed circuit diagram of the reference voltage generator shown in FIG. 1;

7 is a detailed circuit diagram of the over-discharge prevention unit shown in FIG.

8 is a detailed circuit diagram of a power supply voltage detector shown in FIG. 1;

FIG. 9 is a detailed circuit diagram of the lamp protection circuit unit shown in FIG. 1. FIG.

※ Explanation of symbols about main part of drawing ※

One… Power supply section; Power rectifier, 3.. Constant voltage circuit,

4… Charging confirmation unit, 5.. Overcharge protection, 6.. Constant current circuit,

7... Reference voltage generator, 8.. Over-discharge prevention unit, 9... Power supply voltage detector,

100... Lamp, 110... Secondary battery, 120.. Lamp protection circuit.

Claims (5)

lamp, First power supply means, A second power supply means operable when the first power supply means is shut off and capable of charging and discharging; Prevention means for preventing overcharging or overdischarging of the second power supply means; Sensing means for automatically detecting the interruption state and automatically operating the second power supply means when the first power supply means is blocked; And charging check means for indicating a charging state of the second power supply means and overvoltage limiting means for limiting an overvoltage applied to the lamp when the power is initially supplied from the first power supply means. -Type emergency lantern. The method of claim 1, Rechargeable emergency lantern, characterized in that the second power supply means is a secondary battery. The method of claim 1, The prevention means includes an over-discharge prevention portion for preventing over-discharge of the second power supply means when the cutoff voltage is reached after the power supply from the second power supply means lasts for a predetermined time. Rechargeable emergency lantern, characterized in that. The method of claim 1, The sensing means includes a transistor which is turned on or off according to the difference between the reference voltage and the applied divided voltage, and a relay which determines whether to apply voltage from the second power supply means according to the conduction or non-conduction of the transistor. Rechargeable emergency lantern, characterized in that. The method of claim 1, And a constant current means for rectifying and smoothing the power supplied from the first power supply means, and a constant current means for charging the second power supply means with a current suitable for the voltage output from the constant voltage means. Rechargeable emergency lantern.