KR102761963B1 - Control device for supplying a low power and Drive method of the Same - Google Patents

Abstract

The present invention discloses a power control technology. That is, a control device for low power supply according to an embodiment of the present invention safely and efficiently supplies low power supply power to a plurality of smoke (temperature, heat) detection sensors by limiting current and controlling voltage under power supply conditions.
In addition, the present invention is a device that efficiently supplies power to a plurality of smoke (temperature, heat) detection sensors for monitoring the environment within a building, by evenly distributing the first power supply to the plurality of smoke (temperature, heat) detection sensors so that each sensor can operate stably, thereby quickly detecting smoke, dust, and foreign substances and providing a notification service.

Description

Control device for supplying a low power and Drive method of the same

The present invention relates to power control technology, and more particularly, to a low-power supply control device that safely and efficiently provides low-power supply power to a plurality of smoke (temperature, heat) detection sensors by limiting current and controlling voltage under power supply conditions.

Recently, with the advancement of electronic technology, fire detection systems have been developed and applied to detect fires in cultural properties, buildings such as apartments and buildings, and mountains.

These fire detection systems are composed of a plurality of fire detection devices, a fire relay device relaying the fire detection devices, and a fire management device controlling and managing the fire detection devices through the plurality of fire relay devices.

Conventional fire detection systems connect multiple fire detection devices to each fire relay device via wires, which causes problems such as difficulty in installation due to wiring and increased installation costs.

Recently, wireless fire detection systems have been developed and applied to solve these problems, in which a fire relay device and multiple fire detection devices communicate wirelessly.

The wireless fire detection device of the wireless fire detection system is installed independently without wires because it is connected wirelessly to the wireless fire relay device. Therefore, the wireless fire detection device must use a battery as a source power for operation.

In this way, wireless fire detection devices must rely entirely on batteries as their power source. However, batteries have the problem that they cannot store a large amount of power, and their efficiency decreases as they deteriorate with use, making it difficult to maintain a constant desired amount of current.

Therefore, in order to supply a constant amount of current required by a wireless fire detection device, a battery with high efficiency or the largest possible capacity must be used. However, in this case, there was a problem that the weight of the wireless fire detection device could increase and the production cost could increase.

Due to these problems, a low-power design is required that can minimize the production cost and weight, and minimize the current consumption (power) of wireless fire detection devices in order to supply the required current amount consistently for as long as possible for the same battery capacity.

Korean Patent Registration Number: 10-2515282-0000 Korean Patent Registration Number: 10-2645224-0000 Korean Patent Registration Number: 10-1158715-0000 Korean Patent Registration Number: 10-1273674-0000

The low-power supply control device of the present invention has been devised to solve the problems of the prior art as mentioned above, and the first purpose of the present invention is a device that efficiently supplies power to a plurality of smoke (temperature, heat) detection sensors for monitoring the environment inside a building, by evenly distributing the first power supply to the plurality of smoke (temperature, heat) detection sensors so that each sensor can operate stably, thereby quickly detecting smoke, dust, and foreign substances and providing a notification service.

In addition, a second purpose of the present invention is to provide stable and efficient power to a plurality of smoke (temperature, heat) detection sensors so that each detection sensor can operate accurately and data collection and monitoring can be performed smoothly.

In addition, the third object of the present invention is to increase the reliability of low-power power supply and improve the overall performance and lifespan of a sensor network.

To achieve the above-mentioned task, the present invention includes the following configuration.

That is, the low power supply control device according to an embodiment of the present invention comprises: a resistor element connected to an output line of a first power connector and acting as a resistor for limiting current or pulling up/pulling down a first power supply provided from the first power connector; a rectifier element connected to an output line of the resistor element and preventing overcurrent or reverse voltage of the first power supply passing through the resistor element; a first switching transistor connected to an output line of a second power connector and labeled as a POWER-HI state, and allowing the second power supply provided from the second power connector to pass through the collector terminal via the emitter terminal when switched on; A comparator operational amplifier which generates a Low state signal and transmits it to an output terminal when the first power supply is applied by switching-off of the first switching transistor, and outputs the first power supply, and generates a High state signal and transmits it to the output terminal when the second power supply is applied by switching-on of the first switching transistor, and outputs the second power supply; and a second switching transistor which, when receiving the Low state signal from the output terminal of the comparator operational amplifier, induces the first power supply to be supplied to an external power supply device by making the collector terminal according to the base-emitter junction non-conductive.

The low-power supply control device of the present invention is a device that efficiently supplies power to a plurality of smoke (temperature, heat) detection sensors for monitoring the environment within a building, and evenly distributes the first supply power to the plurality of smoke (temperature, heat) detection sensors so that each sensor can operate stably, thereby providing a first effect of quickly detecting smoke, dust, and foreign substances and providing a notification service.

In addition, the present invention provides a second effect of providing stable and efficient power to a plurality of smoke (temperature, heat) detection sensors, thereby enabling each detection sensor to operate accurately and data collection and monitoring to be performed smoothly.

In addition, the present invention provides a third effect of increasing the reliability of low-power power supply and improving the overall performance and lifespan of a sensor network.

FIG. 1 is a drawing illustrating a control device for low power supply according to an embodiment of the present invention.
FIG. 2 is a waveform diagram of an LDO signal output from a low power supply control device according to an embodiment of the present invention.
Figure 3 is a flowchart showing a method for driving a low-power supply control device according to an embodiment of the present invention.

[Example]

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

FIG. 1 is a drawing illustrating a control device for low power supply according to an embodiment of the present invention.

Referring to FIG. 1, a low-power supply control device (1000) is a device that efficiently supplies power to a plurality of smoke (temperature, heat) detection sensors for monitoring the environment within a building. By evenly distributing the first supply power to a plurality of smoke (temperature, heat) detection sensors so that each sensor can operate stably, it quickly detects smoke, dust, and foreign substances and provides notification services such as caution warnings and dangers.

Therefore, a low power supply control device (1000) according to an embodiment of the present invention includes a resistor element (200), a rectifier element (300), a first switching transistor (500), an operational amplifier for a comparator (600), and a second switching transistor (700).

First, as one of the main components belonging to the embodiment of the present invention, a resistor element (200) is connected to the output line of the first power connector (100) and functions as a resistor to limit current or pull up/pull down the first power supply (ex: 6.5 V) provided from the first power connector (100).

The resistor element (200) can also be configured as a variable resistor, allowing the user to adjust the first supply current detected from the first power supply.

A fuse is additionally connected to the output line of the resistor element (200) to protect its own circuit when overcurrent occurs.

The rectifier (300) is connected to the output line of the resistor element (200) and prevents overcurrent or reverse voltage of the first power supply passing through the resistor element (200).

A current detection circuit is additionally connected between the resistance element (200) and the rectifier element (300) to monitor the flow status of the first supply current of the first power supply and generate a warning signal in the event of an overcurrent occurrence.

The first switching transistor (500) is connected to the output line of the second power connector (400) and is labeled as POWER-HI, and when switched on, conducts the second supply power (ex: 24 V) provided from the second power connector (400) to the collector terminal via the emitter terminal.

When the operational amplifier (600) for the comparator receives the first power supply generated from the first power connector (100) due to the switching-off of the first switching transistor (500), it generates a low state signal and transmits it to the output terminal, thereby outputting the first power supply.

In other words, when the first supply power is applied by switching off the first switching transistor (500), the operational amplifier (600) for the comparator compares the first supply power with the internal reference power and, when it recognizes that the internal reference power (ex: 6.86 V) is greater than the first supply power, transmits a low state signal (ex: LDO signal ) to the output terminal. (See FIG. 2)

When the operational amplifier (600) for the comparator receives the second power supply generated from the second power connector (400) due to the switching-on of the first switching transistor (500), it generates a high state signal and transmits it to the output terminal, thereby outputting the second power supply, not the first power supply.

In other words, the operational amplifier (600) for the comparator compares the second supply voltage with the internal reference voltage when the second supply voltage is applied by switching on the first switching transistor (500), and transmits a high state signal to the output terminal when it recognizes that the internal reference voltage is lower than the second supply voltage. (Not shown)

In addition, the output terminal of the operational amplifier (600) for the comparator is connected to an LED indicator (not shown) to visually display one selected from the Low state signal and the High state signal differently.

When the second switching transistor (700) receives a low state signal from the output terminal of the operational amplifier (600) for the comparator, it de-conducts the collector terminal according to the base-emitter junction to induce the first power supply to be supplied to the external power supply device (800).

When the second switching transistor (700) receives a high state signal from the output terminal of the operational amplifier (600) for the comparator, it conducts the collector terminal according to the base-emitter junction to induce the second power supply to be supplied to the external power supply device (800).

Accordingly, the external power supply device (800) receives the first power supply, then divides the first power supply equally into N equal parts according to the number of N smoke (temperature, heat) detection sensors that detect smoke, dust or foreign substances entering the building, and generates a low-power power supply, which is then supplied simultaneously (or in a time-division manner) to the plurality of smoke (temperature, heat) detection sensors (not shown).

Figure 3 is a flowchart showing a method for driving a low-power supply control device according to an embodiment of the present invention.

Referring to FIG. 3, a driving method of a control device for low power supply is a device that efficiently supplies power to a plurality of smoke (temperature, heat) detection sensors for monitoring the environment within a building, and is a driving method that evenly distributes a first power supply to a plurality of smoke (temperature, heat) detection sensors so that each sensor can operate stably, thereby quickly detecting smoke, dust, and foreign substances and providing a notification service.

First, the resistor element is connected to the output line of the first power connector and acts as a resistor to limit current or pull up/pull down the first power supply provided from the first power connector.

The rectifier is connected to the output line of the resistor element and prevents overcurrent or reverse voltage of the first power supply passing through the resistor element.

The first switching transistor is connected to the output line of the second power connector and is labeled as POWER-HI, and when switched on, conducts the second supply power provided from the second power connector through the emitter terminal to the collector terminal.

The operational amplifier for the comparator generates a low state signal and transmits it to the output terminal when the first power supply is applied by switching off the first switching transistor, thereby outputting the first power supply, and generates a high state signal and transmits it to the output terminal when the second power supply is applied by switching on the first switching transistor, thereby outputting the second power supply.

When the second switching transistor receives a low state signal from the output terminal of the operational amplifier for the comparator, it turns off the collector terminal according to the base-emitter junction to induce the first power supply to be supplied to the external power supply device.

Although the present invention has been described above with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various modifications and changes may be made to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below.

Control unit for low power supply (1000)
Resistance element (200) Rectifier (300)
Operational amplifier (600) for comparator of first switching transistor (500)
Second switching transistor (700)

Claims (5)

A resistor element connected to the output line of the first power connector and acting as a resistor for limiting current or pulling up/pulling down the first power supply provided from the first power connector;
A rectifier element connected to the output line of the above resistance element and preventing overcurrent or reverse voltage of the first power supply passing through the above resistance element;
A first switching transistor, which is connected to the output line of the second power connector and is labeled as being in the POWER-HI state, and which conducts the second supply power provided from the second power connector through the emitter terminal to the collector terminal when switched on;
An operational amplifier for a comparator that generates a low state signal and transmits it to an output terminal when the first power supply is applied by switching off the first switching transistor, and outputs the first power supply while generating a high state signal and transmitting it to the output terminal when the second power supply is applied by switching on the first switching transistor; and
The operational amplifier for the comparator comprises a second switching transistor that, when receiving the low state signal from the output terminal of the operational amplifier for the comparator, induces the collector terminal according to the base-emitter junction to be non-conductive so that the first power supply is supplied to an external power supply device, and the operational amplifier for the comparator comprises:
A low power supply control device characterized in that when the first supply power is applied by switching-off of the first switching transistor, the first supply power is compared with the internal reference power and, when it is determined that the internal reference power is greater than the first supply power, the Low state signal is transmitted to the output terminal, and when the second supply power is applied by switching-on of the first switching transistor, the second supply power is compared with the internal reference power and, when it is determined that the internal reference power is less than the second supply voltage, the High state signal is transmitted to the output terminal.
In the first paragraph, the second switching transistor,
A low power supply control device characterized in that, when the high state signal is received from the output terminal of the operational amplifier for the comparator, the collector terminal according to the base-emitter junction is conducted to induce the second power supply to be supplied as power to an external power supply device.
delete In paragraph 1,
A fuse is additionally connected to the output line of the above resistance element to protect its own circuit when overcurrent occurs.
The above resistance element can also be configured as a variable resistor so that the user can adjust the first supply current detected from the first supply power.
A current detection circuit is additionally connected between the above resistance element and the rectifier element to monitor the flow status of the first supply current of the first supply power source and generate a warning signal in the event of an overcurrent occurrence.
A low power supply control device characterized in that the output terminal of the above comparator operational amplifier is connected to an LED indicator to visually display one selected from the low state signal and the high state signal differently.
In the first paragraph, the external power supply device,
A low-power supply control device characterized in that, after receiving the first power supply, the first power supply is divided into N equal parts by the number of N smoke (temperature, heat) detection sensors that detect smoke, dust or foreign substances entering a building, and the low-power supply power is generated by supplying the first power supply to the N smoke (temperature, heat) detection sensors.