KR102149878B1 - Additional connect device for SMPS power supply with IOT based control system - Google Patents

Abstract

The present invention mediates the electrical connection between the SMPS power supply and the load device, and includes an IoT module for wireless communication with an Internet connection terminal through an Internet communication network and a sensor required for state detection, thereby providing information on the output state of the SMPS power supply. IoT that enables parallel connection and multiplex connection of SMPS power supplies through real-time remote monitoring from internet connection terminals such as smartphones and power supply control and output voltage control, and can be used as spare power. It relates to an auxiliary connection device for the SMPS power supply to which the based control system is applied.
The auxiliary connection device for the SMPS power supply device to which the IoT-based control system according to the present invention is applied includes: an input unit to which input power is connected to receive power; An output unit for applying power to the load device and preventing reverse current; A wireless communication unit that wirelessly communicates with an external device to receive a remote control signal and transmits data measured by the sensor; A control unit that electrically cuts off or connects input power to the SMPS power supply and adjusts an output voltage value; A sensor unit measuring power consumption input to the SMPS power supply and measuring output voltage and current rectified from the SMPS power supply; And a driving power supply unit including a battery to convert input power to supply power required for driving the wireless communication unit, the control unit, and the sensor unit, and to drive the parts even when there is no input power.

Description

Auxiliary connect device for SMPS power supply with IoT based control system {Additional connect device for SMPS power supply with IOT based control system}

The present invention mediates the electrical connection between the SMPS power supply and the load device, and includes an IoT module for wireless communication with an Internet connection terminal through an Internet communication network and a sensor required for state detection, thereby providing information on the output state of the SMPS power supply. IoT that enables parallel connection and multiplex connection of SMPS power supplies through real-time remote monitoring from internet connection terminals such as smartphones and power supply control and output voltage control, and can be used as spare power. It relates to an auxiliary connection device for the SMPS power supply to which the based control system is applied.

Through the IoT, which is emerging as the main pillar of the 4th industrial revolution, a large number of home electronic devices can be controlled online. In the case of industrial electronic devices, most of them are equipped with a separate control system and the status information and control are performed through an internal network, which is mainly formed by companies with sufficient capital and large-scale facilities, and is difficult to apply in small facilities.

Therefore, the SMPS power supply device included in many industrial electronic devices is required for the wireless communication unit that wirelessly communicates with external devices such as smartphones through the Internet, and the sensor unit that measures power consumption, output voltage, and current, and the power supply. The power consumption of the SMPS power supply and the power consumption of the SMPS power supply unit are increased by attaching a control unit that can cut off or connect the input power supply and control the output voltage and control the output voltage, and Remotely monitor output voltage, output power, operation status, and abnormal status, remotely control input power connection and disconnection, and output voltage values, and cut off and monitor the input power of the SMPS power supply when the load device is in standby status. The components for overload control are battery-powered to prevent unnecessary power consumption.

As described above, based on IoT technology, it is a conventional technology that detects whether or not a load device is driven, power consumption, etc. remotely, and controls whether or not power is supplied. Patent No. KR10-2016-0100565 "Smart power plug using a wireless communication network System" and Patent No. KR10-17810555 "Internet of Things-based Smart Outlet" was disclosed, and Patent No. KR10-1435631 is a conventional technology that solves the potential difference between two SMPS power supplies and controls them to supply power in parallel. Disclosed is a circuit device for parallel connection of a switching mode power supply and a control method thereof.

The Patent No. KR10-2016-0100565 "Smart Power Plug System Using a Wireless Communication Network" includes a relay module, a wireless communication module, and a controller module to remotely monitor a connected load device using a wireless terminal in possession of the user. And control. However, Korean Patent No. KR10-2016-0100565 "Smart Power Plug System Using Wireless Communication Network" and Patent No. KR10-17810555 "Internet of Things-Based Smart Outlet" are based on 220V plugs used for home use. It is designed and cannot be applied when the necessary power is supplied to an electronic device in the form of an SMPS power supply device.

Patent No. KR10-1435631 "Parallel connection circuit device for switching mode power supply and its control method" is provided with an SMPS connection unit, a first SMPS board, a second SMPS board, a potential difference generator, a relay, and a microcomputer. Parallel connection is made by connecting SMPS boards in parallel, but measuring and detecting the output voltage of both ends of the potential difference generator through a microcomputer and controlling the output voltages of two single SMPS boards so that the potential difference between both ends does not occur and becomes the same output voltage. Let it be. However, in order to apply this and connect the SMPS power supply in parallel, a circuit must be configured and wired according to the above Patent No. KR10-1435631 "Parallel connection circuit device of a switching mode power supply and its control method".

The present invention solves the problem limited to household electronic products of the smart plug connector according to the prior art, and the complex circuit configuration problem of the parallel connection circuit device and the control method of the switching mode power supply device, and to apply the SMPS power supply to industrial electronic devices. As an invention conceived for the supply device, the SMPS power supply is connected through an auxiliary connection device with a built-in battery to monitor and control remotely based on IoT technology, and standby power of the SMPS power supply device. It provides an auxiliary connection device for SMPS power supply with an IoT-based control system that cuts consumption to save power and enables monitoring through the battery even when there is no power supply to check even in emergency conditions such as power outages. The purpose.

KR 10-1781055 B1 KR 10-2016-0100565 A KR 10-1435631 B1

The problem to be solved by the present invention is to connect an auxiliary device to the input terminal and output terminal of the SMPS power supply device used in various industries, such as industry and agriculture other than the home, to connect to the server through a wireless communication network, and a smartphone in possession of the user, etc. Power consumption, output voltage, and output current are measured and displayed by connecting to the server with the Internet connection terminal of SMPS, and the power supply of unused SMPS power supply devices is immediately cut off or the output voltage is adjusted so that the SMPS power supply is in parallel or multiplexed manner. Control system for devices that use SMPS power supply as power at low cost by minimizing the waste of standby power by allowing control and monitoring to be connected and transmitting current information by running with a battery even when the input power is cut off. It is to provide an auxiliary connection device for the SMPS power supply to which an IoT-based control system is applied.

The auxiliary connection device for the SMPS power supply to which the IoT-based control system according to the present invention is applied to achieve this object is a device connected to the SMPS power supply,

An input unit to which input power is connected to receive power;

An output unit for applying power to the load device and preventing reverse current;

A wireless communication unit that wirelessly communicates with an external device to receive a remote control signal and transmits data measured by the sensor;

A control unit that electrically cuts off or connects input power to the SMPS power supply and regulates an output voltage;

A sensor unit measuring power consumption input to the SMPS power supply and measuring an output voltage and output current rectified from the SMPS power supply;

And a driving power supply unit including a battery to convert input power to supply power required for driving the wireless communication unit, the control unit, and the sensor unit, and to drive the wireless communication unit, the control unit, and the sensor unit even when there is no input power.

SMPS power supply device to which an IoT-based control system is applied through a wireless communication network using an Internet connection terminal such as a smartphone, tablet, notebook, PC, etc. used by the user in the SMPS power supply widely used in various fields according to the present invention It is possible to easily and conveniently remotely monitor and control the operation status and power supply of the connected load device by connecting to the auxiliary connection device. Through monitoring, unnecessary power consumption and electrical accidents can be prevented, and power supply of important equipment can be checked for abnormalities. In addition, the SMPS power supply device can be connected in parallel through the device without configuring a separate circuit by generating the same output voltage through the output voltage control. Accordingly, the heat sink required in the existing SMPS parallel connection circuit structure is removed, and the problem of increasing the size of the system can also be solved.

Through the present invention, the output voltage, output current, and power consumption of existing devices are monitored remotely to prevent electrical accidents, and through easy connection of a spare power supply device, the power supply of main equipment is prevented and unused load devices are blocked. It is a very useful invention for industrial development that can save standby power.

1 is a schematic diagram of connection of an auxiliary connection device for an SMPS power supply device to which an IoT-based control system according to the present invention is applied.
2 is a block diagram of an auxiliary connection device for an SMPS power supply to which an IoT-based control system according to the present invention is applied.
3 is a user of the auxiliary connection device for the SMPS power supply device to which the IoT-based control system according to the present invention is applied, and the auxiliary connection device for the SMPS power supply device to which the IoT-based control system is applied by user setting location of the application of the Internet connection terminal is applied. Implementation diagram of the overall status of connected SMPS power supplies.
Figure 4 is a user of the auxiliary connection device for the SMPS power supply device to which the IoT-based control system according to the present invention is applied, and the auxiliary connection device for the SMPS power supply device to which the IoT-based control system is applied by user setting location of the application of the Internet connection terminal is applied. Current status implementation diagram of connected SMPS power supplies.
5 is a user of an auxiliary connection device for an SMPS power supply device to which the IoT-based control system according to the present invention is applied, and the SMPS power supply to which the auxiliary connection device for the SMPS power supply device to which the IoT-based control system is applied is connected to the application of an Internet connection terminal. Diagram of individual detailed monitoring of devices.
6 is a user of the auxiliary connection device for the SMPS power supply device to which the IoT-based control system according to the present invention is applied, and the auxiliary connection device for the SMPS power supply device to which the IoT-based control system is applied by user setting location of the application of the Internet connection terminal is applied. Diagram of the error message of the connected SMPS power supply.
7 is a user of the auxiliary connection device for the SMPS power supply device to which the IoT-based control system according to the present invention is applied, and the auxiliary connection device for the SMPS power supply device to which the IoT-based control system is applied by user setting location of the application of the Internet connection terminal is applied. Diagram of group setting of connected SMPS power supplies.

Hereinafter, an auxiliary connection device for an SMPS power supply to which an IoT-based control system according to the present invention is applied will be described in more detail with reference to the drawings.

Before describing the present invention in more detail,

In the present invention, various changes can be made and various forms can be shown, and implementation examples (aspects) (or examples) will be described in detail in the text. However, this is not intended to limit the present invention to a specific form of disclosure, it is to be understood as including all changes, equivalents or substitutes included in the spirit and scope of the present invention.

In each drawing, the same reference numerals, in particular the number of tens and ones, or the same reference numerals as the tens, ones, and the alphabet indicate members having the same or similar functions, and unless otherwise specified, each reference in the drawings The member indicated by the symbol may be identified as a member conforming to these criteria. In addition, the components in each drawing are expressed by exaggeratingly large (or thick) or small (or thin) or simplified the size or thickness in consideration of the convenience of understanding, but this limits the scope of protection of the present invention. It shouldn't be.

The terms used in the present specification are only used to describe specific embodiments (sun, 態樣, aspect) (or embodiments), and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as ~include~ or ~consist are intended to designate the presence of features, numbers, steps, actions, components, parts, or a combination thereof described in the specification, but one or more other features It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance the possibility of being added.

Unless otherwise defined, all terms, including technical or scientific terms, used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in this application. Does not.

As shown in FIG. 1, in the auxiliary connection device for the SMPS power supply device to which the IoT-based control system according to the present invention is applied, one device is connected to one SMPS power supply device 200 in a pair. For parallel connection and multiplex connection, there must be an auxiliary connection device for the SMPS power supply to which the IoT-based control system of the same quantity as the quantity of the SMPS power supply 200 to be used for connection is applied.

As shown in Figure 2, the auxiliary connection device for the SMPS power supply to which the IoT-based control system according to the present invention is applied is a housing 100, an input unit 110, an output unit 120, a driving power supply unit 130, and a wireless communication unit. (140), the control unit 150, and comprises a sensor unit 160.

For reference, the auxiliary connection device for the SMPS power supply to which the IoT-based control system of the present invention is applied is a product that is mainly used by being detachably connected to the SMPS power supply already installed in the device. It can also be produced as a product that forms part of the supply unit.

The input unit 110 receives external power and is connected to an input terminal of the driving power supply unit 130 and the SMPS power supply unit 200 to supply power to the SMPS power supply unit 200.

The driving power supply unit 130 converts power applied through AC into DC and supplies power required for driving the wireless communication unit 140, the control unit 150, and the sensor unit 160. In addition, a battery and a circuit for charging the battery are included so that the wireless communication unit 140, the control unit 150, and the sensor unit 160 can be driven through a battery when external power is cut off.

The sensor unit 160 is connected between the input unit 110 and the SMPS power supply unit 200 to measure the power consumption of the SMPS power supply unit 200 and the SMPS power supply unit 200 and the output It includes a voltage sensor and a current sensor connected between the units 120 to measure an output voltage and an output current.

The wireless communication unit 140 communicates with an Internet connection terminal (e.g., a smartphone) through an Internet network and transmits the power consumption, output voltage, and output current measured by the sensor unit 160 to the Internet connection terminal. As shown, remote monitoring can be performed on an hourly, daily, or monthly basis, and a control signal from an Internet connection terminal is received and remotely controlled through the control unit 150. From the output current consumption power, it may be determined whether the load device 400 is being driven or in a standby state.

The control unit 150 may use a relay, transistor, triac, etc. to electrically connect or cut off the input unit 110 and the SMPS power supply unit 200, and the SMPS power supply unit 200 and the A digital potentiometer for adjusting an output voltage value before the output voltage sensor of the sensor unit 160 may be included between the output units 120.

The control unit 150 may cut off or apply power to the SMPS power supply 200 according to a command signal received from an Internet connection terminal, and cut off the power supply to the SMPS power supply 200 according to a reserved time. Or you can authorize it. When the output voltage measured by the sensor unit 160 falls below the reference value or the power consumption rises above the reference value, the power supply to the SMPS power supply unit 200 is cut off, and the output voltage abnormality or overload is prevented by the Internet connection terminal. The information is transmitted and notified and output as shown in FIG. When the load device 400 is in the standby state, the power supply to the SMPS power supply device 200 is cut off to perform a control function such as blocking standby power.

When the plurality of SMPS power supply devices 200 to which an auxiliary connection device for an SMPS power supply device to which an IoT-based control system is applied through an Internet connection terminal are connected are set to be multiplexed, the load device 400 is mainly When the power consumption is measured by the sensor unit 160 of the SMPS power supply 200 to which the auxiliary connection device for the SMPS power supply 200 is connected to the IoT-based control system that supplied power to the device, it is connected as an auxiliary. The power of the SMPS power supply 200 to which the auxiliary connection device for the SMPS power supply device to which the IoT-based control system is applied is applied, and the power supply of the SMPS power supply device 200 in operation is cut off. 400) can be controlled so that the power applied to it is cut off.

When designating a plurality of SMPS power supply devices 200 connected to an auxiliary connection device for an SMPS power supply device to which an IoT-based control system is applied as shown in FIG. 7 as a parallel group, the controller 150 is grouped as a digital potentiometer. The output voltage of the SMPS power supply devices 200 is adjusted so that the same value is measured by the output voltage sensor of the sensor unit 160.

The output unit 120 is an output terminal for connecting and applying the output voltage and output current adjusted through the digital potentiometer of the control unit 150 to the load device 400 and an IoT-based control system applied SMPS power supply A reverse current prevention circuit may be included for parallel connection between the plurality of SMPS power supply devices 200 to which the device auxiliary connection devices are connected.

The housing 100 includes the input unit 110, the output unit 120, the driving power supply unit 130, the wireless communication unit 140, the control unit 150, and the sensor unit 160 to power SMPS. It takes the form of easy electrical coupling with the supply device 200.

In the above description of the present invention, the auxiliary connection device for the SMPS power supply device to which the IoT-based control system having a specific structure is applied has been described with reference to the accompanying drawings, but the present invention can be variously modified and changed by those skilled in the art. , These modifications and changes should be construed as belonging to the scope of the present invention.

100: housing
110: input unit
120: output
130: drive power supply
140: wireless communication unit
150: control unit
160: sensor unit
200: SMPS power supply
300: power
400: load device

Claims (5)

An input unit 110 to which input power is connected to receive power;
An output unit 120 for applying power to the load device and preventing reverse current;
A wireless communication unit 140 for wireless communication with an external device to receive a remote control signal and transmit data measured by the sensor;
A control unit 150 that electrically cuts off or connects input power to the SMPS power supply and adjusts an output voltage value;
A power sensor connected between the input unit 110 and the SMPS power supply device to measure power consumption input to the SMPS power supply device, and the SMPS power supply device and the output unit 120 A sensor unit 160 including a voltage sensor and a current sensor measuring an output voltage and an output current rectified from the power supply device; And
Converts input power to supply power required for driving the wireless communication unit 140, the control unit 150, and the sensor unit 160, and even when there is no input power, the wireless communication unit 140, the control unit ( 150) and a driving power supply unit 130 including a battery so that the sensor unit 160 is driven; includes,
An auxiliary connection device for an SMPS power supply device including the input unit,
It consists of the same quantity as the quantity of the SMPS power supply to be used for connection for parallel connection and multiplex connection,
The control unit 150,
To cut off or connect input power between the input unit 110 and the SMPS power supply unit, any one of a relay, a transistor, and a triac is used, and an output voltage between the SMPS power supply unit and the output unit 120 It includes a digital potentiometer for control, applies or cuts input power according to a set schedule when a user sets a scheduled operation or operates on/off in an application, and cuts off the power when the power consumption and output voltage are out of the user set range. , When a plurality of SMPS power supplies are connected in parallel with a group setting in a user application, the same value is measured by the voltage sensor of the sensor unit 160 by controlling the output voltages of the group-set multiple SMPS power supplies, When multiplexing is configured by group setting in the application, the power supply to the SMPS power supply connected to the SMPS power supply auxiliary connection device applied with the IoT-based control system that shows the phenomenon of output voltage deviating from the user setting range, and additional wiring The SMPS power supply auxiliary connection device to which the IoT-based control system is applied stops powering off the connected SMPS power supply and applies power,
The output unit,
And an output terminal for connecting and applying the output voltage and output current adjusted through the digital potentiometer of the control unit to the load device, and a reverse current prevention circuit for parallel connection between the plurality of SMPS power supply devices. Auxiliary connection device for SMPS power supply with IoT based control system applied. The method of claim 1
The driving power supply unit 130 further includes an AC-DC conversion circuit for supplying a voltage required by the wireless communication unit 140, the control unit 150, and the sensor unit 160, and a battery charging circuit using the same. Auxiliary connection device for SMPS power supply to which IoT-based control system is applied. delete delete delete

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