TWI603565B - Power management system and its operation method - Google Patents

Description

Power management system and its operation method

The present invention relates to a power management system and an operation method thereof, and more particularly to a power management system and a method of operating the same according to the magnitude of a voltage value to determine whether to turn off a line.

As the times progress, people are paying more and more attention to their own safety. Most office buildings or community houses have security systems installed to help monitor abnormal conditions in communities, homes or office buildings, such as fires. Abnormalities, intrusions, or other emergencies. In addition, when the security host detects an abnormal condition, the security monitoring host can receive the abnormal signal of the security host and can inform the public or the monitoring personnel as soon as possible, thereby being quickly responded.

Traditional security systems, such as installations in buildings, require multiple security systems to be connected to each other, as each security system needs to be connected to its own power supply to provide the power needed to secure the system. Moreover, in order to provide system or device protection, a fuse is arranged in each system or device, and when there are multiple power supply devices, when the system has an overcurrent or short circuit condition, the connected fuse can be turned off. To achieve the effect of overcurrent protection and short circuit isolation. The system requires personnel to be repaired frequently. Moreover, when a system connected to multiple security systems is damaged, it is easy to cause the entire circuit to collapse, and all systems will not be able to resume operation immediately.

Therefore, it is necessary to design a power management system and its operation method, which can achieve power control effect by voltage detection and line switch, and use the full-time detection of the voltage state of each end point to find out that the device is abnormal. Controlling the shutdown of the endpoint's security host or device can improve the stability of the system and process it in a timely manner without affecting the entire loop.

It is an object of the present invention to provide a power management system that overcomes the technical problems of the prior art. A power management system is provided, connected between a first security host and a second security device host, and the power device is connected to the first security host. The power management system includes: an inductive control unit, a control unit, and a loop control unit. The sensing control unit is configured to detect a first voltage value of the second security device host. The control unit is connected to the sensing control unit, and the control unit receives the first detected voltage value detected by the sensing control unit. The loop control unit is connected to the control unit and the sensing control unit. The loop control unit receives the control signal transmitted by the control unit, and determines whether to close the line between the sensing control unit and the second security device host according to the control signal.

The control unit stores at least one set voltage value, and the control unit compares the received first detected voltage value with the set voltage value, and when the control unit determines that the first detected voltage value is lower than the set voltage value, the control unit sends a control. The signal to the loop control unit transmits the loop signal by the control loop control unit, and controls the inductive control unit to close the line between the inductive control unit and the second security device host, and stops supplying the power of the second security device host.

The sensing control unit of the power management system is further connected to the first security host, and the sensing control unit detects the second detection voltage value between the sensing control unit and the first security host, and the control unit receives the second detection voltage value. Compared with another set voltage value, when the control unit determines that the second detected voltage value is lower than another set voltage value, the control unit sends a control signal to the loop control unit to control the loop control unit to transmit the loop signal, and control the sensing control unit. The line between the inductive control unit and the first security host is turned off.

The set voltage values are respectively set voltages of different nodes, and the set voltage values are set according to user input.

An object of the present invention is to provide a method for operating a power management system, wherein a power management system is connected between a first security host and a second security device host, and the power device is connected to the first security host power management system including an inductive control unit. , control unit and loop control unit. The operating method of the power management system includes the steps of storing at least one set voltage value in the control unit. The sensing supply unit detects the voltage value of the second security device host; the control unit receives the first detection voltage value detected by the sensing control unit; and the loop control unit receives the control signal transmitted by the control unit, and according to the control The signal determines whether to close the line of the sensing control unit and the second security device host; the control unit compares the received first detection voltage value with one of the set voltage values stored in the control unit; and, when controlling When the unit determines that the first detection voltage value is lower than the set voltage value, the control unit sends a control signal to the loop control unit to control the loop control unit to transmit a loop signal, and the control induction control unit turns off the sensing control unit and the second security device. The line between the hosts stops supplying the power of the second security device.

Before storing at least one set voltage value in the control unit, the input voltage value of each node is separately input for different nodes.

The power management system of the present invention can automatically switch and reduce the number of personnel maintenance due to damage. At the same time, the power supply circuit of the well-known security system is strengthened, and after the secondary system is damaged, the main system operation can be quickly restored to achieve the goal of continuous power supply. And to improve the parallel use of DC power is vulnerable to external damage and cause system failure.

When the environment is powered off, the power system can be powered down by the secondary system one by one, so that the main system can continue to operate for a longer period of time, and the entire system cannot be restored immediately after the short circuit of an auxiliary system is short-circuited. In the case of the continuous operation of the security system, the sustainable return to the customer's mobile phone or security company's current damaged area and related power supply (normal / abnormal) state, thereby greatly improving system stability and security.

10‧‧‧First Security Host

20‧‧‧Power supply unit

30‧‧‧ card reader

40‧‧‧Second security equipment host

50‧‧‧ Third Security Device Host

100‧‧‧Power Management System

110, 210‧‧‧Control unit

120, 220‧‧‧ loop control unit

130, 230‧‧‧Induction Control Unit

200‧‧‧Power Management System

V1‧‧‧ first detection voltage value

V2‧‧‧ second detection voltage value

V3‧‧‧ third detection voltage value

V4‧‧‧ fourth detection voltage value

VS1‧‧‧ first set voltage value

VS2‧‧‧ second set voltage value

VS3‧‧‧ third set voltage value

VS4‧‧‧ fourth set voltage value

A, B, C, D‧‧‧ nodes

S1, S11, S111, S3‧‧‧ control signals

S2, S22, S222, S4‧‧‧ loop signals

S300~S350, S400~S450‧‧‧ method

1 is a block diagram of a power management system of the present invention; and FIG. 2 is a block diagram of another embodiment of the power management system of the present invention; 3 is a flow chart of an operation method of a power management system according to the present invention; and FIG. 4 is a flow chart of another operation method of the power management system of the present invention.

Specific embodiments to which the present invention is applied will be described in detail below with reference to the drawings. 1 is a block diagram of a power management system of the present invention. The power management system 100 is connected between the first security host 10 and the second security device host 40, and the power supply device 20 is connected to the first security host 10; wherein, the first security host 10 is a primary security host, and the second security device is a second security device. Host 40 is an attached device host.

The power management system 100 includes a control unit 110, a loop control unit 120, and an inductive control unit 130. There is a Node B between the power management system 100 and the second security device host 40. The sensing control unit 130 detects the voltage value of the node B, that is, the first detected voltage value V1. The control unit 110 is connected to the sensing control unit 130. The control unit 110 receives the first detected voltage value V1 detected by the sensing control unit 130.

The loop control unit 120 connects the control unit 110 and the sensing control unit 130. The loop control unit 120 receives the control signal S1 transmitted by the control unit 110. The control unit 110 controls the loop control unit 120 to turn on or off the line between the inductive control unit 130 and the second security device host 40 with the control signal S1.

The control unit 110 stores at least one set voltage value. In this embodiment, the control unit 110 stores the first set voltage value VS1 and the second set voltage value VS2, wherein the first set voltage value VS1 is the set voltage of the node B, and the second set voltage value VS2 is the node A. The set voltage. It should be noted that the first set voltage value VS1 and the second set voltage value VS2 can be set according to user input. The user can maintain the maximum security of the host operation, or enable the security host to use the backup battery after the power failure, based on the extended operation time, and calculate the set voltage of each node.

The control unit 110 compares the received first detected voltage value V1 with the first set voltage The value VS1 is compared. When the control unit 110 determines that the first detection voltage value V1 is lower than the first set voltage value VS1, the control unit 110 transmits the control signal S1 to the loop control unit 120. The control signal S1 controls the loop control unit 120 to transmit the loop signal S2, and closes the line between the inductive control unit 130 and the second security device host 40. The power supply will stop supplying the second security device host 40.

The sensing control unit 130 of the power management system 100 is connected to the first security host 10, and the sensing control unit 130 detects the second detection voltage value V2 between the sensing control unit 130 and the first security host 10. Referring to FIG. 1, power management There is a node A between the system 100 and the first security host 40. The sensing control unit 130 detects the voltage value of the node A, that is, the second detected voltage value V2. The control unit 110 receives the second detected voltage value V2 detected by the sensing control unit 130.

The control unit 110 controls the loop control unit 120 to turn on or off the line between the inductive control unit 130 and the first security host 10 with the control signal S11. The control unit 110 compares the received second detected voltage value V2 with the second set voltage value VS2. When the control unit 110 determines that the second detection voltage value V2 is lower than the second set voltage value VS2, the control unit 110 sends the control signal S11 to the loop control unit 120. The control signal S11 controls the loop control unit 120 to transmit the loop signal S22, and turns off the line between the inductive control unit 130 and the first security host 10. The power supply will stop supplying the first security host 10.

2 is a block diagram of another embodiment of the power management system of the present invention. In this embodiment, the first security host 10 is connected to two security device hosts (ie, the second security device host 40 and the third security device host 50) and a card reader 30; wherein the first security host 10 is the primary security The host, and the second security device host 40 and the third security device host 50 are auxiliary device hosts. The power management system of FIG. 2 is the same as the power management system of FIG. 1, and additionally connects the card reader 30 and the third security device host 50.

As shown in FIG. 2, the card reader 30 is connected to the power management system 200. The power management system 200 is connected between the power supply device 20 and the card reader 30. The third security device host 50 is connected to the power management system 100. Node C is between power management system 200 and card reader 30. In the power management system 200 The sensing control unit 230 detects the voltage value of the node C, that is, the third detected voltage value V3. Node D is between power management system 100 and third security device host 50. The sensing control unit 130 detects the voltage value of the node D, that is, the fourth detected voltage value V4.

The loop control unit 120 receives the control signal S111 transmitted by the control unit 110. The control unit 110 controls the loop control unit 120 to turn on or off the line between the inductive control unit 130 and the third security device host 50 with the control signal S111.

The loop control unit 220 receives the control signal S3 transmitted by the control unit 210. The control unit 210 controls the loop control unit 220 to turn on or off the line between the inductive control unit 230 and the card reader 30 with the control signal S3.

The control unit 110 stores a first set voltage value VS1, a second set voltage value VS2, and a fourth set voltage value VS4. The control unit 210 stores a third set voltage value VS3. The first set voltage value VS1 is the set voltage of the node B, the second set voltage value VS2 is the set voltage of the node A, and the fourth set voltage value VS4 is the set voltage of the node D. The third set voltage value VS3 is the set voltage of the node C.

It should be noted that the first set voltage value VS1, the second set voltage value VS2, the third set voltage value VS3, and the fourth set voltage value VS4 can be set according to user input. The user calculates the set voltage of each node based on the operation time of maintaining the maximum security of the host or extending the power failure of the host.

The control unit 110 compares the received fourth detected voltage value V4 with the fourth set voltage value VS4. When the control unit 110 determines that the fourth detected voltage value V4 is lower than the fourth set voltage value VS4, the control unit 110 sends the control signal S111 to the loop control unit 120. The control signal S111 controls the loop control unit 120 to transmit the loop signal S222, and closes the line between the inductive control unit 130 and the third security device host 50. The power supply will stop supplying the third security device host 50.

In addition, the control unit 210 compares the received third detected voltage value V3 with the third set voltage value VS3. When the control unit 210 determines that the third detection voltage value V3 is lower than the third set voltage When the value is VS3, the control unit 210 transmits the control signal S3 to the loop control unit 220. The control signal S3 controls the loop control unit 220 to transmit the loop signal S4, and turns off the line between the inductive control unit 230 and the card reader 30. The power supply will stop supplying the card reader 30.

In this embodiment, if the third security device host has a fault condition, the control unit 110 determines that the fourth detected voltage value V4 of the node D is lower than the fourth set voltage value VS4. The control unit 110 transmits the control signal S111 to the loop control unit 120. The control signal S111 controls the loop control unit 120 to transmit the loop signal S222, and closes the line between the inductive control unit 130 and the third security device host 50. The power supply will stop supplying the third security device host 50 to continue to maintain the normal operation of the second security device host 40 and the first security host 10. And through voltage detection, it can reduce or reduce the flaws of the entire system caused by the damage of the traditional fuse and the need for manual maintenance. In the case that the remaining normally operating security host (and the first security host 10 and the second security device host 40) continue to operate, they can continue to report to the customer's mobile phone or the company's current damaged area and related power supply (normal / abnormal) State, which in turn greatly improves system stability and security. Strengthening the judgment time mechanism of the company's back-end monitoring station can increase the effectiveness of early warning before the defense line is completely destroyed.

It should be noted that the first diagram and the second diagram illustrate the electrical connection diagram of connecting two security hosts with three security hosts and a card reader, but the power management system of the present invention does not protect the host or the card by the above. The number of machines and the connection device are limited.

Please refer to FIG. 1 and FIG. 3, which is a flow chart of the operation method of the power management system 100 of the present invention. The power management system 100 is connected between the first security host 10 and the second security device host 40. The power management system 100 includes a control unit 110, a loop control unit 120, and an inductive control unit 130. The method of operation of the power management system 100 includes the following steps:

S300: Store at least one set voltage value in the control unit 110.

S310: Detecting the voltage value of the second security device host 40 by the sensing supply unit 130.

S320: Receive, by the control unit 110, the first detection voltage detected by the sensing control unit 130. The value is V1.

S330: The loop control unit 120 receives the control signal S1 transmitted by the control unit 110, and determines whether to close the line of the inductive control unit 130 and the second security device host 40 according to the control signal S1.

S340: The control unit 110 compares the received first detection voltage value V1 with one of the set voltage values stored in the control unit 110 (the first set voltage value VS1).

S350: When the control unit 110 determines that the first detection voltage value V1 is lower than the set voltage value (the first set voltage value VS1), the control unit 110 sends the control signal S1 to the loop control unit 120 to control the loop control unit 120 to transmit the loop. Signal S2, the control sensing control unit 130 turns off the line between the sensing control unit 130 and the second security device host 40, and stops supplying the power of the second security device host 40.

S342: When the control unit 110 determines that the first detection voltage value V1 is higher than the set voltage value (the first set voltage value VS1), the control unit 110 sends the control signal S1 to the loop control unit 120 to control the loop control unit 120 to transmit the loop. Signal S2, the control sensing control unit 130 continuously turns on the line between the sensing control unit 130 and the second security device host 40, and continues to supply the power of the second security device host 40.

Referring to FIG. 1 and FIG. 4, FIG. 4 is a flow chart of another method of operation of the power management system 100 of the present invention. The power management system 100 is connected between the first security host 10 and the second security device host 40. The power management system 100 includes a control unit 110, a loop control unit 120, and an inductive control unit 130. The method of operation of the power management system 100 includes the following steps:

S400: Input the set voltage value of each node separately for different nodes. For example, for the node A, the second set voltage value VS1 of the node is input, and for the node B, the node B inputs the first set voltage value VS1 of the node.

S406 is connected to the first security host 10 by the sensing control unit 130.

S410: The voltage value of the voltage value of the first security host 10 and the second security device host 40 is detected by the sensing supply unit 130.

S420: The control unit 110 receives the first detected voltage value V1 and the second detected voltage value V2 detected by the sensing control unit 130.

S430: The loop control unit 120 receives the control signals S1 and S11 transmitted by the control unit 110, and determines whether to close the line of the inductive control unit 130 and the first security host 10 and/or the sensing control unit 130 according to the control signals S1 and S11. The line with the second security device host 40.

S440: The control unit 110 stores the received first detection voltage value V1 and the first set voltage value VS1 and/or the second detection voltage value V2 stored in the control unit 110 in the control unit 110. The second "two sets the voltage value VS2 comparison.

S450: When the control unit 110 determines that the first detection voltage value V1 is lower than the first set voltage value VS1, the control unit 110 sends the control signal S1 to the loop control unit 120 to control the loop control unit 120 to transmit the loop signal S2, and control the sensing. The control unit 130 turns off the line between the sensing control unit 130 and the second security device host 40, and stops supplying the power of the second security device host 40. And/or, when the control unit 110 determines that the second detection voltage value V2 is lower than the second set voltage value VS2, the control unit 110 sends the control signal S11 to the loop control unit 120 to control the loop control unit 120 to transmit the loop signal S22. The control sensing control unit 130 turns off the line between the sensing control unit 130 and the second security device host 40, and stops supplying the power of the second security device host 40.

S442: When the control unit 110 determines that the first detection voltage value V1 is higher than the first set voltage value VS1, the control unit 110 sends the control signal S1 to the loop control unit 120 to control the loop control unit 120 to transmit the loop signal S2, and control the sensing. The control unit 130 continuously turns on the line between the inductive control unit 130 and the second security device host 40, and continues to supply the second security device host 40 power. And/or when the control unit 110 determines that the second detection voltage value V2 is higher than the second set voltage value VS2, the control unit 110 sends the control signal S11 to the loop control unit 120 to control the loop control unit 120 to transmit the loop signal S22, and control The sensing control unit 130 continuously turns on the line between the sensing control unit 130 and the first security host 10, and continues to supply the power of the first security host 10.

The above is intended to be illustrative only and not limiting. Any equivalent modifications or changes made to the spirit and scope of this case shall be included in the scope of the appended patent application.

10‧‧‧First Security Host

20‧‧‧Power supply unit

40‧‧‧Second security equipment host

100‧‧‧Power Management System

110‧‧‧Control unit

120‧‧‧Circuit Control Unit

130‧‧‧Induction Control Unit

V ₁ ‧‧‧first detection voltage value

V ₂ ‧‧‧second detection voltage value

A, B‧‧‧ nodes

S ₁ , S ₁₁ ‧‧‧ control signals

S ₂ , S ₂₂ ‧‧‧ loop signal

Claims (6)

A power management system is connected between a first security host and a second security device host, and a power supply device is connected to the first security host. The power management system includes: a sensing control unit configured to detect the first The second control device has a voltage value; a control unit is connected to the sensing control unit, the control unit receives the first detected voltage value detected by the sensing control unit; a loop control unit connects the control unit and the sensing a control unit, the loop control unit receives a control signal transmitted by the control unit, and determines, according to the control signal, whether to close a line between the sensing control unit and the second security device host; wherein the control unit stores at least one Setting a voltage value, the control unit compares the received first detection voltage value with one of the set voltage values, and when the control unit determines that the first detection voltage value is lower than the set voltage value, The control unit sends a control signal to the loop control unit to control the loop control unit to transmit a loop signal, and control Sensing the control unit turns off the sensing circuit in the control unit and the second maintenance device between the host, the second maintenance device to stop supply of the mains. The power management system of claim 1, wherein the sensing control unit of the power management system is further connected to the first security host, and the sensing control unit detects the sensing control unit and the first security host. a second detection voltage value, the control unit compares the received second detection voltage value with another set voltage value, and when the control unit determines that the second detection voltage value is lower than another setting At the voltage value, the control unit sends the control signal to the loop control unit to control the loop control unit to transmit the loop signal, and control the sensing control unit to close the line between the sensing control unit and the first security host. The power management system of claim 1, wherein the set voltage values are respectively set voltages of different nodes, and the set voltage values are set according to user input. A method for operating a power management system, wherein the power management system is connected between a first security host and a second security device host, a power supply device is connected to the first security host, and the power management system includes an inductive control a unit, a control unit, and a loop control unit, the method for operating the power management system includes the steps of: storing at least one set voltage value in the control unit; and detecting, by the inductive supply unit, a voltage of the second protection device host Receiving, by the control unit, the first detected voltage value detected by the sensing control unit; receiving, by the loop control unit, the control signal transmitted by the control unit, and determining, according to the control signal, whether to close the sensing control unit And a line of the second security device host; the control unit compares the received first detection voltage value with one of the set voltage values stored in the control unit; and when the control unit determines When the first detection voltage value is lower than the set voltage value, the control unit sends a control signal to the back A control unit for controlling the circuit control unit transmits a signal loop, the control unit controls the induction control unit close to the sensing circuit and the second maintenance device between the host, the second maintenance device to stop supply of the mains. The operating method of the power management system of claim 4, further comprising: connecting, by the sensing control unit, the first security host; detecting, by the sensing control unit, the sensing control unit and the first security host a second detected voltage value; the control unit compares the received second detected voltage value with another set voltage value; and when the control unit determines that the second detected voltage value is low When the voltage value is set, the control unit sends the control signal to the loop control unit to control the loop control unit to transmit the loop signal, and control the sensing control unit to close the line between the sensing control unit and the first security host. . The method of operating a power management system according to claim 4, wherein before the step of storing at least one set voltage value in the control unit, the setting voltage value of each node is separately input for different nodes.