CN114253181A - System and method for realizing wattage consumption of remote monitoring server - Google Patents

Abstract

The application provides a system and a method for realizing wattage consumption of a remote monitoring server, wherein the system comprises: the isolation inductors are connected with one power supply scheme; the first micro control chip is provided with a plurality of groups of terminals, is connected with the input end and the output end of the isolation inductor through the terminals, obtains the input voltage and the output voltage of the isolation inductor, and calculates the passing current of the isolation inductor; the micro control unit is connected with the first micro control chip and transmits the passing current and the input voltage of each isolation inductor to the second micro control chip; the second micro control chip sends data request information to the micro control unit after receiving a trigger instruction sent by the client through the IP communication network; the second micro control chip is also used for performing decompilation on the input voltage signal transmitted by the micro control unit through current so as to decompilate the input voltage signal into a message which can be transmitted through IP network communication. According to the scheme, the consumed wattage of the power supply scheme of the remote monitoring server can be realized.

Description

System and method for realizing wattage consumption of remote monitoring server

Technical Field

The application relates to a system and a method for realizing wattage consumption of a remote monitoring server, belonging to the technical field of wattage consumption monitoring of a power supply scheme.

Background

With the development of science and technology, on the application of advanced servers, the wattage requirements of main components such as a CPU (central processing unit), a memory, an MCU (micro control unit), a PCH (peripheral channel bus) and the like on a mainboard are increased, power supply schemes are divided into more and more thin, and compared with the previous generations, the power supply schemes designed on the mainboard are increased; with the change of the times, the demand of remote control and measurement is also improved, and the dependence is higher than before, which is a trend of future development.

At present, a corresponding signal is provided to a Micro Control Unit (MCU) through introducing a cross voltage of an Rshunt on a most front Hotswap into a Hotswap Controller through calculation and integration, but the corresponding signal can be controlled and read only by using a special GUI (graphical user interface) for the MCU after instruction, however, the scheme only monitors the consumed wattage of a plurality of groups of important power supply schemes and does not monitor the wattage of each power supply scheme, meanwhile, because the special GUI for the MCU has a short instruction communication distance, a related operator can acquire the consumed wattage of the important power supply schemes within a certain distance range from the MCU, and the monitoring of the power supply schemes is incomplete because the detection is only carried out on the consumed wattages of a plurality of important power supply schemes; meanwhile, the limitation of high requirement on the working place of an operator cannot realize the online reading and storage of the wattage consumed by the power supply scheme, and the subsequent retrieval of the wattage consumed data of the power supply scheme is inconvenient.

Disclosure of Invention

The application provides a system and a method for realizing wattage consumption of a remote monitoring server, which aim to solve the problem that the monitoring of a power supply scheme is not comprehensive because only the wattages consumed by a plurality of important power supply schemes are detected in the prior art; meanwhile, the limitation of high requirement on the working place of an operator cannot realize the online reading and storage of the wattage consumed by the power supply scheme, and the subsequent retrieval of the wattage consumed data of the power supply scheme is inconvenient.

In a first aspect, a system for implementing wattage consumption of a remote monitoring server according to an embodiment of the present application is provided, including:

the isolation inductors are connected with one power supply scheme;

the first micro control chip is provided with a plurality of groups of terminals, wherein two terminals in each group of terminals are respectively connected with the input end and the output end of an isolation inductor and used for acquiring the input voltage and the output voltage of the isolation inductor; the first micro-control chip is also used for calculating the passing current of the isolation inductors according to the input voltage, the output voltage and the impedance value of each isolation inductor;

the micro-control unit is connected with the first micro-control chip and is used for transmitting the passing current and the input voltage of each isolation inductor to the second micro-control chip;

the second micro control chip is used for sending data request information to the micro control unit after receiving a trigger instruction sent by the client through the IP communication network; the data request information comprises input voltage request information and passing current request information of an isolation inductor connected with a target power supply scheme;

the second micro control chip is also used for performing decompiling on the input voltage signal and the passing current transmitted by the micro control unit so as to decompile the input voltage signal and the passing current into a message which can be transmitted through IP network communication.

In one embodiment, the system further comprises:

the filter assembly is connected between the input end of the isolation inductor and one terminal of the corresponding group of terminals; and/or between the output of the isolating inductor and another terminal of the corresponding set of terminals.

In one embodiment, the filtering component is a resistor device with a preset resistance value.

In one embodiment, the second micro control chip includes:

the IP communication unit is used for receiving a trigger instruction sent by the client through an IP communication network;

the sending unit is used for sending data request information to the micro control unit after receiving a trigger instruction sent by the client through the IP communication network;

the receiving unit is used for receiving the input voltage signal and the passing current signal returned by the micro control unit;

the decompiling unit is used for decompiling the received input voltage signal and the passing current so as to decompile the received input voltage signal and the passing current into a network message which can be transmitted through IP network communication;

and the IP communication unit is also used for sending the network message which is decompiled by the decompilation unit to the IP network device.

In one embodiment, the decompiling unit adds a message in a preset format to the input voltage signal and the message corresponding to the current signal, so as to form a network message capable of being transmitted through IP network communication;

the message with the preset format comprises a source port, a destination port, a source network address and a destination network address.

In one embodiment, the second micro control chip further includes:

and the calculation unit is used for calculating the acquired input voltage signal and the acquired passing current signal and determining the consumed wattage of the power supply scheme corresponding to the isolation inductor.

In a second aspect, a method for implementing wattage consumed by a remote monitoring server is provided according to an embodiment of the present application, where the method for implementing wattage consumed by a remote monitoring server is adopted in any one of the systems described above, and the method includes:

the second micro control chip sends data request information to the micro control unit after receiving a trigger instruction sent by the client through the IP communication network; the data request information comprises input voltage signal request information and passing current request information of an isolation inductor connected with a target power supply scheme;

the micro control unit controls the first micro control chip to acquire the input voltage and the output voltage of each isolation inductor according to the request information, and controls the first micro control chip to calculate the passing current of the isolation inductors according to the input voltage, the output voltage and the impedance value of each isolation inductor;

the first micro control unit transmits the passing current and the input voltage of the isolation inductor to the second micro control chip through the micro control unit;

the second micro control chip performs decompiling on the input voltage signal transmitted by the micro control unit through current to decompile the input voltage signal into a message which can be transmitted through IP network communication, and transmits the message which can be transmitted through IP network communication to the client through IP network communication.

In one embodiment, further comprising:

and the second micro control chip calculates the acquired input voltage signal and the acquired passing current signal to determine the consumed wattage of the power supply scheme corresponding to the isolation inductor.

In one embodiment, the second micro control chip decompiles the input voltage signal transmitted by the micro control unit by current to decompile the input voltage signal into a message capable of being transmitted by IP network communication, and sends the message capable of being transmitted by IP network communication to the client through IP network communication, and the method includes:

the second micro control chip adds a message in a preset format in front of the message corresponding to the input voltage signal and the current signal, so as to form a network message which can be transmitted through IP network communication;

the message with the preset format comprises a source port, a destination port, a source network address and a destination network address.

In one embodiment, the input voltage and the output voltage of each isolation inductor are input voltages and output voltages filtered by corresponding filter devices.

The beneficial effect of this application lies in:

according to the system and the method for realizing wattage consumption of the remote monitoring server, supervision data acquired by a power supply scheme can be transmitted through IP network communication, and then the purpose that monitoring personnel can consume wattage through the power supply scheme of the remote monitoring server through IP network communication can be realized.

In addition, the control of the distance between an operator and a unit for control is effectively overcome based on the scheme, the data acquisition, conversion and transmission can be transmitted through a network, the operator does not need to be in the field to remotely monitor the wattage consumption of a power supplier scheme under the condition of no equipment fault, therefore, the power supply scheme connected with the first micro control chip also overcomes the limitation of the distance, and further the first micro control chip can be connected with more power supply schemes, so that the problem that only the total wattage and several groups of important power supply schemes can be read in the traditional scheme and the monitoring action of all the power supply schemes is not supported is effectively overcome. .

The foregoing description is only an overview of the technical solutions of the present application, and in order to make the technical solutions of the present application more clear and clear, and to implement the technical solutions according to the content of the description, the following detailed description is made with reference to the preferred embodiments of the present application and the accompanying drawings.

Drawings

FIG. 1 is a schematic diagram of a system for implementing wattage consumption of a remote monitoring server according to one embodiment of the present application;

FIG. 2 is a schematic diagram of a system for implementing wattage consumption by a remote monitoring server according to another embodiment of the present application;

fig. 3 is a schematic diagram of a constituent module of a second micro control chip provided in the embodiment of the present application;

FIG. 4 is a flow chart of a method for implementing wattage consumption by a remote monitoring server in one embodiment of the present application;

fig. 5 is a flow chart illustrating a method for implementing wattage consumed by a remote monitoring server according to another embodiment of the present invention.

Detailed Description

The following examples are intended to illustrate the present application but are not intended to limit the scope of the present application.

In the prior art, among the power consumption schemes of the power supply schemes, schemes that only the power consumption of several important power supply schemes are detected are adopted, monitored data need to be fed back to an operator through a Micro Control Unit (MCU), the operator needs to acquire the monitored data by using a GUI instruction special for the MCU, and the communication radiation range of the GUI instruction is relatively small, so that the operator needs to reach the radiation range of the GUI instruction, namely, correct monitored data can be acquired within a certain distance range from the MCU. In addition, in the prior art, each technical scheme cannot be monitored, and only a few representative power supply schemes can be selected, so that the purpose of monitoring the wattage of each power supply scheme cannot be achieved.

Based on the technical problems that the distance requirement for an operator to an MCU is high and the wattage of all power supply schemes cannot be monitored in the prior art, the system and the method for realizing the wattage consumption of the remote monitoring server are provided.

Example 1

The embodiment of the application provides a system for realizing remote monitoring of the wattage consumed by a server, which is applied to remote monitoring of the wattage consumed by a client side to a server power supply scheme, as a preferred embodiment, the system for realizing remote monitoring of the wattage consumed by the server provided by the application is started according to a trigger command, the client side is used as an operation end for sending the trigger command by a user, the system for realizing remote monitoring of the wattage consumed by the server provided by the application is used as a receiving end for the trigger command, after a data request command sent by the client side is received, monitoring data acquisition is executed, monitoring data is converted into a communication message which can be transmitted through IP network communication, the converted message is fed back to the client side, wherein, the stage of acquiring the monitoring data can involve calculation of the acquired data, and then obtain the course of other data, likewise, in the course of converting the monitoring data into the communication message that can be transmitted through the communication of IP network, can involve calculating to some monitoring data obtained, and then convert the result of calculation into the communication message that can be transmitted through the communication of IP network and then transmit to the course of customer end too. As follows, the system for realizing wattage consumption of the remote monitoring server provided by the embodiment of the present application is described in detail:

referring to fig. 1, an embodiment of the present application provides a system for implementing wattage consumption of a remote monitoring server, including:

the isolation inductors are connected with one power supply scheme;

the first micro control chip 12 is provided with a plurality of groups of terminals, wherein two terminals in each group of terminals are respectively connected with the input end and the output end of an isolation inductor and are used for acquiring the input voltage and the output voltage of the isolation inductor; the first micro control chip 12 is further configured to calculate a passing current of the isolation inductor 11 according to the input voltage, the output voltage, and the impedance value of each isolation inductor 11;

a micro control unit 13 connected to the first micro control chip 12 for transmitting the passing current of each isolation inductor 11 to a second micro control chip 14;

the second micro control chip 14 is configured to send data request information to the micro control unit 13 after receiving a trigger instruction sent by the client through the IP communication network; the data request information comprises input voltage signal request information and passing current request information of an isolation inductor connected with a target power supply scheme;

the second micro control chip is also used for performing decompiling on the input voltage signal and the passing current transmitted by the micro control unit so as to decompile the input voltage signal and the passing current into a message which can be transmitted through IP network communication.

In the embodiment of the present application, the number of the isolation inductors may be set according to actual requirements, as shown in fig. 1, the isolation inductors 111, 112 and 113 are included, where the isolation inductor 111 is connected to the first power scheme VR1, the isolation inductor 112 is connected to the first power scheme VR2, and the isolation inductor 113 is connected to the first power scheme VR 3.

In this embodiment, a plurality of sets of terminals are disposed on the first micro control chip 12, as shown in fig. 1, the first micro control chip 12 includes three sets of terminals, where the first set of terminals includes a first terminal 121 and a second terminal 122, the second set of terminals includes a third terminal 123 and a fourth terminal 124, and the third set of terminals includes a fifth terminal 125 and a sixth terminal 126, the first micro control chip 12 is connected to the isolation inductor 111 through the first set of terminals, as a specific embodiment, the first terminal 121 of the first micro control chip 12 is connected to an input end of the isolation inductor 111, and the second terminal 122 of the first micro control chip 12 is connected to an output end of the isolation inductor 111, so as to obtain an input voltage and an output voltage of the isolation inductor 111; similarly, the first micro control chip 12 is connected to the isolation inductor 112 through the second set of terminals, as a specific embodiment, the third terminal 123 of the first micro control chip 12 is connected to the input terminal of the isolation inductor 112, and the fourth terminal 124 of the first micro control chip 12 is connected to the output terminal of the isolation inductor 112, so as to obtain the input voltage and the output voltage of the isolation inductor 112; as another specific embodiment, the first micro control chip 12 is connected to the isolation inductor 113 through the third set of terminals, the fifth terminal 125 of the first micro control chip 12 is connected to the input terminal of the isolation inductor 113, and the sixth terminal 126 of the first micro control chip 12 is connected to the output terminal of the isolation inductor 113, so as to obtain the input voltage and the output voltage of the isolation inductor 113.

In this embodiment, after the first micro control chip obtains the input voltage and the output voltage of each isolation inductor, the passing current of the isolation inductor may be calculated based on the input voltage, the output voltage, and the impedance value of the isolation inductor, for example, for the isolation inductor 111, the voltage V at the input end of the isolation inductor 111 is obtained₁₁And the output terminal voltage V of the isolation inductor 111₁₂Then, the voltage V at the input terminal of the isolation inductor 111 can be determined₁₁And the voltage V at the output terminal₁₂The difference between them is the voltage V on the isolation inductor 111₁₁₁(ii) a Similarly, for the isolation inductor 112, the voltage V at the input end of the isolation inductor 112 is obtained₂₁And the output voltage V of the isolation inductor 112₂₂The voltage V at the input of the isolation inductor 112 can then be determined₂₁And the voltage V at the output terminal₂₂The difference between them is the voltage V on the isolation inductor 112₁₁₂(ii) a Similarly, for the isolation inductor 113, the voltage V at the input end which is obtained to the isolation inductor 113₃₁And the output terminal voltage V of the isolation inductor 113₃₂Thereafter, the voltage V at the input of the isolation inductor 113 can be determined₃₁And the voltage V at the output terminal₃₂The difference between them is the voltage V on the isolation inductor 113₁₁₃。

In the embodiment of the present application, after the voltage consumed by the isolation inductor is calculated, the passing current of the isolation inductor can be determined based on the impedance value and the consumed voltage of the isolation inductor. For example, for the isolation inductor 111, the voltage V is determined₁₁₁Then, the mathematical model V can be used₁₁₁/R₁₁₁Determining the through-current I of the isolating inductor 111₁₁₁(ii) a Similarly, for the isolation inductor 112, the voltage V is determined₁₁₂Then, the mathematical model V can be used₁₁₂/R₁₁₂Determining the through-current I of the isolation inductor 112₁₁₂(ii) a For the isolation inductor 113, the voltage V is determined₁₁₃Then, the mathematical model V can be used₁₁₃/R₁₁₃Determining the through-current I of the isolating inductor 113₁₁₃。

In the embodiment of the present application, a Micro Control Unit (MCU)13 is connected to the first micro control chip 12, and is configured to transmit the passing current and the input voltage of each isolation inductor to the second micro control chip 14. I.e. the current I passing through the isolating inductor 111₁₁₁Voltage at input terminal V₁₁To the second microcontroller chip 14; similarly, the passing current I of the inductor 112 will be isolated₁₁₂Voltage at input terminal V₂₁Transmitted to the second micro control chip 14 to isolate the current I passing through the inductor 113₁₁₃Voltage at input terminal V₃₁To the second micro control chip 14.

In the embodiment of the present application, after receiving the input voltage and the passing current of the isolation inductor, the second micro control chip 14 performs inverse compilation on the input voltage and the passing current of the isolation inductor, so as to form a data message that can be transmitted through IP network communication. In the application, the wattage consumption is calculated based on a mathematical model P ═ V × I, where P is the consumed wattage, V is the input voltage of the target isolation inductor, and I is the passing current of the isolation inductor.

In the embodiment of the present application, the second micro control chip 14 is used as a module capable of performing IP network communication with a client in a system for implementing remote monitoring of wattage consumed by a server, and is started when a trigger instruction sent by the client through an IP communication network is received, and after the trigger instruction sent by the client through the IP communication network is received, data request information is sent to the micro control unit 13, the sent data request information includes input voltage request information and passing current request information of an isolation inductor connected to a target power supply scheme, a receiving object of the data request information is the first micro control chip, that is, after the first micro control chip receives the data request information sent by the micro control unit, the first micro control chip starts to obtain the input voltage and the output voltage of the isolation inductor corresponding to the target power supply scheme, and calculates the passing current of the isolation inductor according to the input voltage, the output voltage, and the impedance of the target isolation inductor, and then, the input voltage and the passing current of the target isolation inductor are fed back to the second micro control chip through the micro control unit, so that the second micro control chip converts the input voltage and the passing current into message data which can be sent through an IP communication network, and the message data is further transmitted to the client through the IP communication network.

It is noted that the target inductance may be one or more isolation inductances in the present solution, and as a specific embodiment, a unique identifier corresponding to the isolation inductance may be set for the isolation inductance, and when the client sends a trigger command, the client sends the unique identifier of the target inductance corresponding to the power supply scheme to be monitored at the same time, and the trigger command received by the second micro control chip also includes the unique identifier of the target isolation inductance, and then is obtained based on the unique identifier of the target isolation inductance in the subsequent data obtaining process. As another embodiment, a unique identifier may also be set for the power supply scheme, each isolation inductor has an identifier that is the same as or has a preset mathematical relationship with its corresponding power supply scheme, and when the client sends the trigger command, the client sends the unique identifier of the power supply scheme to be monitored, and based on the preset mapping relationship in the second micro control chip, the identifier of the isolation inductor corresponding to the target power supply scheme may be determined, and then data such as the input voltage, the output voltage, and the like of the corresponding isolation inductor may be obtained according to the determined identifier of the isolation inductor.

In the embodiment of the present application, the second micro control chip 14 is further configured to perform decompiling on the input voltage signal and the passing current transmitted by the micro control unit 13, so as to decompile the input voltage signal and the passing current into a message that can be transmitted through IP network communication. It is pointed out that the input voltage signal and the current can be decompiled separately into a data message that can be transmitted via the IP communication network and then sent to the client simultaneously or one by one. The input voltage signal and the passing current can also be compiled into a message which can be transmitted through IP network communication, namely, the input voltage signal and the passing current are integrated according to a preset rule to form integrated data, and then the integrated data is subjected to decompiling. In the latter case, the client needs to set a data analysis module to analyze the acquired data packet including the integrated data, so as to acquire the input voltage and the passing current.

In the embodiment of the application, the system for remotely monitoring the wattage consumed by the server further comprises a filtering component connected between the input end of the isolation inductor and one terminal of the corresponding group of terminals; and/or between the output of the isolating inductor and another terminal of the corresponding set of terminals.

In the embodiment of the present application, referring to fig. 2, for the isolation inductor 111, a first filtering component 151 is connected between an input end of the isolation inductor 111 and the first terminal 121 of the first micro control chip 12, and a second filtering component 152 is connected between an output end of the isolation inductor 111 and the second terminal 122 of the first micro control chip 12; for the isolation inductor 112, a third filtering assembly 153 is connected between the input end of the isolation inductor 112 and the third terminal 123 of the first micro control chip 12, and a fourth filtering assembly 154 is connected between the output end of the isolation inductor 112 and the fourth terminal 124 of the first micro control chip 12; the isolation inductor 113 is connected with a fifth filter assembly 155 between the input end of the isolation inductor 113 and the fifth terminal 125 of the first micro control chip 12, and a sixth filter assembly 156 is connected between the output end of the isolation inductor 113 and the sixth terminal 126 of the first micro control chip 12.

Further, in the embodiment of the present application, the filter elements are all resistance elements. That is, the first filter assembly 151, the second filter assembly 152, the third filter assembly 153, the fourth filter assembly 154, the fifth filter assembly 155 and the sixth filter assembly 156 are all resistance assemblies. Only the specific resistance values of the resistor elements corresponding to the first filter element 151, the second filter element 152, the third filter element 153, the fourth filter element 154, the fifth filter element 155 and the sixth filter element 156 may be set according to actual requirements, and no specific limitation is imposed thereon.

In one embodiment, the second micro control chip 14 includes:

an IP communication unit 141, configured to receive a trigger instruction sent by a client through an IP communication network;

a sending unit 142, configured to send data request information to the micro control unit after receiving a trigger instruction sent by the client through the IP communication network; the data request information may be a compiled trigger instruction, and at this time, the sending unit 142 may inherit the compiling function therein, and further compile the received command identified by the IP network communication into a GUI command;

the receiving unit 143 is used for receiving the input voltage signal and the passing current signal returned by the micro control unit;

a decompilation unit 144, configured to decompilate the received input voltage signal and the passing current to decompilate the received input voltage signal into a network packet that can be transmitted through IP network communication;

the IP communication unit 141 is further configured to send the network packet compiled by the decompilation unit to the IP network device.

In this embodiment of the application, the second micro control chip 14 may also have data compiling and decompiling functions, on one hand, the received trigger information sent by the client through IP network communication needs to be converted into a GUI command and sent to the micro control unit, and on the other hand, data (including input voltage and passing current of the target isolation inductor) returned by the micro control unit through the GUI command needs to be decompiled into a data packet that can be identified by the IP network communication and then sent to the client through the IP network communication.

Further, in this embodiment of the application, the decompiling unit 144 adds a message in a preset format to the input voltage signal and the message corresponding to the current signal, so as to form a network message that can be transmitted through IP network communication;

the message with the preset format comprises a source port, a destination port, a source network address and a destination network address.

As an embodiment, the decompilation unit decompilates the input voltage signal and the through current signal respectively to form an input voltage signal and a through current signal recognizable for IP network communication, and the specific format is shown in tables 1 and 2:

TABLE 1 message Format of input Voltage signals recognizable for IP network communications

Source IP

Destination IP

Source port

Destination port

Input voltage signal

TABLE 2 message Format of passing Current Signal recognizable by IP network communication

Source IP

Destination IP

Source port

Destination port

Passing current signal

The last bit can be a flag bit, or can be set according to actual requirements, if there is no requirement and the flag bit does not need to be set, the client can be left idle, and after receiving the last bit, the client can start parsing from the left according to a set message parsing protocol.

As another embodiment, for the input voltage signal and the through current signal, the decompilation unit first combines the voltage signal and the through current signal according to a preset format, and then decompilates the combined signals to form a combined signal recognizable by the IP network communication and including the input voltage signal and the through current signal, where the specific format is shown in table 3:

TABLE 3 message Format of Merge signals recognizable for IP network communications

Meanwhile, the second micro control chip 14 further includes:

and the calculating unit 145 is configured to calculate the acquired input voltage signal and the acquired through current signal, and determine the consumed wattage of the power supply scheme corresponding to the isolation inductor.

In this embodiment of the application, the second micro control chip 14 includes a calculating unit 146, and the calculating unit calculates the acquired input voltage signal and the passing current signal to determine the consumed wattage of the power supply scheme corresponding to the isolation inductor. Since the calculating unit in the second micro-control chip 14 directly discards the input voltage signal and calculates through the current signal, and the consumed wattage of the power supply scheme corresponding to the isolation inductor is determined, the decompilating unit 144 also decompilates the calculated consumed wattage into a data message that can be identified by the IP network communication, and then sends the data message to the client.

According to the technical scheme provided by the embodiment of the application, the supervision data acquired by the power supply scheme can be transmitted through IP network communication, so that the technical defect that the supervision data acquired by the power supply scheme in the traditional technical scheme cannot support remote network control and reading and an engineer must be used for performing near-end control and reading on the spot is effectively overcome.

In addition, the control of the distance between an operator and a unit for control is effectively overcome based on the scheme, the data acquisition, conversion and transmission can be transmitted through a network, the operator does not need to be in the field to remotely monitor the wattage consumption of a power supplier scheme under the condition of no equipment fault, therefore, the power supply scheme connected with the first micro control chip also overcomes the limitation of the distance, and further the first micro control chip can be connected with more power supply schemes, so that the problem that only the total wattage and several groups of important power supply schemes can be read in the traditional scheme and the monitoring action of all the power supply schemes is not supported is effectively overcome.

Based on the prior art, the transvoltage of the Rshunt on the most front hotspot is led into a hotspot Controller, and the calculation and the integration are carried out through V-I R, wherein V is the transvoltage on the Rshunt, I is the total current of an input end, R is the resistance value of the Rshunt, and the used resistors are all positive temperature coefficients and can change along with the rise of the temperature, so that the read transvoltage value can deviate.

Example 2

According to an embodiment of the present application, there is provided a method for implementing wattage consumed by a remote monitoring server, which employs the system for implementing wattage consumed by a remote monitoring server according to any one of the above embodiments, and as shown in fig. 4, the method includes:

step S42, after receiving a trigger instruction sent by the client through the IP communication network, the second micro control chip sends data request information to the micro control unit; the data request information comprises input voltage signal request information and passing current request information of an isolation inductor connected with a target power supply scheme;

step S44, the micro control unit controls the first micro control chip to obtain the input voltage and the output voltage of each isolation inductor according to the request information, and controls the first micro control chip to calculate the passing current of the isolation inductor according to the input voltage, the output voltage and the impedance value of each isolation inductor;

step S46, the first micro control unit transmits the passing current and the input voltage of the isolation inductor to the second micro control chip through the micro control unit;

and step S48, the second micro control chip performs decompiling on the input voltage signal and the passing current transmitted by the micro control unit to decompile the input voltage signal and the passing current into a message which can be transmitted through IP network communication, and transmits the message which can be transmitted through IP network communication to the client.

In the embodiment of the present application, referring to fig. 5, the method further includes:

and step S47, the second micro control chip calculates the acquired input voltage signal and the acquired passing current signal, and determines the consumed wattage of the power supply scheme corresponding to the isolation inductor.

At this time, step S48 includes:

the second micro control chip performs decompiling on the input voltage signal, the passing current and the consumed wattage transmitted by the micro control unit to decompile the input voltage signal, the passing current and the consumed wattage into a message capable of being transmitted through IP network communication, and transmits the message capable of being transmitted through IP network communication to the client through IP network communication.

In this embodiment of the application, in step S48, the second micro control chip performs decompiling on the input voltage signal and the passing current transmitted by the micro control unit to decompile the input voltage signal and the passing current into a message transmittable through IP network communication, and sends the message transmittable through IP network communication to the client through IP network communication, including:

the second micro control chip adds a message in a preset format in front of the message corresponding to the input voltage signal and the current signal, so as to form a network message which can be transmitted through IP network communication;

the message with the preset format comprises a source port, a destination port, a source network address and a destination network address.

In this embodiment, the input voltage and the output voltage of each isolation inductor are the input voltage and the output voltage filtered by the corresponding filter device.

In the embodiment of the application, when the input voltage and the output voltage of the isolation inductor are obtained, the input voltage and the output voltage are filtered to eliminate the clutter signals.

In summary, the technical solution provided in the embodiments of the present application, by transmitting the supervision data acquired by the power supply scheme through IP network communication, effectively overcomes the technical defects that the supervision data acquired by the power supply scheme in the conventional technical solution cannot support remote network control and reading, and an engineer must perform near-end control and reading on site, and in addition, based on the technical solution, effectively overcomes the control of the distance between the operator and the unit for control, and the data acquisition, conversion, and transmission can be transmitted through the network, and the operator can remotely monitor the wattage consumption of the power supply scheme without being in the field under the condition of no equipment failure, so the power supply scheme connected with the first micro control chip also overcomes the distance limitation, and further the first micro control chip can be connected with more power supply schemes, thereby effectively overcoming the problem that only the total wattage and several groups of important power supply schemes can be read in the conventional scheme, the problem of monitoring all power supply schemes is not supported.

Optionally, the present application further provides a computer-readable storage medium, which stores a computer program, and the computer program is used for implementing the steps of the above MySQL Galera cluster brain crack automatic repairing method when being executed by a processor.

Optionally, the present application further provides a computer product, which includes a computer-readable storage medium, where a program is stored in the computer-readable storage medium, and the program is loaded and executed by a processor to implement the steps of the foregoing MySQL Galera cluster automatic repair method for brain cracks.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Finally, it should also be noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A system for enabling remote monitoring of wattage consumed by a server, comprising:

the isolation inductors are connected with one power supply scheme;

the first micro control chip is provided with a plurality of groups of terminals, wherein two terminals in each group of terminals are respectively connected with the input end and the output end of an isolation inductor and used for acquiring the input voltage and the output voltage of the isolation inductor; the first micro-control chip is also used for calculating the passing current of the isolation inductors according to the input voltage, the output voltage and the impedance value of each isolation inductor;

the micro-control unit is connected with the first micro-control chip and is used for transmitting the passing current and the input voltage of each isolation inductor to the second micro-control chip;

the second micro control chip is used for sending data request information to the micro control unit after receiving a trigger instruction sent by the client through the IP communication network; the data request information comprises input voltage request information and passing current request information of an isolation inductor connected with a target power supply scheme;

the second micro control chip is also used for performing decompiling on the input voltage signal and the passing current transmitted by the micro control unit so as to decompile the input voltage signal and the passing current into a message which can be transmitted through IP network communication.

2. The system of claim 1, further comprising:

the filter assembly is connected between the input end of the isolation inductor and one terminal of the corresponding group of terminals; and/or between the output of the isolating inductor and another terminal of the corresponding set of terminals.

3. The system of claim 2, wherein the filtering component is a resistor device with a preset resistance.

4. The system of claim 1, wherein the second micro control chip comprises:

the IP communication unit is used for receiving a trigger instruction sent by the client through an IP communication network;

the sending unit is used for sending data request information to the micro control unit after receiving a trigger instruction sent by the client through the IP communication network;

the receiving unit is used for receiving the input voltage signal and the passing current signal returned by the micro control unit;

the decompiling unit is used for decompiling the received input voltage signal and the passing current so as to decompile the received input voltage signal and the passing current into a network message which can be transmitted through IP network communication;

and the IP communication unit is also used for sending the network message which is decompiled by the decompilation unit to the IP network device.

5. The system according to claim 4, wherein the decompilation unit adds a message with a preset format in front of the message corresponding to the input voltage signal and the current signal to form a network message capable of being transmitted through IP network communication;

the message with the preset format comprises a source port, a destination port, a source network address and a destination network address.

6. The system of claim 4, wherein the second micro control chip further comprises:

and the calculation unit is used for calculating the acquired input voltage signal and the acquired passing current signal and determining the consumed wattage of the power supply scheme corresponding to the isolation inductor.

7. A method for implementing wattage consumed by a remote monitoring server, using the system for implementing wattage consumed by a remote monitoring server according to any one of claims 1-6, comprising:

the second micro control chip sends data request information to the micro control unit after receiving a trigger instruction sent by the client through the IP communication network; the data request information comprises input voltage signal request information and passing current request information of an isolation inductor connected with a target power supply scheme;

the micro control unit controls the first micro control chip to acquire the input voltage and the output voltage of each isolation inductor according to the request information, and controls the first micro control chip to calculate the passing current of the isolation inductors according to the input voltage, the output voltage and the impedance value of each isolation inductor;

the first micro control unit transmits the passing current and the input voltage of the isolation inductor to the second micro control chip through the micro control unit;

the second micro control chip performs decompiling on the input voltage signal and the passing current transmitted by the micro control unit to compile the input voltage signal and the passing current into a message which can be transmitted through IP network communication, and transmits the message which can be transmitted through IP network communication to the client through IP network communication.

8. The method of claim 7, further comprising:

and the second micro control chip calculates the acquired input voltage signal and the acquired passing current signal to determine the consumed wattage of the power supply scheme corresponding to the isolation inductor.

9. The method according to claim 7, wherein the second micro control chip decompiles the input voltage signal transmitted by the micro control unit by current to decompile the input voltage signal into a message transmittable through an IP network communication, and transmits the message transmittable through the IP network communication to the client through the IP network communication, and comprises:

the second micro control chip adds a message in a preset format in front of the message corresponding to the input voltage signal and the current signal, so as to form a network message which can be transmitted through IP network communication;

the message with the preset format comprises a source port, a destination port, a source network address and a destination network address.

10. The method of claim 7, wherein the input voltage and the output voltage of each isolation inductor are filtered by the corresponding filter device.

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