CN113187747A - Fan power supply regulation and control method, system and medium - Google Patents

Abstract

The invention discloses a method for regulating and controlling power supply of a fan, which comprises the following steps: acquiring inertial rotation time, a heat dissipation range and first arrangement information of a fan; setting a temperature interval, acquiring first temperature information of the server, and judging the thermal event condition based on the temperature interval and the first temperature information; when the thermal event condition is that no thermal event exists, setting power supply interval time based on inertial rotation time, and intermittently supplying power to the fan based on the power supply interval time; the fan can be pertinently started according to the thermal event in the server to form a complete fan radiating framework, the fan for radiating and the power supply time of the fan can be flexibly adjusted, the radiating requirement of the server is met, electric energy is saved, the server is extremely environment-friendly, and the operating cost of the server is reduced.

Description

Fan power supply regulation and control method, system and medium

Technical Field

The invention relates to the technical field of server fan regulation, in particular to a fan power supply regulation method, system and medium.

Background

In the prior art, a method for regulating and controlling the power supply of the fan on the server adopts a continuous power supply method without interruption, and the method respectively supplies power to the fan on the server alternately and uninterruptedly through a working power supply and a standby power supply so as to control the power consumption of the fan.

Specifically, the method can only control the start and stop of the fans, and cannot flexibly adjust the number of the fans and assign one or some fans to operate according to the temperature condition of the server; meanwhile, although the method adopts two power supplies to supply power to the fan respectively, the fan is in a continuous operation state and consumes electric energy all the time when the server is fully loaded and lightly loaded; moreover, the inertia generated by the rotation of the fan can keep the fan to continue to rotate under the condition of no power supply, so that some natural wind energy which can be used for heat dissipation is generated, and the existing uninterrupted continuous power supply method can waste the natural wind energy.

In summary, the conventional fan power supply regulation and control method cannot flexibly regulate and control the fan power supply according to the temperature condition of the server, thereby reducing the service life of the fan, wasting the natural resources of the fan, and failing to save the operating cost of the server.

Disclosure of Invention

The invention mainly solves the problems that the existing fan power supply regulation and control method can not flexibly regulate and control the fan power supply according to the temperature condition of the server, thereby reducing the service life of the fan, wasting the natural resources of the fan and being incapable of saving the operation cost of the server.

In order to solve the technical problems, the invention adopts a technical scheme that: the method for regulating and controlling the power supply of the fan comprises the following steps:

acquiring inertial rotation time, a heat dissipation range and first arrangement information of a fan;

setting a temperature interval, acquiring first temperature information of a server, and judging a thermal event condition based on the temperature interval and the first temperature information;

and when the thermal event condition is that no thermal event exists, setting power supply interval time based on the inertial rotation time, and intermittently supplying power to the fan based on the power supply interval time.

As a refinement, the step of intermittently supplying power to the fan based on the power supply interval further includes:

setting the working time of the fan;

setting the power supply time and the power supply sequence of the fan based on the working time and the power supply interval time;

and supplying power to the fan according to the power supply time and the power supply sequence.

As an improved scheme, the method further comprises the following steps:

and when the thermal event condition is that a thermal event exists, setting a heat dissipation supporting range of the fan based on the heat dissipation range and the first arrangement information, and processing the thermal event based on the heat dissipation supporting range.

As an improvement, the step of processing the thermal event further comprises:

acquiring second temperature information and second configuration information of firmware equipment in the server;

generating a thermodynamic diagram corresponding to the thermal event based on the second temperature information and the second arrangement information;

processing the thermal event based on the thermodynamic diagram and the heat dissipation support range.

As an improvement, the step of processing the thermal event based on the thermodynamic diagram and the heat dissipation support range further comprises:

setting a color degree, and identifying a heat gathering area in the thermodynamic diagram based on the color degree;

selecting a fan arrangement area matched with the heat aggregation area from the first arrangement information;

setting the fan positioned in the fan arrangement area as the heat radiation fan;

setting the heat dissipation supporting range of the heat dissipation fan as a first heat dissipation supporting range;

processing the thermal event based on the heat dissipation fan and the first heat dissipation support range.

As an improvement, the step of processing the thermal event based on the heat dissipation fan and the first heat dissipation supporting range further includes:

setting first heat dissipation time, and supplying power to the heat dissipation fan according to the first heat dissipation time;

acquiring third temperature information of the server according to the first heat dissipation time;

comparing whether the third temperature information is in the temperature interval or not;

if so, setting a second heat dissipation time, and executing a heat dissipation support strategy based on the second heat dissipation time and the first heat dissipation support range; if not, judging that the thermal event condition is the absence of the thermal event.

As an improvement, the heat dissipation support strategy includes:

supplying power to the heat dissipation fan and the fan within the first heat dissipation supporting range according to the second heat dissipation time;

acquiring fourth temperature information of the server according to the second heat dissipation time;

comparing whether the fourth temperature information is in the temperature interval or not;

if yes, outputting alarm information; if not, judging that the thermal event condition is the absence of the thermal event.

As an improvement, the step of determining a thermal event condition based on the temperature interval and the first temperature information further comprises:

comparing whether the first temperature information is in the temperature interval or not;

if so, judging that the thermal event condition is the existence of the thermal event;

if not, judging that the thermal event condition is the absence of the thermal event.

The invention also provides a fan power supply regulation and control system, which comprises:

the system comprises an initialization module, a thermal event judgment module, an intermittent power supply module and a thermal event processing module;

the initialization module is used for acquiring inertial rotation time, a heat dissipation range and first arrangement information of the fan;

the thermal event judgment module is used for setting a temperature interval and acquiring first temperature information of the server;

the thermal event judging module judges the thermal event condition according to the temperature interval and the first temperature information, and when the thermal event condition is that no thermal event exists, the thermal event judging module sends a first signal to the intermittent power supply module; when the thermal event condition is that a thermal event exists, the thermal event judgment module sends a second signal to the thermal event processing module;

the intermittent power supply module is used for setting power supply interval time according to the first signal and the inertial rotation time and intermittently supplying power to the fan based on the power supply interval time;

the thermal event processing module is used for setting a heat dissipation supporting range of the fan according to the second signal, the heat dissipation range and the first arrangement information, and processing the thermal event based on the heat dissipation supporting range.

The invention also provides a computer readable storage medium, on which a computer program is stored, which, when executed by a processor, implements the steps of the fan power supply regulation method.

The invention has the beneficial effects that:

1. the fan power supply regulation and control method can realize the targeted start of the fan according to different thermal events in the server, form a complete fan heat dissipation framework, flexibly regulate the fan which is specifically used for heat dissipation and the power supply time of the fan, and enable the fan heat dissipation system of the server to be in an energy-saving and environment-friendly state, thereby not only meeting the heat dissipation requirement of the server, but also saving electric energy, being extremely environment-friendly and reducing the operation cost of the server.

2. The fan power supply regulation and control system can realize the targeted starting of the fan according to different thermal events in the server by the mutual matching of the initialization module, the thermal event judgment module, the intermittent power supply module and the thermal event processing module, so that a complete fan heat dissipation framework is formed, the fan which is specifically used for heat dissipation and the power supply time of the fan can be flexibly regulated, the fan heat dissipation system of the server is in an energy-saving and environment-friendly state, the heat dissipation requirement of the server is met, the electric energy is saved, the environment is extremely protected, and the operation cost of the server is reduced.

3. The computer-readable storage medium can realize the cooperation of the guide initialization module, the thermal event judgment module, the intermittent power supply module and the thermal event processing module, further realize the targeted starting of the fan according to different thermal events in the server, form a complete fan heat dissipation framework, flexibly adjust the fan specifically used for heat dissipation and the power supply time of the fan, and enable the fan heat dissipation system of the server to be in an energy-saving and environment-friendly state, thereby not only meeting the heat dissipation requirements of the server, but also saving electric energy, being extremely environment-friendly, reducing the operation cost of the server, and effectively increasing the operability of the fan power supply regulation and control method.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a flowchart of a method for regulating and controlling power supply to a fan according to embodiment 1 of the present invention;

fig. 2 is a schematic flow chart of a specific method for regulating and controlling power supply to a fan according to embodiment 1 of the present invention;

fig. 3 is an architecture diagram of a fan power supply regulation and control system according to embodiment 2 of the present invention;

fig. 4 is a schematic diagram illustrating an implementation effect of the fan power supply regulation and control system according to embodiment 2 of the present invention.

Detailed Description

The following detailed description of the preferred embodiments of the present invention, taken in conjunction with the accompanying drawings, will make the advantages and features of the invention easier to understand by those skilled in the art, and thus will clearly and clearly define the scope of the invention.

In the description of the present invention, it should be noted that the described embodiments of the present invention are a part of the embodiments of the present invention, and not all embodiments; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "first", "second", "third", and "fourth" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, unless otherwise explicitly specified and limited, the terms "inertial rotation time", "heat dissipation range", "arrangement information", "temperature interval", "temperature information", "thermal event condition", "absence of thermal event", "power supply interval time", "intermittent power supply", "presence of thermal event", "heat dissipation support range", "operating time", "power supply sequence", "firmware device", "thermodynamic diagram", "heat dissipation fan", "fan arrangement region", "color degree", "heat accumulation region", "initialization module", "thermal event determination module", "intermittent power supply module", "thermal event processing module" should be interpreted in a broad sense. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In the description of the present invention, it is to be noted that: cpld (complex Programming Logic device) is a complex programmable Logic device; bmc (baseboard Management controller) is a baseboard Management controller.

Example 1

The embodiment provides a method for regulating and controlling power supply of a fan, as shown in fig. 1 and 2, comprising the following steps:

it should be noted that, in the present embodiment, the server is applied, and in the prior art, in order to uniformly plan the operation of the server, the fans and the fan sets in the server are controlled by the CPLD; and its control mode is the incessant power supply of continuity, and this kind of mode is comparatively simple, but is very big to the consumption of electric energy and natural energy, though can reach radiating effect, but will make server running cost increase at last, can't reach optimal radiating effect, and this embodiment has solved to above-mentioned problem:

s100, adding a corresponding power supply control link for each fan in the server, changing the original unified power supply strategy, and providing a technical basis for independently controlling the power supply condition of the fan; carrying out inertia test on the fan to obtain the relative inertia force of the fan; calculating the inertial rotation time of the fan through relative inertial force according to relevant knowledge of aerodynamics; performing wind power test on the fan to obtain an effective heat dissipation range (namely, a heat dissipation range) of the fan, and acquiring the arrangement condition (namely, first arrangement information) of the fan on the server;

it should be noted that, in this embodiment, the power supply control link is finally controlled by the CPLD, and the CPLD is not limited, and may also use a controller such as a BMC or a microprocessor chip to perform power supply regulation; meanwhile, an independent control link is added only as an implementation mode, and the same effect can be realized by setting a CPLD or a BMC to independently send control signals to each fan;

it should be noted that, in this embodiment, the inertia test is to adjust the fan to the same rotation speed as the normal specification, and after a certain time, the power supply of the fan is stopped, and at this time, the fan will continue to rotate due to its own inertia; the relative inertia force of the fan at the moment is obtained through serial port information of the fan and a related program of a control end, and the inertial rotation time of the fan can be accurately calculated according to the mass and the relative inertia force of the fan and related knowledge of aerodynamics; in this step, a program can also be set through the serial port, timing is carried out when the power supply of the fan is stopped, and the timing is stopped when the fan is detected to be inactive, wherein the obtained time is the inertial rotation time of the fan.

It should be noted that, in this embodiment, each server has a corresponding fan arrangement layout diagram; obtaining the arrangement condition of the fans according to the layout diagram; the fan is subjected to wind power test, namely the fan is adjusted to the rotating speed which is the same as the normal specified rotating speed, and at the moment, the maximum range reached by the airflow generated by the rotation of the fan can be sensed through the wind flow sensor, and the maximum range is the effective heat dissipation range of the fan.

S200, after the initialization configuration step is completed, the server is put into use, detection time periods and temperature intervals are set, first serial port temperature sensing information (namely first temperature information) of the server is obtained every detection time period, and the occurrence condition of a thermal event (namely the thermal event condition) is judged according to the first serial port temperature sensing information and the temperature intervals;

step S200 specifically includes:

s210, comparing the first serial port temperature sensing information with a temperature interval;

s220, if the first serial port temperature sensing information is in the temperature interval, judging that a thermal event occurs (namely, a thermal event exists);

s230, if the first serial port temperature sensing information is not in the temperature interval, judging that no thermal event occurs (namely, no thermal event exists);

it should be noted that, in this embodiment, the defined first serial port temperature sensing information is real-time temperature information of the server acquired through a serial port temperature sensor on the server, and the first serial port temperature sensing information is only used as an expression manner and an implementation manner, and is not limited at all. There are various corresponding temperature detection methods, for example: a temperature sensing element can be added in the server, and temperature information can be directly output through the connection between the element and the control end; or the temperature indicator can be installed on the server, the detection robot is configured, and the robot is controlled to check the information of the temperature indicator every detection time period.

S300, when judging that no thermal event occurs, setting power supply interval time of the fan based on inertial rotation time of the fan; executing corresponding intermittent fan power supply measures according to the power supply interval time;

step S300 specifically includes:

s310, setting the working time of the fan according to the power supply interval time;

s320, setting the scanning power supply time and the power supply sequence of the fan according to the working time and the power supply interval time of the fan;

s330, sequentially controlling the power supply conditions of the fans corresponding to the scanning power supply time and the power supply interval time according to the power supply sequence;

it should be noted that, in this embodiment, the power supply interval time of each fan is smaller than and should be infinitely close to its inertial rotation time, so that the natural resource utilization of the fan can be maximized, and if there are many fan sets or there are many servers, the electric energy is greatly saved.

It should be noted that the power supply intervals of the fans with different specifications are different, and because each fan needs to achieve the same heat dissipation effect, i.e. the same fan operating time, different scanning power supply times can be set for each fan according to the power supply intervals; setting a power supply sequence corresponding to each fan according to the scanning power supply time and the power supply interval time corresponding to each fan; for example: an existing fan A, a fan B and a fan C; the power supply interval time of the fan A is 1s, the power supply interval time of the fan B is 2s, and the power supply interval time of the fan C is 3 s; if the required working time of the fan is 10s, the scanning power supply time of the fan A can be set to 9s, the scanning power supply time of the fan B can be set to 8s, and the scanning power supply time of the fan c can be set to 7 s; the same heat dissipation effect is achieved by the inertia of the fan and the corresponding different scanning power supply time under the condition of fully utilizing resources; the corresponding power supplying sequence is sequential power supplying, and the power supplying sequence only represents sequential execution because the reached working time is the same, and the power supplying of one fan is sequentially controlled in this embodiment, which is only an implementation manner, and the same principle can be sequentially and simultaneously controlled by two, three or four fans, etc.

S400, when the thermal event is judged to occur, setting a heat dissipation support range of each fan according to the arrangement condition of the fans and the effective heat dissipation range of the fans; executing corresponding processing measures on the thermal event according to the heat dissipation support range;

step S400 specifically includes:

s410, acquiring the existing temperature information (namely, second temperature information) and the server equipment configuration condition (namely, second configuration information) of each firmware equipment in the server;

s420, generating a thermodynamic diagram related to the thermal event of the server according to the existing temperature information and the server equipment arrangement condition;

s430, setting color degrees, identifying a heat gathering area in the thermodynamic diagram according to the color degrees, and determining a fan arrangement area according to the arrangement conditions of the heat gathering area and the fans; setting the fans in the fan arrangement area as cooling fans;

s440, setting first power supply time (namely first heat dissipation time), and supplying power to the heat dissipation fan according to the first power supply time; timing is carried out at the moment, first time is generated, and when the first time reaches first power supply time, second serial port temperature sensing information (namely third temperature information) of the server is obtained again;

s450, comparing the temperature sensing information of the second serial port with the temperature range;

step S450 specifically includes:

s451, if the second serial port temperature sensing information is not in the temperature range, judging that no thermal event occurs, and generating a first thermal event log corresponding to the cooling fan;

s452, if the second serial port temperature sensing information is in the temperature range, setting a second power supply time (i.e. a second heat dissipation time), and executing a heat dissipation support policy: supplying power to a heat dissipation fan and a fan located within a heat dissipation support range (i.e., a first heat dissipation support range) of the heat dissipation fan according to a second power supply time, modifying the first thermal event log, and generating a second thermal event log corresponding to the fan located within the adjacent support range;

s453, similarly to step S440, when power is supplied to the fan according to the second power supply time, timing again to generate a second time, and when the second time reaches the second power supply time, acquiring the third serial port temperature sensing information (i.e., fourth temperature information) of the server again; if the third serial port temperature sensing information is in the temperature interval, sending alarm information to a server: a part of the server corresponding to the hot aggregation area is in a high-temperature state for a long time, and a high-temperature fault may occur; and if the third serial port temperature sensing information is not in the temperature interval, judging that no thermal event occurs.

In this embodiment, the heat dissipation supporting range around the fan can be set according to the layout drawing and the effective heat dissipation range of the fan; when the fan in the heat dissipation support range is started, the generated airflow can support the heat dissipation of the fan belonging to the adjacent support range.

It should be noted that, according to the relevant steps of the visualization process, the existing temperature information and the arrangement condition of each firmware device in the server may be integrated to generate a flattened layout thermodynamic diagram; correspondingly setting the color degree of a high-heat part according to the existing temperature information, and comparing the color and the color degree on the thermodynamic diagram to distinguish a matched color, wherein the set part of the matched color is a heat accumulation area, equipment in the heat accumulation area is in a high-heat-generation source, and high-efficiency high-quality heat dissipation treatment is required; therefore, in the arrangement condition of the fans, a relatively matched position is selected according to the position of the heat accumulation area in the thermodynamic diagram, the position is the fan arrangement area, the fans positioned in the fan arrangement area are cooling fans, the cooling effect can be generated on the heat accumulation area, and after the cooling fans are selected, corresponding measures are executed according to power supply time to process the heat event.

It should be noted that, in the thermal event log, the number of the fan, the component code, the number of times of the fan processing the thermal event, and whether the current fan is in a power supply state or a non-power supply state need to be acquired; if the fan is in a power supply state, the power supply time and the power supply interval of the fan are also required to be recorded; the times of the fan for processing the thermal events are accumulated according to the generation of each thermal event; in subsequent analysis and maintenance, the high-probability occurrence position of the thermal event in the server can be analyzed through the number of times that the thermal event is processed by the fan and the arrangement condition of the current fan.

By the fan power supply regulation and control method described in the embodiment, the fan can be regulated and controlled in a targeted manner for the overheating event in the server, so that the overheating event is effectively solved, and reasonable utilization of the fan resources is guaranteed; when the server does not have an overheating event, the scanning type fan power supply measure in the method enables the fan in the server to achieve a stable heat dissipation effect, natural resources of the server are not lost, heat dissipation benefits of the server are maximized, operation cost of the server is reduced, and the low-carbon and environment-friendly concept of current scientific and technological development is met.

Example 2

The present embodiment provides a fan power supply regulation and control system, as shown in fig. 3 and 4, including: the system comprises an initialization module, a thermal event judgment module, an intermittent power supply module and a thermal event processing module;

in the fan power supply regulation and control system, the specific operation of the initialization module comprises the following steps:

the initialization module is used for adding a corresponding power supply control link for each fan in the server, changing the original unified power supply strategy and providing a technical basis for independently controlling the power supply condition of the fan;

the initialization module is also used for carrying out inertia test on the fan to obtain the relative inertia force of the fan; the initialization module calculates the inertial rotation time of the fan through relative inertial force according to relevant knowledge of aerodynamics;

the initialization module is further configured to perform a wind test on the fan to obtain an effective heat dissipation range (i.e., a heat dissipation range) of the fan, and obtain an arrangement condition (i.e., first arrangement information) of the fan on the server.

In the fan power supply regulation and control system, the specific operation of the thermal event judgment module comprises the following steps:

the thermal event judgment module is used for putting the server into use after the initialized configuration step is completed, setting a detection time period and a temperature interval, and acquiring first serial port temperature sensing information (namely first temperature information) of the server every detection time period;

specifically, the thermal event judgment module compares the first serial port temperature sensing information with the temperature range; if the first serial port temperature sensing information is in the temperature interval, the thermal event judging module judges that a thermal event occurs (namely the thermal event exists) and sends a first signal to the thermal event processing module; if the first serial port temperature sensing information is not in the temperature interval, the thermal event judgment module judges that no thermal event occurs (namely, no thermal event exists), and sends a second signal to the intermittent power supply module.

In the fan power supply regulation and control system, the specific operation of the intermittent power supply module comprises:

the intermittent power supply module is used for setting power supply interval time of the fan based on inertial rotation time of the fan when receiving the second signal, and executing corresponding intermittent fan power supply measures according to the power supply interval time;

specifically, the intermittent fan power supply measures include: the intermittent power supply module sets the working time of the fan according to the power supply interval time; the intermittent power supply module sets the scanning power supply time and the power supply sequence of the fan according to the working time and the power supply interval time of the fan; and the intermittent power supply module sequentially controls the power supply conditions of the fans corresponding to the scanning power supply time and the power supply interval time according to the power supply sequence.

In the fan power supply regulation and control system, the specific operation of the thermal event processing module comprises the following steps:

the thermal event processing module is used for setting the heat dissipation supporting range of each fan according to the arrangement condition of the fans and the effective heat dissipation range of the fans when receiving the first signal; the thermal event processing module executes corresponding processing measures on the thermal event according to the heat dissipation support range;

specifically, the treatment measures include: the method comprises the following steps that a thermal event processing module obtains the existing temperature information of each firmware device in a server and the configuration condition of the server devices; the thermal event processing module generates a thermodynamic diagram related to the thermal event of the server according to the existing temperature information and the server equipment arrangement condition; the thermal event processing module sets color degree, identifies a thermal aggregation area in the thermodynamic diagram according to the color degree, and determines a cooling fan according to the arrangement conditions of the thermal aggregation area and the fan;

specifically, the thermal event processing module sets a first power supply time and supplies power to the cooling fan according to the first power supply time; the thermal event processing module is used for timing to generate first time, and when the first time reaches first power supply time, the thermal event processing module acquires second serial port temperature sensing information of the server again; the thermal event processing module compares the second serial port temperature sensing information with the temperature interval; if the second serial port temperature sensing information is not in the temperature interval, the thermal event processing module judges that no thermal event occurs and generates a first thermal event log corresponding to the cooling fan; if the second serial port temperature sensing information is in the temperature interval, the thermal event processing module sets a second power supply time and executes a heat dissipation support strategy;

specifically, the heat dissipation support strategy includes: the thermal event processing module supplies power to the cooling fan and the fan located in the cooling support range of the cooling fan according to second power supply time, modifies the first thermal event log, and generates a second thermal event log corresponding to the fan located in the adjacent support range;

specifically, when the fan is powered on according to the second power supply time, the thermal event processing module counts time again to generate the second time, and when the second time reaches the second power supply time, the thermal event processing module acquires the third serial port temperature sensing information of the server again; if the third serial port temperature sensing information is in the temperature interval, the thermal event processing module sends alarm information to the server: a part of the server corresponding to the hot aggregation area is in a high-temperature state for a long time, and a high-temperature fault may occur; and if the third serial port temperature sensing information is not in the temperature interval, the thermal event processing module judges that no thermal event occurs.

Through the fan power supply regulation and control system described in the embodiment, the fans can be regulated and controlled in a targeted manner for the overheating events in the server through the mutual cooperation of the modules, so that the overheating events are effectively solved, and the reasonable utilization of the resources of the fans is ensured; when the server does not have an overheating event, the scanning type fan power supply measure in the method enables the fan in the server to achieve a stable heat dissipation effect, natural resources of the server are not lost, heat dissipation benefits of the server are maximized, operation cost of the server is reduced, and the low-carbon and environment-friendly concept of current scientific and technological development is met.

Example 3

The present embodiments provide a computer-readable storage medium comprising:

the storage medium is used for storing computer software instructions for implementing the fan power supply regulation and control method described in embodiment 1, and includes a program for executing the fan power supply regulation and control method; specifically, the executable program may be embedded in the fan power supply regulation and control system described in embodiment 2, so that the fan power supply regulation and control system may implement the fan power supply regulation and control method described in embodiment 1 by executing the embedded executable program.

Furthermore, the computer-readable storage medium of the present embodiments may take any combination of one or more readable storage media, where a readable storage medium includes an electronic, optical, electromagnetic, infrared, or semiconductor system, apparatus, or device, or any combination thereof.

Different from the prior art, the fan power supply regulation and control method, system and medium provided by the application can be used for starting corresponding fans for different heat dissipation requirements in the server in a targeted manner through the method to form a complete fan heat dissipation framework, and can flexibly regulate the power supply time of the fans for heat dissipation and make the fan heat dissipation system of the server in an energy-saving and environment-friendly state.

The numbers of the embodiments disclosed in the embodiments of the present invention are merely for description, and do not represent the merits of the embodiments.

It will be understood by those skilled in the art that all or part of the steps of implementing the above embodiments may be implemented by hardware, and a program that can be implemented by the hardware and can be instructed by the program to be executed by the relevant hardware may be stored in a computer readable storage medium, where the storage medium may be a read-only memory, a magnetic or optical disk, and the like.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes performed by the present specification and drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. A method for regulating and controlling power supply of a fan is characterized by comprising the following steps:

acquiring inertial rotation time, a heat dissipation range and first arrangement information of a fan;

setting a temperature interval, acquiring first temperature information of a server, and judging a thermal event condition based on the temperature interval and the first temperature information;

and when the thermal event condition is that no thermal event exists, setting power supply interval time based on the inertial rotation time, and intermittently supplying power to the fan based on the power supply interval time.

2. The method as claimed in claim 1, wherein the step of intermittently supplying power to the fan based on the power supply interval further comprises:

setting the working time of the fan;

setting the power supply time and the power supply sequence of the fan based on the working time and the power supply interval time;

and supplying power to the fan according to the power supply time and the power supply sequence.

3. The method for regulating power supply to a fan according to claim 1 or 2, further comprising:

and when the thermal event condition is that a thermal event exists, setting a heat dissipation supporting range of the fan based on the heat dissipation range and the first arrangement information, and processing the thermal event based on the heat dissipation supporting range.

4. The method of claim 3, wherein the step of processing the thermal event further comprises:

acquiring second temperature information and second configuration information of firmware equipment in the server;

generating a thermodynamic diagram corresponding to the thermal event based on the second temperature information and the second arrangement information;

processing the thermal event based on the thermodynamic diagram and the heat dissipation support range.

5. The fan power regulation method of claim 4 wherein the step of processing the thermal event based on the thermodynamic diagram and the heat dissipation support range further comprises:

setting a color degree, and identifying a heat gathering area in the thermodynamic diagram based on the color degree;

selecting a fan arrangement area matched with the heat aggregation area from the first arrangement information;

setting the fan positioned in the fan arrangement area as the heat radiation fan;

setting the heat dissipation supporting range of the heat dissipation fan as a first heat dissipation supporting range;

processing the thermal event based on the heat dissipation fan and the first heat dissipation support range.

6. The method as claimed in claim 5, wherein the step of processing the thermal event based on the heat dissipation fan and the first heat dissipation support range further comprises:

setting first heat dissipation time, and supplying power to the heat dissipation fan according to the first heat dissipation time;

acquiring third temperature information of the server according to the first heat dissipation time;

comparing whether the third temperature information is in the temperature interval or not;

if so, setting a second heat dissipation time, and executing a heat dissipation support strategy based on the second heat dissipation time and the first heat dissipation support range; if not, judging that the thermal event condition is the absence of the thermal event.

7. The method of claim 6, wherein the heat dissipation support strategy comprises:

supplying power to the heat dissipation fan and the fan within the first heat dissipation supporting range according to the second heat dissipation time;

acquiring fourth temperature information of the server according to the second heat dissipation time;

comparing whether the fourth temperature information is in the temperature interval or not;

if yes, outputting alarm information; if not, judging that the thermal event condition is the absence of the thermal event.

8. The method as claimed in any one of claims 4 to 7, wherein the step of determining the thermal event based on the temperature interval and the first temperature information further comprises:

comparing whether the first temperature information is in the temperature interval or not;

if so, judging that the thermal event condition is the existence of the thermal event;

if not, judging that the thermal event condition is the absence of the thermal event.

9. A fan power supply regulation system, comprising: the system comprises an initialization module, a thermal event judgment module, an intermittent power supply module and a thermal event processing module;

the initialization module is used for acquiring inertial rotation time, a heat dissipation range and first arrangement information of the fan;

the thermal event judgment module is used for setting a temperature interval and acquiring first temperature information of the server;

the thermal event judging module judges the thermal event condition according to the temperature interval and the first temperature information, and when the thermal event condition is that no thermal event exists, the thermal event judging module sends a first signal to the intermittent power supply module; when the thermal event condition is that a thermal event exists, the thermal event judgment module sends a second signal to the thermal event processing module;

the intermittent power supply module is used for setting power supply interval time according to the first signal and the inertial rotation time and intermittently supplying power to the fan based on the power supply interval time;

the thermal event processing module is used for setting a heat dissipation supporting range of the fan according to the second signal, the heat dissipation range and the first arrangement information, and processing the thermal event based on the heat dissipation supporting range.

10. A computer-readable storage medium, wherein a computer program is stored on the computer-readable storage medium, and when executed by a processor, the computer program implements the steps of the method for regulating and controlling power supply to a fan according to any one of claims 1 to 8.

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