CN113301765B - Method for controlling operation state of server heat dissipation component, server system and server - Google Patents

Abstract

The application discloses a method and a device for controlling the running state of a server heat dissipation component, a server system, a server, a computer storage medium and electronic equipment, wherein the method comprises the following steps: acquiring configuration parameters of a server assembled in a server cabinet; determining that the connection mode of the server connection cable is the front outgoing line connection mode or the rear outgoing line connection mode according to the configuration parameters; according to the connection mode, adjusting the temperature monitoring mode in the server to be a monitoring mode aiming at a front outgoing line connection mode or a monitoring mode aiming at a rear outgoing line connection mode; and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode. Therefore, the normal heat dissipation function of the server can be ensured no matter the connecting cable of the server assembled in the server cabinet belongs to the connection mode of front outgoing lines or rear outgoing lines, and the work of the server is guaranteed.

Description

Method for controlling operation state of server heat dissipation component, server system and server

Technical Field

The application relates to the technical field of computer application, in particular to a method and a device for controlling the running state of a server heat dissipation component, a server system, a server, a computer storage medium and electronic equipment.

Background

The server cabinet is a cabinet body for placing the server. With the continuous development of servers, the connection cable of a new generation of server gradually evolves from a maintenance scene of back outgoing lines to a maintenance scene of front outgoing lines.

However, when a server with a connection cable as a rear outgoing line is assembled in the server cabinet, the connection cable is assembled in the server cabinet to serve as a front outgoing line, so that the maintenance of the connection cable and the overall structure of the server cabinet are affected, and the situations of complicated maintenance, limited or unavailable layout of the server cabinet and the like are caused.

Disclosure of Invention

The application provides a control method for the running state of a server heat dissipation component, and aims to solve the problem that connecting cables of a server cannot be compatible with front and rear outgoing lines in the prior art.

The application provides a method for controlling the running state of a server heat dissipation component, which comprises the following steps:

acquiring configuration parameters of a server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in the assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in the assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server;

according to the configuration parameters, determining that the connection mode of the server connection cable is the front outgoing line connection mode or the rear outgoing line connection mode;

according to the connection mode, adjusting the temperature monitoring mode in the server to be a monitoring mode aiming at a front outgoing line connection mode or a monitoring mode aiming at a rear outgoing line connection mode;

and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

In some embodiments, the obtaining configuration parameters of the servers installed in the server rack comprises:

and when the server is assembled in the server cabinet, acquiring the power supply model parameter of the server in the configuration parameters through a power supply management bus.

In some embodiments, the determining, according to the configuration parameter, that the connection mode of the server connection cable is the front outgoing line connection mode or the back outgoing line connection mode includes:

inquiring a power supply model table according to the power supply model parameters;

and determining the connection cable of the server to be the front outgoing line connection mode or the rear outgoing line connection mode according to the corresponding relation between the power model parameters and the connection modes of the connection cables in the power model table.

In some embodiments, the adjusting, according to the connection manner, the temperature monitoring manner in the server to be a monitoring manner for a front outgoing line connection manner or a monitoring manner for a rear outgoing line connection manner includes:

when the determined connection mode is the front outlet connection mode, adjusting the monitoring mode of a temperature sensor on a computing board at the air inlet of the server into the monitoring mode of monitoring the temperature of the air inlet of the server;

and when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of a temperature sensor on the main control board at the air inlet of the server into the monitoring mode for monitoring the temperature of the air inlet of the server.

In some embodiments, the controlling the operation state of the heat dissipation component in the server according to the adjusted temperature signal monitored by the temperature monitoring method includes:

taking a control curve of the heat dissipation part;

determining the rotating speed of the heat dissipation part according to the air inlet temperature monitored by the temperature sensor on the computing board at the air inlet or the air inlet temperature monitored by the temperature sensor on the main control board at the air inlet and the control curve;

and controlling the running state of the heat dissipation component in the server according to the rotating speed of the heat dissipation component.

In some embodiments, the adjusting, according to the connection manner, the temperature monitoring manner in the server to be a monitoring manner for a front outgoing line connection manner or a monitoring manner for a rear outgoing line connection manner includes:

when the determined connection mode is the front outgoing line connection mode, adjusting the monitoring mode of a temperature sensor on a main control board at the air outlet of the server into the monitoring mode of monitoring the temperature of the air outlet of the server;

and when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of the temperature sensor on the computing board at the air outlet of the server into the monitoring mode for monitoring the temperature of the air outlet of the server.

In some embodiments, the controlling the operation state of the heat dissipation component in the server according to the adjusted temperature signal monitored by the temperature monitoring method includes:

a control curve of the heat dissipation part is obtained;

determining the rotating speed of the heat dissipation part according to the air outlet temperature monitored by a temperature sensor on the main control board at the air outlet or the air outlet temperature monitored by a temperature sensor on the computing board at the air outlet and the control curve;

and controlling the running state of the heat dissipation component in the server according to the rotating speed of the heat dissipation component.

The present application further provides a control device for an operating state of a server heat dissipation component, including:

the system comprises an acquisition unit, a configuration unit and a processing unit, wherein the acquisition unit is used for acquiring configuration parameters of a server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in the assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in the assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server;

the determining unit is used for determining that the connection mode of the server connecting cable is the front outgoing line connection mode or the rear outgoing line connection mode according to the configuration parameters;

the adjusting unit is used for adjusting the temperature monitoring mode in the server to be a monitoring mode aiming at a front outgoing line connection mode or a monitoring mode aiming at a rear outgoing line connection mode according to the connection mode;

and the control unit is used for controlling the running state of the heat dissipation component in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

The present application also provides a server system, comprising: a server cabinet and a server; the server is assembled in the server cabinet, a connecting cable of the server can be compatible with a front outgoing line connecting mode in an assembling environment of a front outgoing line server, and can be compatible with a rear outgoing line connecting mode in an assembling environment of a rear outgoing line server, wherein the front outgoing line connecting mode is that the connecting cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connecting mode is that the connecting cable of the server is connected with the external equipment through the rear end of the server; according to the acquired configuration parameters of the server, determining that the connection mode of the server connecting cable is the front outgoing line connection mode or the rear outgoing line connection mode; according to the connection mode, adjusting the temperature monitoring mode in the server to be a monitoring mode aiming at a front outlet connection mode or a monitoring mode aiming at a rear outlet connection mode; and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

In some embodiments, when the connection cable of the server assembled in the server cabinet is in a front outgoing line connection mode, the server is assembled in an assembly state when the server cabinet is in the rear outgoing line connection mode after being horizontally rotated to an assembly angle matched with the server cabinet; when a connecting cable of the server assembled in the server cabinet is in a rear outgoing line connection mode, the server is assembled after horizontally rotating to an assembly angle matched with the server cabinet in an assembly state when the server cabinet is in a front outgoing line connection mode.

The present application further provides a server, comprising: a power supply, a heat dissipation component, a computing board, a main control board and a temperature sensor are arranged in the server;

the server is assembled in a server cabinet, wherein a connecting cable of the server can be compatible with a front outgoing line connecting mode in a front outgoing line server assembling environment, and can be compatible with a rear outgoing line connecting mode in a rear outgoing line server assembling environment, the front outgoing line connecting mode is that the connecting cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connecting mode is that the connecting cable of the server is connected with the external equipment through the rear end of the server;

the main control board acquires configuration parameters of the power supply and determines a connection mode of the server connection cable according to the configuration parameters; the main control board adjusts the monitoring modes of the temperature sensors on the computing board and the main control board in the server according to the connection mode, and controls the running state of the heat dissipation part in the server according to the adjusted temperature signals monitored by the temperature sensors.

In some embodiments, when the connection cable of the server assembled in the server cabinet is in a front outgoing line connection mode, the server is assembled in an assembly state when the server cabinet is in the rear outgoing line connection mode after being horizontally rotated to an assembly angle matched with the server cabinet; when a connecting cable of the server assembled in the server cabinet is in a rear outgoing line connection mode, the server is assembled after horizontally rotating to an assembly angle matched with the server cabinet in an assembly state when the server cabinet is in a front outgoing line connection mode.

In some embodiments, when the determined connection mode is the front outlet connection mode, adjusting a monitoring mode of a temperature sensor on the computing board at the air inlet of the server to a monitoring mode of monitoring the temperature of the air inlet of the server;

and when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of the temperature sensor on the main control board at the air inlet of the server into the monitoring mode of monitoring the temperature of the air inlet of the server.

In some embodiments, when the determined connection mode is the front outlet connection mode, adjusting a monitoring mode of a temperature sensor on the main control board at the server air outlet to a monitoring mode of monitoring the temperature of the server air outlet;

and when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of the temperature sensor on the computing board at the air outlet of the server into the monitoring mode for monitoring the temperature of the air outlet of the server.

In some embodiments, the main control board obtains the model parameter of the power supply through a power supply management bus, and determines whether the connection mode of a connection cable in the server is a front-appearing connection mode or a rear-outgoing connection mode according to the power supply model parameter.

The application also provides a computer storage medium for storing the data generated by the network platform and a program for processing the data generated by the network platform;

when the program is read and executed, the following steps are executed:

acquiring configuration parameters of a server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in an assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in an assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server;

determining that the connection mode of the server connection cable is the front outgoing line connection mode or the rear outgoing line connection mode according to the configuration parameters;

according to the connection mode, adjusting the temperature monitoring mode in the server to be a monitoring mode aiming at a front outlet connection mode or a monitoring mode aiming at a rear outlet connection mode;

and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

The present application further provides an electronic device, comprising:

a processor;

a memory for storing a program for processing network platform generated data, said program when read and executed by said processor performing the steps of:

acquiring configuration parameters of a server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in the assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in the assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server;

determining that the connection mode of the server connection cable is the front outgoing line connection mode or the rear outgoing line connection mode according to the configuration parameters;

according to the connection mode, adjusting the temperature monitoring mode in the server to be a monitoring mode aiming at a front outlet connection mode or a monitoring mode aiming at a rear outlet connection mode;

and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

Compared with the prior art, the method has the following advantages:

according to the method for controlling the running state of the heat dissipation component of the server, the connection mode of the server connecting cable is determined to be the front outgoing line connection mode or the rear outgoing line connection mode by acquiring the configuration parameters of the server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in an assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in an assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server; according to the connection mode, adjusting the temperature monitoring mode in the server to be a monitoring mode aiming at a front outgoing line connection mode or a monitoring mode aiming at a rear outgoing line connection mode; and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode. Therefore, the normal heat dissipation function of the server can be ensured no matter the connecting cable of the server assembled in the server cabinet belongs to the connection mode of front outgoing lines or rear outgoing lines, and the work of the server is guaranteed.

According to the server system, configuration parameters are obtained through a main control board of a server assembled in a server cabinet, whether the connection mode of a connecting cable in a server assembly scene is a front outgoing line connection mode or a rear outgoing line connection mode is determined according to the configuration parameters, and according to the connection mode, the temperature monitoring mode in the server is adjusted to be a monitoring mode aiming at the front outgoing line connection mode or a monitoring mode aiming at the rear outgoing line connection mode; and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode. Therefore, the server assembled in the server cabinet can consider both the front outgoing line connection mode and the rear outgoing line connection mode.

The server is assembled in a server cabinet, the configuration parameters of the power supply are obtained through a main control board of the server, and the connection mode of the server connecting cable is determined according to the configuration parameters; and the main control board adjusts the monitoring modes of the temperature sensors on the computing board and the main control board in the server according to the connection mode, and controls the running state of the heat dissipation part in the server according to the adjusted temperature signals monitored by the temperature sensors. Therefore, the requirement of outgoing scenes of different connecting cables can be met.

Drawings

Fig. 1 is a flowchart of an embodiment of a method for controlling an operating state of a server heat dissipation component provided in the present application;

FIG. 2 is a schematic structural diagram of an embodiment of a control apparatus for controlling an operating status of a server heat sink provided in the present application;

FIG. 3 is a block diagram of a server system front outlet server assembly environment provided by the present application;

fig. 4 is a schematic structural diagram of a back-outgoing line server status environment of a server system provided in the present application;

FIG. 5 is a schematic structural diagram of an embodiment of a server outgoing-front line connection mode provided in the present application;

fig. 6 is a schematic structural diagram of an embodiment of a rear outlet connection mode of the server after horizontal rotation in fig. 5.

Description of the figure numbers:

a server rack 401, a server rack front end 401-1, a server rack back end 401-2; a server 402, a front outgoing line connection mode 402-1 and a back outgoing line connection mode 402-2; a fixed front outlet server 403, a fixed rear outlet server 404; a power supply 501, a heat sink 502, a computing board 503, a main control board 504, and temperature sensors 505-1 and 505-2.

Detailed Description

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application. This application is capable of implementation in many different ways than those herein set forth and of similar import by those skilled in the art without departing from the spirit and scope of this application, and thus this application is not limited to the specific implementations disclosed below.

The terminology used in the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. The description used in this application and in the appended claims is for example: the terms "a," "an," "first," and "second," etc., are not intended to be limiting in number or order, but rather are used to distinguish one type of information from another.

Based on the description of the above background art, when a server with a connection cable in a rear outgoing line connection mode is assembled in a server cabinet and another server is assembled in the server cabinet, the server cabinet is limited by the existing connection cable of the assembled outgoing line server, that is, only the assembled outgoing line server is available. However, with the continuous development of technical network hardware, the front outgoing line server will gradually become the leading role of the network server, and therefore, the connection cable of the front outgoing line server is subjected to maintenance work such as plugging and unplugging from the front end of the server, and compared with the rear outgoing line server which is plugged and unplugged from the rear end of the server, the plugging and unplugging maintenance of the connection cable is obviously more convenient and faster to operate from the front end of the server. Therefore, it is obviously inappropriate to assemble the front outgoing line server into the server cabinet of the existing rear outgoing line server, which results in complex server maintenance, challenges to the internal structure of the server cabinet and interference to the machine room environment.

Therefore, a connection cable of a server assembled in a server cabinet can be adapted to a rear outgoing line scene when the connection mode of the server cabinet to a server connection cable is required to be the rear outgoing line working scene; under the condition that the connection mode of the server cabinet to the server connection cable is required to be a front outgoing line scene, the server connection cable assembled in the server cabinet can be suitable for the front outgoing line working scene, namely, the server compatible with the front outgoing line connection mode and the rear outgoing line connection mode is adopted to adapt to different working scene requirements, and the problems that the server is complex to maintain and the like due to the problem of the connection mode of the connection cable are reduced. Similarly, the application also provides a control method for the operation state of the heat dissipation component of the server, which can control the operation state of the heat dissipation component in the server according to the connection mode (or called as an outgoing mode) of the connection cable of the server to adapt to the working scene of front outgoing lines and the working scene of back outgoing lines, thereby ensuring that the normal heat dissipation function of the server can be ensured no matter whether the connection cable of the server assembled in the server cabinet belongs to the connection mode of front outgoing lines or back outgoing lines, and providing guarantee for the operation of the server. The following describes a method for controlling the operating state of a server heat dissipation component provided in the present application, and please refer to fig. 1.

As shown in fig. 1, fig. 1 is a flowchart of an embodiment of a method for controlling an operating state of a server heat sink component, where the method includes:

step S101: acquiring configuration parameters of a server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in the assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in the assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server;

the purpose of step S101 is to obtain configuration parameters of the server when the server is installed in the server cabinet.

The partial nouns involved in step S101 will be explained first.

In this embodiment, the connection cable may include: data lines, power lines, management network lines and the like of the server.

The server front end may be understood as a server mounted in a server cabinet, with a worker facing one end of the server in a normal mode; the other end opposite to the front end of the server is the back end of the server.

The server in the embodiment is a server compatible with a front outgoing line connection mode and a back outgoing line connection mode, so that the server assembled in the server cabinet can be connected with external equipment in the front outgoing line connection mode in a working scene needing front outgoing lines, and the server assembled in the server cabinet can be connected with the external equipment in the back outgoing line connection mode in the working scene needing back outgoing lines. The working scene can be understood as that when a server fixed as a rear outgoing line is assembled in the server cabinet, the working scene is a rear outgoing line working scene, and then when the server is assembled on the basis, a connection cable of the server is required to be a connection mode of the rear outgoing line. Correspondingly, when the server fixed as a front outgoing line is assembled in the server cabinet, the working scene is a front outgoing line working scene, and when the server is assembled again on the basis, a connection cable of the server is required to be a front outgoing line connection mode. Of course, the servers are not assembled in the U server cabinet, and the servers to be assembled include a rear outgoing line scene when the servers are fixed as rear outgoing lines, or a front outgoing line scene when the servers include a front outgoing line, so that the servers provided by the embodiment need to be assembled according to different scenes.

In this embodiment, the specific implementation process of step S101 may be:

when the server is assembled in the server cabinet, the power supply configuration parameters of the server are obtained through the power supply management bus, that is, when the server is assembled in the server cabinet, the power supply configuration parameters of the server are obtained through the power supply management bus. In this embodiment, the power configuration parameter may mainly be a power model parameter.

It should be noted that, in a different outlet scene, the power supplies installed in the servers are different, and when the servers are installed in a scene of a rear outlet connection mode, a power supply matched with the rear outlet connection mode is installed in the servers; when the server is assembled to the front outlet connection mode scene, the power supply matched with the front outlet connection mode is installed in the server.

In this embodiment, the Power model parameter is mainly obtained through a main control board in the server, that is, when the server is assembled in a server cabinet, the main control board obtains the Power model parameter of the server through a Power Management Bus (Pmbus), and the Power model parameter can be obtained by querying a register of the Power supply. The power management bus is an open standard digital power management protocol that facilitates communication with a power converter or other device by defining transport and physical interfaces and a command language.

Step S102: and determining that the connection mode of the server connection cable is the front outgoing line connection mode or the rear outgoing line connection mode according to the configuration parameters.

The specific implementation process of step S102 may include:

step S102-1: inquiring a power supply model table according to the power supply model parameters;

step S102-2: and determining the connecting cable of the server to be the front outgoing line connecting mode or the rear outgoing line connecting mode according to the corresponding relation between the power model parameters and the connecting modes of the connecting cables in the power model table.

Step S103: and adjusting the temperature monitoring mode in the server to be a monitoring mode aiming at a front outlet connection mode or a monitoring mode aiming at a rear outlet connection mode according to the connection mode.

The specific implementation process of step S103 may include two ways, one is to adjust the monitoring mode of the temperature of the air inlet of the server, and the other is to adjust the monitoring mode of the temperature of the air outlet of the server. Different modes need to be correspondingly adjusted according to the specific front outgoing line connection mode and the rear outgoing line connection mode. Because, when the server is installed in the server cabinet in a front outlet scenario, the computing board in the server is close to the front end of the server cabinet, the main control board is close to the rear end of the computing board, and the heat dissipation component is close to the rear end of the main control board or located on the main control board. When the server is assembled in the server cabinet in a rear outgoing line scene, a main control board in the server is close to the front end of the server cabinet, the computing board is close to the rear end of the main control board, and the heat dissipation part is close to the rear end of the main control board or is positioned on the main control board. The assembly of the servers in the front outgoing line scenario and the rear outgoing line scenario may be assembled in different scenarios in a horizontally rotating manner. For details of the server, please refer to a server embodiment provided in the following application, which is only described schematically. Therefore, the specific implementation of step S103 may include:

the first method is as follows:

step S103-1-11: when the determined connection mode is the front outlet connection mode, adjusting the monitoring mode of a temperature sensor on a computing board at the air inlet of the server into the monitoring mode of monitoring the temperature of the air inlet of the server;

the purpose of step S103-1-11 is to, when the connection cable of the server assembled in the server cabinet belongs to a front outgoing line connection manner, that is, the connection cable such as the power line, the management network line, and the data line of the server needs to be connected with an external device from the front end of the server, at this time, the computing board in the server is close to the front end of the server cabinet, and the temperature sensor on the computing board is set to monitor the temperature at the air inlet, that is: and monitoring the temperature at the air inlet, wherein the air inlet is an area close to the computing board provided with the temperature sensor when the front outlet is in a connection mode.

Step S103-1-12: and when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of a temperature sensor on the main control board at the air inlet of the server into the monitoring mode for monitoring the temperature of the air inlet of the server.

The purpose of the step S103-1-12 is to set a temperature sensor on a main control board to monitor the temperature at an air inlet when the connection cable of the server assembled in the server cabinet belongs to a rear outlet connection mode, that is, the connection cable of the server such as a power line, a management network cable, and a data line needs to be connected with an external device from the rear end of the server, and the main control board in the server is close to the front end of the server cabinet.

It should be noted that, when the connection cable of the server is in a rear outgoing line connection mode, the assembly mode of the server and the server cabinet is that the server is horizontally rotated in a front outgoing line scene and then assembled in the server cabinet, and the rotation angle meets the assembly requirement of the server and the server cabinet. Before assembly, the power supply of the server needs to be replaced by the power supply used in the rear outlet scene.

The second method comprises the following steps:

step S103-2-21: when the determined connection mode is the front outlet connection mode, adjusting the monitoring mode of a temperature sensor on a main control board at the air outlet of the server to be the monitoring mode for monitoring the temperature of the air outlet of the server;

the steps S103-2-21 are performed to determine that, when the connection cable of the server assembled in the server cabinet belongs to a front-out connection mode, that is, the connection cables such as a power line, a management network cable, and a data line of the server need to be connected to an external device from the front end of the server, at this time, the computing board in the server is close to the front end of the server cabinet, the main control board in the server is close to the rear end of the server cabinet, and the temperature sensor on the main control board is set to monitor the temperature at the air outlet. Namely: the temperature at the air outlet is monitored, and when the front outlet is in a connection mode, the air outlet is an area close to the main control board provided with the temperature sensor.

Step S103-2-22: and when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of the temperature sensor on the computing board at the air outlet of the server into the monitoring mode for monitoring the temperature of the air outlet of the server.

The step S103-2-22 is to set the temperature sensor on the computing board to monitor the temperature at the air outlet when the connection cable of the server assembled in the server cabinet belongs to a rear outlet connection mode, that is, the connection cables such as the power line, the management network cable, and the data line of the server need to be connected with the external device from the rear end of the server, and at this time, the computing board in the server is close to the rear end of the server cabinet, and the main control board is close to the front end of the server cabinet.

It should be noted that, when the connection cable of the server is in a rear outgoing line connection mode, the assembly mode of the server and the server cabinet is that the server is horizontally rotated in a rear outgoing line scene and then assembled in the server cabinet, and the rotation angle meets the assembly requirement of the server and the server cabinet. Before assembly, the power supply of the server needs to be changed into the power supply used in the rear outlet scene.

In this embodiment, mainly when the determined connection mode is the front outlet connection mode, adjusting the monitoring mode of the temperature sensor on the computing board at the server air inlet to the monitoring mode of monitoring the temperature of the server air inlet; and adjusting the monitoring mode of a temperature sensor on the main control board at the air outlet of the server into the monitoring mode of monitoring the temperature of the air outlet of the server.

When the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of a temperature sensor on a main control board at the air inlet of the server to be the monitoring mode for monitoring the temperature of the air inlet of the server; and adjusting the monitoring mode of the temperature sensor on the computing board at the air outlet of the server into the monitoring mode of monitoring the temperature of the air outlet of the server.

Based on the above, the server in this embodiment is provided with at least two temperature sensors, one of which is located on the main control board and the other of which is located on the computing board, and is respectively used for detecting the temperatures at the air inlet and the air outlet.

Of course, it can also be understood that the monitoring of the temperature may be monitoring the air inlet and the air outlet, or may be monitoring only the air inlet or only the air outlet.

In this embodiment, the air inlet and the air outlet are jointly monitored, but the implementation mode of monitoring one of the air inlet and the air outlet is not excluded.

Step S104: and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

The step S104 is to control the operation state of the heat radiating parts in the server according to the monitored temperature signal. The specific implementation process can be as follows:

when the temperature is monitored in the first monitoring mode, the method comprises the following steps:

step S104-1-11: taking a control curve of the heat dissipation part;

step S104-1-12: determining the rotating speed of a heat dissipation part matched with the air inlet temperature according to the air inlet temperature monitored by a temperature sensor on the computing board at the air inlet or the air inlet temperature monitored by a temperature sensor on the main control board at the air inlet and the control curve;

step S104-1-13: and controlling the running state of the heat dissipation component in the server according to the rotating speed of the heat dissipation component.

When the temperature is monitored in the monitoring mode of the second mode, the method comprises the following steps:

step S104-2-11: a control curve of the heat dissipation part is obtained;

step S104-2-12: determining the rotating speed of the heat dissipation part matched with the air outlet temperature according to the air outlet temperature monitored by a temperature sensor on the main control board at the air outlet or the air outlet temperature monitored by a temperature sensor on the calculation board at the air outlet and the control curve;

step S104-2-13: and controlling the running state of the heat dissipation component in the server according to the rotating speed of the heat dissipation component.

Of course, it may also include:

under the preceding outlet wire connected mode:

taking a control curve of the heat dissipation part;

determining the rotating speed of the heat dissipation part according to the air inlet temperature monitored by the temperature sensor on the computing board at the air inlet, the air outlet temperature monitored by the temperature sensor on the main control board at the air outlet and the control curve;

and controlling the running state of the heat dissipation component in the server according to the rotating speed of the heat dissipation component.

Under the back outlet wire connection mode:

a control curve of the heat dissipation part is obtained;

determining the rotating speed of the heat dissipation part according to the air inlet temperature monitored by a temperature sensor on the main control board at the air inlet, the air outlet temperature monitored by a temperature sensor on the computing board at the air outlet and the control curve;

and controlling the running state of the heat dissipation component in the server according to the rotating speed of the heat dissipation component.

In this embodiment, the heat dissipation component may be a fan, and the main control board is a fan main control board.

The above is a specific description of an embodiment of a method for controlling an operating state of a server heat dissipation component provided in the present application, and the present application further discloses an embodiment of a device for controlling an operating state of a server heat dissipation component, which corresponds to the foregoing embodiment of a method for controlling an operating state of a server heat dissipation component, and please refer to fig. 2. The device embodiments described below are merely illustrative.

As shown in fig. 2, fig. 2 is a schematic structural diagram of an embodiment of a control apparatus for controlling an operating state of a server heat sink component, the apparatus includes:

an obtaining unit 201, configured to obtain configuration parameters of a server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in the assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in the assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server;

the obtaining unit 201 is specifically configured to obtain a power configuration parameter of the server through a power management bus when the server is assembled in the server cabinet.

A determining unit 202, configured to determine, according to the configuration parameter, that a connection manner of the server connection cable is the front outgoing line connection manner or the rear outgoing line connection manner;

the determination unit 202 includes: a query subunit and a determination subunit.

The query subunit is used for querying a power supply model table according to the power supply model parameters;

the determining subunit is configured to determine, according to the correspondence between the power model parameter and the connection mode of the connection cable in the power model table queried by the querying subunit, that the connection cable of the server is the front outgoing line connection mode or the rear outgoing line connection mode.

An adjusting unit 203, configured to adjust, according to the connection manner, a temperature monitoring manner in the server to be a monitoring manner for a front outgoing line connection manner or a monitoring manner for a back outgoing line connection manner;

in the first embodiment, the adjusting unit 203 is specifically configured to, when the determined connection manner is the front outgoing line connection manner, adjust a monitoring manner of a temperature sensor on a computing board at the server air inlet to a monitoring manner of monitoring the temperature of the server air inlet; and adjusting the monitoring mode of a temperature sensor on the main control board at the air outlet of the server into the monitoring mode of monitoring the temperature of the air outlet of the server.

Or, when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of the temperature sensor on the main control board at the server air inlet to the monitoring mode of monitoring the temperature of the server air inlet; and adjusting the monitoring mode of the temperature sensor on the computing board at the air outlet of the server into the monitoring mode of monitoring the temperature of the air outlet of the server.

In a second embodiment, the adjusting unit is specifically configured to adjust a monitoring mode of a temperature sensor on a computing board located at an air inlet of the server to a monitoring mode of monitoring the temperature of the air inlet of the server when the determined connection mode is the front outlet connection mode;

or, the monitoring module is specifically configured to, when the determined connection mode is the rear outlet connection mode, adjust a monitoring mode of a temperature sensor on the main control board at the server air inlet to a monitoring mode of monitoring the temperature of the server air inlet.

In a third embodiment, the adjusting unit is specifically configured to adjust a monitoring mode of a temperature sensor on a main control board located at the air outlet of the server to a monitoring mode of monitoring the temperature of the air outlet of the server when the determined connection mode is the front outlet connection mode;

or, the monitoring module is specifically configured to adjust the monitoring mode of the temperature sensor on the computing board at the server air outlet to the monitoring mode of monitoring the temperature of the server air outlet when the determined connection mode is the rear outlet connection mode.

In this embodiment, the first embodiment is mainly used as a main implementation manner.

And the control unit 204 is configured to control an operating state of the heat dissipation component in the server according to the adjusted temperature signal monitored by the temperature monitoring method.

The control unit 204 may include: the device comprises a calling subunit, a rotating speed determining subunit and a control subunit.

In accordance with the second embodiment of the adjusting unit, the retrieving subunit is configured to retrieve a control curve of the heat dissipating component; the rotating speed determining subunit is configured to determine a rotating speed of the heat dissipation component according to the air inlet temperature monitored by the temperature sensor on the computing board at the air inlet or the air inlet temperature monitored by the temperature sensor on the main control board at the air inlet, and the control curve; and the control subunit is used for controlling the running state of the heat dissipation component in the server according to the rotating speed of the heat dissipation component.

In accordance with the first embodiment of the adjusting unit, the retrieving subunit is configured to retrieve a control curve of the heat dissipating component; the rotating speed determining subunit is configured to determine a rotating speed of the heat dissipating component according to the air inlet temperature monitored by the temperature sensor of the computing board located at the air inlet, the air outlet temperature monitored by the temperature sensor on the main control board located at the air outlet, and the control curve; and the control subunit is used for controlling the running state of the heat dissipation component in the server according to the rotating speed of the heat dissipation component.

In accordance with the third embodiment of the adjusting unit, the retrieving subunit is configured to retrieve a control curve of the heat dissipating component; the rotating speed determining subunit is configured to determine a rotating speed of the heat dissipating component according to the air outlet temperature monitored by the temperature sensor on the main control board located at the air outlet, the air outlet temperature monitored by the temperature sensor on the computing board located at the air outlet, and the control curve; and the control subunit is used for controlling the running state of the heat dissipation component in the server according to the rotating speed of the heat dissipation component.

In this embodiment, the heat dissipation member is a fan installed in the server.

In the above description, for the specific contents of the embodiment of the control device, reference may be made to the contents of the embodiment of the control method for controlling the operation state of the heat dissipation component of the server, and therefore, redundant description is not repeated.

Based on the above, the present application further provides a server system, as shown in fig. 3 and fig. 4, fig. 3 is a schematic structural diagram of an assembly environment of a front outgoing line server of the server system provided by the present application, and fig. 4 is a schematic structural diagram of a state environment of a back outgoing line server of the server system provided by the present application. The server system provided by the present application may include: server rack 401 and server 402; the server is assembled in the server cabinet, a connecting cable of the server can be compatible with a front outgoing line connecting mode in an assembling environment of a front outgoing line server, and can be compatible with a rear outgoing line connecting mode in an assembling environment of a rear outgoing line server, wherein the front outgoing line connecting mode is that the connecting cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connecting mode is that the connecting cable of the server is connected with the external equipment through the rear end of the server; according to the acquired configuration parameters of the server, determining that the connection mode of the server connecting cable is the front outgoing line connection mode or the rear outgoing line connection mode; according to the connection mode, adjusting the temperature monitoring mode in the server to be a monitoring mode aiming at a front outlet connection mode or a monitoring mode aiming at a rear outlet connection mode; and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

In this embodiment, the configuration parameter of the server may be a configuration parameter of a server power supply, for example: and (4) power supply model parameters. The present embodiment is mainly illustrated by using a power model parameter.

As shown in fig. 3, when the connection cable of the server 402 assembled in the server cabinet 401 is in a front outgoing line connection mode, the server is assembled after being horizontally rotated to an assembly angle matched with the server cabinet in an assembly state when the server cabinet is in the rear outgoing line connection mode.

As shown in fig. 3, in an application scenario of the front outgoing line, in this embodiment, a fixed front outgoing line server 403 and a server 402 capable of being compatible with the front outgoing line and the rear outgoing line may be installed in the server cabinet.

As shown in fig. 4, when the connection cable of the server 402 mounted in the server cabinet 401 is in a rear outgoing line connection mode, the server 402 is mounted in a mounting state in which the server cabinet 401 is in the front outgoing line connection mode, and horizontally rotated to a mounting angle matched with the server cabinet 401.

As shown in fig. 4, in an application scenario of the rear outgoing line, in this embodiment, a fixed rear outgoing line server 404 and a server 402 capable of being compatible with the front outgoing line and the rear outgoing line may be installed in the server cabinet 401.

For obtaining configuration parameters of the server 402, determining whether a connection cable of the server 402 (compatible with front outgoing lines and rear outgoing lines) is in a front outgoing line connection mode 402-1 or a rear outgoing line connection mode 402-2, adjusting a temperature monitoring mode in the server (compatible with front outgoing lines and rear outgoing lines) and controlling an operation state of the heat dissipation component of the server (compatible with front outgoing lines and rear outgoing lines), which are related in this embodiment, reference may be made to the description of the control method embodiment of the operation state of the heat dissipation component of the server provided in this application, and no repeated description is given here.

Based on the above, the present application further provides a server, as shown in fig. 5, fig. 5 is a schematic structural diagram of an embodiment of a connection manner of a forward outgoing line of the server provided by the present application. The embodiment comprises the following steps: a power supply 501, a heat dissipation component 502, a computing board 503, a main control board 504 and temperature sensors 505-1 and 505-2 are arranged in the server;

under the condition that the connecting cable belongs to a front outgoing line connecting mode, the assembling mode that the server is assembled in the server cabinet is that a computing board in the server is close to the front end of the server, and the front end of the server and the front end 401-1 of the server cabinet are in the same direction, namely the direction facing a worker or the direction close to a cabinet door of the server cabinet. The main control board in the server is close to the rear end of the server, and the rear end 401-2 of the server is opposite to the front end of the server. The heat dissipation component in the server is located between the main control board and the rear end of the server.

When the connection cable belongs to a rear outlet connection mode (as shown in fig. 6), when the server is assembled in the server cabinet, the power supply needs to be replaced first, and the power supply during the assembly in a front outlet scene is replaced by the power supply in a rear outlet scene. And then, horizontally rotating the server to an angle matched with the server cabinet for assembly, wherein after assembly, a computing board in the server is far away from the front end of the server cabinet and is close to the rear end of the server cabinet, and the main control board is far away from the rear end of the server cabinet and is close to the front end of the server cabinet. The specific assembly can adopt the following modes:

when a connecting cable of the server assembled in the server cabinet is in a front outgoing line connection mode, the server is assembled after horizontally rotating to an assembly angle matched with the server cabinet in an assembly state when the server assembled in the server cabinet is in a rear outgoing line connection mode; when a connecting cable of the server assembled in the server cabinet is in a rear outgoing line connection mode, the server is assembled after horizontally rotating to an assembly angle matched with the server cabinet in an assembly state when the server cabinet is in a front outgoing line connection mode.

No matter how much the server rotates horizontally, the server air inlet is located at the front end of the server cabinet, and the server air outlet is located at the rear end of the server cabinet.

In this embodiment, the server is assembled in the server cabinet, wherein a connection cable of the server is compatible with a front outgoing line connection mode in a front outgoing line server assembly environment, and is compatible with a rear outgoing line connection mode in a rear outgoing line server assembly environment, the front outgoing line connection mode is that the connection cable of the server is connected with an external device through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external device through the rear end of the server;

the main control board acquires configuration parameters of the power supply and determines a connection mode of the server connection cable according to the configuration parameters; the main control board adjusts the monitoring modes of the temperature sensors on the computing board and the main control board in the server according to the connection mode, and controls the running state of the heat dissipation part in the server according to the adjusted temperature signals monitored by the temperature sensors.

In this embodiment, the main control board is a fan main control board, and is configured to determine whether the server is in a front outgoing line connection manner or a rear outgoing line connection manner according to the acquired configuration parameters, and automatically adjust a temperature sensor in the server according to the determined outgoing line connection manner, so as to adapt to temperature monitoring of the front outgoing line connection manner and the rear outgoing line connection manner in different assembly manners, and ensure a heat dissipation effect of the server.

The adjustment of the main control board to the temperature monitoring mode may specifically be adjustment of a temperature sensor, and may include the following three modes:

the first method is as follows:

when the determined connection mode is the front outlet connection mode, adjusting the monitoring mode of a temperature sensor on a computing board at the air inlet of the server to be the monitoring mode for monitoring the temperature of the air inlet of the server; and adjusting the monitoring mode of the temperature sensor on the main control board at the air outlet of the server into the monitoring mode of monitoring the temperature of the air outlet of the server.

Or when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of a temperature sensor on a main control board at the air inlet of the server to the monitoring mode of monitoring the temperature of the air inlet of the server; and adjusting the monitoring mode of the temperature sensor on the computing board at the air outlet of the server into the monitoring mode of monitoring the temperature of the air outlet of the server.

The second method comprises the following steps:

when the determined connection mode is the front outlet connection mode, adjusting the monitoring mode of the temperature sensor on the computing board at the air inlet of the server to the monitoring mode of monitoring the temperature of the air inlet of the server; namely: and adjusting the temperature sensor on the computing board to be an air inlet temperature sensor so as to monitor the air inlet temperature. Specifically, the name (sensor 1) of the temperature sensor on the computing board may be modified to be an inlet temperature sensor (inlet sensor).

Or when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of the temperature sensor on the main control board at the air inlet of the server to the monitoring mode of monitoring the temperature of the air inlet of the server. Specifically, the name (sensor 2) of the temperature sensor on the main control board may be modified to be an inlet air temperature sensor (inlet sensor).

The third method comprises the following steps:

when the determined connection mode is the front outlet connection mode, adjusting the monitoring mode of a temperature sensor on a main control board at the air outlet of the server to be the monitoring mode for monitoring the temperature of the air outlet of the server; specifically, the name (sensor 2) of the temperature sensor on the main control board may be modified to be an outlet temperature sensor (outlet sensor).

Or when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of the temperature sensor on the computing board at the air outlet of the server into the monitoring mode for monitoring the temperature of the air outlet of the server. Specifically, the name (sensor 1) of the temperature sensor on the computing board may be modified to be an outlet temperature sensor (outlet sensor).

The main control board of the server controls the fan rotating speed according to the temperature signal, and the three monitoring modes corresponding to the fan rotating speed can comprise the following three control modes:

the first method is as follows:

when the determined connection mode is the front outlet connection mode, adjusting the monitoring mode of a temperature sensor on a computing board at the air inlet of the server into the monitoring mode of monitoring the temperature of the air inlet of the server; and adjusting the monitoring mode of the temperature sensor on the main control board at the air outlet of the server into the monitoring mode of monitoring the temperature of the air outlet of the server.

Alternatively, the first and second electrodes may be,

when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of a temperature sensor on a main control board at the air inlet of the server to be the monitoring mode for monitoring the temperature of the air inlet of the server; and adjusting the monitoring mode of the temperature sensor on the computing board at the air outlet of the server into the monitoring mode of monitoring the temperature of the air outlet of the server

The second method comprises the following steps:

when the determined connection mode is the front outlet connection mode, adjusting the monitoring mode of a temperature sensor on a computing board at the air inlet of the server into the monitoring mode of monitoring the temperature of the air inlet of the server;

alternatively, the first and second electrodes may be,

and when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of a temperature sensor on the main control board at the air inlet of the server into the monitoring mode for monitoring the temperature of the air inlet of the server.

The third method comprises the following steps:

when the determined connection mode is the front outlet connection mode, adjusting the monitoring mode of a temperature sensor on a main control board at the air outlet of the server to be the monitoring mode for monitoring the temperature of the air outlet of the server;

alternatively, the first and second electrodes may be,

and when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of the temperature sensor on the computing board at the air outlet of the server to be the monitoring mode for monitoring the temperature of the air outlet of the server.

The foregoing is a description of an embodiment of a server provided in the present application, and for specific contents of the embodiment of the server, reference may also be made to the foregoing description of an embodiment of a method for controlling an operating state of a heat dissipation component of the server provided in the present application.

Based on the above, the present application further provides a computer storage medium for storing data generated by a network platform and a program for processing the data generated by the network platform;

when the program is read and executed, the following steps are executed:

acquiring configuration parameters of a server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in the assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in the assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server;

determining that the connection mode of the server connection cable is the front outgoing line connection mode or the rear outgoing line connection mode according to the configuration parameters;

according to the connection mode, adjusting the temperature monitoring mode in the server to be a monitoring mode aiming at a front outgoing line connection mode or a monitoring mode aiming at a rear outgoing line connection mode;

and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

Based on the above, the present application further provides an electronic device, including:

a processor;

a memory for storing a program for processing network platform generated data, said program when read and executed by said processor performing the steps of:

acquiring configuration parameters of a server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in the assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in the assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server;

according to the configuration parameters, determining that the connection mode of the server connection cable is the front outgoing line connection mode or the rear outgoing line connection mode;

according to the connection mode, adjusting the temperature monitoring mode in the server to be a monitoring mode aiming at a front outgoing line connection mode or a monitoring mode aiming at a rear outgoing line connection mode;

and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

In a typical configuration, a computing device includes one or more processors (CPUs), input/output interfaces, network interfaces, and memory.

The memory may include forms of volatile memory in a computer readable medium, random Access Memory (RAM) and/or non-volatile memory, such as Read Only Memory (ROM) or flash memory (flash RAM). Memory is an example of a computer-readable medium.

1. Computer-readable media, including both permanent and non-permanent, removable and non-removable media, may implement the information storage by any method or technology. The information may be computer readable instructions, data structures, modules of a program, or other data. Examples of computer storage media include, but are not limited to, phase change memory (PRAM), static Random Access Memory (SRAM), dynamic Random Access Memory (DRAM), other types of Random Access Memory (RAM), read Only Memory (ROM), electrically Erasable Programmable Read Only Memory (EEPROM), flash memory or other memory technology, compact disc read only memory (CD-ROM), digital Versatile Disks (DVD) or other optical storage, magnetic cassettes, magnetic tape magnetic disk storage or other magnetic storage devices, or any other non-transmission medium, which can be used to store information that can be accessed by a computing device. As defined herein, computer readable media does not include non-transitory computer readable media (transient media), such as modulated data signals and carrier waves.

2. As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and so forth) having computer-usable program code embodied therein.

Although the present application has been described with reference to the preferred embodiments, it is not intended to limit the present application, and those skilled in the art can make variations and modifications without departing from the spirit and scope of the present application, therefore, the scope of the present application should be determined by the claims that follow.

Claims (17)

1. A method for controlling the operation state of a server heat dissipation component is characterized by comprising the following steps:

acquiring configuration parameters of a server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in an assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in an assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server;

determining that the connection mode of the server connection cable is the front outgoing line connection mode or the rear outgoing line connection mode according to the configuration parameters;

according to the connection mode, adjusting the temperature monitoring mode in the server to be an air inlet monitoring mode and/or an air outlet monitoring mode aiming at a front outlet connection mode, or adjusting the temperature monitoring mode in the server to be an air inlet monitoring mode and/or an air outlet monitoring mode aiming at a rear outlet connection mode;

and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

2. The method for controlling the operational status of the server heat sink according to claim 1, wherein the obtaining the configuration parameters of the servers installed in the server rack comprises:

and when the server is assembled in the server cabinet, acquiring the power model parameter of the server in the configuration parameters through a power management bus.

3. The method for controlling an operating state of a server heat dissipation component according to claim 2, wherein the determining, according to the configuration parameter, whether the connection mode of the server connection cable is the front outgoing line connection mode or the rear outgoing line connection mode includes:

inquiring a power supply model table according to the power supply model parameters;

and determining the connecting cable of the server to be the front outgoing line connecting mode or the rear outgoing line connecting mode according to the corresponding relation between the power model parameters and the connecting modes of the connecting cables in the power model table.

4. The method for controlling an operating state of a server heat dissipation component according to claim 1, wherein the adjusting the temperature monitoring mode in the server according to the connection mode is an air inlet monitoring mode and/or an air outlet monitoring mode for a front outgoing line connection mode, or the adjusting the temperature monitoring mode in the server is an air inlet monitoring mode and/or an air outlet monitoring mode for a back outgoing line connection mode includes:

when the determined connection mode is the front outlet connection mode, adjusting the monitoring mode of a temperature sensor on a computing board at the air inlet of the server to be the monitoring mode for monitoring the temperature of the air inlet of the server;

and when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of a temperature sensor on a main control board at the air inlet of the server into the monitoring mode of monitoring the temperature of the air inlet of the server.

5. The method for controlling an operating state of a heat radiating member of a server according to claim 4, wherein the controlling an operating state of a heat radiating member in the server according to the adjusted temperature signal monitored by the temperature monitoring method includes:

taking a control curve of the heat dissipation part;

determining the rotating speed of the heat dissipation part according to the air inlet temperature monitored by the temperature sensor on the computing board at the air inlet or the air inlet temperature monitored by the temperature sensor on the main control board at the air inlet and the control curve;

and controlling the running state of the heat dissipation component in the server according to the rotating speed of the heat dissipation component.

6. The method for controlling the operating state of the server heat dissipation component according to claim 1 or 4, wherein the adjusting the temperature monitoring mode in the server to be an air inlet monitoring mode and/or an air outlet monitoring mode for a front outlet connection mode or the adjusting the temperature monitoring mode in the server to be an air inlet monitoring mode and/or an air outlet monitoring mode for a rear outlet connection mode according to the connection mode includes:

when the determined connection mode is the front outlet connection mode, adjusting the monitoring mode of a temperature sensor on a main control board at the air outlet of the server to be the monitoring mode for monitoring the temperature of the air outlet of the server;

and when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of the temperature sensor on the computing board at the air outlet of the server into the monitoring mode for monitoring the temperature of the air outlet of the server.

7. The method for controlling an operating state of a heat dissipating component of a server according to claim 6, wherein controlling an operating state of a heat dissipating component of the server based on the adjusted temperature signal monitored by the temperature monitoring method includes:

taking a control curve of the heat dissipation part;

determining the rotating speed of the heat dissipation part according to the air outlet temperature monitored by a temperature sensor on the main control board at the air outlet or the air outlet temperature monitored by a temperature sensor on the computing board at the air outlet and the control curve;

and controlling the running state of the heat dissipation component in the server according to the rotating speed of the heat dissipation component.

8. A control device for an operation state of a server heat radiating member, comprising:

the system comprises an acquisition unit, a processing unit and a processing unit, wherein the acquisition unit is used for acquiring configuration parameters of a server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in an assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in an assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server;

the determining unit is used for determining that the connection mode of the server connection cable is the front outgoing line connection mode or the rear outgoing line connection mode according to the configuration parameters;

the adjusting unit is used for adjusting the temperature monitoring mode in the server to be an air inlet monitoring mode and/or an air outlet monitoring mode aiming at the front outlet connection mode or adjusting the temperature monitoring mode in the server to be an air inlet monitoring mode and/or an air outlet monitoring mode aiming at the rear outlet connection mode according to the connection mode;

and the control unit is used for controlling the running state of the heat dissipation component in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

9. A server system, comprising: a server cabinet and a server; the server is assembled in the server cabinet, a connecting cable of the server can be compatible with a front outgoing line connecting mode in an assembling environment of a front outgoing line server, and can be compatible with a rear outgoing line connecting mode in an assembling environment of a rear outgoing line server, wherein the front outgoing line connecting mode is that the connecting cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connecting mode is that the connecting cable of the server is connected with the external equipment through the rear end of the server; determining that the connection mode of the server connecting cable is the front outgoing line connection mode or the rear outgoing line connection mode according to the acquired configuration parameters of the server; according to the connection mode, adjusting the temperature monitoring mode in the server to be an air inlet monitoring mode and/or an air outlet monitoring mode aiming at a front outlet connection mode, or adjusting the temperature monitoring mode in the server to be the air inlet monitoring mode and/or the air outlet monitoring mode aiming at a rear outlet connection mode; and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

10. The server system according to claim 9, wherein when the connection cable of the server mounted in the server rack is a front outgoing line connection manner, the server is mounted in a mounted state when the server rack is the rear outgoing line connection manner after being horizontally rotated to a mounting angle matching with the server rack; when the connecting cable of the server assembled in the server cabinet is in a rear outgoing line connecting mode, the server is assembled after horizontally rotating to an assembling angle matched with the server cabinet in an assembling state when the server is assembled in the server cabinet in a front outgoing line connecting mode.

11. A server, comprising: a power supply, a heat dissipation component, a computing board, a main control board and a temperature sensor are arranged in the server;

the server is assembled in a server cabinet, wherein a connecting cable of the server can be compatible with a front outgoing line connecting mode in a front outgoing line server assembling environment, and can be compatible with a rear outgoing line connecting mode in a rear outgoing line server assembling environment, the front outgoing line connecting mode is that the connecting cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connecting mode is that the connecting cable of the server is connected with the external equipment through the rear end of the server;

the main control board acquires configuration parameters of the power supply and determines a connection mode of the server connection cable according to the configuration parameters; the main control board adjusts the monitoring modes of the temperature sensors on the computing board and the main control board in the server according to the connection mode, and controls the running state of the heat dissipation part in the server according to the adjusted temperature signals monitored by the temperature sensors.

12. The server according to claim 11, wherein when the connection cable of the server mounted in the server cabinet is a front outgoing line connection manner, the server is mounted in a mounted state when the server cabinet is the rear outgoing line connection manner after being horizontally rotated to a mounting angle matching with the server cabinet; when a connecting cable of the server assembled in the server cabinet is in a rear outgoing line connection mode, the server is assembled after horizontally rotating to an assembly angle matched with the server cabinet in an assembly state when the server cabinet is in a front outgoing line connection mode.

13. The server according to claim 11, wherein when the determined connection mode is the front outlet connection mode, a monitoring mode of a temperature sensor on the computing board at the air inlet of the server is adjusted to a monitoring mode of monitoring the temperature of the air inlet of the server;

and when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of the temperature sensor on the main control board at the air inlet of the server into the monitoring mode of monitoring the temperature of the air inlet of the server.

14. The server according to claim 11, wherein when the determined connection mode is the front outlet connection mode, a monitoring mode of a temperature sensor on the main control board at the server air outlet is adjusted to a monitoring mode of monitoring the temperature of the server air outlet;

and when the determined connection mode is the rear outlet connection mode, adjusting the monitoring mode of the temperature sensor on the computing board at the air outlet of the server into the monitoring mode for monitoring the temperature of the air outlet of the server.

15. The server according to claim 11, wherein the main control board obtains a power model parameter of the power supply through a power management bus, and determines whether a connection mode of a connection cable in the server is a front-appearing connection mode or the rear-outgoing connection mode according to the power model parameter.

16. A computer storage medium for storing network platform generated data and a program for processing the network platform generated data;

when the program is read and executed, the following steps are executed:

acquiring configuration parameters of a server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in the assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in the assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server;

determining that the connection mode of the server connection cable is the front outgoing line connection mode or the rear outgoing line connection mode according to the configuration parameters;

according to the connection mode, adjusting the temperature monitoring mode in the server to be an air inlet monitoring mode and/or an air outlet monitoring mode aiming at a front outlet connection mode, or adjusting the temperature monitoring mode in the server to be an air inlet monitoring mode and/or an air outlet monitoring mode aiming at a rear outlet connection mode;

and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

17. An electronic device, comprising:

a processor;

a memory for storing a program for processing network platform generated data, said program when read and executed by said processor performing the steps of:

acquiring configuration parameters of a server assembled in a server cabinet; the connection cable of the server can be compatible with a front outgoing line connection mode in an assembly environment of a front outgoing line server, and can be compatible with a rear outgoing line connection mode in an assembly environment of a rear outgoing line server, wherein the front outgoing line connection mode is that the connection cable of the server is connected with external equipment through the front end of the server, and the rear outgoing line connection mode is that the connection cable of the server is connected with the external equipment through the rear end of the server;

according to the configuration parameters, determining that the connection mode of the server connection cable is the front outgoing line connection mode or the rear outgoing line connection mode;

according to the connection mode, adjusting the temperature monitoring mode in the server to be an air inlet monitoring mode and/or an air outlet monitoring mode aiming at a front outlet connection mode, or adjusting the temperature monitoring mode in the server to be an air inlet monitoring mode and/or an air outlet monitoring mode aiming at a rear outlet connection mode;

and controlling the running state of the heat dissipation part in the server according to the adjusted temperature signal monitored by the temperature monitoring mode.

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