CN114995614A - Speed regulation method, device and equipment for heat dissipation component - Google Patents

Abstract

The embodiment of the application discloses a speed regulating method, a speed regulating device and speed regulating equipment for a heat radiating part. This application is through setting up two kinds of speed governing modes in electronic equipment, when detecting the automatic incident that is arranged in instructing the radiating component's of automatic adjustment electronic equipment radiating component gear, combine the target temperature interval that current temperature value was located and the historical temperature interval that the historical temperature value of the electronic device that has confirmed was located, confirm whether current need adjust radiating component's radiating rate gear prevents the frequent speed governing of radiating component, has set up manual speed governing simultaneously, makes radiating component's speed governing more nimble.

Description

Speed regulation method, device and equipment for heat dissipation component

Technical Field

The present disclosure relates to computer cooling, and more particularly, to a method, an apparatus, and a device for adjusting a speed of a cooling component.

Background

In an electronic apparatus such as a notebook computer, in order to prevent an electronic device (such as a CPU) therein from being damaged due to an excessively high temperature during operation, a heat dissipation member (such as a fan) is often provided for the electronic device to dissipate heat of the electronic device.

However, because the temperature change of the electronic device is sensitive, for example, a CPU in a notebook computer may jump several tens of degrees instantaneously when a folder is opened, which often causes frequent speed adjustment of the heat dissipating component of the CPU, and the frequent speed adjustment may cause a noise problem on the one hand and also reduce the life of the heat dissipating component on the other hand.

Disclosure of Invention

The application discloses a speed regulation method, a speed regulation device and speed regulation equipment for a heat dissipation part, which are used for avoiding frequent speed regulation of the heat dissipation part and reducing noise caused by speed regulation of the heat dissipation part and damage to the heat dissipation part.

According to a first aspect of an embodiment of the present application, there is provided a speed regulation method for a heat dissipation component, where the method is applied to an electronic device, the electronic device at least includes the heat dissipation component and at least one electronic device, the heat dissipation component is configured to dissipate heat for the at least one electronic device, the heat dissipation component is provided with a plurality of heat dissipation speed steps, and the heat dissipation speed steps correspond to scene services and temperature intervals, and the method includes:

executing a set heat dissipation speed regulation strategy, wherein the heat dissipation speed regulation strategy comprises the following steps: an automatic mode and a manual mode;

the automatic mode includes: when an automatic event for indicating automatic adjustment of the heat dissipation speed gear of the heat dissipation part is detected, determining a target temperature interval in which a current temperature value of the electronic device is located from the obtained candidate temperature intervals, determining whether the heat dissipation speed gear of the heat dissipation part needs to be adjusted currently or not according to the target temperature interval and a history temperature interval in which a history temperature value of the electronic device is located, and if so, adjusting the heat dissipation speed gear of the heat dissipation part to a target heat dissipation speed gear corresponding to the target temperature interval;

the manual mode includes: when a manual event related to adjusting the heat dissipation speed gear of the heat dissipation component is detected, determining a target scene service to be loaded by the electronic device based on the manual event, and adjusting the heat dissipation speed gear of the heat dissipation component to a heat dissipation speed gear corresponding to the target scene service according to the target scene service.

Optionally, the detecting of the automatic event for instructing automatic adjustment of the heat dissipation speed gear of the heat dissipation component at least comprises:

when a period for automatically adjusting the heat dissipation speed gear of the heat dissipation component is reached, it is determined that an automatic event for instructing the automatic adjustment of the heat dissipation speed gear of the heat dissipation component is detected.

Optionally, each candidate temperature interval includes: a service temperature interval corresponding to the heat dissipation speed gear and a return difference interval between adjacent service temperature intervals;

the step of determining whether the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently according to the target temperature interval and the determined historical temperature interval in which the historical temperature value of the electronic device is located includes:

if the target temperature interval determined by stopping the current continuous N automatic events and the historical temperature interval where the historical temperature value of the electronic device is located are the same service temperature interval, determining that the heat dissipation speed gear of the heat dissipation part needs to be adjusted currently when the target temperature interval is different from the service temperature interval corresponding to the current heat dissipation speed gear of the heat dissipation part, and otherwise, determining that the heat dissipation speed gear of the heat dissipation part does not need to be adjusted currently.

Optionally, for each return difference interval, the starting temperature value of the return difference interval is the ending temperature value of one adjacent service temperature interval, and the ending temperature value of the return difference interval is the starting temperature value of another adjacent service temperature interval.

Optionally, after determining that the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently, or if a target temperature interval determined by ending current continuous N automatic events and a historical temperature interval in which a historical temperature value of the electronic device is located are the same return difference interval or the target temperature interval is the same as a service temperature interval corresponding to the current heat dissipation speed gear of the heat dissipation component, the method further includes:

and deleting the target temperature interval and the historical temperature interval determined by all recorded automatic events.

If at least one temperature interval different from the target temperature interval exists in the historical temperature intervals respectively determined by the N continuous automatic events, the method further comprises the following steps:

and if the historical temperature intervals respectively determined by the current continuous M automatic events in the continuous N automatic events are the same as the target temperature interval, deleting the historical temperature intervals respectively determined by the automatic events before the recorded continuous M automatic events.

Optionally, the detecting a manual event related to adjusting a heat dissipation speed gear of the heat dissipation component comprises:

when detecting that a scene button configured on a designated interface provided by the electronic equipment is triggered, determining that a manual event related to adjusting a heat dissipation speed gear of the heat dissipation component is detected; the designated interface is an interface which is compiled and used for adjusting the heat dissipation speed gear of the heat dissipation component.

Optionally, after the heat dissipation speed gear of the heat dissipation component is adjusted to the heat dissipation speed gear corresponding to the target scene service according to the target scene service, the method further includes:

prohibiting triggering of a manual event related to adjusting a heat dissipation speed gear of the heat dissipation component if the manual event is detected again within a first specified manual cooling time period thereafter;

wherein the first designated manual cool down time period is determined according to a minimum pacing time interval for adjusting a heat dissipation speed gear of the heat dissipating component based on an automatic event.

Optionally, the detecting of the automatic event for instructing automatic adjustment of the heat dissipation speed gear of the heat dissipation component is performed when the electronic device is in an automatic mode;

after the heat dissipation speed gear of the heat dissipation component is adjusted to the heat dissipation speed gear corresponding to the target scene service according to the target scene service, the method further includes:

automatically adjusting to the automatic mode after waiting for a preset buffering time;

if the adjusted heat dissipation speed gear is smaller than the heat dissipation speed gear before adjustment, in a preset time period after adjustment to the automatic mode, if it is detected that the heat dissipation speed gear of the heat dissipation part is adjusted to be higher than the heat dissipation speed gear adjusted in the previous manual mode in the automatic mode, then if a manual event related to adjustment of the heat dissipation speed gear of the heat dissipation part is detected again in a second specified manual cooling time period, the manual event is prohibited from being triggered;

wherein the second designated manual cooling time period is determined according to a minimum speed regulation time interval for adjusting a heat dissipation speed gear of the heat dissipation component based on an automatic event.

According to a second aspect of the embodiments of the present application, there is provided a speed adjusting device for a heat dissipating component, the speed adjusting device is applied to an electronic device, the electronic device at least includes the heat dissipating component and at least one electronic device, the heat dissipating component is configured to dissipate heat for the at least one electronic device, the heat dissipating component is provided with a plurality of heat dissipating speed stages, the heat dissipating speed stages correspond to a scene service and a temperature interval, and the speed adjusting device includes:

the execution unit is used for executing a set heat dissipation speed regulation strategy, and the heat dissipation speed regulation strategy comprises the following steps: an automatic mode and a manual mode;

the automatic speed regulating unit is used for executing an automatic mode; the automatic mode includes: when an automatic event for indicating automatic adjustment of the heat dissipation speed gear of the heat dissipation component is detected, determining a target temperature interval where a current temperature value of the electronic device is located from the obtained candidate temperature intervals, determining whether the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently or not according to the target temperature interval and a history temperature interval where a history temperature value of the electronic device is located, and if so, adjusting the heat dissipation speed gear of the heat dissipation component to a target heat dissipation speed gear corresponding to the target temperature interval;

the manual speed regulating unit is used for executing a manual mode; the manual mode includes: when a manual event related to adjusting the heat dissipation speed gear of the heat dissipation part is detected, determining a target scene service to be loaded by the electronic equipment based on the manual event, and adjusting the heat dissipation speed gear of the heat dissipation part to a heat dissipation speed gear corresponding to the target scene service according to the target scene service.

According to a third aspect of embodiments of the present application, there is provided an electronic apparatus including: a processor and a memory;

the memory for storing machine executable instructions;

the processor is used for reading and executing the machine executable instructions stored in the memory so as to realize the speed regulation method of the heat dissipation part.

The technical scheme provided by the embodiment of the application can have the following beneficial effects:

according to the technical scheme, the two speed regulation modes are set in the electronic equipment, when an automatic event for indicating the radiating speed gear of the radiating component in the electronic equipment is detected, whether the radiating speed gear of the radiating component needs to be adjusted currently is determined by combining the target temperature interval where the current temperature value is located and the historical temperature interval where the historical temperature value of the determined electronic device is located, the radiating speed gear of the radiating component is prevented from being adjusted frequently, manual speed regulation is set simultaneously, and the speed of the radiating component is adjusted more flexibly.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the application.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present specification and together with the description, serve to explain the principles of the specification.

Fig. 1 is a schematic flow chart of a speed regulating method for a heat dissipating component according to an embodiment of the present disclosure;

fig. 2 is a schematic flow chart illustrating automatic speed regulation of a heat dissipation component according to an embodiment of the present disclosure;

fig. 3 is a schematic flow chart of manual speed regulation of a heat dissipation component according to an embodiment of the present disclosure;

FIG. 4 is a schematic diagram of a speed regulating device for a heat dissipating component according to an embodiment of the present disclosure;

fig. 5 is a schematic diagram of a hardware structure of an electronic device according to an embodiment of the present application.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present application. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the present application, as detailed in the appended claims.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in this application and the appended claims, the singular forms "a", "an", and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items.

It is to be understood that although the terms first, second, third, etc. may be used herein to describe various information, such information should not be limited to these terms. These terms are only used to distinguish one type of information from another. For example, first information may also be referred to as second information, and similarly, second information may also be referred to as first information, without departing from the scope of the present application. The word "if" as used herein may be interpreted as "at … …" or "when … …" or "in response to a determination", depending on the context.

In order to make the technical solutions provided in the embodiments of the present application better understood and make the above objects, features and advantages of the embodiments of the present application more comprehensible, the technical solutions in the embodiments of the present application are described in further detail below with reference to the accompanying drawings.

Referring to fig. 1, fig. 1 is a schematic flow chart provided in the embodiment of the present application. The flow is applied to the electronic equipment. Alternatively, in this embodiment, the electronic apparatus may include at least a heat dissipation member and at least one electronic device. As an embodiment, the heat dissipation component is used to dissipate heat of at least one electronic device, and in a specific implementation, the heat dissipation component may be a fan or the like, and the embodiment is not particularly limited. The electronic device may be a device such as a CPU that is easily damaged by an excessive temperature, and the present embodiment is not particularly limited. As an embodiment, the heat dissipation component is provided with a plurality of heat dissipation speed gears, the heat dissipation speed gears correspond to scene services and temperature intervals, and the heat dissipation component corresponds to different heat dissipation speeds at different heat dissipation speed gears.

In addition, in this embodiment, the electronic device may be a notebook computer, a fan, or the like, and the embodiment is not limited in particular.

As shown in fig. 1, the process includes the following steps:

step 101, executing a set heat dissipation speed regulation strategy, wherein the heat dissipation speed regulation strategy comprises the following steps: an automatic mode and a manual mode; when the heat dissipation speed regulation strategy to be executed is in an automatic mode, if an automatic event for indicating automatic adjustment of the heat dissipation speed gear of the heat dissipation component is detected, step 102 is executed, and when the heat dissipation speed regulation strategy to be executed is in a manual mode, if a manual event related to adjustment of the heat dissipation speed gear of the heat dissipation component is detected, step 103 is executed.

As an embodiment, the detecting of the automatic event for instructing to automatically adjust the heat dissipation speed gear of the heat dissipation component is performed when the electronic device is in an automatic mode, and in the embodiment of the present application, the detecting of the automatic event for instructing to automatically adjust the heat dissipation speed gear of the heat dissipation component may be determined by: when a period of automatically adjusting a heat dissipation speed gear of the heat dissipation component is reached, it is determined that an automatic event indicating automatically adjusting the heat dissipation speed gear of the heat dissipation component is detected.

In this embodiment of the present application, after the electronic device is started, the heat dissipation component installed in the electronic device dissipates heat to the electronic device according to the preset default heat dissipation speed gear, and starts to trigger an automatic event that automatically adjusts the heat dissipation speed gear of the heat dissipation component, where the automatic event is triggered on time according to the set period t that automatically adjusts the heat dissipation speed gear of the heat dissipation component. For example, when the heat dissipation component in the embodiment is a fan, because the ratio of the number of services, in which the number of the services is 50% of the maximum rotation speed of the fan, of the fan rotation speed required for heat dissipation of the electronic device in the services applied to the electronic device is the highest, the heat dissipation speed corresponding to the default heat dissipation speed gear may be set to be 50% of the maximum rotation speed of the fan.

Further, when the period of automatically adjusting the heat dissipation speed gear of the heat dissipation component arrives, the electronic device such as a CPU is triggered to detect the current temperature of the electronic device according to a temperature sensor built in the electronic device, so as to obtain the current temperature value of the electronic device. Here, the current temperature value of the electronic device refers to the junction temperature of the electronic device, and the junction temperature is the current highest temperature in the electronic device.

As an embodiment, when it is detected that a scene button configured on a designated interface provided by the electronic device is triggered, it is determined that a manual event related to adjusting a heat dissipation speed stage of the heat dissipation component is detected, wherein the designated interface is an interface compiled for adjusting the heat dissipation speed stage of the heat dissipation component.

For example, an interface for manual speed adjustment may be set by designing a compiler, four scene switching buttons corresponding to four scenes, such as an idle scene, an audio-visual scene, an office scene, and a game scene, are set in the interface, the four scene switching buttons represent four scene services, each scene service corresponds to one heat dissipation speed gear, for example, a heat dissipation speed gear corresponding to the idle scene is a first gear, a heat dissipation speed gear corresponding to the audio-visual scene is a second gear, a heat dissipation speed gear corresponding to the office scene is a third gear, a heat dissipation speed gear corresponding to the game scene is a fourth gear, and the heat dissipation speed is faster when the gears are larger. When a user clicks a button of a certain scene (for example, a game scene), it is determined that a scene button configured on a designated interface provided by the electronic device is triggered, it is further determined that a target scene service to be loaded by the electronic device is a game according to the triggered scene button (the target scene service is not necessarily operated in the electronic device in this embodiment), and then a heat dissipation speed gear of the heat dissipation component is adjusted to a heat dissipation speed gear corresponding to the game scene service according to a heat dissipation speed gear corresponding to the heat dissipation component when the scene service is the game.

And 102, when an automatic event for indicating the automatic adjustment of the heat dissipation speed gear of the heat dissipation component is detected, automatically adjusting the speed of the heat dissipation component according to a set heat dissipation speed adjustment strategy aiming at the automatic speed adjustment of the heat dissipation component.

As an example, this step 102 is performed on the premise that an automatic event for instructing automatic adjustment of a heat dissipation speed stage of the heat dissipation member is detected in the automatic mode as an example. In this case, reference is made to fig. 2 for the step of automatically adjusting the speed of the heat dissipation member in this embodiment.

As shown in fig. 2, the step of automatically adjusting the speed of the heat dissipating component at least includes:

step 201, determining a target temperature interval in which the current temperature value of the electronic device is located from the obtained candidate temperature intervals.

In step 201, each candidate temperature interval includes: the service temperature interval corresponding to the heat dissipation speed gear and the return difference interval between the adjacent service temperature intervals.

Optionally, for each return difference interval, the starting temperature value of the return difference interval is the ending temperature value of one adjacent service temperature interval, and the ending temperature value of the return difference interval is the starting temperature value of another adjacent service temperature interval.

As an embodiment, in this embodiment, there is a corresponding relationship between different scene services and different heat dissipation speed gears, and there is a corresponding relationship between different scene services and different temperature intervals.

For example, if the electronic device is applied to a scene service, the scene service includes: the game scene, the office scene, the audio-visual scene, the idle scene, when being applied to the game scene based on electronic equipment, the business temperature interval T that temperature value that electronic device probably appears constitutes is: t ∈ [ T1, + ∞ ], when the electronic device is applied to an office scene, a service temperature interval T composed of temperature values that may occur to the electronic device is: t belongs to [ T3, T2], when the electronic device is applied to a video scene, a service temperature interval T formed by temperature values possibly appearing in an electronic device is as follows: t belongs to [ T5, T4], when the electronic device is applied to an idle scene, a service temperature interval T formed by temperature values possibly appearing in the electronic device is as follows: t ∈ [ - ∞, T6], the temperature interval T corresponding to the game scene may be set as: t belongs to [ T1, + ∞ ], and the temperature interval T corresponding to the office scene is as follows: t belongs to [ T3, T2], and the temperature interval T corresponding to the video scene is as follows: t is the element of T5, T4, and the temperature interval T corresponding to the idle scene is as follows: t ∈ [ - ∞, T6 ].

In this embodiment, T1> T2> T3> T4> T5> T6, and a hysteresis difference Δ T is provided between adjacent traffic temperature intervals, and a temperature interval in which the hysteresis difference Δ T provided between the adjacent traffic temperature intervals is located is referred to as a hysteresis interval, where T1 is T2+ Δ T, T3 is T4+ Δ T, and T5 is T6+ Δ T.

Further, based on the service temperature intervals corresponding to different scene services, the heat dissipation component in this embodiment has a corresponding relationship between each service temperature interval and different heat dissipation speed gears. For example, the heat dissipation speed gear corresponding to the idle scene is a first gear, the heat dissipation speed gear corresponding to the audio-visual scene is a second gear, the heat dissipation speed gear corresponding to the office scene is a third gear, the heat dissipation speed gear corresponding to the game scene is a fourth gear, the heat dissipation speed gear corresponding to the temperature interval T e [ - ∞, T6] is a first gear, the heat dissipation speed gear corresponding to the temperature interval T e 5, T4] is a second gear, the heat dissipation speed gear corresponding to the temperature interval T e [ T3, T2] is a third gear, and the heat dissipation speed gear corresponding to the temperature interval T e [ T1 ], and the heat dissipation speed gear corresponding to the infinity gear is a fourth gear. In this embodiment, the manual mode and the automatic mode can be associated by setting the corresponding relationship between the scene service, the temperature range and the heat dissipation speed gear, so that the heat dissipation speed can be adjusted based on the same heat dissipation speed gear in the manual mode and the automatic mode, and the manual mode and the automatic mode are prevented from colliding with each other when the speed of the heat dissipation component is adjusted.

During concrete implementation, for example, the heat dissipation component in this embodiment is a fan, the heat dissipation speed gear corresponding to the heat dissipation component set in each service temperature interval in this embodiment is the gear of the fan, different gears of the fan correspond to different duty ratios, the duty ratio is larger, the fan rotation speed is larger, the heat dissipation performance of heat dissipation is better for the heat dissipation component, in this embodiment, the actual temperature setting of the electronic device when the electronic device is applied to different scene services according to the duty ratios corresponding to different gears of the fan during debugging.

Based on the service temperature interval as the candidate temperature interval and the return difference interval between the adjacent service temperature intervals, it can be determined which service temperature interval or return difference interval the current temperature value of the electronic device is located in according to the current temperature value of the electronic device.

Step 202, determining whether the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently according to the target temperature interval and the determined historical temperature interval in which the historical temperature value of the electronic device is located.

In step 203, if the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently, the heat dissipation speed gear of the heat dissipation component is adjusted to a target heat dissipation speed gear corresponding to the target temperature interval.

As an embodiment, based on the service temperature interval and the return difference interval as the candidate temperature intervals, in this embodiment, the step 202 determines whether the heat dissipation speed level of the heat dissipation component needs to be adjusted currently according to the target temperature interval and the historical temperature interval in which the historical temperature value of the electronic device is determined to be located, and may be divided into the following four cases:

firstly, if a target temperature interval determined by stopping current continuous N automatic events and a historical temperature interval where a historical temperature value of an electronic device is located are the same service temperature interval, when the target temperature interval is different from the service temperature interval corresponding to the current heat dissipation speed gear of a heat dissipation component, determining that the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently, and otherwise, determining that the heat dissipation speed gear of the heat dissipation component does not need to be adjusted currently.

For example, if N is 5, the temperature intervals determined by the current N consecutive automatic events are respectively recorded as: the method comprises the steps of determining a first temperature interval, a second temperature interval, a third temperature interval, a fourth temperature interval and a fifth temperature interval, wherein the fifth temperature interval can be determined as a target temperature interval, the first temperature interval, the second temperature interval, the third temperature interval, the fourth temperature interval and the fifth temperature interval are determined as historical temperature intervals, if the first temperature interval, the second temperature interval, the third temperature interval, the fourth temperature interval and the fifth temperature interval are the same service temperature intervals, and the service temperature intervals corresponding to the current heat dissipation speed gears of the heat dissipation part are different, then the heat dissipation speed gear of the heat dissipation part which needs to be adjusted currently can be determined, and otherwise, the heat dissipation speed gear of the heat dissipation part which does not need to be adjusted currently is determined.

Secondly, if the target temperature interval determined by stopping the current continuous N automatic events and the historical temperature interval where the historical temperature value of the electronic device is located are the same service temperature interval, but when the target temperature interval is the same as the service temperature interval corresponding to the current heat dissipation speed gear of the heat dissipation part, it is determined that the heat dissipation speed gear of the heat dissipation part does not need to be adjusted currently.

Thirdly, if the target temperature interval determined by stopping the current continuous N automatic events and the historical temperature interval where the historical temperature value of the electronic device is located are the same return difference interval, determining that the heat dissipation speed gear of the heat dissipation component does not need to be adjusted currently.

Fourthly, if at least one temperature interval different from the target temperature interval exists in the historical temperature intervals respectively determined by the current continuous N automatic events, determining that the heat dissipation speed gear of the heat dissipation component does not need to be adjusted currently.

For example, the service applied to the electronic device in the above embodiments may include at least: taking a game scene, an office scene, a video scene, and an idle scene as examples, based on the described return difference interval and the service temperature interval corresponding to the service of different scenes, whether the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently is determined under the four conditions:

based on the above embodiment, 6 candidate temperature intervals can be obtained: [ T1, + ∞ ], (T2, T1), [ T3, T2], (T4, T3), [ T5, T4], (T6, T5), [ - ∞, T6 ]. For convenience of recording, the [ T1, + ∞ ] is denoted as a section, (T2, T1) is denoted as a section B, [ T3, T2] is denoted as a section C, (T4, T3) is denoted as a section D, [ T5, T4] is denoted as a section E, (T6, T5) is denoted as a section F, [ - ∞, T6] is denoted as a section G, wherein the sections A, C, E and G are traffic temperature sections, and the sections B, D and F are return difference sections.

Assuming that a service temperature interval corresponding to a current heat dissipation speed gear of a heat dissipation component in the embodiment of the present application is an interval a, the following describes the four cases by way of example:

in the first case: if the determined target temperature interval after the automatic event is detected is a C interval, and the temperature intervals (including the target temperature interval and the historical temperature interval) of the temperature values of the electronic device respectively determined by stopping the current continuous N automatic events are C intervals, N +1 continuous C intervals can be detected in the temperature intervals of the temperature values of the electronic device determined by the currently recorded automatic events, and the target temperature interval (C interval) is different from the service temperature interval (A interval) corresponding to the current heat dissipation speed gear of the heat dissipation component, the heat dissipation speed gear of the heat dissipation component which needs to be adjusted currently is determined, and the heat dissipation speed gear of the heat dissipation component is modified from the heat dissipation speed gear corresponding to the A interval to the heat dissipation speed gear corresponding to the C interval.

In the second case: if the determined target temperature interval after the automatic event is detected is an interval A, and the temperature intervals (including the target temperature interval and the historical temperature interval) in which the temperature values of the electronic device respectively determined by stopping the current continuous N automatic events are all the interval A, it can be detected that N +1 continuous intervals A exist in the temperature intervals in which the temperature values of the electronic device determined by the currently recorded automatic event are located, but the target temperature interval (interval A) is the same as the service temperature interval (interval A) corresponding to the current heat dissipation speed gear of the heat dissipation component, and then it is determined that the heat dissipation speed gear of the heat dissipation component does not need to be adjusted currently.

In the third case: if the target temperature interval determined after the automatic event is detected is a B interval, and the temperature intervals (including the target temperature interval and the historical temperature interval) in which the temperature values of the electronic device are respectively determined by stopping the current continuous N automatic events are all B intervals, it can be detected that N +1 continuous B intervals exist in the temperature intervals in which the temperature values of the electronic device are determined by the currently recorded automatic event, but the B intervals are return intervals, and it can also be determined that the heat dissipation speed gear of the heat dissipation component does not need to be adjusted currently.

In a fourth case: if the determined target temperature interval is a B interval after the automatic event is detected, and the temperature intervals (including the target temperature interval and the historical temperature interval) in which the temperature values of the electronic device are respectively determined by stopping the current continuous N automatic events are the A interval, the A interval and the B interval in sequence, the heat dissipation speed gear of the heat dissipation component which does not need to be adjusted at present can also be determined.

As an embodiment, after determining that the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently (i.e., the adjustment of the heat dissipation speed gear of the heat dissipation component is completed in the first case in the foregoing embodiment), or if the temperature intervals in which the temperature values of the electronic device determined by N consecutive automatic events are located are all return difference intervals or the target temperature interval is the same as the service temperature interval corresponding to the current heat dissipation speed gear of the heat dissipation component (i.e., the second and third cases occur), the embodiment of the present application may further delete the temperature interval in which the temperature value of the electronic device determined by the recorded automatic event is located. For example, in the third case, if the temperature interval in which the temperature value of the electronic device determined by the currently recorded automatic event is located is abcdabb, the record includes a target temperature interval B determined by the current automatic event, because the interval B is a return difference interval, the temperature interval abcdabb in which the temperature value of the electronic device determined by the currently recorded automatic event is located is deleted, and when the period for automatically adjusting the heat dissipation speed gear of the heat dissipation component reaches the next period, the temperature interval in which the temperature value of the electronic device determined by the automatic event is located is restarted to be recorded.

In this embodiment, the reason why the temperature interval in which the temperature value of the electronic device determined according to the recorded automatic event is located is deleted according to the above method is that the recorded temperature interval is used to determine whether the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently and then becomes redundant data, so that in order to reduce memory consumption in the electronic device, the redundant data can be deleted in time through the above steps.

Preferably, as another embodiment, the recorded temperature interval which becomes redundant data can be deleted in time by the following steps: if at least one of the temperature intervals in which the temperature values of the electronic device respectively determined by the N continuous automatic events are located is not the target temperature interval, the historical temperature intervals respectively determined by the M continuous automatic events at the current time are the same as the target temperature interval in the N continuous automatic events, and the historical temperature intervals respectively determined by the automatic events before the M continuous automatic events which are recorded can be further deleted.

For example, taking N as 3, if the temperature interval in which the temperature value of the electronic device determined by the above-mentioned 3 consecutive automatic events is located is AAB, the target temperature interval in which the current temperature value of the electronic device is located is B (for convenience of distinguishing, the target temperature interval is B1, and the B interval in the temperature intervals in which the temperature values of the electronic device determined by the above-mentioned 3 consecutive automatic events are located is B0), after recording the target temperature interval, the temperature interval in which the temperature value of the electronic device determined by the currently recorded automatic event is located is AAB0B1, it can be determined that the heat dissipation speed stage of the heat dissipation component does not need to be adjusted currently, and further, according to the above-mentioned method, it can be detected that the temperature interval in which the temperature value of the electronic device determined by 1 currently consecutive automatic event is located is B0, the temperature interval AA recorded before B0 may be deleted.

At this point, the flow of automatically adjusting the speed of the heat radiating member shown in fig. 2 is completed.

And 103, when a manual event related to the adjustment of the heat dissipation speed gear of the heat dissipation component is detected, manually adjusting the speed of the heat dissipation component according to a set heat dissipation speed adjustment strategy aiming at the manual speed adjustment of the heat dissipation component.

As an example, this step 103 is performed on the premise that a manual event related to adjusting a heat dissipation speed gear of the heat dissipation member is detected in the manual mode. In this regard, reference is made to fig. 3 for the step of manually adjusting the speed of the heat sink in this embodiment.

As shown in fig. 3, the step of manually adjusting the speed of the heat sink member includes at least:

step 301, when a manual event related to adjusting a heat dissipation speed gear of a heat dissipation component is detected, determining a target scene service to be loaded by the electronic device based on the manual event.

And 302, adjusting the heat dissipation speed gear of the heat dissipation part to a heat dissipation speed gear corresponding to the target scene service according to the target scene service.

As an embodiment, after the heat dissipation speed gear of the heat dissipation component is adjusted to the heat dissipation speed gear corresponding to the target scene service, in order to avoid frequent manual speed adjustment caused by an object mistakenly touching a scene button for scene switching, for example, when the electronic device is a computer, the object continuously presses the keyboard, and the manual speed adjustment is limited in the following manner in this embodiment:

and after the heat dissipation speed gear of the heat dissipation part is adjusted to the heat dissipation speed gear corresponding to the target scene service according to the target scene service, setting the manual cooling time after the current time to prohibit triggering of a manual event. Wherein the manual cooling time is determined based on a minimum speed adjustment time interval determined by an automatic event to require adjustment of a heat dissipation speed gear of the heat dissipation component.

After the heat dissipation speed gear of the heat dissipation component is adjusted to the heat dissipation speed gear corresponding to the target scene service according to the target scene service, if a manual event related to adjusting the heat dissipation speed gear of the heat dissipation component is detected again within a first specified manual cooling time period, the manual event is prohibited from being triggered. Wherein the first designated manual cooling time period in the present embodiment is determined according to a minimum speed regulation time interval for adjusting a heat dissipation speed gear of the heat dissipation component based on an automatic event.

As an embodiment, the minimum speed-adjusting time interval (denoted as s) determined by the automatic event to be required to adjust the heat-dissipating speed gear of the heat-dissipating component is related to the period t of automatically adjusting the heat-dissipating speed gear of the heat-dissipating component, N in the above embodiment, and is equal to N × t. In this embodiment, the minimum speed regulation time interval is set according to the speed regulation process of the heat dissipation component in the practical application process, and frequent speed regulation of the heat dissipation component is avoided, so that, in order to avoid frequent manual speed regulation, a first designated manual cooling time period may be set according to the minimum speed regulation time interval, and the first designated manual cooling time period may be greater than or equal to the minimum speed regulation time interval.

In the embodiment of the application, if a scene button configured on a specified interface provided by the electronic equipment is detected to be triggered within a first specified manual cooling time period, the specified interface gives a prompt such as 'manual mode is not temporarily supported', and the triggering of a manual event is prohibited.

As an embodiment, in order to avoid unreasonable heat dissipation speed gears of the heat dissipation component after manual speed regulation, the manual speed regulation may be further limited by:

after the heat dissipation speed gear of the heat dissipation component is adjusted to the heat dissipation speed gear corresponding to the target scene service according to the target scene service, the heat dissipation speed gear can be further automatically adjusted to an automatic mode of the electronic device after waiting for a preset buffer time, and the automatic mode of the electronic device can trigger an automatic event for indicating the automatic adjustment of the heat dissipation speed gear of the heat dissipation component.

Alternatively, the preset buffer time may be related to a period t for automatically adjusting a heat dissipation speed gear of the heat dissipation member, and the preset buffer time may be set to be less than or equal to the period t. The preset buffering time can be set according to the actual operation process of services in the electronic equipment, and the aim is to avoid frequent speed regulation of the heat dissipation part caused by the fact that the electronic equipment enters automatic speed regulation immediately after manual speed regulation.

In this embodiment of the application, if the adjusted heat dissipation speed gear is smaller than the heat dissipation speed gear before adjustment after the heat dissipation speed gear of the heat dissipation component is manually adjusted, after waiting for a preset buffer time, the heat dissipation speed gear of the heat dissipation component is automatically adjusted to the automatic mode, and if it is detected that the heat dissipation speed gear of the heat dissipation component is adjusted to be higher than the heat dissipation speed gear adjusted in the previous manual mode in the automatic mode, the manual event is prohibited from being triggered if a manual event related to the adjustment of the heat dissipation speed gear of the heat dissipation component is detected again within a second specified manual cooling time period.

The preset time period is determined according to the temperature rise speed of the electronic device during operation service, and is greater than or equal to the sum of the minimum speed regulation time interval and the preset buffer time for adjusting the heat dissipation speed gear of the heat dissipation component based on an automatic event; the second designated manual cooling time period can be set according to the actual requirement for manually adjusting the speed of the heat dissipation component, and the second designated manual cooling time period is greater than the first designated manual cooling time period and greater than the minimum speed adjustment time interval for adjusting the heat dissipation speed gear of the heat dissipation component based on the automatic event.

For example, if a user adjusts the heat dissipation speed gear of the heat dissipation component to a low speed by manual speed adjustment when the electronic device is currently in a high-performance scene (the heat dissipation speed gear of the heat dissipation component needs to be a high speed), the automatic mode of the electronic device is automatically adjusted after a preset buffer time, and an automatic event is triggered according to the heat dissipation speed gear period t of the automatically adjusted heat dissipation component in the automatic mode. At this time, because the electronic device is currently in a high-performance scene, the temperature of the electronic device to be cooled can be rapidly increased in a short time, so that the automatic mode can adjust the heat dissipation speed gear of the heat dissipation component to be higher than the heat dissipation speed gear adjusted in the previous manual mode within a preset time period.

In this embodiment, an event of a heat dissipation speed gear of the heat dissipation component occurs within a preset time period, which indicates that the heat dissipation speed gear of the heat dissipation component after being adjusted by a user through manual speed adjustment is unreasonable, and therefore, in order to further avoid the user from mistakenly adjusting the speed through a manual mode, this embodiment sets that triggering of a manual event is prohibited within a second specified manual cooling time period after the current time.

As an embodiment, if it is detected that the heat dissipation speed gear after the manual adjustment is not less than the heat dissipation speed gear before the adjustment, the present embodiment will automatically adjust the electronic device to the automatic mode after waiting for the preset buffer time.

It should be noted that, after the automatic adjustment to the automatic mode is performed again after the manual event is detected, since the historical temperature interval determined by the detected automatic event before the manual event loses the reference effect on the subsequent automatic speed adjustment, the historical temperature interval determined by the automatic event before the manual event can be deleted.

The flow shown in fig. 3 is completed.

It should be noted that the manual mode for manually adjusting the speed of the heat dissipation component is set in the present application, because when the electronic device switches from one scene service to another scene service, the automatic speed adjustment of the heat dissipation component may have a certain delay, and in order to match the scene service more quickly, the embodiment of the present application simultaneously designs the manual mode and matches the scene service.

Thus, the flow of the method for adjusting the speed of the heat radiating member shown in fig. 1 is completed.

Through the flow shown in fig. 1, in the embodiment of the present application, two speed regulation modes may be set for a heat dissipation component in an electronic device, and when an automatic event for indicating that a heat dissipation speed gear of the heat dissipation component in the electronic device is automatically adjusted is detected, by combining a target temperature interval where a current temperature value is located and a historical temperature interval where a historical temperature value of the determined electronic device is located, whether the heat dissipation speed gear of the heat dissipation component needs to be currently adjusted is determined, so that the heat dissipation component is prevented from being frequently regulated, and meanwhile, manual speed regulation is set, so that the speed regulation of the heat dissipation component is more flexible.

As an embodiment, the automatic speed regulation process or the manual speed regulation process may be executed by an MCU (Single Chip Microcomputer) Chip disposed in the electronic device, or may be executed by a CPU Chip disposed in the electronic device.

The introduction of the method embodiment provided by the embodiment of the present application is completed above, and a description is provided below for a speed adjusting device of a heat dissipation component provided by the embodiment of the present application, where the speed adjusting device is applied to an electronic device, the electronic device at least includes the heat dissipation component and at least one electronic device, the heat dissipation component is used for dissipating heat for the at least one electronic device, the heat dissipation component is provided with a plurality of heat dissipation speed gears, and the heat dissipation speed gears correspond to scene services and temperature intervals. As shown in fig. 4, the apparatus includes at least:

the execution unit 401 is configured to execute a set heat dissipation speed regulation policy, where the heat dissipation speed regulation policy includes: an automatic mode and a manual mode;

an automatic speed regulating unit 402 for performing an automatic mode; the automatic mode includes: when an automatic event for indicating automatic adjustment of the heat dissipation speed gear of the heat dissipation component is detected, determining a target temperature interval in which a current temperature value of the electronic device is located from the obtained candidate temperature intervals, determining whether the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently or not according to the target temperature interval and a history temperature interval in which a history temperature value of the electronic device is located, and if so, adjusting the heat dissipation speed gear of the heat dissipation component to a target heat dissipation speed gear corresponding to the target temperature interval.

A manual speed adjusting unit 403 for executing a manual mode; the manual mode includes: when a manual event related to adjusting the heat dissipation speed gear of the heat dissipation part is detected, determining a target scene service to be loaded by the electronic equipment based on the manual event, and adjusting the heat dissipation speed gear of the heat dissipation part to a heat dissipation speed gear corresponding to the target scene service according to the target scene service.

Optionally, the detection of the automatic event by the automatic speed regulating unit 402 for instructing automatic adjustment of the heat dissipation speed gear of the heat dissipation component at least includes:

when a period for automatically adjusting the heat dissipation speed gear of the heat dissipation component is reached, it is determined that an automatic event for instructing the automatic adjustment of the heat dissipation speed gear of the heat dissipation component is detected.

Optionally, each candidate temperature interval includes: a service temperature interval corresponding to the heat dissipation speed gear and a return difference interval between adjacent service temperature intervals;

the determining, by the automatic speed regulating unit 402, whether the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently according to the target temperature interval and the determined historical temperature interval where the historical temperature value of the electronic device is located includes:

if the target temperature interval determined by stopping the current continuous N automatic events and the historical temperature interval where the historical temperature value of the electronic device is located are the same service temperature interval, determining that the heat dissipation speed gear of the heat dissipation part needs to be adjusted currently when the target temperature interval is different from the service temperature interval corresponding to the current heat dissipation speed gear of the heat dissipation part, and otherwise, determining that the heat dissipation speed gear of the heat dissipation part does not need to be adjusted currently.

Optionally, for each return difference interval, the starting temperature value of the return difference interval is the ending temperature value of one adjacent service temperature interval, and the ending temperature value of the return difference interval is the starting temperature value of another adjacent service temperature interval.

Optionally, after the automatic speed adjusting unit 402 determines that the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently, or if a target temperature interval determined by stopping current continuous N automatic events and a historical temperature interval where a historical temperature value of the electronic device is located are the same return difference interval or the target temperature interval is the same as a service temperature interval corresponding to the current heat dissipation speed gear of the heat dissipation component, the automatic speed adjusting unit 402 is further configured to:

deleting the target temperature interval and the historical temperature interval determined by all recorded automatic events;

if at least one temperature interval different from the target temperature interval exists in the historical temperature intervals respectively determined by the N consecutive automatic events, the automatic speed adjusting unit 402 is further configured to:

and if the historical temperature intervals respectively determined by the current continuous M automatic events in the continuous N automatic events are the same as the target temperature interval, deleting the historical temperature intervals respectively determined by the automatic events before the recorded continuous M automatic events.

Optionally, the detecting of the manual event related to adjusting the heat dissipation speed gear of the heat dissipation component by the manual speed regulation unit 403 includes:

when a scene button configured on a designated interface provided by the electronic equipment is triggered, determining that a manual event related to adjusting a heat dissipation speed gear of the heat dissipation component is detected; the designated interface is an interface which is compiled and used for adjusting the heat dissipation speed gear of the heat dissipation component.

Optionally, after the manual speed regulation unit 403 adjusts the heat dissipation speed gear of the heat dissipation component to the heat dissipation speed gear corresponding to the target scene service according to the target scene service, the manual speed regulation unit 403 is further configured to:

prohibiting triggering of a manual event related to adjusting a heat dissipation speed gear of the heat dissipation component if the manual event is detected again within a first specified manual cooling time period thereafter;

wherein the first designated manual cooling time period is determined according to a minimum speed regulation time interval for adjusting a heat dissipation speed gear of the heat dissipation component based on an automatic event.

Optionally, the automatic speed regulating unit 402 detects that an automatic event for instructing to automatically adjust the heat dissipation speed gear of the heat dissipation component is performed when the electronic device is in an automatic mode;

after the manual speed adjusting unit 403 adjusts the heat dissipation speed gear of the heat dissipation component to the heat dissipation speed gear corresponding to the target scene service according to the target scene service, the manual speed adjusting unit 403 is further configured to:

automatically adjusting to the automatic mode after waiting for a preset buffering time;

if the adjusted heat dissipation speed gear is smaller than the heat dissipation speed gear before adjustment, within a preset time period after adjustment to the automatic mode, if it is detected that the heat dissipation speed gear of the heat dissipation part is adjusted to be higher than the heat dissipation speed gear adjusted in the previous manual mode in the automatic mode, then within a second specified manual cooling time period, if a manual event related to adjustment of the heat dissipation speed gear of the heat dissipation part is detected again, the manual event is prohibited from being triggered;

wherein the second designated manual cooling time period is determined according to a minimum speed regulation time interval for adjusting a heat dissipation speed gear of the heat dissipation component based on an automatic event.

The description of the apparatus shown in fig. 4 is thus completed.

Correspondingly, an embodiment of the present application further provides a hardware structure diagram of an electronic device, and specifically, as shown in fig. 5, the electronic device may be a device implementing the method for regulating speed of the heat dissipation component. As shown in fig. 4, the hardware structure includes: a processor and a memory.

Wherein the memory is to store machine executable instructions;

the processor is used for reading and executing the machine executable instructions stored by the memory so as to realize the corresponding method embodiment for regulating the speed of the heat dissipation component.

For one embodiment, the memory may be any electronic, magnetic, optical, or other physical storage device that may contain or store information such as executable instructions, data, and the like. For example, the memory may be: volatile memory, non-volatile memory, or similar storage media. In particular, the Memory may be a RAM (random Access Memory), a flash Memory, a storage drive (e.g., a hard disk drive), a solid state disk, any type of storage disk (e.g., an optical disk, a DVD, etc.), or similar storage medium, or a combination thereof.

Up to this point, the description of the electronic apparatus shown in fig. 5 is completed.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the scope of protection of the present application.

Claims (10)

1. A speed regulation method for a heat dissipation part is characterized in that the method is applied to electronic equipment, the electronic equipment at least comprises the heat dissipation part and at least one electronic device, the heat dissipation part is used for dissipating heat for the at least one electronic device, the heat dissipation part is provided with a plurality of heat dissipation speed gears, and the heat dissipation speed gears correspond to scene services and temperature intervals, and the method comprises the following steps:

executing a set heat dissipation speed regulation strategy, wherein the heat dissipation speed regulation strategy comprises the following steps: an automatic mode and a manual mode;

the automatic mode includes: when an automatic event for indicating automatic adjustment of the heat dissipation speed gear of the heat dissipation part is detected, determining a target temperature interval in which a current temperature value of the electronic device is located from the obtained candidate temperature intervals, determining whether the heat dissipation speed gear of the heat dissipation part needs to be adjusted currently or not according to the target temperature interval and a history temperature interval in which a history temperature value of the electronic device is located, and if so, adjusting the heat dissipation speed gear of the heat dissipation part to a heat dissipation speed gear corresponding to the target temperature interval;

the manual mode includes: when a manual event related to adjusting the heat dissipation speed gear of the heat dissipation part is detected, determining a target scene service to be loaded by the electronic equipment based on the manual event, and adjusting the heat dissipation speed gear of the heat dissipation part to a heat dissipation speed gear corresponding to the target scene service according to the target scene service.

2. The method of claim 1, wherein detecting an automatic event for instructing automatic adjustment of a heat dissipation speed stage of the heat dissipation component comprises at least:

when a period for automatically adjusting the heat dissipation speed gear of the heat dissipation component is reached, it is determined that an automatic event indicating that the heat dissipation speed gear of the heat dissipation component is automatically adjusted is detected.

3. The method of claim 1 or 2, wherein each candidate temperature interval comprises: a service temperature interval corresponding to the heat dissipation speed gear and a return difference interval between adjacent service temperature intervals;

the step of determining whether the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently according to the target temperature interval and the determined historical temperature interval in which the historical temperature value of the electronic device is located includes:

if the target temperature interval determined by stopping the current continuous N automatic events and the historical temperature interval where the historical temperature value of the electronic device is located are the same service temperature interval, determining that the heat dissipation speed gear of the heat dissipation part needs to be adjusted currently when the target temperature interval is different from the service temperature interval corresponding to the current heat dissipation speed gear of the heat dissipation part, and otherwise, determining that the heat dissipation speed gear of the heat dissipation part does not need to be adjusted currently.

4. The method of claim 3, wherein for each backlash interval, the starting temperature value of the backlash interval is the ending temperature value of one adjacent traffic temperature interval, and the ending temperature value of the backlash interval is the starting temperature value of another adjacent traffic temperature interval.

5. The method of claim 3, wherein after determining that the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently, or if a target temperature interval determined by N consecutive automatic events currently and a historical temperature interval in which a historical temperature value of the electronic device is located are the same return difference interval or the target temperature interval is the same as a service temperature interval corresponding to the current heat dissipation speed gear of the heat dissipation component, the method further comprises:

deleting the target temperature interval and the historical temperature interval determined by all recorded automatic events;

if at least one temperature interval different from the target temperature interval exists in the historical temperature intervals respectively determined by the N continuous automatic events, the method further comprises the following steps:

and if the historical temperature intervals respectively determined by the current continuous M automatic events in the continuous N automatic events are the same as the target temperature interval, deleting the historical temperature intervals respectively determined by the automatic events before the recorded continuous M automatic events.

6. The method of claim 1, wherein the detecting a manual event related to adjusting a heat dissipation speed stage of the heat dissipation component comprises:

when a scene button configured on a designated interface provided by the electronic equipment is triggered, determining that a manual event related to adjusting a heat dissipation speed gear of the heat dissipation component is detected; the designated interface is an interface which is compiled and used for adjusting the heat dissipation speed gear of the heat dissipation component.

7. The method of claim 1, wherein after adjusting the heat dissipation speed level of the heat dissipation component to the heat dissipation speed level corresponding to the target scene service according to the target scene service, the method further comprises:

prohibiting triggering of a manual event related to adjusting a heat dissipation speed gear of the heat dissipation component if the manual event is detected again within a first specified manual cooling time period thereafter;

wherein the first designated manual cool down time period is determined according to a minimum pacing time interval for adjusting a heat dissipation speed gear of the heat dissipating component based on an automatic event.

8. The method according to claim 1 or 7,

after the heat dissipation speed gear of the heat dissipation component is adjusted to the heat dissipation speed gear corresponding to the target scene service according to the target scene service, the method further includes:

automatically adjusting to the automatic mode after waiting for a preset buffering time;

if the adjusted heat dissipation speed gear is smaller than the heat dissipation speed gear before adjustment, in a preset time period after adjustment to the automatic mode, if it is detected that the heat dissipation speed gear of the heat dissipation part is adjusted to be higher than the heat dissipation speed gear adjusted in the previous manual mode in the automatic mode, then if a manual event related to adjustment of the heat dissipation speed gear of the heat dissipation part is detected again in a second specified manual cooling time period, the manual event is prohibited from being triggered;

wherein the second designated manual cooling time period is determined according to a minimum speed regulation time interval for adjusting a heat dissipation speed gear of the heat dissipation component based on an automatic event.

9. The utility model provides a heat dissipation part speed adjusting device, its characterized in that, the device is applied to electronic equipment, include heat dissipation part and at least one electron device in the electronic equipment at least, heat dissipation part is used for the heat dissipation of at least one electron device, heat dissipation part is provided with a plurality of radiating rate gears, the radiating rate gear has scene business and temperature interval correspondingly, and the device includes:

the execution unit is used for executing a set heat dissipation speed regulation strategy, and the heat dissipation speed regulation strategy comprises the following steps: an automatic mode and a manual mode;

the automatic speed regulating unit is used for executing an automatic mode; the automatic mode includes: when an automatic event for indicating automatic adjustment of the heat dissipation speed gear of the heat dissipation component is detected, determining a target temperature interval where a current temperature value of the electronic device is located from the obtained candidate temperature intervals, determining whether the heat dissipation speed gear of the heat dissipation component needs to be adjusted currently or not according to the target temperature interval and a history temperature interval where a history temperature value of the electronic device is located, and if so, adjusting the heat dissipation speed gear of the heat dissipation component to a target heat dissipation speed gear corresponding to the target temperature interval;

the manual speed regulating unit is used for executing a manual mode; the manual mode includes: when a manual event related to adjusting the heat dissipation speed gear of the heat dissipation part is detected, determining a target scene service to be loaded by the electronic equipment based on the manual event, and adjusting the heat dissipation speed gear of the heat dissipation part to a heat dissipation speed gear corresponding to the target scene service according to the target scene service.

10. An electronic device, comprising: a processor and a memory;

the memory for storing machine executable instructions;

the processor is configured to read and execute the machine executable instructions stored by the memory to implement the method of any one of claims 1 to 8.

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