CN114466577A - Multifunctional data machine room acquisition and control method and equipment - Google Patents

Abstract

The invention discloses a multifunctional data machine room acquisition and control method and equipment, wherein the multifunctional data machine room acquisition and control method comprises the following steps: detecting internal environment parameters in real time after the data cabinet is started, and adjusting by an internal environment adjusting module according to the internal environment parameters; according to the maximum value of the internal environment parameters of the data cabinet and the average shutdown time t_aveDetermining the additional running time t of the internal environment adjusting module after the data cabinet is shut down at this time₁(ii) a The data cabinet is shut down, and the internal environment adjusting module performs additional operation time t according to the instantaneous operation state during shutdown₁(ii) a Wherein the average shutdown time t_aveThe total time length of the n times of shutdown before the data cabinet is powered on at this time is the quotient of the total time length of the n times of shutdown and the number of times of shutdown. The invention effectively solves the problems that when the data cabinet of the data machine room is frequently opened, the adjusting module can not effectively adjust the internal environment of the data cabinet in time and the energy is wasted。

Description

Multifunctional data machine room acquisition and control method and equipment

Technical Field

The invention relates to the technical field of cabinet equipment of a data machine room, in particular to a multifunctional data machine room acquisition and control method and equipment.

Background

At present, with the rapid development of the information industry, the data machine room plays an increasingly important role in the calculation, transmission and storage processes of data information. In the use process of the data machine room, because the server runs at a high speed, a large amount of heat can be emitted, so that a good heat radiation system needs to be provided for the server to reduce the temperature of the server and ensure the normal operation of the server; meanwhile, parameters such as the relative humidity of the environment where the server is located also need to be controlled so as to ensure the safe operation of each data cabinet.

For a frequently opened data cabinet, the temperature of the data cabinet does not return to the normal temperature when the data cabinet is started for the second time, so that the temperature can reach the temperature threshold value more quickly in the operation process, and the heat dissipation module needs time to restart and return to an effective regulation mode, so that heat dissipation cannot be performed in time; similarly, the adjusting modules such as the dehumidification module and the like also need to be restarted for a period of time to effectively play the adjusting effects of dehumidification and the like; in addition, the frequent switching of the adjusting modules such as the heat dissipation module and the dehumidification module causes poor adjusting effect in a short time, and wastes energy.

Disclosure of Invention

Therefore, the invention provides a multifunctional data room acquisition and control method and equipment, which effectively solve the problems that when a data cabinet of a data room is frequently opened, an adjusting module cannot timely and effectively adjust the internal environment of the data cabinet, and energy is wasted.

On one hand, the invention provides a multifunctional data machine room acquisition and control method, which comprises the following steps: detecting internal environment parameters in real time after the data cabinet is started, and adjusting by an internal environment adjusting module according to the internal environment parameters; according to the maximum value of the internal environment parameters of the data cabinet and the average shutdown time t_aveDetermining the additional running time t of the internal environment adjusting module after the data cabinet is shut down at this time₁(ii) a The data cabinet is shut down, and the internal environment adjusting module performs additional operation time t according to the instantaneous operation state during shutdown₁(ii) a Wherein the average shutdown time t_aveThe quotient of the total time length of n times of shutdown before the data cabinet is started up at this time and the shutdown times is obtained; the maximum value of the internal environment parameter refers to the maximum value of the internal environment parameter measured by the data cabinet in a time period from the nth startup to the current startup before the data cabinet is started upA large value; n is the preset shutdown recording times.

The technical effect achieved after the technical scheme is adopted is as follows: detecting the internal environment parameters, and adjusting the internal environment of the data cabinet, so that the working condition of the data cabinet is good, and the data cabinet can stably store, calculate and transmit data; the maximum value of the internal environment parameter reflects the worst possible working condition of the internal environment, and the extra running time t of the internal environment adjusting module after shutdown is determined according to the maximum value of the internal environment parameter₁The situation that parameters such as temperature, relative humidity and the like rise too fast and are difficult to control when the computer is started next time is avoided; the average shutdown time t_aveThe longer the time, the longer the time length of natural heat dissipation of the data cabinet is when the data cabinet is turned off for the previous n times, the closer the internal environment parameters are to the external environment after each turn-on; the average shutdown time t_aveThe shorter the time, the higher the internal environment parameters are reflected in the previous n times of startup, so that the average shutdown time t is used_aveControlling an additional runtime t of the internal environmental conditioning module₁The shutdown time of the data cabinet is predicted, and the internal environment parameters such as the temperature, the relative humidity and the like of the data cabinet are reduced as much as possible before the data cabinet is started, so that the working condition is good when the data cabinet is started next time; when the data cabinet is shut down, the data cabinet is continuously operated in an instant operation state, so that the adjustment mode after the data cabinet is shut down can correspond to the working condition of the instant shutdown, and a better adjustment effect is achieved.

Further, real-time detection internal environment parameter after the data rack is started up, the internal environment adjusting module adjusts according to the operation of the internal environment parameter, including: after the data cabinet is started, detecting a first temperature and a first relative humidity of an internal environment, determining a first target rotating speed of a heat dissipation module according to the first temperature, and determining a first power of a dehumidification module according to the first relative humidity; when the heat dissipation module reaches the first target rotating speed and the dehumidification module reaches the first power, the heat dissipation module and the dehumidification module operate at t time₂Time, detecting internal environment parameters and adjusting the rotation speed of the heat dissipation module and the dehumidification moduleThe power of the block.

The technical effect achieved after the technical scheme is adopted is as follows: the data cabinet determines the adjusting mode of the heat dissipation module through the first temperature, determines the adjusting mode of the dehumidification module through the first relative humidity, and can effectively control the internal environment parameters; the first target rotating speed of the heat dissipation module is determined according to the first temperature, namely the heat dissipation module can dissipate heat through air cooling, and the heat dissipation module can adopt water cooling, oil cooling and other modes; the heat radiation module reaches the first target rotating speed, and the dehumidification module starts to detect and adjust the internal environment parameters at regular time after reaching the first power, namely the time and t for the heat radiation module to reach the first target rotating speed and the time and t for the dehumidification module to reach the first power₂The internal environment parameters are not necessarily the same but adjustable, so that the abnormal internal environment parameters are avoided in the processes of increasing the rotating speed of the heat dissipation module and increasing the power of the dehumidification module after the computer is started.

Further, an additional operation time t of the internal environment adjusting module₁Has a value range of t₁≥t_min(ii) a If t₁=t_minIf the data cabinet is started up this time, the heat dissipation module reaches the first target rotation speed and the dehumidification module reaches the first power rise time t₃=b₁(ii) a If t₁＞t_minJudging the shutdown time length t between the previous shutdown and the current startup of the data cabinet_dWhether or not t is satisfied₁≤t_dIf t is satisfied₁≤t_dThen t is₃=b₂If t is not satisfied₁≤t_dThen according to t_dAnd t_minIs adjusted by the relationship of (1)₃(ii) a Wherein, t_minMinimum extra run length; b₁A first preset value for the boost time; b₂A second predetermined value for the ramp-up time, and b₁≥b₂。

The technical effect achieved after the technical scheme is adopted is as follows: when the heating condition and the relative humidity of the internal environment of the data cabinet are in a low state, the internal environment adjusting moduleBlocks are not additionally run after the data cabinet is shut down, or at a minimum additional run time t_minIn operation, the temperature and relative humidity of the data cabinet are fast enough to reach a state of equilibrium with the external environment, and cannot be raised fast when the data cabinet is restarted; t is t₁＞t_minWhen the internal environment adjusting module is in a normal additional operation state, if t is met at the moment₁≤t_dMeans an additional running time t of the internal environment adjusting module₁After the operation is finished, the data cabinet is started up for a period of time, at the moment, the internal environment parameters of the data cabinet are stabilized at a lower level, and the temperature and the relative humidity of the data cabinet cannot be rapidly increased when the data cabinet is started up again, so that b can be taken₁=b₂Or b₁＞b₂(ii) a If t is not satisfied₁≤t_dThen it means an additional run time t at said internal environment conditioning module₁Midway, the data cabinet is started up, and at this time, the temperature and the relative humidity inside the data cabinet are not completely reduced, and the starting of the internal environment adjusting module needs to be further accelerated when the data cabinet is started up.

Further, if t is not satisfied₁≤t_dThen according to t_dAnd t_minIs adjusted by the relationship of (1)₃The method comprises the following steps: if t_min＜t_d＜t₁Then, then

(ii) a If t_d≤t_min＜t₁Then t is₃=b₃(ii) a Wherein, b₃A third predetermined value for the ramp-up time, and b₂＞b₃。

The technical effect achieved after the technical scheme is adopted is as follows: at this time t_minAs a determination t_dIf the condition is too short, if t is satisfied_min＜t_d＜t₁Then according to t_dAnd t_minRegulating t of the difference₃，t_dAnd t_minThe smaller the difference, the earlier the data cabinet is started for the second time, t₃The shorter, i.e. the internal environment-regulating mouldThe faster the block is started, so that internal environment parameters such as temperature, relative humidity and the like can be quickly reduced when the data cabinet is started for the second time; if t is satisfied_d≤t_min＜t₁The data cabinet is started earlier for the second time, the internal environment adjusting module needs a faster starting speed, but t is started at the moment₃And by adopting a fixed value, the situation that the current passing through the internal environment adjusting module is too large to generate potential safety hazards can be avoided.

Further, the data cabinet is shut down, and the internal environment adjusting module performs an additional operation time t according to the instantaneous operation state during the shutdown₁The method comprises the following steps: when the data cabinet is started, every t₄Recording the instantaneous running state with time, and recording the latest instantaneous running state and the additional running time t before shutdown after the data cabinet is shut down₁。

The technical effect achieved after the technical scheme is adopted is as follows: the instantaneous running state is recorded in real time, so that when the data cabinet is shut down or shut down at any time, the internal environment adjusting module can continuously run in the instantaneous running state, the adjusting mode after the data cabinet is shut down can correspond to the working condition of the instantaneous shutdown, and a better adjusting effect is achieved.

Further, the data cabinet is shut down, and the internal environment adjusting module performs an additional operation time t according to the instantaneous operation state during the shutdown₁The method comprises the following steps: after the data cabinet is shut down, the internal environment adjusting module detects the difference value between the internal environment parameter and the external environment parameter in real time in the operation process, and when the difference value is smaller than the preset environment difference value, the internal environment adjusting module stops working.

The technical effect achieved after the technical scheme is adopted is as follows: if the working condition is good in the starting process, the extra running time t after the shutdown is carried out₁The length is not required to be too long, the internal environment adjusting module is controlled to stop in time when the difference value between the internal environment parameter and the external environment parameter is smaller, and the energy-saving effect can be achieved.

Further, according to the maximum value of the internal environment parameters of the data cabinet and the average shutdown time t_aveDetermining the additional running time t of the internal environment adjusting module after the data cabinet is shut down at this time₁The method comprises the following steps: if t_ave≥c₁，t₁= 0; if c is₂＜t_ave＜c₁，t₁=k₁k₂t₀(ii) a If t_ave≤c₂，t₁=t_max(ii) a Wherein, c₁、c₂Is an average off time threshold, and c₁＞c₂；t₀A first preset additional time; t is t_maxIs the maximum additional time; k is a radical of₁Is a temperature adjustment coefficient; k is a radical of₂Is the relative humidity adjustment coefficient.

The technical effect achieved after the technical scheme is adopted is as follows: the maximum value of the internal environment parameter reflects the worst possible working condition, and the extra running time t of the internal environment adjusting module is adjusted according to the maximum value of the internal environment parameter₁The internal environment parameters can be effectively reduced, so that the internal environment parameters can be more stable when the computer is started next time; average shutdown time t_aveThe duration of the shutdown can be estimated, the more the shutdown time is, the more the residual time of the internal environment parameters balanced with the external environment is after the time that the internal environment module can run additionally is over, and the more the residual time is, the more the additional running time t of the internal environment adjusting module is reduced moderately₁The method not only ensures that the internal environment parameters are lower when the computer is started next time, but also can play a role in energy conservation.

Further, the maximum value of the internal environment parameter comprises a maximum value T of the internal environment temperature₁(ii) a If T₁≥d₁，k₁=e₁(ii) a If d is₂＜T₁＜d₁，k₁= 1; if T₁≤d₂，k₁=e₂(ii) a Wherein d is₁、d₂The maximum value threshold value of the internal environment temperature is set; e.g. of the type₁Is a first temperature coefficient; e.g. of the type₂Is the second temperature coefficient, e₁＞1＞e₂。

The technical effect achieved after the technical scheme is adopted is as follows: according to the internal environment temperatureThe range of the maximum value of degree, adjust k₁The higher the maximum value of the internal environment temperature is, the worse the estimated working condition is when the computer is started next time, so that k is increased₁Extending the extra operating time t₁Further reducing the internal ambient temperature.

Further, the maximum value of the internal environment parameter comprises a maximum value of relative humidity RH of the internal environment; obtaining the maximum value RH of the relative humidity of the internal environment and the temperature T of the internal environment when the maximum value RH of the relative humidity of the internal environment is reached_hAccording to RH and T_hCalculating the dew point temperature T_dAccording to the dew point temperature T_dRegulating the temperature T with a target₂Determining the relative humidity adjustment coefficient k₂(ii) a Wherein the target regulation temperature T₂A preset target temperature for the internal environment.

The technical effect achieved after the technical scheme is adopted is as follows: the lower the relative humidity of the internal environment is, the safer the operation of various electronic elements of the data cabinet is; the maximum RH reflects the maximum RH and the maximum dew point temperature T_dRegulating the temperature T with a target₂Whether the internal environment is in an effective dehumidification state or not can be judged, and if the dehumidification is slow, the additional operation time t during shutdown needs to be further prolonged₁To reduce the relative humidity of the internal environment.

On the other hand, the invention provides a multifunctional data machine room acquisition and control device, which is used for realizing the multifunctional data machine room acquisition and control method provided by any one of the technical schemes.

The technical effect achieved after the technical scheme is adopted is as follows: each data cabinet of the data machine room can execute a multifunctional data machine room acquisition and control method through the multifunctional data machine room acquisition and control equipment to control internal environment parameters, namely, the internal environment adjusting module continuously operates after the data cabinet is shut down, so that the internal environment of the data cabinet is effectively adjusted in time, and the data cabinet has better working conditions when being started next time.

In summary, the above-mentioned aspects of the present applicationThe technical solution may have one or more of the following advantages or benefits: i) the maximum value of the internal environment parameter reflects the worst working condition which is possibly reached by the internal environment, the higher the maximum value of the internal environment temperature is, the worse the working condition when the engine is started next time is estimated, and k is increased at the moment₁Lengthening the additional operating time t₁Further reducing the internal ambient temperature according to the internal ambient temperature T_hObtaining the dew point temperature T from the maximum RH of the relative humidity of the internal environment_d，According to the dew point temperature T at that time_dRegulating the temperature T with a target₂Judging the dehumidification state, if the dehumidification state is poor, increasing k₂Further reducing the relative humidity of the internal environment; ii) according to the additional running time t₁And a minimum extra operating time t_minDetermining whether the temperature and the relative humidity of the data cabinet can be rapidly reduced, thereby determining the first target rotating speed of the heat dissipation module and the first power increasing time t of the dehumidification module after the data cabinet is started₃The power consumption of the heat dissipation module and the dehumidification module can be reduced when the working condition is good; iii) according to t_dAnd t_minIs adjusted by the relationship of (1)₃Further adjust t₃The value of (2) can accelerate the improvement of the heat dissipation effect of the heat dissipation module and the dehumidification effect of the dehumidification module when the data cabinet is started midway in the additional operation time of the internal environment regulation module; iv) recording the instantaneous running state of the external environment adjusting module in real time, and continuously running in the instantaneous running state when the data cabinet is shut down, so that the adjusting mode after the data cabinet is shut down can correspond to the working condition of the instantaneous shutdown, and a better adjusting effect is achieved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a schematic flow chart of a multifunctional data room acquisition and control method according to a first embodiment of the present invention;

FIG. 2 is a flow chart of the multi-functional data room acquisition and control method of FIG. 1;

FIG. 3 is a flowchart of step S11 in FIG. 2;

FIG. 4 is a flowchart of step S2 in FIG. 2;

fig. 5 is a schematic block diagram of a multifunctional data room acquisition and control device according to a second embodiment of the present invention.

Description of the main element symbols:

100 is a multifunctional data machine room acquisition and control device; 10 is a control module; 20 is a heat dissipation module; 30 is a dehumidification module; 40 is a temperature sensor; and 50 is a humidity sensor.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

[ first embodiment ] A method for manufacturing a semiconductor device

Referring to fig. 1-2, a multifunctional data room acquisition and control method according to a first embodiment of the present invention includes:

step S1: detecting internal environment parameters in real time after the data cabinet is started, and adjusting by an internal environment adjusting module according to the internal environment parameters;

step S2: according to the maximum value of the internal environment parameters of the data cabinet and the average shutdown time t_aveDetermining the additional operation time t of the internal environment adjusting module after the shutdown of the data cabinet₁；

Step S3: the data cabinet is shut down, and the internal environment adjusting module additionally runs time t according to the instantaneous running state during shutdown₁；

Wherein, the average shutdown time t_aveThe quotient of the total time length of n times of shutdown before the data cabinet is started up at this time and the shutdown times is obtained; the maximum value of the internal environment parameter refers to the maximum value of the internal environment parameter measured by the data cabinet in the time period from the nth startup to the current startup before the data cabinet is started up; n is the preset shutdown recording times.

In this embodiment, the maximum value of the internal environment parameter, for example the maximum value of the internal environment temperature T, is recorded₁And the internal environment relative humidity maximum value RH can reflect the worst working condition reached by the internal environment, so that the worst possible working condition reached by the next starting can be estimated, the internal environment parameters are adjusted in advance through the additional operation of the internal environment adjusting module during the previous shutdown or shutdown, even if the shutdown time before the next starting is shorter, the working condition at the next starting is good, and the temperature and the relative humidity of the internal environment are not easy to rise rapidly, so that the control is easier; and detects the average off time t_aveThe time of shutdown can be estimated, so that the additional running time t of the internal environment adjusting module can be further adjusted₁Average shutdown time t_aveThe longer the extra operation time t of the internal environment adjusting module is shortened₁The energy-saving effect is achieved; when the data cabinet is shut down, the data cabinet is continuously operated in an instantaneous operation state, so that the adjustment mode after the data cabinet is shut down can correspond to the working condition of the shutdown, and a better adjustment effect is achieved.

In a specific embodiment, in step S1, the internal environment parameters include, for example, an internal environment temperature, an internal environment humidity, and the like, and the internal environment conditioning module includes, for example, the heat dissipation module 20 and the dehumidification module 30. The internal environment temperature may be measured by the temperature sensors 40 disposed in the data cabinet, for example, an average value of a plurality of temperature sensors 40 uniformly distributed in the data cabinet, or an average value of a plurality of temperature sensors 40 of any electronic component centrally distributed in the data cabinet, and the heat dissipation module 20 may adopt air cooling, water cooling, oil cooling, and the like, which is not limited herein; the internal environment humidity can be measured by the humidity sensor 50 disposed at any position of the data cabinet, and the dehumidifying module 30 can adopt cooling and dehumidifying, physical adsorption dehumidifying or chemical dehumidifying, and the like, which is not limited herein.

Preferably, the heat dissipation module 20 may be air-cooled and dissipated by a fan. Wherein, step S1: data rack real-time detection internal environment parameter after the start, internal environment adjusting module adjusts according to the operation of internal environment parameter, for example includes:

step S11: after the data cabinet is started, detecting a first temperature and a first relative humidity of an internal environment, determining a first target rotating speed of the heat dissipation module 20 according to the first temperature, and determining a first power of the dehumidification module 30 according to the first relative humidity;

step S12: when the heat dissipation module 20 reaches the first target rotation speed and the dehumidification module 30 reaches the first power, the heat dissipation module 20 and the dehumidification module 30 operate at t times₂And time, sensing internal environmental parameters and adjusting the rotation speed of the heat dissipation module 20 and the power of the dehumidification module 30.

It should be noted that the internal environment adjusting module has an additional running time t before the data cabinet is powered on₁On the basis, the internal environment of the data cabinet can be further monitored by detecting the first temperature and the first relative humidity, the data cabinet determines the adjusting mode of the heat dissipation module 20 through the first temperature, determines the adjusting mode of the dehumidification module 30 through the first relative humidity, and can effectively control the internal environment parameters; and with t₂The time is detected in real time, the internal environment temperature and the internal environment humidity are adjusted, and the effects of safety and energy saving can be achieved.

Preferably, the timing detection and the adjustment of the internal environment parameters are started only when the heat dissipation module 20 reaches the first target rotation speed and the dehumidification module 30 reaches the first power, that is, the heat dissipation module 20 reaches the first target rotation speed and the dehumidification module 30 reaches the rise time t of the first power₃Is adjustable, so as to avoid the abnormal internal environmental parameters caused by the slow increase of the rotation speed of the heat dissipation module 20 or the insufficient dehumidification effect of the dehumidification module 30 after the start-up.

Preferably, t is₂For example, 1 to 5min, which is not limited herein.

Further, the target regulation temperature T₂Target regulation for preset target temperature of internal environmentTemperature T₂Either a constant value or a temperature range. Data cabinet every t₂Time detecting the internal ambient temperature if the internal ambient temperature exceeds T₂Cooling is performed if the internal ambient temperature is lower than T₂The rotation speed of the heat dissipation module 20 is maintained or reduced.

Still further, the target adjusts the relative humidity RH₁Presetting a target relative humidity for the internal environment, target adjusting relative humidity RH₁Or may be constant or relative humidity range. Data cabinet every t₂Time detecting internal ambient humidity, if the internal ambient humidity exceeds RH₁Then dehumidification is carried out, if the internal environment humidity is lower than RH₁The current dehumidification intensity is maintained.

In a specific embodiment, see FIG. 3, the additional runtime t of the internal environment adjustment module₁Has a value range of t₁≥t_min(ii) a Wherein, t_minIs the minimum additional run time. When the maximum value of the internal environment parameter and the average shutdown time t_aveWhen the condition is met, the internal environment adjusting module is at least t_minWhen the internal environment parameter is maximum or the average shutdown time t_aveWhen the condition is not met, the internal environment adjusting module does not operate. For example, t_minE.g. 1 to 5min, of course t_minThe setting may be performed according to the actual use frequency or the normal shutdown time of the data cabinet, which is not limited herein.

It should be noted that, if the internal environment of the data cabinet is in a low state, the temperature and the relative humidity of the data cabinet are fast enough to reach a state of equilibrium with the external environment, and the temperature and the relative humidity do not rise fast enough when the data cabinet is powered on again, so that the additional running time t of the internal environment adjusting module is increased₁Take the minimum extra operating time t_minI.e. t₁=t_minOr the internal environment adjusting module does not operate additionally after the data cabinet is shut down.

Further, if t₁=t_minThen, the heat dissipation module 20 reaches the first target rotation speed and the dehumidification module after the data cabinet is started up at this timeBlock 30 reaches the boost time t of the first power₃=b₁(ii) a If t₁＞t_minJudging the shutdown time length t between the previous shutdown and the current startup of the data cabinet_dWhether or not t is satisfied₁≤t_dIf t is satisfied₁≤t_dThen t is₃=b₂If t is not satisfied₁≤t_dThen according to t_dAnd t_minIs adjusted by the relationship of (1)₃(ii) a Wherein, t_minMinimum extra run length; b₁A first preset value for the boost time; b₂A second predetermined value for the ramp-up time, and b₁≥b₂。

Note that t is₁＞t_minIn the meantime, the internal environment adjusting module is in an additional operating state, and if t is satisfied at this time₁≤t_dMeaning an additional run time t of the internal environment conditioning module₁After the completion, the internal environment adjusting module stops working for a period of time, the data cabinet is started, the internal environment parameters of the data cabinet are stabilized at a lower level, and the temperature and the relative humidity of the data cabinet cannot be rapidly increased when the data cabinet is started again, so that the rotating speed of the heat dissipation module 20 and the power of the dehumidification module 30 do not need to be rapidly increased in a short time, and b can be selected₁=b₂Or b₁＞b₂(ii) a If t is not satisfied₁≤t_dThen, an additional running time t of the internal environment adjustment module is implied₁Midway, the data rack starts up, and the inside temperature and the relative humidity of data rack do not reduce completely this moment, need further accelerate the start-up of internal environment adjusting module when starting up.

In one embodiment, if t is not satisfied₁≤t_dThen according to t_dAnd t_minIs adjusted by the relationship of (1)₃The method comprises the following steps: if t_min＜t_d＜t₁Then, then

(ii) a If t_d≤t_min＜t₁Then t is₃=b₃(ii) a Wherein, b₃To increase the timeA preset value, and b₂＞b₃。

Note that, at this time, t_minAs a determination t_dIf the condition is too short, if t is satisfied_min＜t_d＜t₁Then according to t_dAnd t_minRegulating t of the difference₃，t_dAnd t_minThe smaller the difference, the earlier the data enclosure is started for the second time, t₃The shorter the time, the faster the internal environment adjusting module is started, so that the internal environment parameters such as temperature, relative humidity and the like are quickly reduced when the data cabinet is started for the second time; if t is satisfied_d≤t_min＜t₁The second start of the data cabinet is earlier, the internal environment adjusting module needs a faster start speed, but t is the time t₃Using a fixed value, i.e. a third preset value b of the time to be increased₃As the shortest starting time of the internal environment adjusting module, the current passing through the heat dissipation module 20 or the dehumidification module 30 can be prevented from being too large, thereby generating potential safety hazards.

In one embodiment, the data enclosure is powered down and the internal environment conditioning module performs an additional run time t based on the instantaneous run state of the data enclosure during the power down₁Examples include:

step S31: when the data cabinet is started, every t₄Recording the instantaneous running state with time, and recording the latest instantaneous running state before shutdown and the additional running time t after shutdown of the data cabinet₁。

It should be noted that, when the data cabinet is started up, as stated in step S1, the internal environment adjusting module always performs adjustment according to the operation of the internal environment parameters, and the instantaneous operation state recorded in real time can correspond to the current internal environment parameters. When the data rack is shut down or shut down at any time, the internal environment adjusting module can continuously operate in an instant operation state, so that the adjusting mode after the data rack is shut down can correspond to the working condition of the shutdown, after the data rack is shut down, the rotating speed of the heat radiating module 20 and the power of the dehumidifying module 30 cannot be too high to cause energy waste, and the adjusting effect cannot be too low to cause poor adjustment.

Preferably, t is₄Can be obtained byt₂Same, i.e. data cabinets every t₂Time real-time detection and regulation inside environment temperature, inside environment humidity, the running state of record thermal module 20 and initial module simultaneously, the continuous operation of thermal module 20 and initial module after the shutdown of data rack of being convenient for.

In one embodiment, the data enclosure is powered down and the internal environment conditioning module provides an additional operating time t based on the instantaneous operating state at the time of power down₁Examples of the method further include:

step S32: after the data cabinet is shut down, the internal environment adjusting module detects the difference value between the internal environment parameter and the external environment parameter in real time in the operation process, and stops working when the difference value is smaller than the preset environment difference value.

It should be noted that, if the difference between the internal environment parameter and the external environment parameter is small, the working condition is good in the process of starting up this time, and the additional running time t after shutdown is₁And the difference value is not required to be too long, so that the internal environment adjusting module is controlled to stop running in time when the difference value is smaller, and the energy-saving effect can be achieved.

In one specific embodiment, referring to FIG. 4, the internal environment parameter maximum and the average shutdown time t of the data enclosure are determined according to_aveDetermining the additional operation time t of the internal environment adjusting module after the shutdown of the data cabinet₁The method comprises the following steps: if t_ave≥c₁，t₁= 0; if c is₂＜t_ave＜c₁，t₁=k₁k₂t₀(ii) a If t_ave≤c₂，t₁=t_max(ii) a Wherein, c₁、c₂Is an average off time threshold, and c₁＞c₂；t₀A first preset additional time; t is t_maxIs the maximum additional time; k is a radical of₁Is a temperature adjustment coefficient; k is a radical of formula₂Is the relative humidity adjustment coefficient.

Wherein the additional running time t of the internal environment adjusting module is adjusted according to the maximum value of the internal environment parameter₁The internal environment parameters can be effectively reduced, and even if the working condition of the data cabinet is poor when the data cabinet is started next time, the data isThe cabinet can also stably operate; average shutdown time t_aveThe duration of the shutdown can be estimated, the more the shutdown time is, the more the residual time of the internal environment parameters balanced with the external environment is after the time that the internal environment module can run additionally is finished, and the more the residual time is, the additional running time t of the internal environment adjusting module is properly reduced₁The method not only ensures that the internal environment parameters are lower when the computer is started next time, but also can play a role in energy conservation.

It should be noted that: and in the process of starting the data cabinet, recording the internal environment parameters in real time and comparing the internal environment parameters so as to determine the maximum value of the recorded internal environment parameters, and directly reading the internal environment parameters when the data cabinet is shut down.

Preferably, the average off time t_aveThe average number of the data left after the longest shutdown time in n startup can be selected, so that the average shutdown time t caused by long-time nonuse of the data cabinet is avoided_aveAn error is generated. Wherein n is, for example, 3 to 10, and when the number of times of starting up the data cabinet is less than n, the average time t of shutdown is_aveThe time of the last shutdown is taken.

In a specific embodiment, the maximum value of the internal environment parameter comprises a maximum value of the internal environment temperature T₁(ii) a If T₁≥d₁，k₁=e₁(ii) a If d is₂＜T₁＜d₁，k₁= 1; if T₁≤d₂，k₁=e₂(ii) a Wherein d is₁、d₂The maximum value threshold value of the internal environment temperature is set; e.g. of the type₁Is a first temperature coefficient; e.g. of the type₂Is the second temperature coefficient, e₁＞1＞e₂. For example, e₁=1.2，e₂And =0.8, which is not limited herein.

Wherein k is adjusted according to the range of the maximum value of the internal environment temperature₁The higher the maximum value of the internal environment temperature is, the worse the estimated working condition is when the computer is started next time, so that k is increased₁Extending the extra operating time t₁Further reducing the internal ambient temperature.

In a specific embodiment, the internal environment parameter maximum comprises an internal environment relative humidity maximum RH; obtaining the maximum RH and the temperature T of the internal environment when the maximum RH is reached_hAccording to RH and T_hCalculating the dew point temperature T_dAccording to the dew point temperature T_dRegulating the temperature T with a target₂Determining the relative humidity adjustment coefficient k₂. The lower the relative humidity of the internal environment is, the safer the operation of various electronic elements of the data cabinet is; the maximum RH reflects the maximum RH and the maximum dew point temperature T_dRegulating the temperature T with a target₂Whether the internal environment is in an effective dehumidification state can be judged.

For example, when the target adjusts the temperature T₂At or above dew point temperature T_dIn time, the internal ambient humidity is difficult to reduce, so when the data cabinet is shut down or shut down, further dehumidification is required, k₂For example, 1.2; when the target adjusts the temperature T₂Less than dew point temperature T_dThe dehumidification module 30 can effectively dehumidify k₂For example, 1, and is not limited herein.

Preferably, t is_maxA value of (a) is greater than or equal to k₁、k₂When the maximum value t is reached₁Is taken as the average shutdown time t_maxThe smaller the internal environment conditioning module is, the less time the data cabinet can naturally dissipate heat after shutdown, thus extending the additional operating time t of the internal environment conditioning module₁The effective heat dissipation of data rack is favorable to.

[ second embodiment ]

Referring to fig. 5, a second embodiment of the present invention provides a multifunctional data room acquisition and control device 100, where the multifunctional data room acquisition and control device 100 is used to implement the multifunctional data room acquisition and control method provided in any of the above embodiments. The multifunctional data room acquisition and control device 100 includes a control module 10, and at least one heat dissipation module 20, a dehumidification module 30, a temperature sensor 40, and a humidity sensor 50.

In a particular embodimentIn an embodiment, the control module 10 controls the operation of the heat dissipation module 20 and the dehumidification module 30 according to the internal ambient temperature and the internal ambient humidity detected by the temperature sensor 40 and the humidity sensor 50; at the same time, the control module 10 records the maximum value of the internal environment parameter and/or the average shutdown time t_aveThe heat dissipation module 20 and the dehumidification module 30 are controlled to continuously operate after the data cabinet is powered off, so that the internal environment of the data cabinet can be effectively adjusted in time, and the data cabinet has better working conditions when being powered on next time.

Further, the control module 10 adjusts the additional run time t of the module according to the internal environment₁And shutdown time t_dObtaining the time t for the heat dissipation module 20 to reach the first target speed and the dehumidification module 30 to reach the first power after the startup₃Therefore, the rotation speed of the heat dissipation module 20 and the power of the dehumidification module 30 are further increased, the internal environment during startup is timely adjusted, and the data cabinet can stably run even when being frequently opened.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (10)

1. A multifunctional data machine room acquisition and control method is characterized by comprising the following steps:

detecting internal environment parameters in real time after the data cabinet is started, and adjusting by an internal environment adjusting module according to the internal environment parameters;

according to the maximum value of the internal environment parameters of the data cabinet and the average shutdown time t_aveDetermining the additional running time t of the internal environment adjusting module after the data cabinet is shut down at this time₁；

The data enclosure is powered off and the power supply is turned off,the internal environment adjusting module additionally runs time t according to the instantaneous running state during shutdown₁；

Wherein the average shutdown time t_aveThe quotient of the total time length of n times of shutdown before the data cabinet is started up at this time and the shutdown times is obtained; the maximum value of the internal environment parameter refers to the maximum value of the internal environment parameter measured by the data cabinet in a time period from the nth startup to the current startup before the data cabinet is started up; n is the preset shutdown recording times.

2. The method as claimed in claim 1, wherein the step of detecting internal environment parameters in real time after the data cabinet is powered on, and the step of adjusting the internal environment adjusting module according to the internal environment parameters comprises:

after the data cabinet is started, detecting a first temperature and a first relative humidity of an internal environment, determining a first target rotating speed of a heat dissipation module according to the first temperature, and determining a first power of a dehumidification module according to the first relative humidity;

when the heat dissipation module reaches the first target rotating speed and the dehumidification module reaches the first power, the heat dissipation module and the dehumidification module operate at t time₂And detecting the internal environment parameters and adjusting the rotating speed of the heat dissipation module and the power of the dehumidification module.

3. The multifunctional data room acquisition and control method according to claim 2, wherein the additional running time t of the internal environment adjusting module₁Has a value range of t₁≥t_min；

If t₁=t_minIf the data cabinet is started up this time, the heat dissipation module reaches the first target rotation speed and the dehumidification module reaches the first power rise time t₃=b₁；

If t₁＞t_minJudging the shutdown of the data cabinet from the previous shutdown to the current startupDuration t_dWhether or not t is satisfied₁≤t_dIf t is satisfied₁≤t_dThen t is₃=b₂If t is not satisfied₁≤t_dThen according to t_dAnd t_minIs adjusted by the relationship of (1)₃；

Wherein, t_minMinimum extra run length; b₁A first preset value for the boost time; b₂A second predetermined value for the ramp-up time, and b₁≥b₂。

4. The method according to claim 3, wherein if t is not satisfied, the method further comprises₁≤t_dThen according to t_dAnd t_minIs adjusted by the relationship of (1)₃The method comprises the following steps:

if t_min＜t_d＜t₁Then, then

；

If t_d≤t_min＜t₁Then t is₃=b₃；

Wherein, b₃A third predetermined value for the ramp-up time, and b₂＞b₃。

5. The method as claimed in claim 1, wherein the data cabinet is powered off, and the internal environment adjusting module is additionally operated for a time t according to an instantaneous operation state of the data cabinet during power off₁The method comprises the following steps:

when the data cabinet is started, every t₄Recording the instantaneous running state by time, and recording the latest additional running time t of the instantaneous running state before shutdown after the data cabinet is shut down₁。

6. The method as claimed in claim 1, wherein the data cabinet is powered off, and the internal environment adjusting module is configured to adjust the internal environment according to the power offInstantaneous operating state additional operating time t₁The method comprises the following steps:

after the data cabinet is shut down, the internal environment adjusting module detects the difference value between the internal environment parameter and the external environment parameter in real time in the operation process, and when the difference value is smaller than the preset environment difference value, the internal environment adjusting module stops working.

7. The multifunctional data room acquisition and control method according to any one of claims 1 to 6, characterized in that the maximum value of the internal environment parameters of the data cabinet and the average shutdown time t are determined according to the maximum value_aveDetermining the additional running time t of the internal environment adjusting module after the data cabinet is shut down at this time₁The method comprises the following steps:

if t_ave≥c₁，t₁=0；

If c is₂＜t_ave＜c₁，t₁=k₁k₂t₀；

If t_ave≤c₂，t₁=t_max；

Wherein, c₁、c₂Is an average off time threshold, and c₁＞c₂；t₀A first preset additional time; t is t_maxIs the maximum additional time; k is a radical of₁Is a temperature adjustment coefficient; k is a radical of₂Is the relative humidity adjustment coefficient.

8. The multifunctional data room acquisition and control method according to claim 7, wherein the maximum value of the internal environment parameter comprises a maximum value T of the internal environment temperature₁；

If T₁≥d₁，k₁=e₁；

If d is₂＜T₁＜d₁，k₁=1；

If T₁≤d₂，k₁=e₂；

Wherein d is₁、d₂The maximum value threshold value of the internal environment temperature is set; e.g. of the type₁Is at a first temperatureA coefficient; e.g. of the type₂Is the second temperature coefficient, e₁＞1＞e₂。

9. The multifunctional data room acquisition and control method according to claim 7, wherein the maximum value of the internal environment parameter comprises a maximum value of internal environment relative humidity RH;

obtaining the maximum value RH of the relative humidity of the internal environment and the temperature T of the internal environment when the maximum value RH of the relative humidity of the internal environment is reached_hAccording to RH and T_hCalculating the dew point temperature T_dAccording to the dew point temperature T_dRegulating the temperature T with a target₂Determining the relative humidity adjustment coefficient k₂；

Wherein the target regulation temperature T₂A preset target temperature for the internal environment.

10. A multifunctional data machine room acquisition and control device, characterized in that the multifunctional data machine room acquisition and control device is used for implementing the multifunctional data machine room acquisition and control method as claimed in any one of claims 1 to 9.

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