CN114679900B - Outdoor intelligent oil well control cabinet convenient for heat dissipation and cooling - Google Patents
Outdoor intelligent oil well control cabinet convenient for heat dissipation and cooling Download PDFInfo
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- CN114679900B CN114679900B CN202210437670.4A CN202210437670A CN114679900B CN 114679900 B CN114679900 B CN 114679900B CN 202210437670 A CN202210437670 A CN 202210437670A CN 114679900 B CN114679900 B CN 114679900B
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K7/00—Constructional details common to different types of electric apparatus
- H05K7/20—Modifications to facilitate cooling, ventilating, or heating
- H05K7/20009—Modifications to facilitate cooling, ventilating, or heating using a gaseous coolant in electronic enclosures
- H05K7/20209—Thermal management, e.g. fan control
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K7/00—Constructional details common to different types of electric apparatus
- H05K7/20—Modifications to facilitate cooling, ventilating, or heating
- H05K7/20009—Modifications to facilitate cooling, ventilating, or heating using a gaseous coolant in electronic enclosures
- H05K7/20127—Natural convection
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K7/00—Constructional details common to different types of electric apparatus
- H05K7/20—Modifications to facilitate cooling, ventilating, or heating
- H05K7/20009—Modifications to facilitate cooling, ventilating, or heating using a gaseous coolant in electronic enclosures
- H05K7/20136—Forced ventilation, e.g. by fans
- H05K7/20145—Means for directing air flow, e.g. ducts, deflectors, plenum or guides
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K7/00—Constructional details common to different types of electric apparatus
- H05K7/20—Modifications to facilitate cooling, ventilating, or heating
- H05K7/2029—Modifications to facilitate cooling, ventilating, or heating using a liquid coolant with phase change in electronic enclosures
- H05K7/20309—Evaporators
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05K—PRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
- H05K7/00—Constructional details common to different types of electric apparatus
- H05K7/20—Modifications to facilitate cooling, ventilating, or heating
- H05K7/2029—Modifications to facilitate cooling, ventilating, or heating using a liquid coolant with phase change in electronic enclosures
- H05K7/20381—Thermal management, e.g. evaporation control
Abstract
The invention discloses an outdoor intelligent oil well control cabinet convenient for heat dissipation and cooling, which belongs to the technical field of intelligent oil well control cabinet cooling and comprises a cooling module, a control module, a cooperative module and a server; an intelligent oil well control cabinet model is arranged in the control module; the cooling module is used for radiating and cooling the intelligent oil well control cabinet, acquiring a water cooling scheme, and arranging a water cooling device in the intelligent oil well control cabinet according to the water cooling scheme; acquiring the temperature in an intelligent oil well control cabinet in real time, wherein the temperature is marked as T1, the specific heat of liquid refrigerant in a water cooling device is acquired, the temperature of each heating structure is marked as Cp, the total heating value of the heating mechanism is calculated, the evaporation latent heat of the liquid refrigerant is acquired, the water supply quantity is acquired according to a formula and the temperature is reduced according to the acquired water supply quantity, and the mark is marked as Q; through setting up cooling module, realize that each heating structure in the intelligent oil well switch board is cooled down to the pertinence.
Description
Technical Field
The invention belongs to the technical field of intelligent oil well control cabinet cooling, and particularly relates to an outdoor intelligent oil well control cabinet convenient for heat dissipation and cooling.
Background
The oil well control cabinet is control equipment for ensuring safe production of oil wells, generally, the reliable operation temperature of the oil well control cabinet applied to each oil field is lower, but in summer high-temperature weather, the temperature of the existing control cabinet can reach more than 85 ℃ due to poor heat dissipation, overheat protection is often caused to stop, normal operation of equipment such as a controller is influenced, the failure rate of the equipment such as the controller is often obviously increased due to overhigh temperature, and the control cabinet is required to cool in order to ensure the reliable operation of the equipment in the control cabinet in summer high-temperature weather; therefore, the invention provides an outdoor intelligent oil well control cabinet which is convenient for heat dissipation and temperature reduction, and is used for solving the problems.
Disclosure of Invention
In order to solve the problems of the scheme, the invention provides an outdoor intelligent oil well control cabinet convenient for heat dissipation and temperature reduction.
The aim of the invention can be achieved by the following technical scheme:
an outdoor intelligent oil well control cabinet convenient for heat dissipation and temperature reduction comprises a cooling module, a control module, a coordination module and a server;
an intelligent oil well control cabinet model is arranged in the control module;
the cooling module is used for radiating and cooling the intelligent oil well control cabinet, acquiring a water cooling scheme, and arranging a water cooling device in the intelligent oil well control cabinet according to the water cooling scheme; acquiring the temperature in an intelligent oil well control cabinet in real time, marking as T1, acquiring the specific heat of liquid refrigerant in a water cooling device, marking as Cp, acquiring the temperature of each heating structure, calculating the total heating value of the heating structures, marking as Q, acquiring the evaporation latent heat of the liquid refrigerant, marking as r, acquiring the water supply quantity according to the formula BW=Q/[ lambda X Cp X b 1X (T1-T2) +b2X r ], and cooling according to the acquired water supply quantity;
the collaborative module is used for carrying out collaborative cooling based on the cooling module, setting and installing the air duct plate, setting an air cooling model, carrying out air cooling simulation according to the air cooling model, obtaining a plurality of groups of air cooling schemes, and identifying ventilation combinations in the air cooling schemes; acquiring a temperature interval of a heating structure in the intelligent oil well control cabinet from historical data, dividing and correlating the temperature interval with a ventilation combination, and establishing an air cooling temperature scheme table; the temperature of each heating structure in the intelligent oil well control cabinet is obtained in real time, the obtained temperature of each heating structure is input into an air cooling temperature scheme table, the corresponding air cooling scheme is matched, and the obtained air cooling scheme is used for carrying out cooperative cooling.
Further, T2 is the temperature of the makeup water, b1 and b2 are both proportionality coefficients, the value range is 0< b1<2,0< b2<1, lambda is a correction factor, and the value range is 0< lambda less than or equal to 1.
Further, the method for setting the intelligent oil well control cabinet model comprises the following steps:
acquiring an intelligent oil well control cabinet design diagram, establishing a control cabinet three-dimensional model according to the acquired intelligent oil well control cabinet design diagram, identifying a heating structure in the intelligent oil well control cabinet, performing heating grading on the heating structure, marking a corresponding heating structure model in the control cabinet three-dimensional model, marking a corresponding heating grading label, establishing a space coordinate system, and marking the current control cabinet three-dimensional model as the intelligent oil well control cabinet model.
Further, the method for obtaining the water cooling scheme comprises the following steps:
acquiring an intelligent oil well control cabinet model, acquiring a coordinate area and a heating level of a heating structure model in the intelligent oil well control cabinet model, identifying a mounting area in the intelligent oil well control cabinet model, and integrating the heating structure model coordinate area and the mounting area into a mounting model; and establishing a water cooling scheme library, and matching the water cooling scheme from the water cooling scheme library according to the installation model.
Further, the method for establishing the water cooling scheme library comprises the following steps:
the method comprises the steps of obtaining an existing intelligent oil well control cabinet and a corresponding water cooling scheme, marking the intelligent oil well control cabinet as a reference control cabinet, establishing a reference installation model in the reference control cabinet, establishing a first database, inputting the reference installation model and the corresponding water cooling scheme into the first database for storage, and marking the first database as a water cooling scheme library.
Further, the method for matching the water cooling scheme from the water cooling scheme library according to the installation model comprises the following steps:
marking an installation model as i, marking a reference installation model in a water cooling scheme library as i, wherein i=1, 2, … … and n, and n is a positive integer; marking a heating structure model coordinate area in a reference installation model as j, j=1, 2, … … and m, wherein m is a positive integer;
establishing a similarity model, and performing calculation on a heating structure model coordinate area in the installation model and a heating structure model coordinate area in the reference installation modelIn association, calculating a similarity value of a heating structure model coordinate region in the installation model and a heating structure model coordinate region in the reference installation model through a similarity model, and marking the similarity value as hij according to a formulaObtaining a matching degree value of the installation model and a reference installation model;
and sequencing according to the matching degree values, marking a reference installation model with the highest matching degree value and the water cooling scheme which does not exceed the installation area of the installation model as a target model, and obtaining the water cooling scheme corresponding to the target model.
Further, fij is a heating level of a heating structure model in a reference installation model, and F is a heating level of a heating structure model corresponding to fij in the installation model; alpha j is an adjusting coefficient, and the value range is [0,1].
Further, the method for setting and installing the air duct board comprises the following steps:
obtaining an installation model from a cooling module, supplementing the installation model according to a water cooling scheme, marking the supplemented installation model as a water cooling model, arranging a cooperative device in an intelligent oil well control cabinet, and arranging the cooperative device in the water cooling model;
and establishing an air duct model, analyzing the water-cooling model through the air duct model, obtaining the installation position of the air duct plate on the intelligent oil well control cabinet, the number of ventilation holes on the air duct plate and the distribution of corresponding ventilation holes, setting the air duct plate according to the number of the ventilation holes and the distribution of the ventilation holes, and installing the set air duct plate according to the installation position on the intelligent oil well control cabinet.
Compared with the prior art, the invention has the beneficial effects that:
by arranging the cooling module, each heating structure in the intelligent oil well control cabinet is cooled in a targeted manner, so that the intelligent oil well control cabinet is ensured to work in a normal temperature environment, and faults caused by overhigh temperature are avoided; the intelligent oil well control cabinet is matched with the cooling module by arranging the cooperation module, and the cooling of the intelligent oil well control cabinet is accelerated by using cool air generated by the cooling module; and through setting up different forced air cooling schemes according to different temperatures, make full use of wind channel board and cooperative device realize according to the temperature of different heating structures and adjust inside air flow, realize heating structure's rapid cooling.
Drawings
In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings can be obtained according to these drawings without inventive effort to a person skilled in the art.
Fig. 1 is a functional block diagram of the present invention.
Description of the embodiments
The technical solutions of the present invention will be clearly and completely described in connection with the embodiments, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.
As shown in FIG. 1, an outdoor intelligent oil well control cabinet convenient for heat dissipation and temperature reduction comprises an air duct plate, a cooling module, a control module, a coordination module and a server;
the air duct plate is arranged on the intelligent oil well control cabinet and is used for carrying out internal and external ventilation of the intelligent oil well control cabinet, a plurality of ventilation holes are distributed on the air duct plate, the ventilation holes can be automatically closed according to the needs, namely, the opening and closing of the ventilation holes are controlled by a system, and the quantity of the ventilation holes on the air duct plate and the distribution of the corresponding ventilation holes are arranged according to the cooperative modules;
an intelligent oil well control cabinet model is arranged in the control module;
the method for setting the intelligent oil well control cabinet model comprises the following steps:
acquiring an intelligent oil well control cabinet design diagram, establishing a control cabinet three-dimensional model according to the acquired intelligent oil well control cabinet design diagram, identifying a heating structure in the intelligent oil well control cabinet, performing heating grading on the heating structure, marking a corresponding heating structure model in the control cabinet three-dimensional model, marking a corresponding heating grading label, establishing a space coordinate system, and marking the current control cabinet three-dimensional model as the intelligent oil well control cabinet model.
The heating and grading of the heating structure is mainly carried out according to the heating value of the heating structure in the operation process, and the heating and grading can be set by the expert group discussion and can also be set according to the design description.
The cooling module is used for heat dissipation and cooling of the intelligent oil well control cabinet, and the specific method comprises the following steps:
acquiring a water cooling scheme, and arranging a water cooling device in the intelligent oil well control cabinet according to the water cooling scheme; acquiring the temperature in an intelligent oil well control cabinet in real time, marking as T1, acquiring the specific heat of liquid refrigerant in a water cooling device, marking as Cp, acquiring the temperature of each heating structure, calculating the total heating value of the heating structures, marking as Q, acquiring the evaporation latent heat of the liquid refrigerant, marking as r, and acquiring the water supply quantity according to the formula BW=Q/[ lambda X Cp X1X (T1-T2) +b2X r ], wherein T2 is the temperature of the water supply, b1 and b2 are both proportionality coefficients, the value range is 0< b1<2,0< b2<1, lambda is a correction factor, and the value range is 0< lambda less than or equal to 1; and cooling according to the obtained water supply quantity.
The method for calculating the total heating value of the heating structure is to make the heating value corresponding to each temperature of the heating structure by an expert group in advance, and then match the heating value to the corresponding heating value according to the collected temperature.
The method for arranging the water cooling device in the intelligent oil well control cabinet according to the water cooling scheme is that the water cooling scheme is sent to corresponding designers, and the designers can adjust the water cooling scheme according to the actual installation environment, so that the water cooling scheme is more in line with the additional installation of the existing intelligent oil well control cabinet.
The method for obtaining the water cooling scheme comprises the following steps:
acquiring an intelligent oil well control cabinet model, acquiring a coordinate region and a heating level of a heating structure model in the intelligent oil well control cabinet model, and identifying an installation region in the intelligent oil well control cabinet model, wherein the installation region refers to a region in which a water cooling device can be installed in the intelligent oil well control cabinet; integrating the coordinate area and the installation area of the heating structure model into an installation model; and establishing a water cooling scheme library, and matching the water cooling scheme from the water cooling scheme library according to the installation model.
The method for establishing the water cooling scheme library comprises the following steps:
the existing intelligent oil well control cabinet and a corresponding water cooling scheme are obtained, the water cooling effect is not ideal and is removed, and the intelligent oil well control cabinet is not obtained; the method comprises the steps of marking a reference control cabinet, establishing a reference installation model in the reference control cabinet, establishing a first database, inputting the reference installation model and a corresponding water cooling scheme into the first database for storage, and marking the first database as a water cooling scheme library.
The method for matching the water cooling scheme from the water cooling scheme library according to the installation model comprises the following steps:
marking an installation model as i, marking a reference installation model in a water cooling scheme library as i, wherein i=1, 2, … … and n, and n is a positive integer; marking a heating structure model coordinate area in a reference installation model as j, j=1, 2, … … and m, wherein m is a positive integer;
establishing a similarity model, associating a heating structure model coordinate region in the calculated installation model with a heating structure model coordinate region in the reference installation model, calculating a similarity value of the heating structure model coordinate region in the installation model and the heating structure model coordinate region in the reference installation model through the similarity model, and marking the similarity value as hij, wherein H23 represents the similarity of the installation model and a corresponding heating structure model coordinate region with the reference installation model with the reference number of 2 and the reference installation model with the reference number of 3; according to the formulaObtaining a matching degree value of the installation model and the reference installation model, wherein fij is the heating grading of the heating structure model in the reference installation model, and F is the heating grading of the heating structure model corresponding to fij in the installation model; alpha j is an adjusting coefficient, and the value range is [0,1];
The adjustment coefficient alpha j can generate random numbers within a specified range, namely [0,1], and then optimize the coefficient through a genetic algorithm; the coefficient and the initial value are optimized through a genetic algorithm, and iterative calculation can be performed by using a genetic algorithm tool box in matlab software.
And sequencing according to the matching degree values, marking a reference installation model with the highest matching degree value and the water cooling scheme which does not exceed the installation area of the installation model as a target model, and obtaining the water cooling scheme corresponding to the target model.
The similarity model is used for calculating the similarity of the coordinate area of the model of the heating structure, and an algorithm model for calculating the similarity is specifically established as common knowledge in the art, and can be directly obtained and used if the similarity model has the similarity model capable of realizing the corresponding purpose, which is not described in detail.
The method of correlating the calculation of the heat generating structure model coordinate region in the installation model with the reference of the heat generating structure model coordinate region in the installation model is common knowledge in the art, and thus will not be described in detail.
The cooperation module is used for carrying out cooperation cooling based on the cooling module, and the concrete method comprises the following steps:
setting and installing an air duct plate, setting an air cooling model, performing air cooling simulation according to the air cooling model to obtain a plurality of groups of air cooling schemes, and identifying ventilation combinations in the air cooling schemes; acquiring a temperature interval of a heating structure in the intelligent oil well control cabinet from the historical data, namely acquiring historical detection data according to the installation area of the intelligent oil well control cabinet, and further acquiring the temperature interval; dividing and correlating the temperature interval with the ventilation combination, and establishing an air cooling temperature scheme table;
the temperature of each heating structure in the intelligent oil well control cabinet is obtained in real time, the obtained temperature of each heating structure is input into an air cooling temperature scheme table, the corresponding air cooling scheme is matched, and the obtained air cooling scheme is used for carrying out cooperative cooling.
The division and association of the temperature zone and the ventilation combination is to divide the temperature zone into a plurality of cells according to the ventilation combination, and the specific division and association of the temperature zone are common knowledge in associating the cells with the corresponding ventilation combination, and therefore, detailed description thereof will not be given.
The method for setting and installing the air duct plate comprises the following steps:
the method comprises the steps of obtaining an installation model from a cooling module, supplementing the installation model according to a water cooling scheme, namely, supplementing an installed water cooling device into the installation model, marking the supplemented installation model as a water cooling model, arranging a cooperative device in an intelligent oil well control cabinet, wherein the cooperative device is a blowing device such as a fan and the like, is used for rapidly cooling cold air generated by the water cooling device, can be turned according to requirements, and can be replaced by an air cooling device capable of realizing the functions; setting the cooperative device in a water-cooling model;
and establishing an air duct model, analyzing the water-cooling model through the air duct model, obtaining the installation position of the air duct plate on the intelligent oil well control cabinet, the number of ventilation holes on the air duct plate and the distribution of corresponding ventilation holes, setting the air duct plate according to the number of the ventilation holes and the distribution of the ventilation holes, and installing the set air duct plate according to the installation position on the intelligent oil well control cabinet.
The method for setting the air cooling model is to supplement the air duct plate into the water cooling model, and mark the supplemented water cooling model as the air cooling model.
The air duct model is built based on a CNN network or a DNN network, and the training set comprises a water cooling model and air duct board installation positions, the number of ventilation holes and corresponding ventilation hole distribution which are correspondingly arranged, and the specific building and training process is common knowledge in the art, so that the detailed description is omitted.
The method for carrying out air cooling simulation according to the air cooling model comprises the following steps:
simulating the opening of the vent holes in different air duct plates and the internal air flow under the operation of the cooperative device by means of the existing software such as a wind tunnel test, estimating the air cooling effect brought by different internal air flows, and setting different air cooling schemes according to the air cooling effect and a ventilation combination, wherein the ventilation combination refers to the combination of the opening of the vent holes in different air duct plates and the operation of the cooperative device; the above-mentioned undisclosed part is prior art and is therefore not described in detail.
The above formulas are all formulas with dimensions removed and numerical values calculated, the formulas are formulas which are obtained by acquiring a large amount of data and performing software simulation to obtain the closest actual situation, and preset parameters and preset thresholds in the formulas are set by a person skilled in the art according to the actual situation or are obtained by simulating a large amount of data.
The above embodiments are only for illustrating the technical method of the present invention and not for limiting the same, and it should be understood by those skilled in the art that the technical method of the present invention may be modified or substituted without departing from the spirit and scope of the technical method of the present invention.
Claims (3)
1. An outdoor intelligent oil well control cabinet convenient for heat dissipation and temperature reduction is characterized by comprising a cooling module, a control module, a coordination module and a server;
an intelligent oil well control cabinet model is arranged in the control module;
the cooling module is used for radiating and cooling the intelligent oil well control cabinet, acquiring a water cooling scheme, and arranging a water cooling device in the intelligent oil well control cabinet according to the water cooling scheme; acquiring the temperature in an intelligent oil well control cabinet in real time, marking as T1, acquiring the specific heat of liquid refrigerant in a water cooling device, marking as Cp, acquiring the temperature of each heating structure, calculating the total heating value of the heating structures, marking as Q, acquiring the evaporation latent heat of the liquid refrigerant, marking as r, acquiring the water supply quantity according to the formula BW=Q/[ lambda X Cp X b 1X (T1-T2) +b2X r ], and cooling according to the acquired water supply quantity;
the collaborative module is used for carrying out collaborative cooling based on the cooling module, setting and installing the air duct plate, setting an air cooling model, carrying out air cooling simulation according to the air cooling model, obtaining a plurality of groups of air cooling schemes, and identifying ventilation combinations in the air cooling schemes; acquiring a temperature interval of a heating structure in the intelligent oil well control cabinet from historical data, dividing and correlating the temperature interval with a ventilation combination, and establishing an air cooling temperature scheme table; acquiring the temperature of each heating structure in the intelligent oil well control cabinet in real time, inputting the acquired temperature of each heating structure into an air cooling temperature scheme table, matching the acquired temperature with a corresponding air cooling scheme, and carrying out cooperative cooling according to the acquired air cooling scheme;
t2 is the temperature of the makeup water, b1 and b2 are both proportionality coefficients, the value range is 0< b1<2,0< b2<1, lambda is a correction factor, and the value range is 0< lambda less than or equal to 1;
the method for setting the intelligent oil well control cabinet model comprises the following steps:
acquiring an intelligent oil well control cabinet design diagram, establishing a control cabinet three-dimensional model according to the acquired intelligent oil well control cabinet design diagram, identifying a heating structure in the intelligent oil well control cabinet, performing heating grading on the heating structure, marking a corresponding heating structure model in the control cabinet three-dimensional model, marking a corresponding heating grading label, establishing a space coordinate system, and marking the current control cabinet three-dimensional model as the intelligent oil well control cabinet model;
the method for obtaining the water cooling scheme comprises the following steps:
acquiring an intelligent oil well control cabinet model, acquiring a coordinate area and a heating level of a heating structure model in the intelligent oil well control cabinet model, identifying a mounting area in the intelligent oil well control cabinet model, and integrating the heating structure model coordinate area and the mounting area into a mounting model; establishing a water cooling scheme library, and matching a water cooling scheme from the water cooling scheme library according to an installation model;
the method for setting and installing the air duct plate comprises the following steps:
obtaining an installation model from a cooling module, supplementing the installation model according to a water cooling scheme, marking the supplemented installation model as a water cooling model, arranging a cooperative device in an intelligent oil well control cabinet, and arranging the cooperative device in the water cooling model;
and establishing an air duct model, analyzing the water-cooling model through the air duct model, obtaining the installation position of the air duct plate on the intelligent oil well control cabinet, the number of ventilation holes on the air duct plate and the distribution of corresponding ventilation holes, setting the air duct plate according to the number of the ventilation holes and the distribution of the ventilation holes, and installing the set air duct plate according to the installation position on the intelligent oil well control cabinet.
2. The outdoor intelligent oil well control cabinet convenient for heat dissipation and temperature reduction according to claim 1, wherein the method for establishing the water cooling scheme library comprises the following steps:
the method comprises the steps of obtaining an existing intelligent oil well control cabinet and a corresponding water cooling scheme, marking the intelligent oil well control cabinet as a reference control cabinet, establishing a reference installation model in the reference control cabinet, establishing a first database, inputting the reference installation model and the corresponding water cooling scheme into the first database for storage, and marking the first database as a water cooling scheme library.
3. The outdoor intelligent oil well control cabinet convenient for heat dissipation and cooling according to claim 1, wherein the method for matching the water cooling scheme from the water cooling scheme library according to the installation model comprises the following steps:
marking an installation model as i, marking a reference installation model in a water cooling scheme library as i, wherein i=1, 2, … … and n, and n is a positive integer; marking a heating structure model coordinate area in a reference installation model as j, j=1, 2, … … and m, wherein m is a positive integer;
establishing a similarity model, correlating a heating structure model coordinate area in the calculated installation model with a heating structure model coordinate area in the reference installation model, calculating a similarity value of the heating structure model coordinate area in the installation model and the heating structure model coordinate area in the reference installation model through the similarity model, marking the similarity value as hij, and according to a formulaObtaining a matching degree value of the installation model and a reference installation model;
sequencing according to the matching degree values, marking a reference installation model with the highest matching degree value and the water cooling scheme not exceeding the installation area of the installation model as a target model, and obtaining a water cooling scheme corresponding to the target model;
fij is the heating grading of the heating structure model in the reference installation model, and F is the heating grading of the heating structure model corresponding to fij in the installation model; alpha j is an adjusting coefficient, and the value range is [0,1].
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