CN108595308B - Handling system and method of big data server based on management - Google Patents

Abstract

A handling system and method based on big data server of management, still set up temperature sensor and humidity transducer in the laboratory after the laboratory construction finishes, the said controller links with upper computer, the said upper computer links with big data server through the network; a variable one is set in the controller; the controller comprises a fitting value deriving module, a standby value deriving module and a final fitting value deriving module; the big data server is arranged in a cuboid-shaped server cabinet; the method effectively avoids the defects that the capacity of the controller for the temperature and humidity data of the laboratory transmitted by the upper computer is not small, the cost is not low, the difficulty in reducing the cost is increased, the fitting accuracy of subsequent exponential fitting is lowered, the error after fitting is large when the time delay change is not small, the large data server in the server cabinet is obstructed and damaged, and the server cabinet is burnt in the prior art.

Description

Handling system and method of big data server based on management

Technical Field

The invention relates to the technical field of big data, in particular to a handling system and a handling method of a big data server based on management.

Background

The operation and maintenance stage of the laboratory is performed after the laboratory is built, and equipment of the laboratory, such as a power supply, the humidity and the temperature of the laboratory, need to be detected in this respect, but no special detection device exists at present, so that sufficient data collection is lacked in the operation and maintenance stage, and the large data construction is not enough.

Therefore, a big data server system for laboratory engineering management is developed, and comprises a monitoring terminal and a big data server, wherein the monitoring terminal is connected with the big data server through a network, and the monitoring terminal and the big data server mutually transmit interactive data to realize the laboratory engineering management;

still be provided with temperature sensor and humidity transducer in the laboratory after the laboratory construction is accomplished, temperature sensor and humidity transducer are connected with the controller, the controller is connected with the host computer, the host computer is connected with big data server through the network.

The big data server comprises project cost supervision, project quality supervision, project progress supervision and project safety supervision contents;

the engineering cost supervision comprises the following steps: the method comprises the following steps that firstly, when budgeting is carried out, the cost of similar projects and the real-time change of network quotation formed by key cost are tracked in a business database; secondly, in the process of engineering, real-time control of the node cost is realized according to the comparison of the node cost of the same project, the node cost budget of the project and the actual node cost in an industry database;

the engineering quality supervision comprises the following steps: the method comprises the steps that firstly, the recorded data of the engineering contract units and the provided historical operating conditions and credit conditions including materials, equipment and technologies are longitudinally analyzed through an industry database and network information, and compared with the related data of other similar units, the optimal supply contractor is selected, and the engineering quality is guaranteed; secondly, in the process of project proceeding, timely reminding quality hidden danger points of similar projects in an industry database, and carrying out early warning by combining progress data and the like;

the project progress supervision comprises the following steps: on one hand, the method emphasizes that the implementation condition of the project progress is tracked, checked and analyzed on the basis of carrying out comparative analysis on similar projects in an industry database, and meanwhile, progress condition data such as a construction department and a material supply department are compared with the project construction plan data in a row-column mode, so that the construction progress is supervised or adjusted at any time; in addition, weather real-time factors are fully considered in progress monitoring, and project progress is adjusted;

the engineering safety supervision comprises the following steps: on one hand, the occupational health safety and environmental supervision are brought into the standard by combining the safety supervision data of similar items of an industry database, and analysis and engineering adjustment are carried out on different data in various aspects of special weather condition records, geological conditions, historical protection scheme implementation data, underground pipeline distribution, construction equipment, construction machinery safety quality standards and canteen catering conditions in different seasons of a construction area; comprehensively analyzing the real-time condition of the engineering safety by combining the project real-time progress data, the real-time cost data and the real-time quality data;

after the laboratory is built, the collected temperature and humidity data of the laboratory are sent to an upper computer through a controller and then are sent to a big data server for storage through the upper computer for the temperature and humidity data and the local time of the laboratory.

The laboratory construction project supervision mechanism based on big data is formed by collecting a network and a professional database through a created top database to obtain a large amount of data related to the same project, extracting data from project cost, quality, progress and safety control indexes through a second layer database, and collecting historical data according to the project implementation time sequence; then, data analysis and comparison are carried out, the top-layer database is used for transversely comparing whether the project cost, quality, progress and safety control degree meet the standards, and the second-layer database is used for longitudinally comparing implementation standards of project cost, quality, progress and safety; and finally, implementing early warning and countermeasures, and taking control measures once contents which are inconsistent with the plan are found in data analysis. The system is scientific and reasonable, has a comprehensive, real and reliable data system and high practical value, and can effectively and comprehensively monitor, analyze and diagnose the engineering project of the laboratory engineering construction in real time, thereby avoiding the loss caused by improper cost, quality, progress and safety control. After the laboratory is built, the collected temperature and humidity data of the laboratory are sent to the upper computer through the controller and then are sent to the big data server for storage through the upper computer, and therefore the defect of insufficient big data can be supplemented in real time.

In addition, the collected temperature and humidity data of the laboratory are sent to the upper computer through the controller, so that the capacity of the controller for the temperature and humidity data of the laboratory transmitted by the upper computer is small, the cost is low, and the difficulty of reducing the cost is increased.

The temperature sensor and the humidity sensor often need to measure in parallel before sending the collected temperature and humidity of the laboratory to the controller, and the current way of measuring the temperature and humidity information of various laboratories in parallel is as follows:

1. the controller is activated in parallel, the temperature sensor and the humidity sensor are provided with parallel ports to acquire parallel instructions transmitted by the controller, the temperature sensor and the humidity sensor are both parallel by the parallel instructions, and the temperature sensor and the humidity sensor perform measurement on the temperature and humidity information of each laboratory under the activation of the parallel instructions when the parallel instructions are transmitted, so that the concurrency of the temperature and humidity information of each laboratory measured by different temperature sensors and humidity sensors is ensured, the standards of the components of the temperature sensors and humidity sensors are not low, and in addition, the reliability is insufficient due to the concurrent instructions;

2. the controller is in a fitting parallel mode, a mapping relation is established between the time point of transmitting the temperature and humidity information of the laboratory to the controller and the temperature and humidity information of the laboratory without the concurrent measurement of a temperature sensor and a humidity sensor, a time interval is randomly set, and the time point mapped by the temperature and humidity information of the laboratory transmitted to the controller in the time interval is taken as an independent variable and the temperature and humidity information of the laboratory mapped by the time point is taken as a dependent variable for carrying out exponential fitting every time interval.

With the efficient development and application of the data transmission standard, the temperature and humidity information of the laboratory can be transmitted in a packet form, so that the data is common, and the performances of good compatibility and uncomplicated architecture are provided, thus being the future direction of the temperature and humidity information transmission of the laboratory; however, during the packet transmission, due to the random influence of the transmission link congestion, the extra message response and the transmission link delay, the temperature and humidity information transmitted to the laboratory in the controller is often accompanied by the delay variation, so that the fitting accuracy of the subsequent exponential fitting becomes low, and even when the delay variation is not small, the problem of large error after fitting occurs.

In order to prevent collision damage, the big data server is arranged in the cuboid-shaped server cabinet, during the working period of the big data server, the temperature rise phenomenon can occur in the server cabinet, the cabinet body with the first through groove is poor in refrigeration performance during the exhaust period, and if efficient refrigeration treatment cannot be performed, the big data server in the server cabinet is often damaged, and even the server cabinet is burnt.

In addition, the mode of sending the temperature and humidity data of the laboratory to the big data server through the upper computer is as follows: the monitoring equipment sends the acquired analog quantity signal to the micro-processing unit, the micro-processing unit receives the analog quantity signal as data and then carries out analog-to-digital conversion on the analog quantity signal, and then the digital signal is connected to a communication network through the wireless data transmission module and sent to a local end; in the conventional digital signal transmission mode, the condition that the micro-processing unit is connected to the communication network is used, if the micro-processing unit is not connected to the communication network, and another analog quantity signal appears in the micro-processing unit during the analog-to-digital conversion period and the main control software during the analog-to-digital conversion period, the analog quantity signal is lost and cannot be converted into a digital signal to be transmitted to a local terminal, so that the digital signal transmitted to the local terminal is not all the digital signals appearing in the micro-processing unit during the operation period, and the integrity of the digital signal is not good.

Disclosure of Invention

In order to solve the problems, the invention provides a handling system and a handling method of a large data server based on management, which effectively overcome the defects that in the prior art, the capacity of a controller for temperature and humidity data of a laboratory transmitted by an upper computer is not small, the cost is not low, the difficulty in reducing the cost is increased, the fitting accuracy of subsequent exponential fitting is lowered, the error after fitting is large when the time delay change is not small, the large data server in a server cabinet is damaged, and the server cabinet is burnt.

In order to overcome the defects in the prior art, the invention provides a solution for a handling system and a handling method thereof based on a large data server for management, which comprises the following steps:

a handling system of a big data server based on management comprises a monitoring terminal and the big data server, wherein the monitoring terminal is connected with the big data server through a network, and the monitoring terminal and the big data server mutually transmit interactive data to realize laboratory engineering management;

after the construction of the laboratory is finished, a temperature sensor and a humidity sensor are also arranged in the laboratory, the temperature sensor and the humidity sensor are connected with a controller, the controller is connected with an upper computer, and the upper computer is connected with a big data server through a network;

a variable one is set in the controller;

the controller comprises a fitting value deriving module, a standby value deriving module and a final fitting value deriving module;

the big data server is arranged in a cuboid-shaped server cabinet, the server cabinet comprises a cabinet body 501, a base 502 is fixedly connected with the lower part of the cabinet body 501, a first through groove 503 is arranged at the lower part of the cabinet body 501, a supporting platform 505 for placing the big data server is fixedly connected with two sides of the inner surface of the cabinet body 501, a second through groove 504 is arranged at two sides of the cabinet body 501, a through containing groove 518 is arranged at one side of the cabinet body 501 and is positioned at the lower position of the second through groove 504, a cuboid-shaped positioning frame 511 is fixedly connected with the inner surface of the through containing groove 518, a positioning screw 517 is arranged at the vertex of the cuboid-shaped positioning frame 511, a screw groove of the positioning screw 517 penetrates through a screw groove of the cuboid-shaped positioning frame 511 and is in threaded connection with a screw groove on the cabinet body 501, a first motor 513 is arranged inside the cuboid-shaped positioning frame 511, a columnar supporting piece 512 is fixedly connected with the outer wall of the first motor 513, a head of the columnar supporting piece 512, which is farther away from the first motor 513, is fixedly connected with the cuboid-shaped positioning frame 511, a rotating rod of the first motor 513 is fixedly connected with a rotating vane-shaped blade 514, one side of a cuboid positioning frame 511 is fixedly connected with a refrigerating machine 515, the refrigerating machine 515 is communicated with the outside of the cabinet body 501, a wavy cavity 510 with two through ends is fixedly connected with the refrigerating machine 515, one side of the rectangular positioning frame 511 positioned inside the refrigerating machine 515 is fixedly connected with a wavy cavity 510 with two through ends, one side of the cabinet body 501 is fixedly connected with a pumping motor 506, the pumping motor 506 is fixedly connected with the cabinet body 501 in a welding manner, a container 509 containing refrigerating fluid is fixedly connected with the cabinet body 501 in a welding manner, the water outlet end of the pumping motor 506 is communicated with a cavity I507 with two through ends, the water inlet end of the pumping motor 506 is communicated with a cavity II 508 with two through ends, one end of the cavity II 508 with two through ends is communicated with the container containing refrigerating fluid, the cavity I507 with the cavity II with two through ends is communicated with the cavity II 508 with the pumping motor 506, one end of the cavity II through two ends is further away from the pumping motor 506, one end of the cavity I507 is sequentially communicated with the cabinet body 501 and the cuboid positioning frame 511, and the wavy cavity II through The communicated cavities 510 are communicated, one end of the wavy cavity 510 with two communicated ends, which is farther away from the cavity 507 with two communicated ends, penetrates through the rectangular positioning frame 511 and extends out of the rectangular positioning frame 511, the upper end of the rectangular positioning frame 511 is provided with the condenser tube 516, one end of the wavy cavity 510 with two communicated ends, which is farther away from the cavity 507 with two communicated ends, is communicated with the condenser tube 516, one side of the cabinet body 501, which is positioned at the lower position of the water pumping motor 506, is fixedly connected with the container 509 containing the refrigerating fluid, and one end of the condenser tube 516, which is farther away from the wavy cavity 510 with two communicated ends, is communicated with the container 509 containing the refrigerating fluid.

The fit value deriving module is used for deriving a fit value of the intermediate time point.

The derived standby value module is used to derive a standby value for the intermediate point in time.

The derive last fit value module is configured to derive a last fit value for any time point O in the time interval.

The number of the second through grooves 504 is more than six, and all the second through grooves 504 are arranged at equal intervals.

A method of a managed big data server based handling system, comprising: after the laboratory is built, the collected temperature and humidity data of the laboratory are sent to an upper computer through a temperature sensor and a humidity sensor in the laboratory, and the temperature and humidity data and the local time of the laboratory are sent to a big data server through the upper computer for storage;

the method for transmitting the collected temperature and humidity data of the laboratory to the upper computer through the controller runs on the controller, and comprises the following measures:

a1: the temperature sensor and the humidity sensor send the sensed temperature and humidity of the laboratory to the controller, and the controller immediately obtains the sensed temperature and humidity information of the laboratory when receiving the temperature and humidity information of the laboratory;

the temperature sensor and the humidity sensor send the sensed temperature and humidity of the laboratory to the controller, and the controller immediately obtains the sensed temperature and humidity information of the laboratory when receiving the temperature and humidity information of the laboratory;

a2: periodically traversing the information of the temperature and the humidity of the laboratory sensed in the set time period after the set time period, identifying the same information segment which continuously appears subsequently, processing the identified same information segment which continuously appears subsequently by using a deflate algorithm to reduce the size of the information of the temperature and the humidity of the laboratory, and organizing the information of the temperature and the humidity of the laboratory again to form initial information;

the set period of time is less than 8s;

at a2, the size of the information about the temperature and humidity of the laboratory is reduced, and the information about the temperature and humidity of the laboratory is reorganized to form initial information, including:

constructing a first information piece and a second information piece which correspond to the same information segment which continuously appears subsequently, wherein the first information piece is the capacity of the same information segment which continuously appears subsequently, and the second information piece is the number of bytes at intervals between the first byte of the same information segment which continuously appears subsequently and the first byte of the same previous information segment of the information segment plus one;

replacing the same information segment which continuously appears subsequently with the information piece I and the information piece II in the temperature and humidity information of the laboratory, so as to obtain the temperature and humidity information of the laboratory with the reduced size;

establishing a third information piece corresponding to the same information segment which continuously appears subsequently, wherein the third information piece is used for representing the position of a first information piece in the information of the temperature and the humidity of the laboratory with the reduced size, the first information piece is one of the first information piece and the second information piece, and the other information piece is positioned behind the first information piece;

packaging the information of the temperature and the humidity of the laboratory after the size reduction and the information sheet III to organize the initial information;

the server cabinet can ventilate the inside of the cabinet body 501 through a through groove I503 at the lower part of the cabinet body 501, two through grooves II 504 are arranged at two sides of the cabinet body 501 to facilitate the inside of the cabinet body 501 to refrigerate, a cuboid positioning frame 511 is fixedly connected with one side of the cabinet body 501, a motor I513 arranged in the cuboid positioning frame 511 pulls a rotary vane-shaped vane 514 to rotate through the rotary kinetic energy of the motor I513, the rotary kinetic energy of the rotary vane-shaped vane 514 refrigerates the inside of the cabinet body 501, a container 509 containing refrigerating fluid is arranged at one side of the cabinet body 501, a cavity II 508 with two through holes communicated with each other through the container 509 containing refrigerating fluid is communicated with a pumping motor 506 through a cavity II 508 with two through holes, the cavity II 508 with two through holes communicated with each other through two holes is communicated with the pumping motor 506, the cavity I507 with the pumping motor 506 through two holes communicated with each other through the water outlet end of the pumping motor 506, a wave-shaped cavity channel 510 with each other through two holes and a condensing pipe 516, the reciprocating motion of the refrigerant liquid in the container 509 filled with the refrigerant liquid can be achieved, and the refrigerant liquid is fixedly connected with the refrigerating machine 515 through the wavy cavity 510 with two through ends, so that the refrigerating machine 515 can be refrigerated.

The information of the temperature and the humidity of the laboratory sensed in the periodic set period of time traversing the period of time comprises:

“15、16、17、18、19、20、21、16、17、18、19、2022, 24, 15, 17, 16, 18, … ", assuming that the italicized symbol" 16, 17, 18, 19, 20 "is the same piece of information that continues to appear subsequently, the processing must be performed on the same piece of information that continues to appear subsequently: that is, a first information piece and a second information piece corresponding to the same information segment that continues to appear subsequently can be constructed, where the first information piece is the capacity of the same information segment that continues to appear subsequently, the second information piece is the number of bytes at an interval between the first byte of the same information segment that continues to appear subsequently and the first byte of the previous information segment that is the same as the information segment, plus one, that is, the value of the first information piece is five, which represents the number of bytes of the same information segment that continues to appear subsequently, and the value of the second information piece is six, which represents the first byte of the same information segment that continues to appear subsequentlyThe number of bytes in the interval between the first bytes of the same preceding information segment as the information segment plus one, i.e. "16, 17, 18, 19, 20, 21,16The number of bytes between two 16 in the information segment is five, then the number is added to be six, or the value of the information piece two is two, the number of bytes which represents the interval between the first byte of the same information segment which continuously appears subsequently and the last byte of the previous information segment which is the same with the information segment is added to be one, the same information segment which continuously appears subsequently is replaced by the value of five and the value of six, and then the temperature and humidity information of the laboratory with the reduced size is obtained: "15, 16, 17, 18, 19, 20, 21, 5, 6, 22, 24, 15, 17, 16, 18, …"; the positions of the first information sheet and the second information sheet can be replaced with each other; in addition, a third message piece is constructed, the third message piece is used for indicating the position of a header message piece in the temperature and humidity information of the reduced laboratory, the header message piece is one of the first message piece and the second message piece, the other message piece is positioned behind the header message piece, the third message piece is used for indicating the position of the header message piece in the temperature and humidity information of the reduced laboratory, the first byte of the header message piece can be positioned on the several bytes in the temperature and humidity information of the reduced laboratory, the value of the third message piece is eight, and then the temperature and humidity information of the reduced laboratory, namely' 15, 16, 17, 18, 19, 20, 21, 5, 6, 22, 24, 15, 17. 16, 18, …' and the information piece three with the value of eight are packaged to organize the initial information;

a3: the controller sends an initial message to the upper computer;

in addition, after the temperature sensor and the humidity sensor send the sensed temperature and humidity of the laboratory to the controller, the process of treating the temperature and humidity information of the laboratory, which comprises the following steps of sequentially executing:

s1: when the temperature and humidity information of the laboratory is transmitted to the controller, a mapping relation is established between the time point of transmitting the temperature and humidity information of the laboratory to the controller and the temperature and humidity information of the laboratory, in addition, a time interval is randomly set, and the temperature and humidity information of all the laboratories in the time interval is arranged according to the time sequence of transmitting the temperature and humidity information of the laboratory to the controller when one time interval passes, so that the temperature and humidity information I, the temperature and humidity information II, the temperature and humidity information III … … of the laboratory are sequentially arranged according to the time sequence, and the time points of mapping the temperature and humidity information K of the laboratory with the temperature and humidity information I, the temperature and humidity information II, the temperature and humidity information III … … of the laboratory are respectively the time point I, the time point K, A second time point and a third time point … … time point k, wherein k is a positive integer and represents the number of information of the temperature and the humidity of the laboratory in the time interval;

s2: assigning a variable one in the controller to be L, wherein the value of L at the moment is one;

s3: deriving a fitting value of the intermediate time point, specifically performing the following steps:

3-1: the sum of L plus one and the sum of L plus two are respectively M and N, the time point L, the time point M and the time point N are firstly obtained, and then the information L of the temperature and the humidity of the laboratory, the information M of the temperature and the humidity of the laboratory and the information N of the temperature and the humidity of the laboratory, which are respectively mapped with the time point L, the time point M and the time point N, are obtained, wherein L, M and N are positive integers, and N is not more than k;

3-2: by means of the information L of the temperature and the humidity of the laboratory and the information N of the temperature and the humidity of the laboratory, which are respectively mapped by the time point L and the time point N, the time point L is used as an independent variable, the information L of the temperature and the humidity of the laboratory is used as a dependent variable of the time point L, the time point N is used as an independent variable, and the information N of the temperature and the humidity of the laboratory is used as a dependent variable of the time point N for carrying out exponential fitting, then a fitting value corresponding to the time point M is obtained according to an exponential fitting formula, the fitting value is the fitting value of the middle time point, and the algorithm of exponential fitting in 3-2 is a least square method;

s4: and deriving a standby value of the intermediate time point as follows:

dividing the sum obtained by adding the fitting value of the middle time point and the standby value of the middle time point by two to obtain a mean value, wherein the mean value is the standby value of the middle time point;

s5: deriving a final fitted value for any time point O in the time interval:

5-1: comparing the time points M with the time intervals between the time points L and N respectively, and selecting the time point L or the time point N with smaller time interval as the standby time point;

5-2: by means of the information of the temperature and the humidity of the laboratory mapped by the standby time point and the standby time point obtained in the step 5-1 and the standby value of the standby time point, namely the time point M and the standby value of the standby time point, the standby time point is used as an independent variable, the information of the temperature and the humidity of the laboratory mapped by the standby time point is used as a dependent variable of the standby time point, the time point M is used as an independent variable and the standby value of the standby time point is used as a dependent variable of the time point M for carrying out exponential fitting, then the fitting value of any time point O in the time interval is obtained according to an exponential fitting formula, the fitting value is the fitting value of the any time point O, and the algorithm of the exponential fitting in the step 5-2 is a least square method;

s6: and judging whether N is equal to k, if N is equal to k, terminating the process of processing the information of the temperature and the humidity of the laboratory, and if N is not equal to k, adding one to the current value of L to be the value of L, and going to S3 to execute the process.

The invention has the beneficial effects that:

the method enables the sensor to send the sensed temperature and humidity of the laboratory to the controller, the controller receives the information of the temperature and humidity of the laboratory, the sensed information of the temperature and humidity of the laboratory is obtained immediately, then the information of the temperature and humidity of the laboratory sensed in the period is traversed periodically after the set period, the same information section which continuously appears subsequently is identified, the identified same information section which continuously appears subsequently is processed to reduce the size of the information of the temperature and humidity of the laboratory, the information of the temperature and humidity of the laboratory is organized again to form initial information, and the size of the information capacity is greatly reduced compared with the size of the information of the temperature and humidity of the laboratory which reduces the size of the information of the temperature and humidity of the laboratory which is not executed on the same information section which continuously appears subsequently, the capacity transmitted to the upper computer is reduced, so that the cost is low, and the cost is reduced more easily.

The capacity of the temperature and humidity information of the laboratory is not small, the initial temperature and humidity information of the laboratory is directly transmitted to the upper computer in the current mode, information blockage of a communication network is often formed on one hand, the temperature and humidity information of the laboratory with the small capacity is obtained on the other hand, resource waste is not small, and realization of other functions is not facilitated on the other hand.

The fitting value of the middle time point is derived by firstly obtaining the time point L, the time point M and the time point N, then obtaining the information L of the temperature and the humidity of the laboratory, the information M of the temperature and the humidity of the laboratory and the information N of the temperature and the humidity of the laboratory which are respectively mapped with the time point L, the time point M and the time point N, then deriving the standby value of the middle time point, and deriving the final fitting value of any time point O in the time interval. Compared with the current mode, the method reduces the fitting deviation caused by the time delay change, improves the fitting accuracy during the time delay change and is very effective for reducing the negative effect during the time delay change.

According to the server cabinet with the refrigerating function, the inside of the cabinet body 501 can be refrigerated through the first motor 513 and the rotary blade 514, the cabinet body 501 can be refrigerated through the wavy cavity 510 with two through ends, the refrigerator 515 and the container 509 containing the refrigerating fluid, the server cabinet can be efficiently refrigerated, a large data server inside the cabinet body 501 can be efficiently refrigerated, and the refrigerating speed is improved. In addition, the server cabinet can execute the reciprocating motion of the refrigerant through the two through cavities 508, the two through cavities 507 and the wavy through cavities 510, so that the refrigeration speed can be improved, and the damage to a large data server in the server cabinet can be reduced. In addition, the server cabinet can execute the reciprocating motion of the refrigerant through the two through cavities 508, the two through cavities 507 and the wavy through cavities 510, so that the refrigeration speed can be improved, and the damage to a large data server in the server cabinet can be reduced.

Drawings

FIG. 1 is a schematic diagram of the managed big data server based handling system of the present invention.

Fig. 2 is an inside schematic view of a server rack of the present invention.

Fig. 3 is an edge schematic of a server rack of the present invention.

Detailed Description

The present invention will be further described with reference to the following examples.

The handling system of the big data server based on management comprises a monitoring terminal and the big data server, wherein the monitoring terminal is connected with the big data server through a network, and the monitoring terminal and the big data server mutually transmit interactive data to realize laboratory engineering management;

after the construction of the laboratory is finished, a temperature sensor and a humidity sensor are also arranged in the laboratory, the temperature sensor and the humidity sensor are connected with a controller, the controller is connected with an upper computer, and the upper computer is connected with a big data server through a network;

a variable one is set in the controller;

the controller comprises a fitting value deriving module, a standby value deriving module and a final fitting value deriving module;

the big data server is arranged in a cuboid-shaped server cabinet, the server cabinet comprises a cabinet body 501, a base 502 is fixedly connected with the lower part of the cabinet body 501, a first through groove 503 is arranged at the lower part of the cabinet body 501, a supporting platform 505 for placing the big data server is fixedly connected with two sides of the inner surface of the cabinet body 501, a second through groove 504 is arranged at two sides of the cabinet body 501, a through accommodating groove 518 is arranged at one side of the cabinet body 501 and at the lower position of the second through groove 504, a cuboid-shaped positioning frame 511 is fixedly connected with the inner surface of the through accommodating groove 518, a positioning screw 517 is arranged at the top of the cuboid-shaped positioning frame 511, a spiral groove of the positioning screw 517 penetrates through a thread groove of the cuboid-shaped positioning frame 511 and is in threaded connection with a thread groove on the cabinet body 501, the cuboid-shaped positioning screw 517 can position the cuboid-shaped positioning frame 511, the reliability of the rotating vane blade is improved, a first motor 513 is arranged in the cuboid-shaped positioning frame 511, the outer wall of the first motor 513 is fixedly connected with a columnar supporting piece 512, one end of the columnar supporting piece 512, which is farther away from the first motor 513, is fixedly connected with a rectangular positioning frame 511, a rotating rod of the first motor 513 is fixedly connected with a rotary vane paddle 514, refrigerating operation can be performed on the inner side of the cabinet body 501 through the first motor 513 and the rotary vane paddle 514, a server cabinet performs high-school refrigeration, a large data server in the cabinet body 501 performs high-efficiency refrigeration to improve the refrigerating speed, one side of the rectangular positioning frame 511 is fixedly connected with a refrigerating machine 515, the refrigerating machine 515 is communicated with the outer side of the cabinet body 501, a wavy cavity 510 with two through ends is fixedly connected with the refrigerating machine 515 in a welding manner, one side of the rectangular positioning frame 511, which is positioned in the refrigerating machine 515, a water pumping motor 506 is fixedly connected with the cabinet body 501 in a welding manner, a container 509 containing refrigerating fluid is fixedly connected with the cabinet body 501 in a welding manner, the water outlet end of the water pumping motor 506 is communicated with the first cavity 507 with two through ends, the water inlet end of the water pumping motor 506 is communicated with the second cavity 508 with two through ends, the second cavity 508 with two through ends is farther away from the water pumping motor 506 and is communicated with the container 509 containing refrigerating fluid, the reciprocating motion of the refrigerating fluid is executed through the second cavity 508 with two through ends and the first cavity 507 with two through ends and the wavy cavity 510 with two through ends, the refrigerating speed can be improved, the damage to a large data server in a server cabinet can be reduced, the first cavity 507 with two through ends is communicated with the cuboid positioning frame 511 through the cabinet body 501 and the wavy cavity 510 with two through ends arranged in the cuboid positioning frame 511 in sequence, the wavy cavity 510 with two through ends is farther away from the first cavity 507 with two through ends and penetrates through the cuboid positioning frame 511 and extends out of the cuboid positioning frame 511, the upper end of the rectangular positioning frame 511 is provided with a condenser tube 516, one end of the wavy through cavity 510, which is farther from the cavity 507 with two through ends, is communicated with the condenser tube 516, one end of the cabinet body 501, which is positioned at the lower position of the water pumping motor 506, is fixedly connected with a container 509 containing refrigerating fluid, one end of the condenser tube 516, which is farther from the wavy through cavity 510 with two through ends, is communicated with the container 509 containing refrigerating fluid, the cabinet body 501 can be better refrigerated through the wavy through cavity 510 with two through ends, the refrigerating machine 515 and the container 509 containing refrigerating fluid, efficient refrigeration is performed on the server cabinet, efficient refrigeration is performed on a large data server in the cabinet body 501, and the refrigeration speed is improved.

According to the server cabinet with the refrigerating function, the inside of the cabinet body 501 can be refrigerated through the first motor 513 and the rotary blade 514, the cabinet body 501 can be refrigerated through the wavy cavity 510 with two through ends, the refrigerator 515 and the container 509 containing the refrigerating fluid, the server cabinet can be efficiently refrigerated, a large data server inside the cabinet body 501 can be efficiently refrigerated, and the refrigerating speed is improved.

In addition, the server cabinet can execute the reciprocating motion of the refrigerant through the two through cavities 508, the two through cavities 507 and the wavy through cavities 510, so that the refrigeration speed can be improved, and the damage to a large data server in the server cabinet can be reduced.

The fit value deriving module is used for deriving a fit value of the intermediate time point.

The derived standby value module is used to derive a standby value for the intermediate point in time.

The derive last fit value module is configured to derive a last fit value for any time point O in the time interval.

The number of the second through grooves 504 is more than six, and all the second through grooves 504 are arranged at equal intervals.

The big data server comprises project cost supervision, project quality supervision, project progress supervision and project safety supervision contents;

the engineering cost supervision comprises the following steps: the method comprises the following steps that firstly, when budgeting is carried out, the cost of similar projects and the real-time change of network quotation formed by key cost are tracked in a business database; secondly, in the process of engineering, real-time control of the node cost is realized according to the comparison of the node cost of the same project, the node cost budget of the project and the actual node cost in an industry database;

the engineering quality supervision comprises the following steps: the method comprises the steps that firstly, the recorded data of the engineering contract units and the provided historical operating conditions and credit conditions including materials, equipment and technologies are longitudinally analyzed through an industry database and network information, and compared with the related data of other similar units, the optimal supply contractor is selected, and the engineering quality is guaranteed; secondly, in the process of project proceeding, timely reminding quality hidden danger points of similar projects in an industry database, and carrying out early warning by combining progress data and the like;

the project progress supervision comprises the following steps: on one hand, the method emphasizes that the implementation condition of the project progress is tracked, checked and analyzed on the basis of carrying out comparative analysis on similar projects in an industry database, and meanwhile, progress condition data such as a construction department and a material supply department are compared with the project construction plan data in a row-column mode, so that the construction progress is supervised or adjusted at any time; in addition, weather real-time factors are fully considered in progress monitoring, and project progress is adjusted;

the engineering safety supervision comprises the following steps: on one hand, the occupational health safety and environmental supervision are brought into the standard by combining the safety supervision data of similar items of an industry database, and analysis and engineering adjustment are carried out on different data in various aspects of special weather condition records, geological conditions, historical protection scheme implementation data, underground pipeline distribution, construction equipment, construction machinery safety quality standards and canteen catering conditions in different seasons of a construction area; comprehensively analyzing the real-time condition of the engineering safety by combining the project real-time progress data, the real-time cost data and the real-time quality data;

after the laboratory is built, the collected temperature and humidity data of the laboratory are sent to an upper computer through a controller and then are sent to a big data server for storage through the upper computer for the temperature and humidity data and the local time of the laboratory.

The laboratory construction project supervision mechanism based on big data is formed by collecting a network and a professional database through a created top database to obtain a large amount of data related to the same project, extracting data from project cost, quality, progress and safety control indexes through a second layer database, and collecting historical data according to the project implementation time sequence; then, data analysis and comparison are carried out, the top-layer database is used for transversely comparing whether the project cost, quality, progress and safety control degree meet the standards, and the second-layer database is used for longitudinally comparing implementation standards of project cost, quality, progress and safety; and finally, implementing early warning and countermeasures, and taking control measures once contents which are inconsistent with the plan are found in data analysis. The system is scientific and reasonable, has a comprehensive, real and reliable data system and high practical value, and can effectively and comprehensively monitor, analyze and diagnose the engineering project of the laboratory engineering construction in real time, thereby avoiding the loss caused by improper cost, quality, progress and safety control. After the laboratory is built, the collected temperature and humidity data of the laboratory are sent to the upper computer through the controller and then are sent to the big data server for storage through the upper computer, and therefore the defect of insufficient big data can be supplemented in real time.

A method of a managed big data server based handling system, comprising: after the laboratory is built, the collected temperature and humidity data of the laboratory are sent to an upper computer through a temperature sensor and a humidity sensor in the laboratory, and the temperature and humidity data and the local time of the laboratory are sent to a big data server through the upper computer for storage;

the method for transmitting the collected temperature and humidity data of the laboratory to the upper computer through the controller runs on the controller, and comprises the following measures:

a1: the temperature sensor and the humidity sensor send the sensed temperature and humidity of the laboratory to the controller, and the controller immediately obtains the sensed temperature and humidity information of the laboratory when receiving the temperature and humidity information of the laboratory;

the temperature sensor and the humidity sensor send the sensed temperature and humidity of the laboratory to the controller, and the controller immediately obtains the sensed temperature and humidity information of the laboratory when receiving the temperature and humidity information of the laboratory;

a2: periodically traversing the information of the temperature and the humidity of the laboratory sensed in the set time period after the set time period, identifying the same information segment which continuously appears subsequently, processing the identified same information segment which continuously appears subsequently by using a deflate algorithm to reduce the size of the information of the temperature and the humidity of the laboratory, and organizing the information of the temperature and the humidity of the laboratory again to form initial information;

the set period of time is less than 8s;

at a2, the size of the information about the temperature and humidity of the laboratory is reduced, and the information about the temperature and humidity of the laboratory is reorganized to form initial information, including:

constructing a first information piece and a second information piece which correspond to the same information segment which continuously appears subsequently, wherein the first information piece is the capacity of the same information segment which continuously appears subsequently, and the second information piece is the number of bytes at intervals between the first byte of the same information segment which continuously appears subsequently and the first byte of the same previous information segment of the information segment plus one;

replacing the same information segment which continuously appears subsequently with the information piece I and the information piece II in the temperature and humidity information of the laboratory, so as to obtain the temperature and humidity information of the laboratory with the reduced size;

establishing a third information piece corresponding to the same information segment which continuously appears subsequently, wherein the third information piece is used for representing the position of a first information piece in the information of the temperature and the humidity of the laboratory with the reduced size, the first information piece is one of the first information piece and the second information piece, and the other information piece is positioned behind the first information piece;

and packaging the information of the temperature and the humidity of the laboratory after the size reduction and the information sheet III to organize the initial information.

To clarify the above, the following practical examples are given:

the information of the temperature and the humidity of the laboratory sensed in the periodic set period of time traversing the period of time comprises:

“15、16、17、18、19、20、21、16、17、18、19、2022, 24, 15, 17, 16, 18, … ", wherein the pause number represents a value of one byte before, and it can be determined by checking that" 16, 17, 18, 19, 20 "indicated by italics is the same information segment that continues to appear subsequently, and the processing is performed on the same information segment that continues to appear subsequently: that is, a first information piece and a second information piece corresponding to the same information segment that continues to appear subsequently can be constructed, where the first information piece is the capacity of the same information segment that continues to appear subsequently, the second information piece is the number of bytes spaced between the first byte of the same information segment that continues to appear subsequently and the first byte of the previous information segment that is the same as the information segment, plus one, that is, the value of the first information piece is five, which represents the number of bytes of the same information segment that continues to appear subsequently, the value of the second information piece is six, which represents the number of bytes spaced between the first byte of the same information segment that continues to appear subsequently and the first byte of the previous information segment that continues to appear subsequently, plus one, that is, "16, 17, 18, 19, 20, 21,16"the number of bytes between two 16 of said information pieces is five, then adds up to six, or the value of said information piece two is two, and represents the number of bytes between the first byte of the same information segment that appears subsequently and the last byte of the same previous information segment, then adds up to one, so that only one information piece can correctly represent that the first byte of the same information segment that appears subsequently is in the same position as the first byte of the same information segment that appears subsequentlyThe relative position of the information segment can be used as the information segment two, and it should be clarified that only two different modes for identifying the information segment two are given, after the guidance of the mode, the mode of the position of the same information segment which continuously appears subsequently can be identified by another mode for the information of the temperature and the humidity of a simpler laboratory, such as a plurality of same information segments which continuously appear subsequently and a single information segment which continuously appears for a plurality of times subsequently, and the mode obtained after the guidance of the mode does not exceed the related scope of the technical scheme. The same information section which continues to appear subsequently is replaced by the value five and the value six, so that the temperature and humidity information of the laboratory with the reduced size is obtained: "15, 16, 17, 18, 19, 20, 21, 5, 6, 22, 24, 15, 17, 16, 18, …"; therefore, the positions of the first information sheet and the second information sheet can be replaced with each other, so that the subsequent execution is not hindered; the upper computer needs to give the corresponding method for restoring the temperature and humidity information of the laboratory by means of the correlation between the positions of the first information sheet and the second information sheet, and the method is not affiliated to the scope of the technical scheme and is not elaborated. In addition, a third message track is constructed, the third message track is used for indicating the position of a header message track in the temperature and humidity information of the laboratory after the reduction in size, the header message track is one of a first message track and a second message track, the other message track is positioned behind the header message track, in detail, the third message track is used for indicating that the position of the header message track in the temperature and humidity information of the laboratory after the reduction in size can be that the first byte of the header message track is positioned on the fourth byte of the temperature and humidity information of the laboratory after the reduction in size, so that the value of the third message track is eight, and it is stated that because of few practical examples of the third message track, a single mode of identifying the third message track is given, and after the mode is guided, temperature and humidity information for a less simple laboratory having several subsequent continuous information pieces, a single subsequent continuous information piece several timesThe mode of the third information piece can be identified by another mode, and the mode obtained after the inspiration does not exceed the related scope of the technical proposal.

Then packaging the information of the temperature and the humidity of the laboratory after the size reduction, namely '15, 16, 17, 18, 19, 20, 21, 5, 6, 22, 24, 15, 17, 16, 18, …' and the information piece three with the value of eight to organize the initial information; when the third upper computer obtains the initial information and performs restoration of the temperature and humidity information of the laboratory, and when the third information piece determines the position of the first information piece, it can be understood that the information piece immediately after the first information piece is another information piece, not the temperature and humidity information of the laboratory.

A3: the controller sends an initial message to the upper computer.

The method comprises the steps that the temperature sensor and the humidity sensor send the sensed temperature and humidity of the laboratory to the controller, the controller receives the information of the temperature and humidity of the laboratory, then the sensed information of the temperature and humidity of the laboratory is obtained immediately, the information of the temperature and humidity of the laboratory sensed in the period is traversed periodically after a set period, the same information segment which continuously appears subsequently is identified, the identified same information segment which continuously appears subsequently is processed to reduce the size of the information of the temperature and humidity of the laboratory, the information of the temperature and humidity of the laboratory is organized again to form initial information, and the information capacity is the same as the information of the temperature and humidity of the laboratory which does not reduce the size of the information of the temperature and humidity of the laboratory on the same information segment which continuously appears subsequently, the information capacity is greatly reduced, the capacity transmitted to the upper computer is reduced, the cost is low, and the cost is reduced more easily.

The capacity of the temperature and humidity information of the laboratory is not small, the initial temperature and humidity information of the laboratory is directly transmitted to the upper computer in the current mode, information blockage of a communication network is often formed on one hand, the temperature and humidity information of the laboratory with the small capacity is obtained on the other hand, resource waste is not small, and realization of other functions is not facilitated on the other hand.

After the temperature sensor and the humidity sensor send the sensed temperature and humidity of the laboratory to the controller, a process of treating the information of the temperature and humidity of the laboratory, which includes the following sequential execution, is performed:

s1: when the temperature and humidity information of the laboratory is transmitted to the controller, a mapping relation is established between the time point of transmitting the temperature and humidity information of the laboratory to the controller and the temperature and humidity information of the laboratory, in addition, a time interval is randomly set, and the temperature and humidity information of all the laboratories in the time interval is arranged according to the time sequence of transmitting the temperature and humidity information of the laboratory to the controller when one time interval passes, so that the temperature and humidity information I, the temperature and humidity information II, the temperature and humidity information III … … of the laboratory are sequentially arranged according to the time sequence, and the time points of mapping the temperature and humidity information K of the laboratory with the temperature and humidity information I, the temperature and humidity information II, the temperature and humidity information III … … of the laboratory are respectively the time point I, the time point K, A second time point and a third time point … … time point k, wherein k is a positive integer and represents the number of information of the temperature and the humidity of the laboratory in the time interval;

s2: assigning a variable one in the controller to be L, wherein the value of L at the moment is one;

s3: deriving a fitting value of the intermediate time point, specifically performing the following steps:

3-1: the sum of L plus one and the sum of L plus two are respectively M and N, the time point L, the time point M and the time point N are firstly obtained, and then the information L of the temperature and the humidity of the laboratory, the information M of the temperature and the humidity of the laboratory and the information N of the temperature and the humidity of the laboratory, which are respectively mapped with the time point L, the time point M and the time point N, are obtained, wherein L, M and N are positive integers, and N is not more than k; it should be clarified that it is not necessary to distinguish which of the information L of the temperature and humidity of the laboratory, the information M of the temperature and humidity of the laboratory, and the information N of the temperature and humidity of the laboratory is the information of the temperature and humidity of the laboratory with the time delay change, that is, the treatment is performed on the condition that the information of the temperature and humidity of the whole laboratory has the time delay change;

3-2: by means of the information L of the temperature and the humidity of the laboratory and the information N of the temperature and the humidity of the laboratory, which are respectively mapped by the time point L and the time point N, the time point L is used as an independent variable, the information L of the temperature and the humidity of the laboratory is used as a dependent variable of the time point L, the time point N is used as an independent variable, and the information N of the temperature and the humidity of the laboratory is used as a dependent variable of the time point N for carrying out exponential fitting, then a fitting value corresponding to the time point M is obtained according to an exponential fitting formula, the fitting value is the fitting value of the middle time point, and the algorithm of exponential fitting in 3-2 is a least square method;

s4: and deriving a standby value of the intermediate time point as follows:

dividing the sum obtained by adding the fitting value of the middle time point and the standby value of the middle time point by two to obtain a mean value, wherein the mean value is the standby value of the middle time point;

s5: deriving a final fitted value for any time point O in the time interval:

5-1: comparing the time points M with the time intervals between the time points L and N respectively, and selecting the time point L or the time point N with smaller time interval as the standby time point;

5-2: by means of the information of the temperature and the humidity of the laboratory mapped by the standby time point and the standby time point obtained in the step 5-1 and the standby value of the standby time point, namely the time point M and the standby value of the standby time point, the standby time point is used as an independent variable, the information of the temperature and the humidity of the laboratory mapped by the standby time point is used as a dependent variable of the standby time point, the time point M is used as an independent variable and the standby value of the standby time point is used as a dependent variable of the time point M for carrying out exponential fitting, then the fitting value of any time point O in the time interval is obtained according to an exponential fitting formula, the fitting value is the fitting value of the any time point O, and the algorithm of the exponential fitting in the step 5-2 is a least square method;

s6: and judging whether N is equal to k, if N is equal to k, terminating the process of processing the temperature and humidity information of the laboratory, and if N is not equal to k, adding one to the current value of L to be the value of L, and going to S3 to execute the subsequent derivation.

3-2, by means of the information L of the temperature and the humidity of the laboratory and the information N of the temperature and the humidity of the laboratory, which are respectively mapped by the time point L and the time point N, performing exponential fitting by taking the time point L as an independent variable, taking the information L of the temperature and the humidity of the laboratory as an independent variable, taking the time point N as an independent variable and taking the information N of the temperature and the humidity of the laboratory as a dependent variable of the time point N, and then obtaining a fitting value corresponding to the time point M according to an exponential fitting formula, wherein the fitting value is the fitting value of the middle time point, and the algorithm of the exponential fitting in 3-2 is a least square method. Because of the strong randomness of the delay variation, the least squares method finds the best functional match of the data by minimizing the sum of the squares of the errors. Unknown data can be easily obtained by the least square method, and the sum of squares of errors between these obtained data and actual data is minimized.

In this regard, in an implementation, the time point L, the time point M, and the time point N are obtained first, and then the information L of the temperature and humidity of the laboratory, the information M of the temperature and humidity of the laboratory, and the information N of the temperature and humidity of the laboratory, which are mapped with the time point L, the time point M, and the time point N, respectively, are obtained. And obtaining a first fitting value of the arbitrary time point O by means of interpolation obtained by performing exponential fitting on the information L of the temperature and the humidity of the laboratory and the information M of the temperature and the humidity of the laboratory, which are mapped by the time point L and the time point M, and keeping the error of the actual state of the data small. Therefore, the method obtains the corresponding fitting value of the time point M in advance by means of the information L of the temperature and the humidity of the laboratory and the information N of the temperature and the humidity of the laboratory, which are respectively mapped by the time point L and the time point N; and then, averaging the information M of the temperature and the humidity of the laboratory mapped by the simultaneous point M, wherein the time interval between the time point L and the time point M is assumed to be smaller, so that a final fitting value two of any time point O is derived by combining the information L of the temperature and the humidity of the laboratory corresponding to the time point L and the time point M and the average value through exponential fitting. And comparing the first fitting value with the second fitting value which is closer to the true value of the data of any time point O, so that the deviation caused by time delay change is reduced.

The fitting value of the middle time point is derived by firstly obtaining the time point L, the time point M and the time point N, then obtaining the information L of the temperature and the humidity of the laboratory, the information M of the temperature and the humidity of the laboratory and the information N of the temperature and the humidity of the laboratory which are respectively mapped with the time point L, the time point M and the time point N, then deriving the standby value of the middle time point, and deriving the final fitting value of any time point O in the time interval. Compared with the current mode, the method reduces the fitting deviation caused by the time delay change, improves the fitting accuracy during the time delay change and is very effective for reducing the negative effect during the time delay change.

The server cabinet can ventilate the inside of the cabinet body 501 through a through groove I503 at the lower part of the cabinet body 501, two through grooves II 504 are arranged at two sides of the cabinet body 501 to facilitate the inside of the cabinet body 501 to refrigerate, a cuboid positioning frame 511 is fixedly connected with one side of the cabinet body 501, a motor I513 arranged in the cuboid positioning frame 511 pulls a rotary vane-shaped vane 514 to rotate through the rotary kinetic energy of the motor I513, the rotary kinetic energy of the rotary vane-shaped vane 514 refrigerates the inside of the cabinet body 501, a container 509 containing refrigerating fluid is arranged at one side of the cabinet body 501, a cavity II 508 with two through holes communicated with each other through the container 509 containing refrigerating fluid is communicated with a pumping motor 506 through a cavity II 508 with two through holes, the cavity II 508 with two through holes communicated with each other through two holes is communicated with the pumping motor 506, the cavity I507 with the pumping motor 506 through two holes communicated with each other through the water outlet end of the pumping motor 506, a wave-shaped cavity channel 510 with each other through two holes and a condensing pipe 516, the reciprocating motion of the refrigerant liquid in the container 509 filled with the refrigerant liquid can be achieved, the refrigerant liquid is fixedly connected with the refrigerating machine 515 through the wavy cavity 510 with two through ends, the refrigerating machine 515 can be refrigerated, and the refrigerating speed is improved.

According to the server cabinet with the refrigerating function, the inside of the cabinet body 501 can be refrigerated through the first motor 513 and the rotary blade 514, the cabinet body 501 can be refrigerated through the wavy cavity 510 with two through ends, the refrigerator 515 and the container 509 containing the refrigerating fluid, the server cabinet can be efficiently refrigerated, a large data server inside the cabinet body 501 can be efficiently refrigerated, and the refrigerating speed is improved. In addition, the server cabinet can execute the reciprocating motion of the refrigerant through the two through cavities 508, the two through cavities 507 and the wavy through cavities 510, so that the refrigeration speed can be improved, and the damage to a large data server in the server cabinet can be reduced. In addition, the server cabinet can execute the reciprocating motion of the refrigerant through the two through cavities 508, the two through cavities 507 and the wavy through cavities 510, so that the refrigeration speed can be improved, and the damage to a large data server in the server cabinet can be reduced.

The present invention has been described in an illustrative manner by the embodiments, and it should be understood by those skilled in the art that the present disclosure is not limited to the embodiments described above, but is capable of various changes, modifications and substitutions without departing from the scope of the present invention.

Claims (6)

1. A handling system of a big data server based on management is characterized by comprising a monitoring terminal and a big data server, wherein the monitoring terminal is connected with the big data server through a network, and the monitoring terminal and the big data server mutually transmit interactive data to realize laboratory engineering management;

after the construction of the laboratory is finished, a temperature sensor and a humidity sensor are also arranged in the laboratory, the temperature sensor and the humidity sensor are connected with a controller, the controller is connected with an upper computer, and the upper computer is connected with a big data server through a network;

a variable one is set in the controller;

the controller comprises a fitting value deriving module, a standby value deriving module and a final fitting value deriving module;

the big data server is arranged in a cuboid-shaped server cabinet, the server cabinet comprises a cabinet body, the lower part of the cabinet body is fixedly connected with a base, the lower part of the cabinet body is provided with a first through groove, two sides of the inner surface of the cabinet body are fixedly connected with a supporting platform for placing the big data server, two sides of the cabinet body are provided with a second through groove, one side of the cabinet body is provided with a through containing groove at the lower position of the second through groove, the inner surface of the through containing groove is fixedly connected with a cuboid-shaped positioning frame, the top point of the cuboid-shaped positioning frame is provided with a positioning screw rod, a spiral groove of the positioning screw rod penetrates through a screw groove of the cuboid-shaped positioning frame and is in threaded connection with the screw groove on the cabinet body, a first motor is arranged inside the cuboid-shaped positioning frame, the outer wall of the first motor is fixedly connected with a columnar supporting piece, the end, farther away from the first motor, of the columnar supporting piece is fixedly connected with the cuboid-shaped positioning frame, and a rotating rod of the first motor is fixedly connected with a propeller piece, one side of the cuboid positioning frame is fixedly connected with a refrigerating machine, the refrigerating machine is communicated with the outside of the cabinet body, the wavy cavity channel with two through ends is fixedly connected with the refrigerating machine in a welding way, one side of the refrigerating machine, which is positioned inside the cuboid positioning frame, is fixedly connected with the wavy cavity channel with two through ends, one side of the cabinet body is fixedly connected with a water pumping motor, the water pumping motor is fixedly connected with the cabinet body in a welding way, a container containing refrigerating fluid is fixedly connected with the cabinet body in a welding way, the water outlet end of the water pumping motor is communicated with the cavity channel with two through ends, the cavity channel with two through ends is communicated with the cavity channel with two through ends, the other end, which is farther away from the water pumping motor, of the cavity channel with two through ends is communicated with the container containing refrigerating fluid through the cuboid positioning frame sequentially through the cabinet body and the wavy cavity channel with two through ends, the other end, which is farther away from the cavity channel with two through ends, penetrates through the cuboid positioning frame and extends Outside the rectangular positioning frame, the upper end of the rectangular positioning frame is provided with a condenser pipe, the end, away from the cavity with two communicated ends, of the wavy cavity is communicated with the condenser pipe, the end, away from the cavity with two communicated ends, of the wavy cavity is further communicated with the condenser pipe, one side of the cabinet body, which is positioned at the lower position of the water pumping motor, is fixedly connected with a container containing refrigerating fluid, and the end, away from the cavity with two communicated ends, of the condenser pipe is communicated with the container containing refrigerating fluid; after the laboratory is built, the collected temperature and humidity data of the laboratory are sent to an upper computer through a temperature sensor and a humidity sensor in the laboratory, and the temperature and humidity data and the local time of the laboratory are sent to a big data server through the upper computer for storage;

the method for transmitting the collected temperature and humidity data of the laboratory to the upper computer through the controller runs on the controller, and comprises the following measures:

a1: the temperature sensor and the humidity sensor send the sensed temperature and humidity of the laboratory to the controller, and the controller immediately obtains the sensed temperature and humidity information of the laboratory when receiving the temperature and humidity information of the laboratory;

a2: periodically traversing the information of the temperature and the humidity of the laboratory sensed in the set time period after the set time period, identifying the same information segment which continuously appears subsequently, processing the identified same information segment which continuously appears subsequently to reduce the size of the information of the temperature and the humidity of the laboratory, and organizing the information of the temperature and the humidity of the laboratory again to form initial information; the set period of time is less than 8s;

at a2, the size of the information about the temperature and humidity of the laboratory is reduced, and the information about the temperature and humidity of the laboratory is reorganized to form initial information, including:

constructing a first information piece and a second information piece which correspond to the same information segment which continuously appears subsequently, wherein the first information piece is the capacity of the same information segment which continuously appears subsequently, and the second information piece is the number of bytes at intervals between the first byte of the same information segment which continuously appears subsequently and the first byte of the same previous information segment of the information segment plus one;

replacing the same information segment which continuously appears subsequently with the information piece I and the information piece II in the temperature and humidity information of the laboratory, so as to obtain the temperature and humidity information of the laboratory with the reduced size;

establishing a third information piece corresponding to the same information segment which continuously appears subsequently, wherein the third information piece is used for representing the position of a first information piece in the information of the temperature and the humidity of the laboratory with the reduced size, the first information piece is one of the first information piece and the second information piece, and the other information piece is positioned behind the first information piece;

packaging the information of the temperature and the humidity of the laboratory after the size reduction and the information sheet III to organize the initial information;

the information of the temperature and the humidity of the laboratory sensed in the periodic set period of time traversing the period of time comprises:

"15, 16, 17, 18, 19, 20, 21, 16, 17, 18, 19, 20, 22, 24, 15, 17, 16, 18, …", assuming that the italicized symbol "16, 17, 18, 19, 20" is the same information segment that continues to appear subsequently, the processing must be performed on the same information segment that continues to appear subsequently: namely, a first information piece and a second information piece which correspond to the same information segment which continuously appears subsequently can be constructed, the first information piece is the capacity of the same information segment which continuously appears subsequently, the second information piece is the number of bytes which are spaced between the first byte of the same information segment which continuously appears subsequently and the first byte of the previous information segment which is the same as the information segment, namely the number of the first information piece is five, the number represents the number of bytes of the same information segment which continuously appears subsequently, the second information piece is six, the number represents the number of bytes which are spaced between the first byte of the same information segment which continuously appears subsequently and the first byte of the previous information segment which is the same as the information segment, namely the number of bytes between two 16 of the information segments of 16, 17, 18, 19, 20, 21 and 16' is five, and then the number of the bytes is six, or the value of the second information piece is two, which represents the number of the bytes at the interval between the first byte of the same information segment which continues to appear subsequently and the last byte of the same previous information segment of the information segment plus one; the same information section which continues to appear subsequently is replaced by the value five and the value six, so that the temperature and humidity information of the laboratory with the reduced size is obtained: "15, 16, 17, 18, 19, 20, 21, 5, 6, 22, 24, 15, 17, 16, 18, …"; the positions of the first information sheet and the second information sheet can be replaced with each other; in addition, a third message piece is constructed, the third message piece is used for indicating the position of a header message piece in the temperature and humidity information of the reduced laboratory, the header message piece is one of the first message piece and the second message piece, the other message piece is positioned behind the header message piece, the third message piece is used for indicating the position of the header message piece in the temperature and humidity information of the reduced laboratory, the first byte of the header message piece can be positioned on the several bytes in the temperature and humidity information of the reduced laboratory, the value of the third message piece is eight, and then the temperature and humidity information of the reduced laboratory, namely' 15, 16, 17, 18, 19, 20, 21, 5, 6, 22, 24, 15, 17. 16, 18, …' and the information piece three with the value of eight are packaged to organize the initial information;

a3: the controller sends an initial message to the upper computer;

in addition, after the temperature sensor and the humidity sensor send the sensed temperature and humidity of the laboratory to the controller, the process of treating the temperature and humidity information of the laboratory, which comprises the following steps of sequentially executing:

s1: when the temperature and humidity information of the laboratory is transmitted to the controller, a mapping relation is established between the time point of transmitting the temperature and humidity information of the laboratory to the controller and the temperature and humidity information of the laboratory, in addition, a time interval is randomly set, and the temperature and humidity information of all the laboratories in the time interval is arranged according to the time sequence of transmitting the temperature and humidity information of the laboratory to the controller when one time interval passes, so that the temperature and humidity information I, the temperature and humidity information II, the temperature and humidity information III … … of the laboratory are sequentially arranged according to the time sequence, and the time points of mapping the temperature and humidity information K of the laboratory with the temperature and humidity information I, the temperature and humidity information II, the temperature and humidity information III … … of the laboratory are respectively the time point I, the time point K, A second time point and a third time point … … time point k, wherein k is a positive integer and represents the number of information of the temperature and the humidity of the laboratory in the time interval;

s2: assigning a variable one in the controller to be L, wherein the value of L at the moment is one;

s3: deriving a fitting value of the intermediate time point, specifically performing the following steps:

3-1: the sum of L plus one and the sum of L plus two are respectively M and N, the time point L, the time point M and the time point N are firstly obtained, and then the information L of the temperature and the humidity of the laboratory, the information M of the temperature and the humidity of the laboratory and the information N of the temperature and the humidity of the laboratory, which are respectively mapped with the time point L, the time point M and the time point N, are obtained, wherein L, M and N are positive integers, and N is not more than k;

3-2: by means of the information L of the temperature and the humidity of the laboratory and the information N of the temperature and the humidity of the laboratory, which are respectively mapped by the time point L and the time point N, the time point L is used as an independent variable, the information L of the temperature and the humidity of the laboratory is used as a dependent variable of the time point L, the time point N is used as an independent variable, and the information N of the temperature and the humidity of the laboratory is used as a dependent variable of the time point N for carrying out exponential fitting, then a fitting value corresponding to the time point M is obtained according to an exponential fitting formula, the fitting value is the fitting value of the middle time point, and the algorithm of exponential fitting in 3-2 is a least square method;

s4: and deriving a standby value of the intermediate time point as follows:

dividing the sum obtained by adding the fitting value of the middle time point and the standby value of the middle time point by two to obtain a mean value, wherein the mean value is the standby value of the middle time point;

s5: deriving a final fitted value for any time point O in the time interval:

5-1: comparing the time points M with the time intervals between the time points L and N respectively, and selecting the time point L or the time point N with smaller time interval as the standby time point;

5-2: by means of the information of the temperature and the humidity of the laboratory mapped by the standby time point and the standby time point obtained in the step 5-1 and the standby value of the standby time point, namely the time point M and the standby value of the standby time point, the standby time point is used as an independent variable, the information of the temperature and the humidity of the laboratory mapped by the standby time point is used as a dependent variable of the standby time point, the time point M is used as an independent variable and the standby value of the standby time point is used as a dependent variable of the time point M for carrying out exponential fitting, then the fitting value of any time point O in the time interval is obtained according to an exponential fitting formula, the fitting value is the fitting value of the any time point O, and the algorithm of the exponential fitting in the step 5-2 is a least square method;

s6: judging whether N is equal to k, if N is equal to k, terminating the process of treating the information of the temperature and the humidity of the laboratory, if N is not equal to k, adding one to the current value of L to be the value of L, and going to S3 to execute the process;

the server cabinet can ventilate the inside of the cabinet body through a first through groove at the lower part of the cabinet body, two through grooves are arranged at two sides of the cabinet body to be beneficial to refrigerating the inside of the cabinet body, a cuboid positioning frame is fixedly connected at one side of the cabinet body, a first motor arranged in the cuboid positioning frame pulls a rotary vane-shaped paddle to rotate through the rotary kinetic energy of the first motor, the rotary kinetic energy of the rotary vane-shaped paddle refrigerates the inside of the cabinet body, a container containing refrigerating fluid is arranged at one side of the cabinet body, a second cavity communicated with the two ends of the container containing the refrigerating fluid is communicated with a pumping motor through the second cavity communicated with the two ends of the container containing the refrigerating fluid, the refrigerating fluid in the container containing the refrigerating fluid can be extracted, and the reciprocating motion of the refrigerating fluid in the container containing the refrigerating fluid can be achieved through the first cavity communicated with the water outlet end of the pumping motor, the wavy cavity channel communicated with the two ends of the condensing pipe, the wavy cavity channel with two through ends is fixedly connected with the refrigerator in a welding way, so that the refrigerator can be refrigerated.

2. The managed big data server-based treatment system of claim 1, wherein the derive fit values module is to derive fit values for a medium time point.

3. The managed big data server-based handling system of claim 1, wherein the derived standby value module is to derive a standby value for a medium time point.

4. The managed big data server-based treatment system of claim 1, wherein the derive last fit value module is to derive a last fit value for any time point O in the long interval.

5. The system according to claim 1, wherein the number of the second through-slots is six or more, and all the second through-slots are arranged at equal intervals.

6. The managed big data server-based handling system according to claim 1, comprising: the identified subsequent occurrences of the same piece of information are processed to reduce the size of the temperature and humidity information for the laboratory in a manner that the identified subsequent occurrences of the same piece of information are processed with a deflate algorithm to reduce the size of the temperature and humidity information for the laboratory.

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