CN113010518A - Method and device for processing pipeline cleaning data - Google Patents
Method and device for processing pipeline cleaning data Download PDFInfo
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- 238000005406 washing Methods 0.000 claims description 19
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- G06F16/2474—Sequence data queries, e.g. querying versioned data
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- G—PHYSICS
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Abstract
The invention provides a method and a device for processing pipeline cleaning data, wherein the processing method comprises the following steps: acquiring a time sequence arranged in a time sequence; the method comprises the steps of obtaining the length of a target pipeline, and obtaining the conductivity of wastewater flowing out of a water outlet of the target pipeline, the instantaneous flow of the wastewater, the temperature of the wastewater, the concentration of suspended matters in the wastewater and the turbidity of the wastewater at each time in the process of carrying out ice slurry cleaning on the inner wall of the target pipeline, and the total ice consumption and the total salt consumption in the process of ice slurry cleaning; and generating the starting time and the ending time of cleaning, the total consumed time, the total water consumption, the total mass of flushed sediments, the mass of sediments in unit pipe length, the salinity residual rate and generating a report. In summary, the processing method can generate a report, which is convenient for the staff to check various data indexes in the current operation.
Description
Technical Field
The invention relates to the technical field of ice slurry pipe cleaning, in particular to a method and a device for processing pipeline cleaning data.
Background
With the increase of the service life of the water pipeline, oxygen in water and the pipeline generate oxidation reaction, or the poor filtering effect in the water treatment stage can cause the accumulation of iron and manganese element deposits on the pipe wall. The accumulation of the sediments causes the inner diameter of the pipe to be reduced, the water quantity is insufficient, the water supply is not smooth, and the pipeline can be blocked in serious cases. In addition, when the content of manganese or aluminum elements in water is high and the water is not effectively chlorinated, the growth of a biological film is easily caused, the biological film reacts with certain elements in the water of a pipe network to cause the water quality to deteriorate, so that microorganisms in the water multiply, bacterial colonies increase and the threat to the health of people is caused. Therefore, the inner wall of the water pipe needs to be cleaned frequently.
Wherein, the ice slurry pigging is a pipeline inner wall cleaning technology who commonly uses, and its rationale is: the inner wall of the pipeline is cleaned by injecting ice slurry to remove the mineral deposits, biological films and other deposits. However, in the cleaning process or after the cleaning process, the staff lacks a method for checking various data indexes in the current operation, lacks effective data for evaluating whether the operation result is good or not, and lacks a record and retention means for ice slurry pigging operation.
Disclosure of Invention
The invention aims to provide a method and a device for processing pipeline cleaning data.
In order to achieve one of the above objects, an embodiment of the present invention provides a method for processing pipeline cleaning data, including the steps of: obtaining a time sequence T arranged in time sequenceiN, N is a natural number; acquiring the length L of the target pipeline, and cleaning the inner wall of the target pipeline at each time T in the ice slurry cleaning processiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateriAnd total ice and salt consumption during the ice slurry wash; from said time series TiObtaining a cleaning start time TsAnd a washing end time TeAnd 1 is equal to or less than s<e is less than or equal to N; generating the total time consumption T of the ice slurry cleaninge-TsGenerating the average value of the instantaneous flow (T) of the total water consumption of the ice slurry cleaninge-Ts) Total consumption of ice, resulting in deposits washed out by this washing of the ice slurry Generating deposits per unit length of pipe in the current ice slurry washThe salt residue rate of the ice slurry cleaning at the time is (total salt consumption-saltSum)/total salt consumption, wherein, generating a report, wherein the report at least comprises: total time, total water consumption, total mass of flushed out sediment, mass of sediment per unit length of tube, and residual salt content.
As a further improvement of an embodiment of the present invention, the report further includes: a minimum value, a maximum value, and an average value of the temperature of the wastewater; a minimum value, a maximum value and an average value of the flow rate of the wastewater; a minimum, maximum, and average value of the conductivity of the wastewater; a minimum value, a maximum value, and an average value of the turbidity of the wastewater; minimum, maximum and average values of suspended matter concentration in the wastewater.
As a further improvement of an embodiment of the present invention, the method further comprises the following steps: and converting the report into a corresponding pdf file.
As a further improvement of an embodiment of the present invention, said "from said time series TiObtaining a cleaning start time TsAnd a washing end time TeAnd 1 is equal to or less than s<N ≦ e "specifically includes: from said time series TiObtaining a cleaning start time TsAnd a washing end time TeWherein F issNot less than a first preset threshold value, and Fj<A first preset threshold, j ═ 1, 2, 3.., s-1; ceNot more than a second predetermined threshold value, and Ck>A second predetermined threshold value, k ═ m, m + 1., e-1, and s is not less than 1<m<e≤N。
As a further improvement of one embodiment of the invention, the step of "cleaning the inner wall of the target pipeline with ice slurry at each time TiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateri", specifically includes: during the ice slurry cleaning process of the inner wall of the target pipeline, at each time TiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateriThen, to the conductivity CiInstantaneous flow rate FiTemperature TempiSuspended matter concentration DiAnd turbidity TubiAnd performing smooth noise reduction processing.
The embodiment of the invention discloses a processing device of pipeline cleaning data, which comprises the following modules: a time sequence acquisition module for acquiring the time sequence T arranged in time sequenceiN, N is a natural number; a parameter acquisition module for acquiring the length L of the target pipeline and performing ice slurry cleaning on the inner wall of the target pipeline at each time TiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateriAnd total ice and salt consumption during the ice slurry wash; a data processing module for processing the time series TiObtaining a cleaning start time TsAnd a washing end time TeAnd 1 is equal to or less than s<e is less than or equal to N; generating the total time consumption T of the ice slurry cleaninge-TsGenerating the average value of the instantaneous flow (T) of the total water consumption of the ice slurry cleaninge-Ts) -total consumption of ice, resulting in the rinsing of the ice slurryOf the discharged depositGenerating deposits per unit length of pipe in the current ice slurry washThe salt residue rate of the ice slurry cleaning at the time is (total salt consumption-saltSum)/total salt consumption, wherein, the report module is used for generating a report, and the report at least comprises: total time, total water consumption, total mass of flushed out sediment, mass of sediment per unit length of tube, and residual salt content.
As a further improvement of an embodiment of the present invention, the report further includes: a minimum value, a maximum value, and an average value of the temperature of the wastewater; a minimum value, a maximum value and an average value of the flow rate of the wastewater; a minimum, maximum, and average value of the conductivity of the wastewater; a minimum value, a maximum value, and an average value of the turbidity of the wastewater; minimum, maximum and average values of suspended matter concentration in the wastewater.
As a further improvement of an embodiment of the present invention, the present invention further includes the following modules: and the format processing module is used for converting the report into a corresponding pdf file.
As a further improvement of an embodiment of the present invention, the data processing module is further configured to: from said time series TiObtaining a cleaning start time TsAnd a washing end time TeWherein F issNot less than a first preset threshold value, and Fj<A first preset threshold, j ═ 1, 2, 3.., s-1; ceNot more than a second predetermined threshold value, and Ck>A second predetermined threshold value, k ═ m, m + 1., e-1, and s is not less than 1<m<e≤N。
As a further embodiment of the present inventionIn an improvement, the parameter obtaining module is further configured to: during the ice slurry cleaning process of the inner wall of the target pipeline, at each time TiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateriThen, to the conductivity CiInstantaneous flow rate FiTemperature TempiSuspended matter concentration DiAnd turbidity TubiAnd performing smooth noise reduction processing.
Compared with the prior art, the invention has the technical effects that: the embodiment of the invention provides a method and a device for processing pipeline cleaning data, wherein the processing method comprises the following steps: acquiring a time sequence arranged in a time sequence; the method comprises the steps of obtaining the length of a target pipeline, and obtaining the conductivity of wastewater flowing out of a water outlet of the target pipeline, the instantaneous flow of the wastewater, the temperature of the wastewater, the concentration of suspended matters in the wastewater and the turbidity of the wastewater at each time in the process of carrying out ice slurry cleaning on the inner wall of the target pipeline, and the total ice consumption and the total salt consumption in the process of ice slurry cleaning; and generating the starting time and the ending time of cleaning, the total consumed time, the total water consumption, the total mass of flushed sediments, the mass of sediments in unit pipe length, the salinity residual rate and generating a report. In summary, the processing method can generate a report, which is convenient for the staff to check various data indexes in the current operation.
Drawings
FIG. 1 is a schematic flow chart of a method for processing pipeline cleaning data according to the present invention;
fig. 2 is a structural diagram of a report in the present invention.
Detailed Description
The present invention will be described in detail below with reference to embodiments shown in the drawings. These embodiments are not intended to limit the present invention, and structural, methodological, or functional changes made by those skilled in the art according to these embodiments are included in the scope of the present invention.
Terms such as "upper," "above," "lower," "below," and the like, used herein to denote relative spatial positions, are used for ease of description to describe one element or feature's relationship to another element or feature as illustrated in the figures. The spatially relative positional terms may be intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as "below" or "beneath" other elements or features would then be oriented "above" the other elements or features. Thus, the exemplary term "below" can encompass both an orientation of above and below. The device may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.
Also, it should be understood that, although the terms first, second, etc. may be used herein to describe various elements or structures, these described elements should not be limited by these terms. These terms are only used to distinguish these descriptive objects from one another. For example, a first control instruction may be referred to as a second control instruction, and similarly a second control instruction may also be referred to as a first control instruction, without departing from the scope of the present application.
The embodiment of the invention provides a method for processing pipeline cleaning data, which comprises the following steps as shown in figure 1:
step 101: obtaining a time sequence T arranged in time sequenceiN, N is a natural number; here, the time series TiIn chronological order, thus Tj+1-Tj>0, j ═ 1, 2,. ang, N-1; in practical use, the related parameters (namely the conductivity C) of the ice slurry cleaning can be obtained every other preset timeiInstantaneous flow rate FiTemperature TempiSuspended matter concentration DiAnd turbidity TubiEtc.), therefore, adjacent TiThe time intervals between may be equal or vary little, i.e. Tj+1-TjIs a constant value or varies little.
Step 102: acquiring the length L of the target pipeline, and cleaning the inner wall of the target pipeline at each time T in the ice slurry cleaning processiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateriAnd total ice and salt consumption during the ice slurry wash;
conductivity here generally refers to the ability of a solution to conduct current, in siemens per meter. The instantaneous flow refers to the amount of fluid flowing through the water outlet of the target pipeline in unit time; the suspended matter refers to solid matters suspended in the wastewater, including inorganic matters, organic matters, silt, clay, microorganisms and the like which are insoluble in the water, and the concentration of the suspended matters in the water is one of indexes for measuring the water pollution degree; turbidity is one of the physical property indexes of water. It characterizes the degree of light transmission inhibition by suspended substances in water. Generally, the more insoluble matter in water, the higher the turbidity. Turbidity is formed by the presence of particulate matter such as clay, sludge, colloidal particles, plankton and other microorganisms in water, and is an important indicator for determining the degree of clarity or turbidity of water.
Here, several sensors may be provided in the target pipe for acquiring these parameters, e.g., (1) conductivity C of the wastewater may be measured at the water outlet of the target pipe using a conductivity sensoriThe principle may be that two parallel plates are put into the effluent wastewater, a certain potential (usually a sine wave voltage) is applied across the plates, and then the current flowing between the plates is measured. The conductivity is measured according to ohm's law, the inverse of the conductivity (G) -resistance (R); the instantaneous flow F of the wastewater can be measured at the outlet of the target pipe using a flow sensoriThe flow meter can be a differential pressure type flow meter, a speed type flow meter, a time difference type ultrasonic flow meter or a volumetric flow meter and the like; (3) the temperature T can be measured at the water outlet of the target pipe by using a temperature sensorempi(ii) a (4) The suspended matter concentration D can be measured by using a suspended matter concentration meter at the water outlet of the target pipelineiThe suspended matter concentration meter can be composed of a transmitter and a sensor, infrared light sent by the transmitter on the sensor is absorbed, reflected and scattered by a measured object in the transmission process, only a small part of light can irradiate the detector, and the transmittance of transmitted light has a certain relation with the concentration of measured wastewater, so that the concentration of the wastewater can be calculated by measuring the transmittance of the transmitted light; (5) the turbidity Tub can be measured at the outlet of the target pipeline by using a photoelectric turbidimeteri。
Here, in practice, five file csv (Comma-Separated Values) files for storing the conductivity C, respectively, may be created respectivelyiInstantaneous flow rate FiTemperature TempiSuspended matter concentration DiAnd turbidity TubiIt is understood that, in the process of ice slurry cleaning of the inner wall of the target pipe, one conductivity C is obtained each timeiInstantaneous flow rate FiTemperature TempiSuspended matter concentration DiAnd turbidity TubiThen the time T is obtainediAnd these values are added to the corresponding csv file, i.e. time TiAnd electrical conductivity CiAdding to the corresponding csv file, time TiAnd instantaneous flow rate FiAdding to the corresponding csv file, time TiAnd temperature TempiAdding to the corresponding csv file, time TiAnd suspended matter concentration DiAdded to the corresponding csv file. Will time TiAnd turbidity TubiAdded to the corresponding csv file. After the ice slurry is washed, acquiring the total ice consumption and the total salt consumption;
step 103: from said time series TiObtaining a cleaning start time TsAnd a washing end time TeAnd 1 is equal to or less than s<e is less than or equal to N; generating the total time consumption T of the ice slurry cleaninge-TsGenerating the average value of the instantaneous flow (T) of the total water consumption of the ice slurry cleaninge-Ts) -total consumption of ice, generating this time of ice slurryCleaning the dislodged depositsGenerating deposits per unit length of pipe in the current ice slurry washThe salt residue rate of the ice slurry cleaning at the time is (total salt consumption-saltSum)/total salt consumption, wherein,
step 104: generating a report, wherein the report at least comprises: total time, total water consumption, total mass of flushed out sediment, mass of sediment per unit length of tube, and residual salt content. Here, the report may take a variety of formats, such as an Html (Hyper Text Markup Language) web page, a word document, and the like.
In summary, the processing method can generate a report, so that a worker can check various data indexes in the current operation in the cleaning process or after the cleaning process, can evaluate whether the operation result is good, and has a record retaining means for ice slurry pigging operation.
Here, in practice, it is necessary to use a piece of software to implement the processing method, and the software can be developed by using Python 3.8 language, design UI framework by using PyQt5, and use the part method in numpy and pandas scientific package. It will be appreciated that the software may have the function of checking five csv files, that is, when a deviation or error occurs in the data in a certain csv file, a prompt message is sent.
Here, fig. 2 shows the style of one report.
In this embodiment, the report further includes: a minimum value, a maximum value, and an average value of the temperature of the wastewater; a minimum value, a maximum value and an average value of the flow rate of the wastewater; a minimum, maximum, and average value of the conductivity of the wastewater; a minimum value, a maximum value, and an average value of the turbidity of the wastewater; minimum, maximum and average values of suspended matter concentration in the wastewater.
In this embodiment, the method further includes the following steps: and converting the report into a corresponding pdf (Portable Document Format) file. Here, a wkhtmltopdf plug-in may be used to convert a report in html format into a pdf file.
In this embodiment, the "slave to the time series TiObtaining a cleaning start time TsAnd a washing end time TeAnd 1 is equal to or less than s<N ≦ e "specifically includes:
from said time series TiObtaining a cleaning start time TsAnd a washing end time TeWherein F issNot less than a first preset threshold value, and Fj<A first preset threshold, j ═ 1, 2, 3.., s-1; ceNot more than a second predetermined threshold value, and Ck>A second predetermined threshold value, k ═ m, m + 1., e-1, and s is not less than 1<m<e≤N。
Here, when the inner wall of the target pipe is washed with ice slurry, the data is recorded in a comprehensive manner at time T1This time the ice slurry wash can not have started yet, but at time TNThe ice slurry wash may have ended. Furthermore, it will be appreciated that the flow rate of the waste water is relatively small (i.e. F) prior to the injection of the ice slurryj<A first predetermined threshold value, j-1, 2, 3.., s-1), at a time TsThe injection of a sufficient quantity of ice slurry into the pipe is started, so that the instantaneous flow rate of the wastewater flowing out of the target pipe is also substantially increased (i.e. greater than the first predetermined threshold value, i.e. F)sNot less than the first preset threshold). Thereafter, the ice slurry is continuously injected into the target pipe, and after a certain period of time, salt is injected into the target pipe to melt the ice slurry, at which time the conductivity of the wastewater is greatly increased (i.e., C)k>A second preset threshold value, k ═ m, m + 1.., e-1), and thereafter, and as the cleaning work continues, the impurity content in the target pipe is greatly reduced, and the conductivity of the wastewater is greatly reduced(i.e. C)eNot more than a second preset threshold).
In this embodiment, the "cleaning of the inner wall of the target pipeline with ice slurry" is performed at each time TiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateri", specifically includes:
during the ice slurry cleaning process of the inner wall of the target pipeline, at each time TiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateriThen, to the conductivity CiInstantaneous flow rate FiTemperature TempiSuspended matter concentration DiAnd turbidity TubiAnd performing smooth noise reduction processing. Here, for the conductivity CiIn other words, when the difference between a certain value and the average value is too large, the value can be eliminated; likewise, for instantaneous flow FiIn other words, when the difference between a certain value and the average value is too large, the value can be eliminated; to temperature TempiIn other words, when the difference between a certain value and the average value is too large, the value can be eliminated; for suspended matter concentration DiIn other words, when the difference between a certain value and the average value is too large, the value can be eliminated; for turbidity TubiIn other words, when the difference between a certain value and the average value is too large, the value can be eliminated; thereby enabling to smooth data and reduce the occurrence of errors.
The embodiment of the invention provides a device for processing pipeline cleaning data, which comprises the following modules:
a time sequence acquisition module for acquiring the time sequence T arranged in time sequenceiN, N is a natural number;
a parameter acquisition module for acquiring the length L of the target pipeline and cleaning the inner wall of the target pipeline with ice slurryAt each time TiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateriAnd total ice and salt consumption during the ice slurry wash;
a data processing module for processing the time series TiObtaining a cleaning start time TsAnd a washing end time TeAnd 1 is equal to or less than s<e is less than or equal to N; generating the total time consumption T of the ice slurry cleaninge-TsGenerating the average value of the instantaneous flow (T) of the total water consumption of the ice slurry cleaninge-Ts) Total consumption of ice, resulting in deposits washed out by this washing of the ice slurryGenerating deposits per unit length of pipe in the current ice slurry washThe salt residue rate of the ice slurry cleaning at the time is (total salt consumption-saltSum)/total salt consumption, wherein,
the report module is used for generating a report, and the report at least comprises: total time, total water consumption, total mass of flushed out sediment, mass of sediment per unit length of tube, and residual salt content.
In this embodiment, the report further includes: a minimum value, a maximum value, and an average value of the temperature of the wastewater; a minimum value, a maximum value and an average value of the flow rate of the wastewater; a minimum, maximum, and average value of the conductivity of the wastewater; a minimum value, a maximum value, and an average value of the turbidity of the wastewater; minimum, maximum and average values of suspended matter concentration in the wastewater.
In this embodiment, the following modules are further included: and the format processing module is used for converting the report into a corresponding pdf file.
In this embodiment, the data processing module is further configured to:
from said time series TiObtaining a cleaning start time TsAnd a washing end time TeWherein F issNot less than a first preset threshold value, and Fj<A first preset threshold, j ═ 1, 2, 3.., s-1; ceNot more than a second predetermined threshold value, and Ck>A second predetermined threshold value, k ═ m, m + 1., e-1, and s is not less than 1<m<e≤N。
In this embodiment, the parameter obtaining module is further configured to:
during the ice slurry cleaning process of the inner wall of the target pipeline, at each time TiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateriThen, to the conductivity CiInstantaneous flow rate FiTemperature TempiSuspended matter concentration DiAnd turbidity TubiAnd performing smooth noise reduction processing.
It should be understood that although the present description refers to embodiments, not every embodiment contains only a single technical solution, and such description is for clarity only, and those skilled in the art should make the description as a whole, and the technical solutions in the embodiments can also be combined appropriately to form other embodiments understood by those skilled in the art.
The above-listed detailed description is only a specific description of a possible embodiment of the present invention, and they are not intended to limit the scope of the present invention, and equivalent embodiments or modifications made without departing from the technical spirit of the present invention should be included in the scope of the present invention.
Claims (10)
1. A method for processing pipeline cleaning data is characterized by comprising the following steps:
obtaining a time sequence T arranged in time sequenceiN, N is a natural number;
acquiring the length L of the target pipeline, and cleaning the inner wall of the target pipeline at each time T in the ice slurry cleaning processiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateriAnd total ice and salt consumption during the ice slurry wash;
from said time series TiObtaining a cleaning start time TsAnd a washing end time TeAnd 1 is equal to or less than s<e is less than or equal to N; generating the total time consumption T of the ice slurry cleaninge-TsGenerating the average value of the instantaneous flow (T) of the total water consumption of the ice slurry cleaninge-Ts) Total consumption of ice, resulting in deposits washed out by this washing of the ice slurry Generating deposits per unit length of pipe in the current ice slurry washThe salt residue rate of the ice slurry cleaning at the time is (total salt consumption-saltSum)/total salt consumption, wherein,
generating a report, wherein the report at least comprises: total time, total water consumption, total mass of flushed out sediment, mass of sediment per unit length of tube, and residual salt content.
2. The process of claim 1, wherein said report further comprises:
a minimum value, a maximum value, and an average value of the temperature of the wastewater; a minimum value, a maximum value and an average value of the flow rate of the wastewater; a minimum, maximum, and average value of the conductivity of the wastewater; a minimum value, a maximum value, and an average value of the turbidity of the wastewater; minimum, maximum and average values of suspended matter concentration in the wastewater.
3. The process of claim 1, further comprising the steps of:
and converting the report into a corresponding pdf file.
4. The processing method according to claim 1, wherein said "is from said time series TiObtaining a cleaning start time TsAnd a washing end time TeAnd 1 is equal to or less than s<N ≦ e "specifically includes:
from said time series TiObtaining a cleaning start time TsAnd a washing end time TeWherein, in the step (A),
Fsnot less than a first preset threshold value, and Fj<A first preset threshold, j ═ 1, 2, 3.., s-1;
Cenot more than a second predetermined threshold value, and Ck>A second predetermined threshold value, k ═ m, m + 1., e-1, and s is not less than 1<m<e≤N。
5. The process of claim 1, wherein said "during the ice slurry cleaning of the inner wall of the target pipe, at each time TiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd turbidity of the wastewaterDegree Tubi", specifically includes:
during the ice slurry cleaning process of the inner wall of the target pipeline, at each time TiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateriThen, to the conductivity CiInstantaneous flow rate FiTemperature TempiSuspended matter concentration DiAnd turbidity TubiAnd performing smooth noise reduction processing.
6. The device for processing the pipeline cleaning data is characterized by comprising the following modules:
a time sequence acquisition module for acquiring the time sequence T arranged in time sequenceiN, N is a natural number;
a parameter acquisition module for acquiring the length L of the target pipeline and performing ice slurry cleaning on the inner wall of the target pipeline at each time TiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateriAnd total ice and salt consumption during the ice slurry wash;
a data processing module for processing the time series TiObtaining a cleaning start time TsAnd a washing end time TeAnd 1 is equal to or less than s<e is less than or equal to N; generating the total time consumption T of the ice slurry cleaninge-TsGenerating the average value of the instantaneous flow (T) of the total water consumption of the ice slurry cleaninge-Ts) Total consumption of ice, resulting in deposits washed out by this washing of the ice slurryGenerating unit pipe length deposit in the ice slurry cleaningIs/are as followsThe salt residue rate of the ice slurry cleaning at the time is (total salt consumption-saltSum)/total salt consumption, wherein,
the report module is used for generating a report, and the report at least comprises: total time, total water consumption, total mass of flushed out sediment, mass of sediment per unit length of tube, and residual salt content.
7. The processing apparatus according to claim 6, wherein the report further comprises:
a minimum value, a maximum value, and an average value of the temperature of the wastewater; a minimum value, a maximum value and an average value of the flow rate of the wastewater; a minimum, maximum, and average value of the conductivity of the wastewater; a minimum value, a maximum value, and an average value of the turbidity of the wastewater; minimum, maximum and average values of suspended matter concentration in the wastewater.
8. The processing apparatus according to claim 6, further comprising the following modules:
and the format processing module is used for converting the report into a corresponding pdf file.
9. The processing apparatus as claimed in claim 6, wherein the data processing module is further configured to:
from said time series TiObtaining a cleaning start time TsAnd a washing end time TeWherein F issNot less than a first preset threshold value, and Fj<A first preset threshold, j ═ 1, 2, 3.., s-1; ceNot more than a second predetermined threshold value, and Ck>A second predetermined threshold value, k ═ m, m + 1., e-1, and s is not less than 1<m<e≤N。
10. The processing apparatus as claimed in claim 6, wherein the parameter obtaining module is further configured to:
during the ice slurry cleaning process of the inner wall of the target pipeline, at each time TiObtaining the conductivity C of the wastewater flowing out of the water outlet of the target pipelineiInstantaneous flow F of said waste wateriTemperature Temp of the waste wateriThe concentration D of suspended matter in the wastewateriAnd the turbidity Tub of the wastewateriThen, to the conductivity CiInstantaneous flow rate FiTemperature TempiSuspended matter concentration DiAnd turbidity TubiAnd performing smooth noise reduction processing.
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