CN113883413A - Microfluidic chip fendorin bottle inflation method based on semiconductor desorption - Google Patents

Abstract

The invention provides a microfluidic chip fendorin bottle inflation method based on semiconductor desorption, which comprises the steps of firstly, carrying out adsorption inflation treatment on fendorin in a forest through a fendorin adsorption rod in a fendorin inflation device; step two, judging whether the at least two inflation parameters meet the termination condition of desorption; thirdly, clustering the at least two inflation parameters through hyper variance clustering desorption, and calculating the fitness values of the at least two target inflation parameters; and step four, enabling air molecules to contact the fendorin adsorption rods through air circulation to carry out adsorption and inflation, positioning and timing optimization on inflation adsorption and discharge desorption by taking an electric eel swarm algorithm as guidance, combining the advantages of bidirectional multi-component desorption, optimizing a plane function by using a method involving discharge ion disturbance operation and improving carbon dioxide supply by utilizing the semiconductor desorption period, the biological information stimulation capability and the negative oxygen ion distribution state information coordination, and repairing the forest performance.

Description

Microfluidic chip fendorin bottle inflation method based on semiconductor desorption

Technical Field

The invention relates to the technical field of fendorin transportation, in particular to a microfluidic chip fendorin bottle inflation method based on semiconductor desorption.

Background

The fendorin is an aromatic hydrocarbon, and is filled in a forest, so that the fendorin can be transported without leaving home, and a fendorin bath can be enjoyed at home.

Traditional adsorption column needs carry out gaseous collection work in the fixed place of fixed time when using, and the coordination needs the staff to cooperate in real time during operation, does not form the volume production scale that contains various compositions simultaneously, and the leading cause is that the adsorption material is passive work, lacks the concentrated liquefied gas of active equipment, and it is numerous to need to optimize the parameter of aerifing the composition.

Meanwhile, the common adsorption column in the prior art has long adsorption working time, low concentration of adsorbed fendorin and single composition of adsorbed gas.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a microfluidic chip fendorin bottle inflation method based on semiconductor desorption, which aims to solve the problems in the prior art. .

In order to achieve the purpose, the invention is realized by the following technical scheme: a microfluidic chip fendorin bottle inflation method based on semiconductor desorption comprises the following steps:

placing a fendorin aerating device in a forest, carrying out adsorption aeration treatment on fendorin in the forest through a fendorin adsorption rod in the fendorin aerating device, before adsorption aeration is started, releasing carbon dioxide collected by a user when the user uses the device through an internal desorption structure, conveying the carbon dioxide into the forest, then carrying out fendorin adsorption aeration work, and obtaining at least two target aeration parameters in an auxiliary manner according to the basic concentration of fendorin in the forest and the adsorption concentration of the characteristics of an adsorbing material;

step two, judging whether the at least two inflation parameters meet the termination condition of desorption, wherein the condition is whether the proportion of internal gas components is out of order, when the basic concentration of the fendorin in the forest is in direct proportion to the adsorption concentration of the characteristic of the adsorption material, the condition is met, the step four is shifted, and when the basic concentration of the fendorin in the forest is in inverse proportion to the adsorption concentration of the characteristic of the adsorption material, the condition is not met, the step three is shifted;

thirdly, clustering the at least two inflation parameters through hyper-variance clustering desorption, calculating the fitness values of the at least two target inflation parameters, taking the inflation parameter with the optimal fitness value as a clustering center of the at least two target inflation parameters, assisting workers to find out a working center with the highest overall efficiency to determine the optimal temperature and humidity during working, adjusting the temperature and humidity through a semiconductor, performing semiconductor desorption treatment, performing disturbance treatment on the recovery parameters of the at least two target inflation parameters in real time, and turning to the second step;

and step four, introducing the at least two inflation parameters into the semiconductor desorption, optimizing the concentration of the fendorin adsorption rod, outputting the corresponding chip working temperature of the chip adsorption concentration, weighting the working temperature according to the relative concentration of each component to obtain a uniform working temperature, and allowing air molecules to contact the fendorin adsorption rod through air circulation to perform adsorption inflation.

As an improvement of the method for inflating the microfluidic chip fendorin bottle based on semiconductor desorption in the present invention, in the fifth step, the semiconductor desorption process includes the following steps:

firstly, determining the upper limit and the lower limit of the concentration of the fendorin adsorbed by a fendorin aerating device and the adjustable temperature change frequency of equipment, calculating the proportion of the upper limit and the lower limit, and then calculating the required iteration times;

secondly, determining a 'flower system', wherein the 'flower system' is a self-similar component of the fendorin, and the self-similar component is mainly determined according to the requirements of a scene;

thirdly, determining a slow release parameter of each iteration, wherein the slow release parameter is the coverage volume of the phytoncide;

fourthly, inflating the semiconductor to desorb the corresponding structure, processing the slow release parameters, and adjusting the thermal desorption period and temperature according to the preset breathing period and vital capacity;

fifthly, determining an evaluation function of semiconductor desorption and outputting initial parameters, wherein the evaluation method comprises two methods, namely laboratory test and simulation calculation;

sixthly, selecting excellent initial parameters, calculating the energy required by each deflation calculated by the fendorin adsorption rod by taking the maximum electric range of the fendorin inflation device as the initial value of the fendorin inflation device, wherein the energy is in direct proportion to the temperature;

and seventhly, determining an elimination mechanism, wherein the elimination mechanism is as follows: and recording the performance index of the slow release evaluation function and the performance index of the evaluation function optimized by the negative ions, comparing the negative ions with the absolute concentration index by using a variance formula to form intermediate product electrons, eliminating the daughter electrons with low indexes, and completing the charging and desorption operation from the electrons to the ion disturbance.

Preferably, in the third step, the slow release parameters include a covered span tolerance and a flux tolerance for each iteration, and the slow release parameters are expressed by complex numbers.

Preferably, in the second step, the fendorin inflator includes a chip structure formed by a fractal emitter group and a MATLAB simulator software package, and the fendorin inflator includes a rectangular planar structure and a rod-shaped three-dimensional structure.

Furthermore, a chip structure formed by the fractal emitter group is provided with a square angle structure.

As an improvement of the microfluidic chip fendorin bottle inflation method based on semiconductor desorption, in the fourth step, the calculation of the fendorin adsorption rods comprises the calculation of two or four cylindrical surfaces, the calculation is respectively synthesized, and the energy required by the cylindrical surfaces is in direct proportion to the number of the fendorin adsorption rods in the cylindrical surfaces.

As an improvement of the microfluidic chip fendorin bottle inflation method based on semiconductor desorption, the fendorin inflation device is provided with a charging operation accessory, and the charging modes of the charging operation accessory comprise extrusion type power generation, shaking type power generation and photoelectric effect power generation.

As an improvement of the microfluidic chip fendorin bottle inflation method based on semiconductor desorption, the fendorin adsorption rod is prepared by embedding a calculation formula: x ═ X_t|，x_tIs more than or equal to 0, wherein x_tCalculating the absolute concentration of the fendorin for the concentration of the fendorin, comparing the absolute concentration X with the value Y of the individual health care requirement, when the X is more than or equal to Y, indicating that the absolute concentration requirement meets the individual health care requirement, and when the X is more than or equal to Y<And Y, indicating that the requirement of absolute concentration cannot meet the requirement of individual health care, wherein a carbon dioxide collecting device is arranged in the fendorin bottle, and the output quantity of the collected daily carbon dioxide of the user is compared with the standard value of the corresponding age to output the estimated value of the body data of the user.

As an improvement of the microfluidic chip fendorin bottle inflation method based on semiconductor desorption, the fendorin inflation device is provided with at least two capillaries for inflation, the fendorin inflation device is provided with a replaceable bidirectional concentration filter element, and the bidirectional concentration filter element is provided with an inner core consisting of a molecular sieve, hydrogel, activated carbon, silica gel, pumice and a nano membrane.

Compared with the prior art, the invention has the beneficial effects that:

1. the method takes the electric eel swarm algorithm as the guide, respectively positions and optimizes the gas-filled adsorption and the discharge desorption in a timing way, combines the advantages of bidirectional multi-component desorption, utilizes the mutual cooperation of the semiconductor desorption period, the biological information stimulating capacity and the negative oxygen ion distribution state information, optimizes the plane function by operating the method related to the discharge ion disturbance, and optimizes the disturbance thought in the theory, thereby improving the forest repair performance of carbon dioxide supply;

2. according to the method, a mixed model of semiconductor desorption and hyper-variance is used, according to the inflation optimization relation of a multi-component disturbance association model in a negative oxygen ion theory, the implicit fendorin distribution characteristic information is extracted deeply, and the time-space multi-component optimal forest working state is confirmed during adsorption operation;

3. the fendorin aerating device provided by the invention utilizes a fractal chip structure, has compact coverage range, bidirectional operation and low environmental destructiveness, has ideal physiological frequency domain characteristics, and has low carbon, high acquisition degree of a fendorin directional diagram, high efficiency automation and reasonable benefits;

4. the fendorin aerating device of the invention provides an N-3 iteration mode, and the proportion Rr of each iteration is a rational number, so that the fendorin aerating device has the characteristics of small volume, low manufacturing cost, easy mass production, safety, greenness, two-way environmental protection and suitability for adsorbing and adjusting comprehensive household health and maintenance gas systems in the morning, the noon and the evening.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, it is obvious that the drawings in the following description are only one embodiment of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a flow chart of the method for inflating a fendorin bottle according to the present invention;

FIG. 2 is a schematic perspective view of the adsorption aeration according to the present invention;

FIG. 3 is a schematic side view of the adsorbent aeration apparatus of the present invention;

FIG. 4 is a schematic top view of the adsorbent aeration apparatus of the present invention;

FIG. 5 is a schematic view of the internal structure of the adsorbent aeration apparatus of the present invention.

Detailed Description

In order to make the technical means, the original characteristics, the achieved purposes and the effects of the invention easily understood and obvious, the technical solutions in the embodiments of the present invention are clearly and completely described below to further illustrate the invention, and obviously, the described embodiments are only a part of the embodiments of the present invention, but not all the embodiments.

Example 1

The specific embodiment is a method for inflating a microfluidic chip fendorin bottle based on semiconductor desorption, the flow chart of the method is shown in fig. 1, the schematic diagram of the adsorption and inflation three-dimensional structure is shown in fig. 2, the schematic diagram of the adsorption and inflation side-view structure is shown in fig. 3, the schematic diagram of the adsorption and inflation top-view structure is shown in fig. 4, the schematic diagram of the adsorption and inflation internal structure is shown in fig. 5, and the method for inflating the microfluidic chip fendorin bottle based on semiconductor desorption comprises the following steps:

placing a fendorin aerating device in a forest, carrying out adsorption aeration treatment on fendorin in the forest through a fendorin adsorption rod in the fendorin aerating device, releasing carbon dioxide collected by a user when the user uses the device through an internal desorption structure before adsorption aeration is started, conveying the carbon dioxide into the forest, then carrying out fendorin adsorption aeration work, and obtaining at least two target aeration parameters in an auxiliary manner according to the basic concentration of fendorin in the forest and the adsorption concentration of the characteristics of an adsorbing material;

step two, judging whether at least two inflation parameters meet the termination condition of desorption, wherein the condition is whether the proportion of internal gas components is out of order, when the basic concentration of the fendorin the forest is in direct proportion to the adsorption concentration of the characteristic of the adsorption material, the condition is met, the step four is shifted, when the basic concentration of the fendorin the forest is in inverse proportion to the adsorption concentration of the characteristic of the adsorption material, the condition is not met, and the step three is shifted;

step three, clustering at least two inflation parameters through hyper-variance clustering desorption, calculating the fitness values of at least two target inflation parameters, taking the inflation parameter with the optimal fitness value as a clustering center of the at least two target inflation parameters, assisting workers to find out a working center with the highest overall efficiency to determine the optimal temperature and humidity during working, adjusting the temperature and humidity through a semiconductor, adjusting the temperature according to different types of phytoncines during phytoncine adsorption desorption, adjusting the humidity according to the outside humidity during carbon dioxide adsorption desorption, performing semiconductor desorption, performing disturbance processing on the recovery parameters of the at least two target inflation parameters in real time, and transferring to step two;

and step four, introducing at least two inflation parameters into the semiconductor desorption, optimizing the concentration of the fendorin adsorption rod, outputting the corresponding chip working temperature of the chip adsorption concentration, weighting the working temperature according to the relative concentration of each component to obtain uniform working temperature, and enabling air molecules to contact the fendorin adsorption rod to perform adsorption and inflation through air circulation.

In the third step, the semiconductor desorption treatment process comprises the following steps:

firstly, determining the upper limit and the lower limit of the concentration of the fendorin adsorbed by a fendorin aerating device and the adjustable temperature change frequency of equipment, calculating the proportion of the upper limit and the lower limit, then calculating the needed iteration number, for example, the lower limit is Fd (1) times per minute, the upper limit is Fu (3) times per minute, then calculating the proportion of the upper limit and the lower limit, Rf (Fu/Fd) is 3, we take the proportion Rr (1.2) of each iteration, and then calculating the needed iteration number N (log) (Rf)/log (Rr) 3, namely 3 iterations;

secondly, determining a 'flower system', wherein the 'flower system' is a fendorin self-similar component, the self-similar component is mainly determined according to the requirements of a scene, if the flower system is early morning, the flower system with two components is adopted, if the flower system is midday, the flower system with six components is adopted, if the flower system is evening, the flower system with four components is adopted, and the midday forest has the most fendorin;

thirdly, determining a slow release parameter of each iteration, wherein the slow release parameter is the volume which can be covered by the fendorin;

fourthly, the inflatable semiconductor desorbs corresponding structures, processes slow release parameters, and adjusts the period and temperature of thermal desorption according to a preset breathing period and vital capacity;

fifthly, determining an evaluation function of semiconductor desorption and outputting initial parameters, wherein the evaluation method comprises two evaluation methods, namely laboratory test and simulation calculation;

sixthly, selecting excellent initial parameters, taking the maximum electric range of the fendorin inflating device as an initial value of the fendorin inflating device, and calculating the energy required by each deflation by the fendorin adsorption rod in direct proportion to the temperature;

and seventhly, determining an elimination mechanism, wherein the elimination mechanism is as follows: recording the performance index of a slow release evaluation function and the performance index of an evaluation function optimized by negative ions, comparing the negative ions with the absolute concentration index by using a variance formula to form intermediate product electrons, eliminating the daughter electrons with low indexes, completing the charging and desorbing operation from electrons to ion disturbance, recording Pr as the performance index of the evaluation function optimized by negative oxygen ions, Pl as the performance index of the evaluation function optimized by positive oxygen ions, and dP ═ max (Pr, Pl) -min (Pr, Pl), wherein if the indexes of the negative ions are higher than positive, the positive daughter electrons are eliminated by the probability of 2 ×. dP/(Pr + Pl);

in the third step, the slow release parameters comprise the coverage range tolerance and flux tolerance of each iteration, and the slow release parameters are expressed by complex numbers;

in the second step, the fendorin aerating device comprises a chip structure formed by a fractal emitter group and an MATLAB simulator software package, and the fendorin aerating device comprises a rectangular plane structure and a bar-shaped three-dimensional structure;

the chip structure formed by the fractal emitter group is provided with a square angle structure.

Simultaneously, in step four, the calculation that fendorin adsorbed the stick and calculated including two or four cylinders is synthesized respectively, and the cylinder required energy is directly proportional with the quantity that fendorin adsorbed the stick in the cylinder, is provided with the operation accessory that charges on the fendorin aerating device, and the mode of charging of the operation accessory of charging includes the extrusion formula electricity generation, rocks formula electricity generation and photoelectric effect electricity generation, and fendorin adsorbs the stick and passes through embedded computational formula: x ═ X_t|，x_tIs more than or equal to 0, wherein x_tCalculating the absolute concentration of the fendorin for the concentration of the fendorin, comparing the absolute concentration X with the value Y of the individual health care requirement, when the X is more than or equal to Y, indicating that the absolute concentration requirement meets the individual health care requirement, and when the X is more than or equal to Y<And Y, indicating that the requirement of absolute concentration cannot meet the requirement of individual health care, arranging a carbon dioxide acquisition device in the fendorin bottle, comparing the output quantity of the daily carbon dioxide of the user with a standard value of the corresponding age, outputting the estimated value of the body data of the user, arranging at least two capillaries in the fendorin inflation device for inflation, arranging a replaceable bidirectional concentration filter element in the fendorin inflation device, and arranging an inner core consisting of a molecular sieve, hydrogel, active carbon, silica gel, pumice and a nano membrane on the bidirectional concentration filter element.

When the microfluidic chip fendorin bottle inflation method based on semiconductor desorption is used, one semiconductor is used for adjusting the temperature and the humidity during working, a plurality of liquefaction chips at the lower part are controlled, meanwhile, the operation of collecting fendorin with different components, carbon dioxide and fendorin with a plurality of filter cores made of composite materials with different internal characteristics is carried out, the treatment in the forest is opposite to the treatment in the house of a user, in order to match the fendorin flux, the new concentration is obtained by utilizing the effect obtained after the concentration is detected by the previous artificial electronic nose discharge, then the obtained result is compared with the position of a moving chip every time, whether the residual concentration is too strong or too weak when the signal wave is transmitted to a specified position relative to the position of the chip is judged, if the residual concentration is not too strong, the residual concentration is adopted when the residual concentration is in conformity with high conformity, and the residual concentration is discharged again when the conformity with low conformity is judged, and the conformity is calculated by using the hyper-variance, wherein the evaluation of the objective function is based on the hyper-variance and the global optimal charging desorption optimization instead of the fendorn variance, and the global optimization combines a reinitialization scheme triggered by the current population state, combines each variable update and fitness-based grouping, and provides new plane dynamics by using a complex weighted disturbance relevance ion learning strategy to enable the individual to escape from the local optimization.

Having thus described the principal technical features and basic principles of the invention, and the advantages associated therewith, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Furthermore, it should be understood that although the present description is described in terms of various embodiments, not every embodiment includes only a single embodiment, and such descriptions are provided for clarity only, and those skilled in the art will recognize that the embodiments described herein can be combined as a whole to form other embodiments as would be understood by those skilled in the art.

Claims (9)

1. A microfluidic chip fendorin bottle inflation method based on semiconductor desorption is characterized by comprising the following steps:

placing a fendorin aerating device in a forest, carrying out adsorption aeration treatment on fendorin in the forest through a fendorin adsorption rod in the fendorin aerating device, before adsorption aeration is started, releasing carbon dioxide collected by a user when the user uses the device through an internal desorption structure, conveying the carbon dioxide into the forest, then carrying out fendorin adsorption aeration work, and obtaining at least two target aeration parameters in an auxiliary manner according to the basic concentration of fendorin in the forest and the adsorption concentration of the characteristics of an adsorbing material;

step two, judging whether the at least two inflation parameters meet the termination condition of desorption, wherein the condition is whether the proportion of internal gas components is out of order, when the basic concentration of the fendorin in the forest is in direct proportion to the adsorption concentration of the characteristic of the adsorption material, the condition is met, the step four is shifted, and when the basic concentration of the fendorin in the forest is in inverse proportion to the adsorption concentration of the characteristic of the adsorption material, the condition is not met, the step three is shifted;

thirdly, clustering the at least two inflation parameters through hyper-variance clustering desorption, calculating the fitness values of the at least two target inflation parameters, taking the inflation parameter with the optimal fitness value as a clustering center of the at least two target inflation parameters, assisting workers to find out a working center with the highest overall efficiency to determine the optimal temperature and humidity during working, adjusting the temperature and humidity through a semiconductor, performing semiconductor desorption treatment, performing disturbance treatment on the recovery parameters of the at least two target inflation parameters in real time, and turning to the second step;

and step four, introducing the at least two inflation parameters into the semiconductor desorption, optimizing the concentration of the fendorin adsorption rod, outputting the corresponding chip working temperature of the chip adsorption concentration, weighting the working temperature according to the relative concentration of each component to obtain a uniform working temperature, and allowing air molecules to contact the fendorin adsorption rod through air circulation to perform adsorption inflation.

2. The microfluidic chip fendorin bottle inflation method based on semiconductor desorption as claimed in claim 1, wherein in the third step, the semiconductor desorption treatment process comprises the following steps:

firstly, determining the upper limit and the lower limit of the concentration of the fendorin adsorbed by a fendorin aerating device and the adjustable temperature change frequency of equipment, calculating the proportion of the upper limit and the lower limit, and then calculating the required iteration times;

secondly, determining a 'flower system', wherein the 'flower system' is a self-similar component of the fendorin, and the self-similar component is mainly determined according to the requirements of a scene;

thirdly, determining a slow release parameter of each iteration, wherein the slow release parameter is the coverage volume of the phytoncide;

fourthly, inflating the semiconductor to desorb the corresponding structure, processing the slow release parameters, and adjusting the thermal desorption period and temperature according to the preset breathing period and vital capacity;

fifthly, determining an evaluation function of semiconductor desorption and outputting initial parameters, wherein the evaluation method comprises two methods, namely laboratory test and simulation calculation;

sixthly, selecting excellent initial parameters, calculating the energy required by each deflation calculated by the fendorin adsorption rod by taking the maximum electric range of the fendorin inflation device as the initial value of the fendorin inflation device, wherein the energy is in direct proportion to the temperature;

and seventhly, determining an elimination mechanism, wherein the elimination mechanism is as follows: and recording the performance index of the slow release evaluation function and the performance index of the evaluation function optimized by the negative ions, comparing the negative ions with the absolute concentration index by using a variance formula to form intermediate product electrons, eliminating the daughter electrons with low indexes, and completing the charging and desorption operation from the electrons to the ion disturbance.

3. The semiconductor desorption-based microfluidic chip fendorin bottle inflation method according to claim 1, wherein in the fourth step, the calculation of the fendorin adsorption rods comprises calculation of two or four cylindrical surfaces, the calculation is respectively synthesized, and the energy required by the cylindrical surfaces is in direct proportion to the number of the fendorin adsorption rods in the cylindrical surfaces.

4. The microfluidic chip fendorin bottle inflation method based on semiconductor desorption as claimed in claim 2, wherein in the third step, the slow release parameters comprise a coverage range tolerance and a flux tolerance of each iteration, and the slow release parameters are expressed by complex numbers.

5. The microfluidic chip fendorin bottle inflation method based on semiconductor desorption as claimed in claim 2, wherein in the second step, the fendorin inflation device comprises a chip structure formed by a fractal emitter group and a MATLAB simulator software package, and the fendorin inflation device comprises a rectangular plane structure and a rod-shaped three-dimensional structure.

6. The microfluidic chip fendorin bottle inflation method based on semiconductor desorption as claimed in claim 5, wherein the chip structure formed by the fractal emitter group is provided with a square angle structure.

7. The semiconductor desorption-based microfluidic chip fendorin bottle inflation method as claimed in claim 1, wherein the fendorin inflation device is provided with a charging operation accessory, and the charging mode of the charging operation accessory comprises extrusion type power generation, shaking type power generation and photoelectric effect power generation.

8. The microfluidic chip fendorin bottle inflation method based on semiconductor desorption as claimed in claim 1, wherein the fendorin adsorption rod is obtained by embedding a calculation formula: x ═ X_t|，x_tIs more than or equal to 0, wherein x_tCalculating the absolute concentration of the fendorin for the concentration of the fendorin, comparing the absolute concentration X with the value Y of the individual health care requirement, when the X is more than or equal to Y, indicating that the absolute concentration requirement meets the individual health care requirement, and when the X is more than or equal to Y<And Y, indicating that the requirement of absolute concentration cannot meet the requirement of individual health care, wherein a carbon dioxide collecting device is arranged in the fendorin bottle, and the output quantity of the collected daily carbon dioxide of the user is compared with the standard value of the corresponding age to output the estimated value of the body data of the user.

9. The semiconductor desorption-based microfluidic chip fendorin bottle inflation method according to claim 1, wherein at least two capillaries are arranged in the fendorin inflation device for inflation, a replaceable bidirectional concentration filter element is arranged in the fendorin inflation device, and an inner core consisting of a molecular sieve, hydrogel, activated carbon, silica gel, pumice and a nano membrane is arranged on the bidirectional concentration filter element.

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