Theoretical and Experimental Studies of the Effect of Inclined Scraper on Removal of Raw Cotton from Mesh Surface ()
1. Introduction
During the cotton separation from transporting air, raw cotton is removed with the help of scraper, adhering cotton on central part of mesh surface forms cotton roller around the scraper shaft [1] - [4] . Previous studies have shown that flying fluffs of raw cotton are less than 200 mm drop in the vacuum valve after two or three turns of the scraper, thus, they are often twisted by the scraper shaft especially in the separation of low grade cotton with high humidity and dirtiness, forming together a cotton roll.
Further increase in volume of cotton gradually leads to filling the entire area of mesh with raw cotton, and hence it disrupts transportation, in addition, the scraper may break down, resulting in an accident and requiring manual cleaning the mesh of separator as well as replacing the scraper.
As shown by the theoretical analysis, clogging the separator, formation of cotton roll occurs due to the existing designs of power pulse from the central portion of the scraper to the perforated disc, which is operating on removal of cotton, is negligible.
2. Mathematic Model of Problem and Theoretical Investigation of Cotton Mass Movement in the Plane of Scraper
Slices and flying fluff of cotton, while operating separator under the influence of forces P, N and gravity, moves to the mesh surface. The magnitude of force N that is created by scraper decreases when it approaches closer to the shaft and becomes minimum when shaft and scraper is in touch. Consequently, in the pneumatic transport of cotton at the time of its separation from the transporting air occurs clogging of the mesh surface, leading to a sharp drop in pressure and further separator clogging [5] - [9] .
Theoretical approach on cotton roller of clogged separator and interruption as a result of this pneumatic installation, revealed reasons for the formation of the roll and developed concrete actions to address it [10] -[13] .
The motion of flying fluffs of cotton is considered, taking its material point, plane motion is accomplished in the plane of the mesh disc (Figure 1). Point position on the disk surface can be determined at any time by the coordinates x and y or the radius vector.
r and the polar angle (beginning at 0). In this case it has relations
(1)
Lagrange’s equations of the second kind are used in order to identify the point of the law of motion:
(2)
Here―the kinetic energy:
(3)
is the weight of flying fluffs;,―Generalized forces calculated by the formula
(4)
where and―the forces acting in the direction of the axes and.
Studying the case when flying fluffs commits movement in angular direction with scraper jointly then we obtain the expression for the force;
(5)
where―the impact force of scraper to flying fluffs, as determined in the following sections based on the law of motion of the scraper;―friction coefficient of the flying fluff to the mesh surface;―friction coefficient of flying fluff to rubberized surface;―aerodynamic force of the air; and―speed of flying fluff toward axes and:
(6)
where and―radial and angular air speed of flying fluffs.
Substituting the values of and in Equation (4), taking into account Equations (1) and (6) we obtain:
(7)
(8)
The equations of motion flying fluffs, thus, according to Equation (2) taken the form:
(9)
Until the impact moment to scraper, the point position has been determined by coordinates, at. At uniform rotation of scraper together with fluffs has
(10)
where―the angular air speed of the scraper.
Taking the result of Equation (5), we obtain an expression for where the impact force of scraper will be;
(11)
As follows from Equation (11) magnitude of a force decreases with increasing angle of the scraper and gradually takes a minimum value or equal to zero, and mass of fluffs under the action of centrifugal force is separated from the scraper and leaves mesh surface. Studied the motion of flying fluffs on the mesh surface and identified the coordinates of flying fluffs at the time of separation from the scraper according to Equation (5) when we have the expression.
(12)
(t―The moment flying fluffs are separated from the surface of scraper), from which it follows that the motion of flying fluffs occurs in the radial direction.
To determine the trajectory of flying fluffs on the mesh surface, Equation (5) is used in, for the unknown and.
If, , that and fluff leaves the mesh surface.
Analysis of Equation (12) shows that when, it equals. If, , then,
(13)
Thus:
1) If, then
2) If, then
In this case, when fluffs move without interruption from surface of the shaft,
Here,―the impact force of scraper to fluffs, located on the surface of the shaft;
―The friction coefficient of flying fluffs to the surface of shaft (Figure 2).
Fluffs of cotton separated from the surface of the shaft when then, where
(14)
Separation occurs only when
if
Differential Equation (5) can not be integrated in quadratures, so we use the well-known standard Runge- Kutta program, which is implemented at MAPLE-9.5.
3. Experimental studies of the effect of inclined scraper on removal raw cotton through mesh surface
New scraper is set as it inclined to the plane of the separator, passing through the base of the scraper in the opposite direction to its motion. The position of the scraper in the separator, and its angle of inclination can be adjusted.
In order to gain a better understanding of the process of raking raw cotton from the surface of the mesh disc with new existing scrapers, the movement of raw cotton that is on the screen surface under the action of the rotating scraper at ordinary level has been studied and construction of scrapers was proposed. According to the obtained equations, motion trajectories of cotton fluffs on the mesh surface are constructed for both designs. Motion trajectory of fluffs on the mesh surface is presented in which the existing one is used on the inclined scraper.
Comparative analysis of the movement trajectory on the mesh surface of separator with the existing and inclined scrapers show that setting the scraper at an angle to the radius has a positive effect, i.e. All flying fluffs located on the mesh surface are removed during one rotation of the scraper shaft.
Therefore, to address shortcomings of separator SS-15A, it is proposed to replace the current scraper to new inclined scraper, which is set at an angle to the radius of the perforated disk (calculations have shown that the effective operation of the scraper is provided at). When the cotton is removed, this design of scraper creates an additional force near the scraper shaft that creates conditions to prevent the formation of cotton roller in the center on the plane of scraper from the center to the periphery.
In cotton factories at Kirov experimental study was performed preliminary in order to determine the optimal parameters of the inclined scraper.
On the basis of theoretical studies in mechanical workshop, the scraper, which is adjustable relating to the radius of the mesh disc at inclined angle, was made. In order to change the angle of inclination of the scraper, while adjusting its position, it is necessary to make the rotation of the screw in the direction of screwing or threading, as a result it affects relatively an increase or decrease in the inclination angle of scraper. Besides, in order to avoid jamming of raw cotton between the scraper and disc during its removal, scraper was installed with the possibility of changing the angle between the scraper and the disk.
4. Results
The experiments were conducted in cotton factory of Kirov with different inclinations of the scraper relative to the disk radius at;;;; and at;;;; on the pneumatic transporting installations, consisting of the separator SS-15A, fan LC-12M, dust collection devices and pipeline to transport raw cotton. To facilitate comparison of the new and existing scrapers, they were installed in the same separator.
During the testing, raw cotton “Tashkent-1” in various sorts and humidity that was collected by machine was used.
Experiments were conducted in the separation vacuum valve dividing its length into three equal sections. When this sample is taken from each section that allowed us to estimate the magnitude of changes in the quality of raw cotton during changes in technological, structural and geometrical parameters of single unit of separator located in the middle part of the separation chamber or its end wall.
Figure 3 and Figure 4 show plots depending on size of vices and waste of fiber in value of angles and.
From the constructed graph it is shown that the performance of scraper inclined to the radius of disk by the value to the mesh surface, the formation of technological defects of raw cotton is optimally reduced.
Following the above studies, taking into account the angle that is found, and industrial design of inclined scraper is made and production testing is conducted in Kirov cotton factories.
5. Conclusions
The mathematical model of the problem and theoretical studies of the motion of cotton mass on plane of scraper
Figure 3. Trajectory of fluffs on the mesh surface using existing and inclined scrapers.
Figure 4. Graphs that are dependant on the size of defects and debris of fiber according to angles a and b. Inclined scraper at angle: a = 90, 100, 110, 120, 130. Horizontal axes indicates b angle.
are made. To identify the point of the law of motion, Lagrange’s equations of the second kind are used.
The obtained results show that the presence of zero-pressure portion on the mesh surface of separator may provide complete removal of cotton from its surface and to eliminate mesh clogging. To prevent the formation of cotton around the scraper roller retaining effective cross-section of the mesh surface, new construction of scraper was suggested. During removal of cotton it creates an additional force that prevents the formation of cotton roll.
As it can be seen from Figure 2, the locus of points on the surface of mesh forms a curve A, followed by a flying fluffs of cotton perform the motion in the radial and tangential directions simultaneously. In addition, when for all values of and (corresponding trajectories of flying fluffs of cotton and curve B that is shown in dotted lines). Comparative analysis of the curves A and B shows that the presence of zero-pressure portion on the surface of the separator mesh may provide complete removal of cotton from its surface and eliminate mesh clogging.
Figure 3 and Figure 4 show graphs dependency on the size of defects and debris of fiber according to angles and.
It can be seen from the constructed graph that the performance of the scraper inclined to the radius of the disk on the value of and to the surface of the mesh, optimally reduce the formation of technological defects of raw cotton.
After conducting the above studies, taking into account angle of inclination that is found, industrial design of inclined scraper is made and production tests are carried out on cotton factories.