MECHANICAL ENGINEERING AND MACHINE SCIENCE
DOI - 10.32743/UniTech.2021.92.11.12565
RESEARCH OF PARAMETERS AT THE APPEARANCE OF SHEARING FORCES IN THE COMPOUND TENSION ROLLER OF TRANSPORTATION AND TECHNOLOGICAL MACHINES
Yunus Mirzakhonov
Candidate of technical sciences, assistant professor, Ferghana Polytechnic Institute, Republic of Uzbekistan, Ferghana E-mail: [email protected]
Sobitjon Akhtambaev
Assistant, Ferghana Polytechnic Institute, Republic of Uzbekistan, Ferghana E-mail: [email protected]
Nurzod Abdukodirov
Assistant, Ferghana Polytechnic Institute, Republic of Uzbekistan, Ferghana E-mail: [email protected]
Gulnoza Jalilova
Assistant, Ferghana Polytechnic Institute, Republic of Uzbekistan, Ferghana E-mail: gulnozam545@,gmail. com
ИССЛЕДОВАНИЕ ПАРАМЕТРОВ ПРИ ВОЗНИКНОВЕНИИ СРЕЗАЮЩИХ СИЛ В СОСТАВНОМ НАТЯЖНОМ РОЛИКЕ ТРАНСПОРТНЫХ И ТЕХНОЛОГИЧЕСКИХ МАШИНАХ
Юнус Умарович Мирзахонов
канд. техн. наук, доцент, Ферганский Политехнический Институт, Республика Узбекистан, г. Фергана
Ахтамбаев Собитжон Сохибжонович
ассистент,
Ферганский Политехнический Институт, Республика Узбекистан, г. Фергана
Абдукодиров Нурзод Шавкатжон угли
ассистент,
Ферганский Политехнический Институт, Республика Узбекистан, г. Фергана
Жалилова Гулноза Хабибулло кизи
ассистент преподаватель, Ферганский Политехнический Институт, Республика Узбекистан, г. Фергана
ABSTRACT
This scientific article discusses the development of a new design of a composite tension roller to prevent lateral slipping of the belt in transporting and technological machines, as well as theoretical studies of a raw cotton loader.
Библиографическое описание: RESEARCH OF PARAMETERS AT THE APPEARANCE OF SHEARING FORCES IN A COMPOUND TENSION ROLLER WITH TRANSPORTATION AND TECHNOLOGICAL MACHINES // Universum: технические науки : электрон. научн. журн. Mirzakhonov Y.U. [и др.]. 2021. 11(92). URL: https://7univer-sum. com/ru/tech/archive/item/12565
АННОТАЦИЯ
В данной научной статье рассматривается разработка новой конструкции составного натяжного ролика для предотвращения бокового схода ленты транспортирующих и технологических машинах, а также теоретические исследования перегружателя хлопка-сырца.
Keywords: roller, linear speed of the conveyor belt, required power on the drum shaft, power consumption of the electric motor, driving and driven pulleys, covering belt, signaling sensors, K.P.D. conveyor drive, tension forces, shear force, habasit belt, poli belt, rubbirized belt, resultant force.
Ключевые слова: ролик, линейная скорость конвейерной ленты, требуемая мощность на валу барабана, потребляемая мощность электродвигателя, ведущий и ведомый шкивы, защитная лента, датчики сигнализации, K.P.D. привод конвейера, силы натяжения, сила сдвига, лента хабасита, лента поли, прорезиненная лента, равнодействующая сила.
Introduction. Composite tension rollers are used mainly in conveying and technological machines, as well as drives with large gear ratios and small center distances. They make it possible to transmit more power with the same overall dimensions of the transmission. The compound idler is in a heavier condition due to additional bending in the opposite direction.
In this case, the variable component of the stress cycle will be greater than in a transmission without a tension roller. Fig. 1 shows a kinematic diagram of a composite tension roller with an automatic adjusting device for a flat-belt transmission when the axes of rotation of the pulleys and the angle of inclination of the axis of the side parts are not parallel when the composite tension roller rotates.
Literature review. Knowing that the power and rotational speed of the electric motor are known, we can determine the calculated speed of movement for different diameters of the drive pulley:
_rç-DLln я-D? • n
V1 _ ™ ' V2 _
60
60
(1)
where D1, D2 are the diameters of the driving and driven pulleys. [1].
The circumferential force Ft and the resultant Fb force in the belt drive according to the kinematic diagram shown in Fig. 1 are determined by the formulas:
F„ =
60-k-P
я-D -n
(2)
дв
where P - is the power consumption of the electric motor;
K - is the coefficient taking into account the type of belt.
Figure 1. Kinematic diagram of a compound idler roller
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1, 2-driving and driven pulleys, 3- covering belt, 4-integral tension roller, 5- signaling sensors, 6- roller axis tilt mechanism, 7- automatic adjusting device.
According to the kinematic diagram in Fig. 1, the shear force arising from the non-parallelism of the axes of rotation of the pulleys is determined
60 • k • P .
F^tt =--sin p
СД
(3)
л • D • n
where ] is the angle of deviation of the axis of rotation of the driven pulley relative to the axis of the driving pulley.
Methodology. In the future, we will consider the derivation of the formula for determining the shear force for the raw cotton loader when the drum axes are not parallel. Shear force in the conveyor of the raw cotton loader.
F* =
к • PT 77 • V
sin P
(4)
where ] - K.P.D. conveyor drive;
V - linear speed of the conveyor belt; Pt - required power on the drum shaft:
Pt =
Я • Tf •Ф 1000
(5)
where X is a coefficient taking into account the nature of the convey or operation .
The torque is determined according to:
t = ( s m - s з )
Di 2
(6)
where SHE, SCE - tension forces in the incoming and outgoing branches of the conveyor. Table 1 shows similar calculations for determining the shear force in a composite tension roller with an automatic regulating device for a flat-belt transmission according to (3).
Research results. Analysis of the calculation results given in Table 1 shows that the value of the shear force varies within 80 ... 200 N. With an increase in the linear speed of the conveyor belt of the raw cotton loader, the shear force decreases, so at V = 6 m / s FSD = 80 n, and at V = 8 m / s FC^ = 77 n. It was revealed that the load from raw cotton has an insignificant effect on the change in the shear force. The main parameter affecting a significant change in the shear force of the conveyor of the raw cotton loader is the change in the angle of inclination of the rotation axes of the working drums, so at [ = 4 V = 6 m / s, FC£ = 80 n, and at [ =
10 °, FC^ = 210 n. Analysis of the results of calculating the shear force for a composite tension roller of a flat-belt transmission showed that the change in the magnitude of the shear force not only depends on the change in the angle of inclination of the pulley axis and speed modes, but also on the type of belt. type of belts. When the angle of deviation of the axis of rotation [3 of the driven pulley for the Habasit belt
[ = 4 °,
FCA = 31.63 n, and for the "Rubberized" belt FC£ = 37.13 n. In other cases, the difference between the sheave sheaves at the same angles of misalignment of the pulleys for the types of belts under consideration does not exceed 3.5 ... 4.0 n. The maximum value of the shear force at n = 4 ° (rubberized belt), VI = 5.58 m / s. This is due to the fact that the coefficient of friction of the belt with the pulleys is higher for the rubberized belt relative to "Habasit". It can be seen from the table that a change in the angle of non-parallelism of the axes of the pulleys significantly affects the magnitude of the shear force. It was also revealed that with an increase in the linear speed of the belt, the magnitude of the shear force decreases, the kinetic energy increases, as well as the inertia of the system.
Table 1.
Basic parameters affecting the lateral displacement of the conveyor belt of the raw cotton loader at idle and load conditions
Without load With load
№ V, m/s b, grad Fb, N P, Vt F^, N Fb, N P, Vt F^, N
4 77 80
1. 6 6 1100 2286 80 1130 2359 123
8 153 158
10 210 217
4 65 67
2. 7 6 925 2151 105 953 110
8 130 133
10 212 220
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Dependence of the shear force FCfl on the deflection angle of the axis b0 of rotation of the driven drum at idle and load
conditions.
F
200
СД
150
100
50
4
8
ß°
10
V=5,63 м/с без нагрузки V=6,28 м/с без нагрузки
V=5,63 м/с с нагрузкой V=6,28 м/с с нагрузкой
Table 2.
Theoretical dependence of the shear force FC^ on the change in the deviation angle of the driven pulley axis relative to the driving pulley axis at different speed modes of movement
2
6
Types Deviation- Shear force F™ (N) at
Belts angle, grad V1 V2 V3
1 8 7 5,82
1. Habasit 2 15,8 14 11,6
3 23,7 20,85 17,38
4 31,63 27,83 23,2
1 8,62 7,6 6,3
2. Poli-belt 2 17,2 15,13 12,6
3 25,8 22,7 18,9
4 34,4 30,3 25,2
1 9,3 8,2 6,83
3.Rubberized 2 18,6 16,34 13,6
3 27,8 24,5 20,4
4 37,13 32,7 27,2
In order to balance or eliminate the shearing force that occurs due to the non-parallelism of the axes of rotation of the drums (pulleys), the axis of the recommended composite tension roller must be installed obliquely in the opposite direction from the skew angle of the drum axes.
The resultant force is equal to:
F = Fn + F*
FR = FR + FR
(7)
Fj^ h Fg - respectively, the normal and tangential components of the resultant force.
Frictional force during belt descent
F = f • Fn
F ТР f F R
(8)
where f is the coefficient of friction between the belt and the composite tension roller.
Fl = FB = Fb • sin « • (9)
where □ □ is the angle of inclination of the axes of rotation of the composite tension roller relative to the vertical plane
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Condition for compensation of the belt coming off the pulley
Fxp + рсд • cos(a + ß) > FCд
(10)
where □ -is the angle of rotation between the axes of rotation of the driving and driven pulleys.
The formula for determining the angle of inclination of the axis of the composite tension roller relative to the vertical plane has the form [3]:
a > arcctg
1 + sin2 ß
f +1 • sin2ß ^ 2
(11)
To clarify the calculated indicators of the belts of foreign firms "Habasit", "Poly Belt", Table 3 is given. It can be noted from the table that all data are indicative values under normal climatic conditions, i.e. t = 20 ° C and air humidity 65% [2].
Table 3.
Estimated indicators of conveyor belts of foreign firms "Habasit" and "Poly Belt"
Indicators Habasit Poli Belt
1. Ribbon types SNB-5E SAB-5E
2. Transport side, material PVC PVC
3. Transport side, surface Гладкая Гладкая
4. Running side, material: fabric PES PES
5. Tickness, mm 1,6 1,6
6. Mass of belt, Kg/m2 1,9 1,9
7. Pulling force for 1% stretching per unit width, k1% (h/mm) 5 5
8. Permisibble pulling force per unit of width, K^on (h/mm) 9,5 9,5
9. Tensile strength per unit of width (h/mm) 75 75
10. Friction index on the drive drum made of steel 0,15 0,15
11. Friction index for the drive drum with adhesion coating, ^o 0,35 0,35
12. Friction value on a sliding base made of pickled sheet metal 0,2 0,2
13. Friction index on a sliding base made of Duroplast, ^o 0,25 0,25
14. Coefficient of Puasson 0,4 0,45
15. Shear modulus, satin weave fabric, O, h/m2 20...35 20.35
According to the obtained conditions for determining the angle of inclination of the axis of the composite tension roller, a calculation was carried out for different types of belt, the results of which are given in Table 4.
Conclusion. The results of the calculations established the necessary values of the angle of installation of the axis of the composite tension roller, depending on the angle of non-parallelism of the conveyor pulleys of
the raw cotton loader ... So, for p = 5 a = 22; at p = 7 °, a = 24 ° 26 'for Habasit and, accordingly, a= 21... 22 ° 30' for a rubberized belt. It should be noted that the results obtained make it possible to select the necessary parameters of the composite tensioner to prevent the belt (belt) from coming off the pulleys, depending on the modes of movement and the angle of non-parallelism of the drums.
Table 4.
Dependences of the angle of inclination of the axis a° of the composite tension roller by the critical angle
of the belt descent p° at normal load T = Tnom
Type of belts Friction coefficient, f ß, grad a, grad
5 22°20'
6 23°42'
Habasit 0,34 7 24°26'
8 25°06'
9 25°45'
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Type of belts Friction coefficient, f ß, grad a, grad
5 22006'
6 22045'
Poli belt 0,32 7 23030'
8 24000'
9 24048'
5 21000'
6 21036'
Rubberized 0,30 7 22030'
8 23012'
9 24000'
The technical and economic efficiency of the proposed belt conveyor with a tensioning device is to increase the reliability and efficiency of the conveyor by eliminating the side slip of the belt.
To study the efficiency of the effective design of the centering tensioner, a prototype was made from the Kapro-lon-V material and installed on a conveyor belt of the
TLKh-18 type (Fig. 3). The tests were carried out from 04/24/2018 to 04/23/2019.
Figure 4 shows a general view of the installation of a prototype of the recommended design on a conveyor belt of the TLH-18 type.
Production tests were carried out in a cotton ginning plant at "Expokoller Prin Teks" LLC in the Tashlak region of the Fergana region.
Figure 3. General view of the belt conveyor
Figure 4. General view of a prototype tensioner
References:
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