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Mechanical Engineering Design

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... will be considered. we have utilized some CAD soft wares like ANSYS,solidworks , ... gears first meshed with each other and transmitted rotary motion . – PowerPoint PPT presentation

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Title: Mechanical Engineering Design


1
(No Transcript)
2
Mechanical Engineering Design
3
Contents
  • Preface 4
  • What is a gearbox?5
  • Project description..7
  • Bulky characteristics of gearbox..8
  • Gear design.9
  • Shaft design34
  • Deflection consideration37
  • Bearing selection41
  • Computer programming54
  • Acknowledgments..55
  • References..56

4
Preface
  • The present work is a class project of mechanical
    engineering design
  • on Samands gearbox. The quad did as much as
    possible in order to
  • analyze ,collect, calculate and present the
    results. At first we have a
  • historical vision on gearbox then all the parts
    of gearboxs
  • evaluations (some with more details) will be
    considered. we have
  • utilized some CAD soft wares like
    ANSYS,solidworks , catia Mdesign and the
    programming is MATLAB language.
  • We are really grateful of Dr.vakili on behalf of
    the recommendations and hope to satisfy him about
    the process.

5
? What is a gearbox
  • Gears are about as old as any of
  • the machinery of mankind. The oldest machine
  • is the potter's wheel. At first time over 3000
  • years ago primitive gears first meshed
  • with each other and transmitted rotary motion .
  • Water wheels were used to convert energy of
  • moving water into energy that would power
  • machines. Wooden gears connected water
  • wheels to machines that would grind wheat
  • and hammer metals.
  • A transmission or gear box provides speed
  • and torque conversion and from a rotating
  • power source to another device using gear
  • ratios. In British English the term
  • TRANSMISSION refers to the whole drive
  • train, including gearbox, clutch, prop shaft,(
  • for rear wheel drive), differential and final
  • drive shafts. The most common use is in
  • motor vehicals,where the transmission
  • adapts the out put of the internal combustion

6
  • Often, a transmission will have
  • multiple gear ratios (or simply
  • "gears"), with the ability to switch
  • between them as speed varies.
  • This switching may be done
  • manually (by the operator), or
  • automatically. Directional (forward
  • and reverse) control may also be
  • provided. Single-ratio
  • transmissions also exist, which
  • simply change the speed and torque (and sometimes
  • direction) of motor output .

Gearboxes have found use in a wide variety of
differentoften stationaryapplications, such as
wind turbines. Transmissions are also used in
agricultural, industrial, construction, mining
and automotive equipment. In addition to ordinary
transmission equipped with gears, such equipment
makes extensive use of the hydrostatic drive and
electrical adjustable-speed drives.
7
Project description
  • It is desired to design a gearbox To get this
    we first anaylzed
  • the forces and power generated in the internal
    combustion engine
  • then according to the inpute data like the
    maximum torque and maximum power gears designed
    Then by considering the shasfts distans and gears
    diameters the critical gear mated during the
    engaging identified Then all diameters of shafts
    were found out It is important to note that we
    used some steps through the shafts inorder to
    reduce the material used in manufacturing
  • At last all the bearings were selected for the
    most critical
  • condition and all the data and informations were
    wrote besides .the figures

8
Bulky characteristics of gearbox
39.15Kg Total weight
420mm length
240mm width
310mm height
0.0312m3 Occupied volume
195 Approximate cost
150(mm) Normal distance of shafts
360mm Upper shaft length
410mm Lower shaft length
40mm Distance of gear 5,4
5mm Distance of gear 4,3
20mm Distance of gear 3,2
5mm Distance of gear 2,REV
60mm Distance of gear REV,1
9
Gear design
  • There are some important notes to be informed.
    First we calculated the power generated ,from
    some principle physics and fluid mechanics.
    During the engaging of the gears to the higher
    speeds, the power increases and the torque
    reduces. For the rear gear we assumed the
    conditions as well as 1stt gear,inorder to have
    the worst situation. the assumption for the
    overload factor was according to the speed of the
    shaft. when we have low speeds it should be less
    than 1.5 and when the speed increases ,the
    unbalanced forces increases and the overload
    factor shouldnt be less than 2.The gear strength
    for live assumed 108 cycles the reliability
    was set 99.Temperture factor was not considered.
    The surface condition factor was almost 1 because
    of our gear materials. All the gears are from
    steel but different hard nesses.

10
Gear1(pinion)
2.5 Mn
70mm D
24 N
40mm F
St,grade2 ,550HB Material
3000rpm W
64.5hp H
13128N Wtnd
20 n
30
1 Ko
1.2 SF
1.2 SH
8 Qv
11
(more details)
12
Gear1(gear)
2.5 Mn
230mm D
80 N
40mm F
St,grade2 ,550HB Material
913rpm W
64.5hp H
13128N Wtnd
20 n
30
1 Ko
1.4 SF
1.3 SH
8 Qv
13
(more details)
14
Rear gear (pinion)
2.5 Mn
70mm D
28 N
40mm F
St,grade2 Carburized hardened Material
3000rpm W
64.5hp H
13128N Wtnd
20 n
0
1.25 Ko
1.5 SF
1.2 SH
8 Qv
15
(more details)
16
Rear gear (gear)
2.5 Mn
230mm D
92 N
40mm F
St,grade2 Carburized hardened Material
913rpm W
64.5hp H
13128N Wtnd
20 n
0
1.25 Ko
1.02 SF
1.1 SH
8 Qv
17
(More details)
18
2nd gear (pinion)
4 Mn
105mm D
22 N
40mm F
St,grade2 Carburized hardened Material
3700rpm W
70hp H
7700N Wtnd
20 n
30
1.5 Ko
2 SF
1.2 SH
8 Qv
19
(more details)
20
2nd gear (gear)
4 Mn
195mm D
42 N
40mm F
St,grade2 Carburized hardened Material
2000rpm W
70hp H
7700N Wtnd
20 n
30
1.5 Ko
2 SF
1.2 SH
8 Qv
21
(More details)
22
3rd gear (pinion)
4 Mn
130mm D
30 N
30mm F
St,grade2 450HB Material
4500rpm W
80hp H
5845N Wtnd
20 n
30
1.5 Ko
2 SF
1.12 SH
9 Qv
23
(more details)
24
3rd gear (gear)
4 Mn
170mm D
40 N
30mm F
St,grade2 450HB Material
3440rpm W
80hp H
5845N Wtnd
20 n
30
1.5 Ko
2 SF
1.12 SH
9 Qv
25
(more details)
26
4th gear (pinion)
4 Mn
152mm D
33 N
30mm F
St,grade1 300HB Material
5300rpm W
90hp H
4775N Wtnd
20 n
30
2 Ko
1.1 SF
2 SH
9 Qv
27
(More details)
28
4th gear (gear)
4 Mn
148mm D
32 N
30mm F
St,grade1 300HB Material
5443rpm W
90hp H
4775N Wtnd
20 n
30
2 Ko
1.1 SF
2 SH
9 Qv
29
(More details)
30
5th gear (pinion)
4 Mn
172mm D
38 N
20mm F
St,grade1 350HB Material
6000rpm W
100hp H
4140N Wtnd
20 n
30
2 Ko
1.1 SF
2.5 SH
9-10 Qv
31
(More details)
32
5th gear (gear)
4 Mn
128mm D
28 N
20mm F
St,grade1 350HB Material
8062rpm W
100hp H
4140N Wtnd
20 n
30
2.5 Ko
1.1 SF
2.5 SH
9-10 Qv
33
(More details)
34
Shaft design
  • Now it is the time to design the shafts. The most
    important note is the gears weight. For the upper
    shaft, we assumed concentrated weight at the
    center of the gears but at the lower shaft
    because of their large size, we assumed uniform
    distributed force. The other note is the steps.
    During the calculation, we saw that there are
    some parts that can be manufactured with less
    diameters. saw we considered some steps and used
    3mm fillet radius. The fatigue failure was one of
    the important factor. this is stated after
    evaluating the other parameters like critical
    frequency and defelction.the SODERBERG was the
    relation for the fatigue failure. The deflection
    would result in larger diameters, so we used one
    more bearing in each shaft to reduce the
    deflection.
  • The calculations resulted in the critical
    condition when engaging the rear or the 1st gear.
    so we examined the gear 4 in order to reject it
    as the bad condition then we solved the problem
    on the base of rear and 1st gear.

35
Upper shaft
Critical situation is when rear gear is engaged.
36mm 50mm 45mm Diameters from left to right
1030HR 1030HR 1030HR Material
36
Lower shaft
Critical situation is when rear gear is engaged
50mm 47mm 34mm Diameters from left to right
1045 CD 1045 CD 1045 CD Material
37
Deflection considerations(ANSYS)
Other gears just vanished.
Modeling
38
Showing the fillets of the steps.
Uniform load distribution of the gear.
39
Stress distribution. (before middle bearing)
Stress distribution. (after middle bearing)
40
Stress distribution. (after middle bearing)
Stress distribution. (after middle bearing)
41
Bearing selection
  • We were supposed to select 4 bearings ,two for
    the upper shaft and two for the lower shaft. But
    when evaluating the deflections we saw that it is
    worth to try the 3rd bearing for each shaft and
    reduce the undesirable deflection which can cause
    force increased during the engaging. So we did
    it and
  • According to the critical forces, we selected the
    suitable bearing from SKF online bearing
    selection for a long life.Ofcourse in bearing
    selection, its diameters ,mass and cost were
    considered.

42
Upper shaft (right side)
43
Upper shaft (right side)
44
Upper shaft (Left side)
45
Upper shaft (Left side)
46
Upper shaft (middle)
47
Upper shaft (middle)
48
Lower shaft( right side)
49
Lower shaft( right side)
50
Lower shaft( left side)
51
Lower shaft( left side)
52
Lower shaft (middle)
53
Lower shaft (middle)
54
Computer programming
  • In order to computerize the evaluations ,we wrote
    the program which gets some input data like
    m,Np,Ng,Wt,speed and some others and predicts the
    coefficient of safety for pitting and
    bending.Ofcourse we are really grateful of
    Mr.milanchiyan for his prior program which we
    have extended it .There is an animation which
    shows the operation.

55
Acknowledgment
  • At first we really thanks GOD which provided the
    conditions in order to work on the project as
    much as possible. Then we are really grateful of
    our wise master,Dr.vakili on behalf of the
    recommendations. We really thanks from TAKARAN
    CO(ISACO bureau in TEHARAN) , our dear engineer
    ,Mr.Ghorbani and our classmate Mr.milanchiyan.We
    hope to develop our performance in future
    works.enshalah.

56
References
  • 1.Budynas,Nisbett,shigleys mechanical
    engineering design,6th,7th,8th edition,Mc graw
    Hill,

2 .???? ???? ????????????? ? ????? ???? ??? ?????
ANSYS
3.????? ?? ANSYS????? ????????????? ??????? ????
??????
4.www.SKF.COM
57
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