Lathe , Drilling, Milling and Grinding machine
2,893 views
51 slides
Aug 05, 2021
Slide 1 of 51
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
About This Presentation
Lathe, Drilling, Milling & Grinding, turning, facing, tread cutting, tapping, down milling, up milling, cylindrical grinding, center less grinding, end milling, slotting
Slide Content
Lathe, Drilling,
Milling & Grinding
Siddesh Kumar N M
Assistant Professor
Department of Mechanical Engineering
PES College of Engineering
Milling & Grinding
Siddesh Kumar N M
Assistant Professor
Department of Mechanical Engineering
PES College of Engineering
Lathe
Mother of all
machine tool
2Department of Mechanical Engineering PESCE
Mother of all
machine tool
2Department of Mechanical Engineering PESCE
Introduction to Lathe
•The commonly used general purpose lathe in workshop is engine lathe
•Major parts of lathe are as follows
•Bed
•Tail Stock
•Head Stock
•Carriage
•Lead Screw
•Cross slide
•Compound rest
3Department of Mechanical Engineering PESCE
•The commonly used general purpose lathe in workshop is engine lathe
•Major parts of lathe are as follows
•Bed
•Tail Stock
•Head Stock
•Carriage
•Lead Screw
•Cross slide
•Compound rest
3Department of Mechanical Engineering PESCE
L
a
t
h
e
4
Department of Mechanical Engineering PESCE
a
t
h
e
4
Department of Mechanical Engineering PESCE
Bed
•Bed is the foundation of all the machine & supports to all parts
•It consists of inner guide ways and external guide ways on which the head
stock and tail stock is mounted
•Guide ways maintain the allignment of the tail stock and head stock
•Bed is made up of cast iron
5Department of Mechanical Engineering PESCE
•Bed is the foundation of all the machine & supports to all parts
•It consists of inner guide ways and external guide ways on which the head
stock and tail stock is mounted
•Guide ways maintain the allignment of the tail stock and head stock
•Bed is made up of cast iron
5Department of Mechanical Engineering PESCE
Tail Stock
•Tail stock is also called as dead centre
•The main function of the tail stock is to hold the work piece at
the other end
•It mainly holds the spindle and drill tool
•Made up of cast iron
•It is mounted loosely on the guide ways and locked where ever
required
6Department of Mechanical Engineering PESCE
•Tail stock is also called as dead centre
•The main function of the tail stock is to hold the work piece at
the other end
•It mainly holds the spindle and drill tool
•Made up of cast iron
•It is mounted loosely on the guide ways and locked where ever
required
6Department of Mechanical Engineering PESCE
Head Stock
•Head stock consists of all the gears and pullleys
•The main spindle is projected out from the head
stock
•It consists of spindle, chuck , back gear and pulley
system
7Department of Mechanical Engineering PESCE
•Head stock consists of all the gears and pullleys
•The main spindle is projected out from the head
stock
•It consists of spindle, chuck , back gear and pulley
system
7Department of Mechanical Engineering PESCE
Compound
rest
•It is mounted on cross slide and supports to the
tool post
•It can be tilted through an angle to produce the
tapers
8Department of Mechanical Engineering PESCE
rest
•It is mounted on cross slide and supports to the
tool post
•It can be tilted through an angle to produce the
tapers
8Department of Mechanical Engineering PESCE
Carriage
•It support the tool and slides over the bed
ways between tail stock and head stock
•Parallel feed are obtained by moving the
cariage
•It holds compound rest and tool holder
9Department of Mechanical Engineering PESCE
•It support the tool and slides over the bed
ways between tail stock and head stock
•Parallel feed are obtained by moving the
cariage
•It holds compound rest and tool holder
9Department of Mechanical Engineering PESCE
Lead Screw
•It is a screw rod which runs ongitudinal in the
lathe
•It is engaged at the time of thread cutting and
other operations
10Department of Mechanical Engineering PESCE
•It is a screw rod which runs ongitudinal in the
lathe
•It is engaged at the time of thread cutting and
other operations
10Department of Mechanical Engineering PESCE
Specification of lathe
Swing is the largest work diameter which can be swung for the lathe bed.
The distance between tailstock and headstock center.
Bed length of the machine in a meter ( m ).
The lead screw of the pitch.
The horse power of the machine.
Number of speed of HS spindle and speed range.
The machine weight in a tone.
11Department of Mechanical Engineering PESCE
Swing is the largest work diameter which can be swung for the lathe bed.
The distance between tailstock and headstock center.
Bed length of the machine in a meter ( m ).
The lead screw of the pitch.
The horse power of the machine.
Number of speed of HS spindle and speed range.
The machine weight in a tone.
11Department of Mechanical Engineering PESCE
Principle
of working
of lathe
It holds the work between two supports so call as centers.
Face plateor Chuckare using for holding the work.
Face plate or Chuck are mountedon the machine spindle.
Thecutting toolis holding with the help of Tool post.
The movement of the job is rotating about thespindle axis.
Against the revolving work, the tool is feed.
Thetoolmoves either parallel or inclination to the work axis.
12Department of Mechanical Engineering PESCE
of working
of lathe
It holds the work between two supports so call as centers.
Face plateor Chuckare using for holding the work.
Face plate or Chuck are mountedon the machine spindle.
Thecutting toolis holding with the help of Tool post.
The movement of the job is rotating about thespindle axis.
Against the revolving work, the tool is feed.
Thetoolmoves either parallel or inclination to the work axis.
12Department of Mechanical Engineering PESCE
Principleof workingof lathe
13
Department of Mechanical Engineering PESCE
13
Department of Mechanical Engineering PESCE
Operations
•Cylindriacal turing
•Facing
•Thread cutting
•Taper turning
14Department of Mechanical Engineering PESCE
•Cylindriacal turing
•Facing
•Thread cutting
•Taper turning
14Department of Mechanical Engineering PESCE
Cylindrical
turning
•It is the operation performed to remove the excess
material from the workpiece to produce a cylindrical
work surface
•The work piece is supported between the two centres
•The movement of the tool and work piece is parallel to
each other and perpendicular to work piece
•The cut material will come in the form of chips
15Department of Mechanical Engineering PESCE
turning
•It is the operation performed to remove the excess
material from the workpiece to produce a cylindrical
work surface
•The work piece is supported between the two centres
•The movement of the tool and work piece is parallel to
each other and perpendicular to work piece
•The cut material will come in the form of chips
15Department of Mechanical Engineering PESCE
Cylindricalturning
•Turning is the operation of reducing the diameter of
a work piece to produce a cone -shaped or a
cylindrical surface as shown in fig. above.
•A simple single point cutting tools are use for
turning operations.
16Department of Mechanical Engineering PESCE
•Turning is the operation of reducing the diameter of
a work piece to produce a cone -shaped or a
cylindrical surface as shown in fig. above.
•A simple single point cutting tools are use for
turning operations.
16Department of Mechanical Engineering PESCE
Facing
•Facing is the operation for generation of flat surface
•In this one end of the work piece is fixed in the chuck and the other end
is kept free and the tool is moved over the free end surface
•Facingis an operation of reducing the length of a work piece to produce a
flat surface square with the axis.
•Aregular turningtool may also be using for facing a large work piece.
17Department of Mechanical Engineering PESCE
•Facing is the operation for generation of flat surface
•In this one end of the work piece is fixed in the chuck and the other end
is kept free and the tool is moved over the free end surface
•Facingis an operation of reducing the length of a work piece to produce a
flat surface square with the axis.
•Aregular turningtool may also be using for facing a large work piece.
17Department of Mechanical Engineering PESCE
Facing
18Department of Mechanical Engineering PESCE
18Department of Mechanical Engineering PESCE
Thread
cutting
•Threadingis a operations to produce a helical groove on a cylindrical or conical
surface by feeding the toollongitudinallywhen the job is revolved between center’s
or by a chuck.
•Threads can be produced either oninternal or externalsurface of a cylindrical bar.19Department of Mechanical Engineering PESCE
cutting
•Threadingis a operations to produce a helical groove on a cylindrical or conical
surface by feeding the toollongitudinallywhen the job is revolved between center’s
or by a chuck.
•Threads can be produced either oninternal or externalsurface of a cylindrical bar.19Department of Mechanical Engineering PESCE
Threadcutting
20Department of Mechanical Engineering PESCE
20Department of Mechanical Engineering PESCE
Taper turning
•Taper turning is the method to produce the conical surface on the workpiece
•Swivelling compond rest method
•In this method the compond rest is tilted to an angle to get the required taper angle
•The tool axis is tiled to an angle to get the taper angle
•Tail stock set over method
•In this method tail stock is tilted to an angle to get the required taper angle
•The work piece axis is tiled to an angle to get the taper angle
21Department of Mechanical Engineering PESCE
•Taper turning is the method to produce the conical surface on the workpiece
•Swivelling compond rest method
•In this method the compond rest is tilted to an angle to get the required taper angle
•The tool axis is tiled to an angle to get the taper angle
•Tail stock set over method
•In this method tail stock is tilted to an angle to get the required taper angle
•The work piece axis is tiled to an angle to get the taper angle
21Department of Mechanical Engineering PESCE
Taper turning
22Department of Mechanical Engineering PESCE
22Department of Mechanical Engineering PESCE
Operations
performed
in lathe
23Department of Mechanical Engineering PESCE
performed
in lathe
23Department of Mechanical Engineering PESCE
Drilling
24Department of Mechanical Engineering PESCE
24Department of Mechanical Engineering PESCE
Principle of
Drilling machine
•A spindle which turns the tool (called drill) which can
be advanced in the workpiece either automatically or by
hand.
•A work table which holds the workpiece rigidly in
position.
•Working principle: The rotating edge of the drill exerts a
large force on the workpiece and the hole is generated.
The removal of metal in a drilling operation is by
shearing and extrusion.
25Department of Mechanical Engineering PESCE
Drilling machine
•A spindle which turns the tool (called drill) which can
be advanced in the workpiece either automatically or by
hand.
•A work table which holds the workpiece rigidly in
position.
•Working principle: The rotating edge of the drill exerts a
large force on the workpiece and the hole is generated.
The removal of metal in a drilling operation is by
shearing and extrusion.
25Department of Mechanical Engineering PESCE
Radial
Drilling
Machine
26Department of Mechanical Engineering PESCE
Drilling
Machine
26Department of Mechanical Engineering PESCE
RadialDrillingMachine
•Base: The base is a heavy casting that supports the machine structure; it provides rigid mounting for the column and stability for the
machine. The base is usually provided with holes and slots which help to Bolt the base to a table or bench and allow the work-holding device
or the workpiece to be fastened to the base.
•Column: The column is a vertical post that Column holds the worktable and the head containing the driving mechanism. The column may be
of round or box section.
•The table, either rectangular or round. Drill machine/press in shape supports the workpiece and is carried by the vertical column. The surface
of the table is 90-degree to the column and it can be raised, lowered and swiveled around it. The table can be clamp/hold the required the
workpiece. Slots are provided in most tables to allow the jigs, fixtures or large workpieces to be securely fixed directly tothe table.
•Drilling Head: The drilling head, mounted close to the top of the column, houses the driving arrangement and variable speed pulleys. These
units transmit rotary motion at different speeds to the drill spindle. The hand feed lever is used to control the vertical movement of the
spindle sleeve and the cutting tool.
27Department of Mechanical Engineering PESCE
•Base: The base is a heavy casting that supports the machine structure; it provides rigid mounting for the column and stability for the
machine. The base is usually provided with holes and slots which help to Bolt the base to a table or bench and allow the work-holding device
or the workpiece to be fastened to the base.
•Column: The column is a vertical post that Column holds the worktable and the head containing the driving mechanism. The column may be
of round or box section.
•The table, either rectangular or round. Drill machine/press in shape supports the workpiece and is carried by the vertical column. The surface
of the table is 90-degree to the column and it can be raised, lowered and swiveled around it. The table can be clamp/hold the required the
workpiece. Slots are provided in most tables to allow the jigs, fixtures or large workpieces to be securely fixed directly tothe table.
•Drilling Head: The drilling head, mounted close to the top of the column, houses the driving arrangement and variable speed pulleys. These
units transmit rotary motion at different speeds to the drill spindle. The hand feed lever is used to control the vertical movement of the
spindle sleeve and the cutting tool.
27Department of Mechanical Engineering PESCE
Twist drill and
its
nomenclature
28Department of Mechanical Engineering PESCE
its
nomenclature
28Department of Mechanical Engineering PESCE
Twist drill anditsnomenclature
•Body:Thebodyofthetwistdrillspiralgroovescutonit.Thesegroovesservetoofferclearancetothechipsformedatthe
cuttingedge.Theyalsopermitthecuttingfluidtospreadtothecuttingedges.
•Shank:Itisapartthatgetsfittedintothedrillchuckorsleeve.Itmightbeparallelshankortapershank.Smallerdiameter
drillshavestraightshank.Morsetaperisgenerallyprovidedforlargediametertapereddrills.Thetapershankbringsthe
tangattheendofshank.Thisfitsintoaslotinthemachinespindle,sleeveorsocketandgivesapositivegrip.
•Neck:Itistheundercutportionbetweenthebodyandtheshank.Usually,sizeandotherdetailsaremarkedattheneck.
29Department of Mechanical Engineering PESCE
•Body:Thebodyofthetwistdrillspiralgroovescutonit.Thesegroovesservetoofferclearancetothechipsformedatthe
cuttingedge.Theyalsopermitthecuttingfluidtospreadtothecuttingedges.
•Shank:Itisapartthatgetsfittedintothedrillchuckorsleeve.Itmightbeparallelshankortapershank.Smallerdiameter
drillshavestraightshank.Morsetaperisgenerallyprovidedforlargediametertapereddrills.Thetapershankbringsthe
tangattheendofshank.Thisfitsintoaslotinthemachinespindle,sleeveorsocketandgivesapositivegrip.
•Neck:Itistheundercutportionbetweenthebodyandtheshank.Usually,sizeandotherdetailsaremarkedattheneck.
29Department of Mechanical Engineering PESCE
Twist drill anditsnomenclature
•Point:Itistheconefashionedendofthedrill.Thepointisshapedtoproducelip,face,andflankandchiseledgeordeadcenter.
•LandorMargin:Itisanarrowstrip.Itrangesbackontheedgeofthedrillflutes.Thesizeofdrillismeasuredacrossthelandsat
thepointend.Landretainsthedrillaligned.
•Web:Itisthecentralportionofdrilllocatedbetweentherootsofthegroovesandlengtheningfromthepointtowardstheshank.
•Chiseledge:Theintersectionofflankformsthechiseledge.Thisactsasaflatdrill.Itcutsasmallholeintheworkpieceatthe
beginning.Thereforecuttingedgesremovesfurthermaterialstocompletethehole.
•Cuttingedge:Thecuttingedgesofadrillareknownaslips.Bothlipsshouldhaveequallength,sameangleofinclinationand
correctclearance.
30Department of Mechanical Engineering PESCE
•Point:Itistheconefashionedendofthedrill.Thepointisshapedtoproducelip,face,andflankandchiseledgeordeadcenter.
•LandorMargin:Itisanarrowstrip.Itrangesbackontheedgeofthedrillflutes.Thesizeofdrillismeasuredacrossthelandsat
thepointend.Landretainsthedrillaligned.
•Web:Itisthecentralportionofdrilllocatedbetweentherootsofthegroovesandlengtheningfromthepointtowardstheshank.
•Chiseledge:Theintersectionofflankformsthechiseledge.Thisactsasaflatdrill.Itcutsasmallholeintheworkpieceatthe
beginning.Thereforecuttingedgesremovesfurthermaterialstocompletethehole.
•Cuttingedge:Thecuttingedgesofadrillareknownaslips.Bothlipsshouldhaveequallength,sameangleofinclinationand
correctclearance.
30Department of Mechanical Engineering PESCE
Drilling
machining
operations
•Drilling
•Boring
•Reaming
•Tapping 31
Department of Mechanical Engineering PESCE
machining
operations
•Drilling
•Boring
•Reaming
•Tapping 31
Department of Mechanical Engineering PESCE
Boring
•Boring is acutting processthat involves the use of a
single-point cutting tool or boring head to enlarge
an existing hole in a workpiece. While drilling is
performed to create an initial hole in a workpiece,
boring is performed to enlarge an existing hole in a
workpiece.
32Department of Mechanical Engineering PESCE
•Boring is acutting processthat involves the use of a
single-point cutting tool or boring head to enlarge
an existing hole in a workpiece. While drilling is
performed to create an initial hole in a workpiece,
boring is performed to enlarge an existing hole in a
workpiece.
32Department of Mechanical Engineering PESCE
Reaming
•Reaming is acutting processthat involves the use of
a rotary cutting tool to create smooth interior walls
in an existing hole in a workpiece. The rotary cutting
tool used in reaming is known as a reamer.
33Department of Mechanical Engineering PESCE
•Reaming is acutting processthat involves the use of
a rotary cutting tool to create smooth interior walls
in an existing hole in a workpiece. The rotary cutting
tool used in reaming is known as a reamer.
33Department of Mechanical Engineering PESCE
Tapping
•Tapping is amachining process for producing internal
threads.
•TAPPING is a machining process for producing internal
threads.
•A tap is a cylindrical or conical thread-cutting tool
having threads of a desired form on the periphery.
Combining rotary motion with axial motion, the tap cuts
or forms the internal thread.
34Department of Mechanical Engineering PESCE
•Tapping is amachining process for producing internal
threads.
•TAPPING is a machining process for producing internal
threads.
•A tap is a cylindrical or conical thread-cutting tool
having threads of a desired form on the periphery.
Combining rotary motion with axial motion, the tap cuts
or forms the internal thread.
34Department of Mechanical Engineering PESCE
Milling machine
•Milling is a process of cutting or removing metal from ajob by giving a feed.With single or multiple cutting edges.
•The number of cutting edges removes the material in a small amount from a job. This process is utilized to produce a flat
surface or curved surface or many other complex shapes with high accuracy and better surface finish.
35Department of Mechanical Engineering PESCE
•Milling is a process of cutting or removing metal from ajob by giving a feed.With single or multiple cutting edges.
•The number of cutting edges removes the material in a small amount from a job. This process is utilized to produce a flat
surface or curved surface or many other complex shapes with high accuracy and better surface finish.
35Department of Mechanical Engineering PESCE
Principle of milling machine:
•The workpiece is placed on the work table. The cutting tool is also known as a cutter which rotates is to rotate to cut
the material. the cutter moves from right to left to remove the material from the workpiece. Due to the workpiece
advance, the cutter teeth remove the material from the workpiece for the desired shape.
•Both tool and workpiece will be rotating.
36Department of Mechanical Engineering PESCE
•The workpiece is placed on the work table. The cutting tool is also known as a cutter which rotates is to rotate to cut
the material. the cutter moves from right to left to remove the material from the workpiece. Due to the workpiece
advance, the cutter teeth remove the material from the workpiece for the desired shape.
•Both tool and workpiece will be rotating.
36Department of Mechanical Engineering PESCE
Down milling
•The workpiece mounted at the table is moved in the identical path as that of the rotation of
theMilling cutter.
•The slicing force is maximum at the beginning and minimum on the give-up of cut.
•TheChip thickness is extra at the beginning of the reduction. The workpiece is not disturbed due
to the
•A chunk of the cutter on the work. The coolant at once reaches the slicing point. So the first-class
of
•The floor end received is high. Because of the backlash blunders among the feed screw of the
tableAnd the nut, vibration is set up on the workpiece.
37Department of Mechanical Engineering PESCE
•The workpiece mounted at the table is moved in the identical path as that of the rotation of
theMilling cutter.
•The slicing force is maximum at the beginning and minimum on the give-up of cut.
•TheChip thickness is extra at the beginning of the reduction. The workpiece is not disturbed due
to the
•A chunk of the cutter on the work. The coolant at once reaches the slicing point. So the first-class
of
•The floor end received is high. Because of the backlash blunders among the feed screw of the
tableAnd the nut, vibration is set up on the workpiece.
37Department of Mechanical Engineering PESCE
Up milling
•On this approach, the workpiece mounted at the desk is fed against the route of
rotation of the
•Milling cutter. The cutting force is minimum at some stage at the beginning of the
reduction and maximum at the cease of reduction.
•The thickness of the chip is more at the give up of the reduce. Because the slicing
pressure is directed upwards, it tends to boost the workpiece from the fixtures.
•An issue is felt in pouring coolant on the cutting edge. Due to these motives, the
great of the floor acquired by using this method is wavy. This strategy being safer
is usually used and once in a while referred to as conventional milling.
38Department of Mechanical Engineering PESCE
•On this approach, the workpiece mounted at the desk is fed against the route of
rotation of the
•Milling cutter. The cutting force is minimum at some stage at the beginning of the
reduction and maximum at the cease of reduction.
•The thickness of the chip is more at the give up of the reduce. Because the slicing
pressure is directed upwards, it tends to boost the workpiece from the fixtures.
•An issue is felt in pouring coolant on the cutting edge. Due to these motives, the
great of the floor acquired by using this method is wavy. This strategy being safer
is usually used and once in a while referred to as conventional milling.
38Department of Mechanical Engineering PESCE
Up milling and Down milling
39Department of Mechanical Engineering PESCE
39Department of Mechanical Engineering PESCE
Milling machine
40Department of Mechanical Engineering PESCE
40Department of Mechanical Engineering PESCE
Plane milling
•Plane milling: plane milling is also known as slab milling
or surface milling. This technic of milling flat surfaces
with the axis of the slicing tool parallels the surface
being machined.
•The rotating milling cutter provides continuous reduction
but moves from one side of the workpiece to some
other quiet. This process is as shown in the figure below.
41Department of Mechanical Engineering PESCE
•Plane milling: plane milling is also known as slab milling
or surface milling. This technic of milling flat surfaces
with the axis of the slicing tool parallels the surface
being machined.
•The rotating milling cutter provides continuous reduction
but moves from one side of the workpiece to some
other quiet. This process is as shown in the figure below.
41Department of Mechanical Engineering PESCE
End milling
•End milling: in this operation flat surface is produced as well as slots
pockets, keyways are created in the workpiece. The tool moves to the right
angle to the axis of the rotating cutter.
•The tool has cutting edges at the end as well as the periphery.
42Department of Mechanical Engineering PESCE
•End milling: in this operation flat surface is produced as well as slots
pockets, keyways are created in the workpiece. The tool moves to the right
angle to the axis of the rotating cutter.
•The tool has cutting edges at the end as well as the periphery.
42Department of Mechanical Engineering PESCE
Slotter
•slotter is a milling operation in which groove or slots
are made in the workpiece.
•It has cutting edges on the periphery on both sides
of the tool.
43Department of Mechanical Engineering PESCE
•slotter is a milling operation in which groove or slots
are made in the workpiece.
•It has cutting edges on the periphery on both sides
of the tool.
43Department of Mechanical Engineering PESCE
Horizontal
Milling
Machine
44Department of Mechanical Engineering PESCE
Milling
Machine
44Department of Mechanical Engineering PESCE
Vertical
Milling
Machine
45Department of Mechanical Engineering PESCE
Milling
Machine
45Department of Mechanical Engineering PESCE
Grinding machine
46Department of Mechanical Engineering PESCE
46Department of Mechanical Engineering PESCE
Grinding machine
•Grinding is a metal removal operation by means of abressive particles which are rigidly mounted on the rotating wheel
•Each abrasive particle acts as a single point cutting tool
•Grinding wheel is a multipoint cutting operation
•Grinding operation is perfomed to remove very less material normally grinding is performed for finsihing operation
•Abrasives used are Silicon carbide, boron carbide,alumnium oxide and cubic boron nitride etc.
47Department of Mechanical Engineering PESCE
•Grinding is a metal removal operation by means of abressive particles which are rigidly mounted on the rotating wheel
•Each abrasive particle acts as a single point cutting tool
•Grinding wheel is a multipoint cutting operation
•Grinding operation is perfomed to remove very less material normally grinding is performed for finsihing operation
•Abrasives used are Silicon carbide, boron carbide,alumnium oxide and cubic boron nitride etc.
47Department of Mechanical Engineering PESCE
Types of
grinding
machine
Cylindrical grinding machine
Centre less grinding machine
Department of Mechanical Engineering PESCE 48
grinding
machine
Cylindrical grinding machine
Centre less grinding machine
Department of Mechanical Engineering PESCE 48
Cylindrical
grinding machine
Working Principle: The work piece is held between two centres
and the rotating grinding wheel is feed against it,this removes
the material and imparts the good surace finish
•The work must be constantly rotated
•The grinding wheel must be contantly rotated
•The grinding wheel is feed towards or away from the work
material
•Either the work or grinding wheel shld transvers each other
49Department of Mechanical Engineering PESCE
grinding machine
Working Principle: The work piece is held between two centres
and the rotating grinding wheel is feed against it,this removes
the material and imparts the good surace finish
•The work must be constantly rotated
•The grinding wheel must be contantly rotated
•The grinding wheel is feed towards or away from the work
material
•Either the work or grinding wheel shld transvers each other
49Department of Mechanical Engineering PESCE
Centreless grinding
machine
•Working Principle: The work piece is placed between two wheels
on the rest plate, wheels will roatate in clock wise direction where
as workpiece will rotate in counter clock wise directon
•Grinding wheel removed the material from work piece and
regulating wheel will guides the work piece
•Centre less means work piece is not held in between the centres
•Centreless grinding is a outside diameter grinding process
•The workpiece is not mechanically constrained while machining
50Department of Mechanical Engineering PESCE
machine
•Working Principle: The work piece is placed between two wheels
on the rest plate, wheels will roatate in clock wise direction where
as workpiece will rotate in counter clock wise directon
•Grinding wheel removed the material from work piece and
regulating wheel will guides the work piece
•Centre less means work piece is not held in between the centres
•Centreless grinding is a outside diameter grinding process
•The workpiece is not mechanically constrained while machining
50Department of Mechanical Engineering PESCE
Thank you....
By:
Siddesh Kumar N M
Assistant Professor
Department of Mechanical Engineering
PES College of Engineering
Click to add text
Click to add text
51
By:
Siddesh Kumar N M
Assistant Professor
Department of Mechanical Engineering
PES College of Engineering
Click to add text
Click to add text
51
Tags
Categories
GeneralDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 2,893
- Slides 51
- Favorites 4
- Age 1581 days
Related Slideshows
22
Pray For The Peace Of Jerusalem and You Will Prosper
RodolfoMoralesMarcuc
32 views
26
Don_t_Waste_Your_Life_God.....powerpoint
chalobrido8
33 views
31
VILLASUR_FACTORS_TO_CONSIDER_IN_PLATING_SALAD_10-13.pdf
JaiJai148317
31 views
14
Fertility awareness methods for women in the society
Isaiah47
30 views
35
Chapter 5 Arithmetic Functions Computer Organisation and Architecture
RitikSharma297999
27 views
5
syakira bhasa inggris (1) (1).pptx.......
ourcommunity56
30 views