U.S. patent application number 09/751645 was filed with the patent office on 2002-07-04 for counterbalanced advancing metal cutting saw.
Invention is credited to Lanzer, Delmar.
Application Number | 20020083812 09/751645 |
Document ID | / |
Family ID | 25022883 |
Filed Date | 2002-07-04 |
United States Patent
Application |
20020083812 |
Kind Code |
A1 |
Lanzer, Delmar |
July 4, 2002 |
Counterbalanced advancing metal cutting saw
Abstract
An advancing power saw used for any metal cutting application.
The power saw is provided with an oscillating mechanism that drives
the saw up and down in a vertical direction. A hydraulic cylinder
advances the saw toward the metal being cut while the saw is
oscillating creating a circular pathway for the saw blade during
the cutting operation. A balancing apparatus is provided in
association with the saw blade that advances in an opposite
direction to that of the saw blade to act as a counterbalance for
the saw. The balancing apparatus has a weight provided at one end
which dampens the vibrations created by the saw during the cutting
operation and substantially equalizes pressure on the saw
blade.
Inventors: |
Lanzer, Delmar; (Fort Wayne,
IN) |
Correspondence
Address: |
Kevin R. Erdman
Baker & Daniels
Suite 2700
300 N. Meridian Street
Indianapolis
IN
46204
US
|
Family ID: |
25022883 |
Appl. No.: |
09/751645 |
Filed: |
December 29, 2000 |
Current U.S.
Class: |
83/490 ;
83/615 |
Current CPC
Class: |
Y10T 83/7793 20150401;
B23D 45/028 20130101; Y10T 83/7788 20150401; B23D 47/10 20130101;
Y10T 83/8824 20150401; Y10T 83/7801 20150401 |
Class at
Publication: |
83/490 ;
83/615 |
International
Class: |
B26D 001/16 |
Claims
What is claimed is:
1. An advancing power saw for cutting metal objects, said saw
comprising: a platform; a support plate movably disposed on said
platform; a saw blade assembly disposed upon said support plate,
said saw blade assembly including a saw blade coupled with a motor
and associated with an oscillating mechanism; and a counterweight
operatively associated with said support plate and arranged to move
in a direction opposite to the direction said support plate
moves.
2. The power saw of claim 1 further comprising an advancing
mechanism, said advancing mechanism advancing and retracting said
support plate.
3. The power saw of claim 1 further comprising a plurality of
rails, at least one of said plurality of rails operatively
connected to said support plate, and at least one of said plurality
of rails operatively connected to said counterweight, whereby said
rails are adapted to actuate in opposite directions.
4. The power saw of claim 3 wherein counterweight has a sufficient
mass in relation to said power saw to dampen vibrations in said
power saw.
5. The power saw of claim 3 wherein counterweight has a sufficient
mass in relation to said power saw to substantially equalize
pressure on said saw blade.
6. The power saw of claim 3 further comprising at least one
hydraulic cylinder associated with said rails.
7. The power saw of claim 3 further comprising at least one
hydraulic cylinder associated with said counterweight and at least
one hydraulic cylinder associated with said support plate.
8. The power saw of claim 1 wherein said oscillating mechanism
further comprises an oscillating motor, said oscillating motor
operatively associated with said oscillating mechanism by a
connecting arm.
9. The power saw of claim 1 further comprising at least one pivot
support disposed at one end of said platform.
10. The power saw of claim 1 wherein said saw support plate and
said counterweight pivot about said pivot support.
11. The power saw of claim 9 wherein said pivot support is disposed
beneath said rails.
12. The power saw of claim 9 wherein said pivot support extends
above said rails.
13. The power saw of claim 1 further comprising a pulley assembly,
said pulley assembly coupled to said counterweight and said support
plate, whereby said pulley assembly advances said counterweight in
a direction opposite of said support plate.
14. An advancing power saw for cutting metal objects, said saw
comprising: a platform having a movable support plate; oscillating
saw means for cutting said metal objects disposed on said support
plate; and balancing means for dampening vibration of said
oscillation saw means.
15. The power saw of claim 14 wherein said oscillating saw means
includes a saw blade, said saw blade rotatably supported atop said
support plate.
16. The power said of claim 14 further comprising at least one
pivot support wherein said saw support plate is supported above
said platform by said pivot support.
17. The power saw of claim 16 wherein said pivot support is
disposed beneath said rails.
18. The power saw of claim 16 wherein said pivot support extends
above said rails.
19. The power saw of claim 14 wherein said oscillating saw means is
operatively associated with an oscillating motor, said oscillating
saw means and said oscillating motor coupled by a connecting
arm.
20. The power saw of claim 14 wherein said oscillating saw means
further comprises an advancing mechanism, said advancing mechanism
operatively associated with said support plate, whereby said
advancing mechanism advances and retracts said saw blade.
21. The power saw of claim 14 wherein said balancing means is
operatively associated with said support plate and arranged to move
in a direction opposite to the direction said support plate
moves.
22. The power saw of claim 14 wherein said balancing means further
comprises a plurality of rails, at least one of said plurality of
rails operatively connected to said saw support plate, and at least
one of said plurality of rails operatively connected to said
balancing means, whereby said rails are adapted to actuate in
opposite directions.
23. The power saw of claim 22 further comprising at least one
hydraulic cylinder associated with said rails.
24. The power saw of claim 22 further comprising at least one
hydraulic cylinder associated with said counterweight and at least
one hydraulic cylinder associated with said support plate.
25. The power saw of claim 14 wherein said balancing means supports
at one end a counterbalance, whereby said counterbalance dampens
vibrations in said power saw.
26. The power saw of claim 25 wherein said counterbalance is a
weight related to the vibrations in said power saw.
27. The power saw of claim 25 wherein said counterbalance
substantially equalizes pressure on said saw blade.
28. The power saw of claim 14 wherein said oscillating saw means
further comprises a pulley assembly, said pulley assembly coupled
to said balancing means and to said support plate, whereby said
pulley assembly advances said balancing means in a direction
opposite of said support plate.
Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of Invention
[0002] The present invention relates to power saws used for any
metal cutting application. More particularly, the field of the
invention involves such power saws used for cutting metal objects
such as railroad rails used in railroad joints.
[0003] 2. Description of the Related Art
[0004] In general, metal objects such as railroad rails, engine
blocks, and stainless steel rods are cut for several purposes
including forming railroad joints and material testing. These types
of metals are conventionally cut by power saws. Conventional power
saws include a saw blade that is driven by a belt coupled to a
relatively high horsepower motor. The saw blade is advanced
downwardly at a constant rate toward the piece of metal by a
hydraulic cylinder or the like. Another feature of conventional
power saws used to cut metal is an oscillating device which
provides the saw blade with an oscillatory motion as it advances
through the metal object. The saw blade follows a circular path as
it cuts through the metal.
[0005] Power saws lacking an oscillating device maintain the blade
in constant contact with the metal being cut. The temperature of
the metal article at the point of contact thus elevates becoming
too hot and alters the integrity of the metal. Further, due to the
high temperatures, the saw blade tends to cut towards the hotter
areas of the metal as it is being forced through the object. The
resulting cut surface of the metal then has ridges and is not
substantially flat which prevent uniform contact of the cut
surfaces of two adjacent railroad rails in a railroad joint for
example. The life of the saw blade is reduced in this type of power
saw because of the stress applied to the blade from the force of
the blade in constant contact with the metal being cut. Power saws
having oscillating devices dissipate the heat created by the
cutting operation so that the integrity of the metal does not
change. However, the oscillatory motion of the saw blade is not
controlled in a smooth, continuous motion which prevents
dissipation of the heat created during cutting, thereby allowing
the integrity of the metal to change. Once this occurs, the
horsepower requirements necessary to force the saw through the
remainder of the piece of metal being cut as well as the stress
applied to the saw blade increase drastically.
[0006] Conventional power saws for cutting metal objects lack
control of the vibrations created during the cutting operation.
Such conventional saws lack speed desired for the cutting
operation. Further, conventional power saws require frequent
replacement of the saw blade.
SUMMARY OF THE INVENTION
[0007] The present invention involves a counterbalanced,
oscillating advancing power saw capable of cutting several types of
metal. The power saw includes an oscillating motor which oscillates
the saw blade vertically. The saw also includes a hydraulic
cylinder which forces the saw blade toward the piece of metal being
cut. A counterbalance is arranged to move in the opposite direction
of the saw as its blade advances towards the metal to facilitate an
approximately constant cutting pressure as the saw blade advances.
The saw also includes a rotating platform which allows the cut
through the metal to be at any desirable angle up to 45 degrees
left or right from center.
[0008] The present invention provides an advancing power saw for
cutting metal objects. The power saw has a platform and a saw
support plate which is disposed on the platform. A saw blade
assembly is disposed upon the support plate and includes a saw
blade coupled with a motor and associated with an oscillating
mechanism. A counterweight is operatively associated with the
support plate and arranged to move in a direction opposite to the
direction the support plate moves.
[0009] In an exemplary embodiment, the power saw includes an
advancing mechanism for advancing and retracting the support plate.
A pulley system is coupled to the counterweight and the support
plate such that the pulley system advances the counterweight in an
equal and opposite direction of the support plate. The
counterweight is made of a plurality of rails where at least one of
the plurality of rails is operatively connected to the support
plate, and at least one of the plurality of rails is operatively
connected to the counterweight, such that the rails actuate in
opposite directions. The counterweight has sufficient mass in
relation to the power saw to dampen vibrations in the power saw and
equalize the pressure on the saw blade. The power saw further
includes at least one hydraulic cylinder is associated with the
rails to facilitate the cutting stroke and return stroke of the saw
assembly. For lateral movement of the saw assembly, at least one
hydraulic cylinder is associated with the counterweight and at
least one hydraulic cylinder is associated with the support plate.
The oscillating mechanism includes an oscillating motor with is
associated with the oscillating mechanism by a connecting arm. The
support plate and the counterweight are supported by at least one
pivot support disposed atop the platform. The pivot support is
disposed beneath the rails. The pivot support extends above the
rails.
[0010] In another form, the present invention provides an advancing
power saw for cutting metal objects including a platform having a
movable support plate. Further included is an oscillating saw
operation for cutting the metal objects disposed on the support
plate and a balancing operation for dampening vibration of the
oscillating saw operation.
[0011] In an exemplary embodiment, the oscillating saw operation
includes a saw blade rotatably supported atop the support plate. At
least one pivot support is provided to support the support plate
above the platform. The pivot support is disposed beneath the
rails. The pivot support extends above the rails. The oscillating
saw operation is operatively associated with an oscillating motor
by a connecting arm. An advancing mechanism is provided and is
operatively associated with the support plate such that the
advancing mechanism advances and retracts the saw blade. The
balancing operation is operatively associated with the support
plate and arranged to move in a direction opposite to the direction
the support plate moves. The balancing operation includes a
plurality of rails, at least one of which is operatively connected
to the support plate, and at least one of which is operatively
connected to the balancing operation. The power saw further
includes at least one hydraulic cylinder which is associated with
the rails. At least one hydraulic cylinder is associated with the
balancing operation and at least one hydraulic cylinder is
associated with the support plate. The balancing operation supports
at one end a counterbalance which dampens vibrations in the power
saw and is a weight. The counterbalance further equalizes pressure
on the saw blade. Further included in the oscillating saw operation
is a pulley assembly coupled to the balancing operation and to the
support plate to advance the balancing operation in a direction
opposite of the support plate.
[0012] An advantage of the power saw of the present invention is
that by oscillating the saw blade, the contact point between the
blade and the metal is not constant to create high temperatures,
eliminating the possibility of altering the integrity of the metal.
Another advantage of the power saw is the balancing apparatus which
counterbalances the weight of the saw blade to control vibrations
produced during the cutting operation and substantially equalizes
pressures on the saw blade. This lengthens the life of the saw
blade and allows the metal to be cut faster.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] The above mentioned and other features and objects of this
invention, and the manner of attaining them, will become more
apparent and the invention itself will be better understood by
reference to the following description of embodiments of the
invention taken in conjunction with the accompanying drawings,
wherein:
[0014] FIG. 1 is a perspective view of the power saw of the present
invention;
[0015] FIG. 2 is a side elevation of the power saw of FIG. 1;
[0016] FIG. 3 is an enlarged, sectional view showing the
oscillating mechanism of the present invention in the initial
position;
[0017] FIG. 4 is the oscillating mechanism of FIG. 3 in an actuated
position;
[0018] FIG. 5 is an enlarged, fragmentary view of the oscillating
mechanism of FIG. 3 taken along view lines 5-5 of FIG. 3 showing
the contact point with the saw support plate;
[0019] FIG. 6 is a fragmentary, perspective view of the balancing
apparatus of the present invention in the advanced position;
[0020] FIG. 7 is a side, sectional view of the pulley system of the
present invention which advances the balancing apparatus;
[0021] FIG. 8 is a rear, sectional view of the present invention
taken along view line 8-8 of FIG. 7;
[0022] FIG. 9 is a rear, sectional view of the present invention
taken along view line 9-9 of FIG. 7;
[0023] FIG. 10 is a rear, sectional view of the present invention
taken along view line 10-10 of FIG. 7;
[0024] FIG. 11 is a side elevational view of the power saw of the
present invention in its initial position;
[0025] FIG. 12 is the power saw of FIG. 11 with the saw blade and
balancing apparatus partially advanced;
[0026] FIG. 13 is the power saw of FIG. 11 with the saw blade and
balancing apparatus completely advanced;
[0027] FIG. 14 is a plan view of the power saw of the present
invention provided with coolant jets;
[0028] FIG. 15 is a side elevation of a second embodiment of the
power saw of the present invention;
[0029] FIG. 16 is a sectional view of the pulley system and
balancing apparatus taken along view line 16-16 of FIG. 15;
[0030] FIG. 17 is a sectional view of the pulley system and
balancing apparatus taken along view line 17-17 of FIG. 15;
[0031] FIG. 18 is a rear, sectional view of the second embodiment
of the present invention taken along view line 18-18 of FIG.
15;
[0032] FIG. 19 is a rear, sectional view of the second embodiment
of the present invention taken along view line 19-19 of FIG. 15;
and
[0033] FIG. 20 is a rear, sectional view of the second embodiment
of the present invention taken along view line 20-20 of FIG.
15.
[0034] Corresponding reference characters indicate corresponding
parts throughout the several views. Although the drawings represent
embodiments of the present invention, the drawings are not
necessarily to scale and certain features may be exaggerated in
order to better illustrate and explain the present invention. The
exemplification set out herein illustrates embodiments of the
invention, in several forms, and such exemplifications are not to
be construed as limiting the scope of the invention in any
manner.
DESCRIPTION OF THE PRESENT INVENTION
[0035] The embodiments disclosed below are not intended to be
exhaustive or limit the invention to the precise form disclosed in
the following detailed description. Rather, the embodiments are
chosen and described so that others skilled in the art may utilize
their teachings.
[0036] Referring to FIGS. 1 and 2, advancing power saw 10 is used
for cutting a plurality of types of metal including cast iron
engine blocks, stainless steel rods and railroad rail 20. Railroad
rail 20 is illustrated in the figures and discussed below as an
example of the type of metal that can be cut by power saw 10. Power
saw 10 is supported by base 12 upon which rotatable platform 14 is
mounted. Base 12 and platform 14 are both constructed from a
material such as steel possessing strength properties to support
the weight of power saw 10. As shown in FIG. 2, between base 12 and
14 are fixed disk 16 and movable disk 18 also constructed from a
material such as steel and stacked atop one another. Fixed disk 16
is secured to base 12 and movable disk 18 is attached to platform
14 by any suitable means such as welding or the use of fasteners.
Movable disk 18 is rotatably mounted with respect to fixed disk 16
so as to permit rotation of platform 14 and thus power saw 10,
allowing rail 20 to be cut at any desired angle. Optionally, a
power positioning device, e.g. a hydraulic or electric motor, may
drive the rotation of platform 14. Thus, such a saw assembly could
be accessible from any direction, allowing for the saw assembly to
be used on more than one production line. Base 12 is fixed to the
floor in the area where power saw 10 is being used by fasteners 22
such as bolts or screws.
[0037] Advancing power saw 10 includes saw support plate 24 mounted
atop and movable in relation to balancing apparatus 26 as
illustrated in FIGS. 1, 2, 11, 12, and 13. Saw support plate 24 and
balancing apparatus 26 are held above platform 14 by a pair of
pivot supports 28, oscillating mechanism 30 and a pair of springs
32. Pivot supports 28 are secured to the top surface of platform 14
by suitable methods such as welding or brazing and are disposed on
both sides of end 34 of platform 14 to support the width of saw
support plate 24 and balancing apparatus 26. At end 36 of platform
14 is oscillating mechanism 30 which supports saw support plate 24
and balancing apparatus 26 and causes the up and down movement of
power saw 10 in the direction of arrow 42. Pivot supports 28 have
apertures 38 in which the ends of beam 40 are journalled for
rotation. As oscillation mechanism 30 moves power saw 10 up and
down in the direction of arrow 42, beam 40 supporting balancing
apparatus 26 (FIGS. 1, 2, 6 and 7) acts as a pivots about which saw
support plate 24 and balancing apparatus 26 rotate. Oscillating
mechanism 30 will be discussed in greater detail below. Also
supporting plate 24 and balancing apparatus 26 are a pair of
springs 32 disposed on the top surface of platform 14 between pivot
supports 28 and oscillating mechanism 30. Springs 32 help
facilitate and maintain the oscillatory motion of power saw 10
created by oscillating mechanism 30. Springs 32 could also be a
device such as a hydraulic cylinder.
[0038] Referring to FIGS. 3, 4 and 5, oscillating mechanism 30
along with balancing apparatus 26 prevent saw blade 46 from being
in contact with metal articles such as rail 20 for substantial
lengths of time which would create high temperatures causing the
integrity of rail 20 to change. Secured to platform 14 by fasteners
52, oscillating motor 50 is operatively associated with oscillating
mechanism 30 by connecting arm 54. Oscillating motor 50 is a motor
of an appropriate size for actuating connecting arm 54 back and
forth in the direction of arrow 62 and oscillating power saw 10.
Motor 50 includes motor output 56 which is fixed by any suitable
method such as welding or fasteners within aperture 58 located in
plate 60. As motor output 56 rotates in the direction of arrow 62
plate 60 rotates as shown in FIGS. 3 and 4. Extending substantially
perpendicularly from plate 60 is peg 64 which may be integrally
formed with plate 60 or secured within a second aperture located in
plate 60. The opposite end of peg 64 is received in aperture 66
located in end 68 of connecting arm 54. End 70 of connecting arm 54
is provided with eyebolt 72 which is threadedly secured to arm 54.
Eyebolt 72 has hole 74 through its center which receives bolt 76 to
fasten connecting arm 54 to plate 78 of oscillating mechanism 30.
Oscillating motor 50 pivots plate 60 in the direction of arrow 62
which actuates connecting arm 54 and thus plate 78 back and forth
in the direction of arrow 80. The operation of oscillating motor 50
may be variably controlled depending on the size and shape of the
material being cut. This motion of plate 78 generates the
oscillations of power saw 10 as will be described below.
[0039] Referring to FIG. 5, the opposite end of plate 78 from the
link with connecting arm 54 is fixedly mounted on shaft 82. The
ends of shaft 82 are pivotally mounted within pillow blocks 84
which are secured to platform 14 by fasteners 86. A square collar
88 is disposed on shaft 82 between pillow blocks 84. Elongated
plate 90 is attached to surface 92 of collar 88 by means such as
welding or brazing. Collar 88 and plate 90 are configured with
respect to shaft 82 in such a manner that when oscillating
mechanism 30 is in its initial position shown in FIGS. 3 and 5,
plate 90 stands approximately perpendicularly to platform 14. At
each end of plate 90 are members 94 which are secured to plate 90
by a pair of fasteners 96. Members 94 extend downwardly at an angle
from plate 90 so as to be positioned outside of and substantially
below pillow blocks 98. Pillow blocks 98 are secured by fasteners
100 to balancing apparatus end plate 102 extending downwardly and
substantially perpendicular to end 104 of balancing apparatus 26.
Balancing apparatus end plate 102 is secured to balancing apparatus
26 by fasteners 106. Each member 94 has one end of shaft 108 fixed
within aperture 110. Shaft 108 is positioned to contact pillow
blocks 98 at 112 such that as connecting arm 54 is moved away from
pillow block 98 (FIG. 4), toward pivot supports 28, by oscillating
motor 50, power saw 10 is forced upwardly in a direction of arrow
42 (FIG. 2). As motor 50 continues to rotate output shaft 56, plate
60 moves back and forth in the direction of arrow 62 and plate 78
in the direction of arrow 80 causing saw blade 46 to move
continuously up and down in the direction of arrow 42. The distance
in which saw blade 46 moves in the direction of arrow 42 is
directly related to the length of connecting arm 54 including
eyebolt 72 which can be adjusted by threading eyebolt 72 further
onto or off of connecting arm 54. The components of oscillating
mechanism 30 and connecting arm 54 are constructed from a material
such as steel which is strong enough to support the weight of power
saw 10 as it is oscillated.
[0040] Supported by pivot supports 28, oscillating mechanism 30,
and springs 32, saw support plate 24 is fixedly mounted atop
balancing apparatus 26 and supports drive motor 44 which is
operatively connected to saw blade 46 through drive belt 48. Drive
belt 48 is shown in FIGS. 1 and 2 as a single belt but may consist
of a plurality of belts. As shown in FIG. 1, saw blade 46 is
fixedly mounted between ends 114 and 116 of shaft 118. End 114 of
shaft 118 is rotatably mounted in pillow block 120 which is aligned
with edge 128 of supporting plate 24. End 116 of shaft 118 is
rotatably mounted in pillow block 122 which is aligned with edge
124 of cutout 126. Cutout 126 is located along the front edge of
saw support plate 24 to provide clearance for saw blade 46. A third
pillow block 130 is aligned adjacent with edge 132 of cutout 126 so
that shaft 118 is rotatably supported on both sides of saw blade
46, reducing the amount of stress on shaft 118 created during the
cutting operation. End 116 passes through pillow block 130 and
through aperture 134 in saw blade 46 to be received by pillow block
122. End 114 of shaft 118 extends through pillow block 120 past
edge 128 of plate 24 and has gear 136 fixedly attached to end 114
by suitable methods such as welding or the like. Alternatively,
shaft 118 may be similarly mounted to bottom surface 137 of saw
support plate 24 if the application requires that saw blade 46 be
mounted in a lower position.
[0041] Secured to the opposite end of saw support plate 24 from saw
blade 46 is drive motor 44 fixed in position by fasteners 138 such
as bolts or screws. Drive motor 44 is a 125 h.p. motor having
output shaft 140 which extends past edge 128 of plate 24 and has
gear 142 fixedly mounted to shaft 140. It is noted that motor 44
may be of any size suitable to rotate saw blade 46 at the speeds
required to cut rail 20. Gear 142 aligns with gear 136, both of
which being engaged by drive belt 48. As drive motor 44 rotates,
output shaft 140 drives belt 48 which causes rotation of gear 142
and shaft 118. The rotation of shaft 118 is transferred to saw
blade 46 to cut rail 20. Guard 144 stands substantially
perpendicularly from saw support plate 24 and is provided to
protect motor 44 from sparks or debris created during the cutting
of rail 20.
[0042] Referring to FIGS. 6, 8, 9, and 10, balancing apparatus 26
will now be discussed in greater detail. Balancing apparatus 26
maintains continuous oscillations of power saw 10 and controls
vibrations produced during the cutting operation. Balancing
apparatus 26 further facilitates a substantially constant cutting
pressure against rail 20 as saw 10 advances, thereby equalizing
pressure on saw blade 46. By equalizing pressure on blade 46 and
reducing the amount of vibrations passing through saw blade 46, the
life of blade 46 is extended and the cut through rail 20 is faster.
In order to control the vibrations created during operation of saw
10, balancing apparatus 26 is provided with counterbalance or
weight 146 at end 148. The amount of vibrations produced during the
cutting operation varies, depending on the thickness and type of
material such as steel or stainless steel of rail 20.
Counterbalance 146 may be in the range of 400 to 1500 lbs.
depending on the magnitude of the vibrations. The more severe the
vibrations the more weight is required to control them.
[0043] As shown in FIGS. 6, 8, 9 and 10, counterbalance 146 is
supported at end 148 by two outer, U-shaped beams or rails 150 and
152 which are welded together at 154 and extend the length of
balancing apparatus 26. Saw support plate 24 is secured to spacer
plates 156 which simply raise support plate 24 over the upper
surface of beams 152 so that as saw support plate 24 is advanced in
one direction, it does not bind with balancing apparatus 26 moving
in the opposite direction. Spacer plates 156 are welded to upper
surface 158 of substantially L-shaped rails 160. Leg 162 of rails
160 extends downwardly from and is approximately perpendicular to
leg 164 of rails 160. A pair of stationary I-beams or rails 166 are
supported at one end by beam 40 and are secured to balancing
apparatus end plate 102 by fasteners 106 at the opposite end. Legs
162 along with I-beams 166 create cavities 168 in which rollers 170
are disposed. Rollers 170 are fixed to leg 162 of rails 160 by
fasteners 172 and are in rolling contact with inner surfaces 180 of
I-beams 166. Rollers 170 facilitate movement of saw support plate
24 and thus saw blade 46 in the direction of arrow 80 toward rail
20 (FIGS. 6, 12 and 13) and back to the initial position of FIG. 11
after the cutting operation is complete. The opposite side of
I-beam rails 166 form cavities 174 with U-shaped beams 150. Rollers
176 are disposed within cavities 174 and are rotatably mounted to
beams 150 by fasteners 178. Rollers 176 are in rolling contact with
inner surfaces 182 of I-beams 166 for facilitating movement of
counterbalance 146 in a direction opposite that of saw blade 46
during operation and back to the initial position of FIG. 11 when
rail 20 is completely cut.
[0044] Referring to FIGS. 6, 7, 11, 12 and 13, hydraulic cylinder
184, well known in the art, is provided to facilitate the cutting
stroke and the return stroke of saw blade 46 in both directions of
arrow 80. Hydraulic cylinder 184 is supported by beam 40 at one end
and includes rod 186. The end of rod 186 is secured to plate 188
downwardly extending from saw support plate 24 by connector 190.
Hydraulic fluid enters hydraulic cylinder 184 through fluid lines
192 (FIG. 6), forcing rod 186 out of cylinder 184. As rod 186 is
forced out of cylinder 184, saw support plate 24 is advanced toward
rail 20 (FIG. 12) to the actuated position of FIG. 13. Hydraulic
fluid is released from cylinder 184 to allow rod 186 to retract,
returning saw support plate 24 to the initial position of FIG.
11.
[0045] Referring to FIG. 7, pulley assembly 194 advances balancing
apparatus 26 in a direction opposite that of saw blade 46 during
the cutting operation and retracts balancing apparatus 26 back to
the initial position (FIG. 11) once the cutting operation is
complete. Cross member 196 is welded to lower surface 198 of
I-beams 166 (FIG. 8). Shaft 200 is fixed at each end to a pair of
downwardly extending supports 202. At the center of shaft 200 is
gear 204 which is engaged by chain 206. As shown in FIG. 7, near
end 104 of balancing apparatus 26, chain 206 is also engaged on
gear 208 fixed to shaft 210 supported by downwardly extending
supports 212, similar to supports 202. Supports 212 are secured to
cross member 214 which is welded to surface 198 of the opposite end
of stationary I-beams 166. Fixedly attached to chain 206 are joints
216 and 218 which actuate chain 206 about gears 204, 208 and
balancing apparatus 26 as hydraulic cylinder 184 moves saw support
plate 24. Referring to FIG. 9, joint 216 includes extensions 220
which are welded to lower surface 222 of beams 150. Each extension
220 is then welded to cross member 224 to join beams 150 together
so that when actuated, beams 150 advance and retract in unison.
Extending downwardly from the center of cross member 224 is the
support 226 for collar 228 which is fixed to chain 206 at this
point. Similarly, joint 218 shown in FIG. 10 includes extensions
230 which are secured to surface 232 located on the underside of
rails 160. Welded to the lower end of extensions 230 is cross
member 234 which joins rails 160 such that they advance and retract
in unison. Collar 236 is welded directly to cross member 234 and is
fixed to chain 206. In the initial position shown in FIG. 11,
joints 216 and 218 are closest together. As hydraulic cylinder 184
forces saw support plate 24 towards rail 20, joint 218 is moved
toward support 212. The upper portion of chain 206 travels around
gear 208 to force joint 216 closer to supports 202. This movement
of joint 216 forces counterbalance 146 to move in a direction
opposite that of saw support plate 24. The movement of
counterbalance 146 is proportional to saw support plate 24 as shown
in FIGS. 12 and 13 such that the vibrations produced during the
cutting operation are dampened by the weight of counterbalance 146.
The dual motion of power saw 10 in the direction of arrows 42 and
80 creates an elliptical pathway that saw blade 46 follows enabling
the limited contact time between saw blade 46 and rail 20.
[0046] A second embodiment of balancing apparatus 26, pivots 28,
and pulley assembly 194 of the present invention is illustrated in
FIGS. 15 through 20. Balancing apparatus 244 is similar to
balancing apparatus 26 in that stationary rail 246 along with rail
248 supporting saw support plate 24 create cavity 250 for rollers
252. Stationary rail 246 and rail 254 which supports counterbalance
146 define cavity 256 in which rollers 258 are disposed. Rollers
252 and 258 then facilitate movement of saw support plate 24 in a
direction towards rail 20 as counterbalance 146 moves
simultaneously in the opposite direction.
[0047] In this embodiment, rails 248 are advanced by concurrent
operation of a pair of hydraulic cylinders 260 and 262 which are
fixed at one end to beam 274 (FIG. 20) located between rails 248
and to beam 275 situated between the ends of rails 246 at their
opposite end (FIGS. 16 and 17). Rails 254 move in the opposite
direction of rails 248 by a single hydraulic cylinder 264 which is
secured at one end to beam 280 (FIG. 19) located between stationary
rails 246 and at its opposite end to beam 276 (FIG. 18) positioned
between rails 254. By incorporating two hydraulic cylinders 260 and
262 to advance saw support plate 24 and a single hydraulic cylinder
264 to move counterbalance 146, counterbalance 146 travels one-half
the distance that saw support plate 24 travels, reducing the amount
of space that power saw 10 requires.
[0048] Pivots 282 (FIG. 15) in the second embodiment are disposed
on either side of balancing apparatus 244 and extend to a point
above rails 246 and 248 of balancing apparatus 244. Pivots 282
include supports 284 which are secured at one end to platform 14.
At the opposite end of supports 284 are connecting plates 286
attached to supports 284 by fasteners 288. Disposed between
connecting plates 286 on each side of balancing apparatus 244 is
rod 290, the ends of which are rotatably supported in connecting
plates 286. Fixed to the lower portion of rod 290 is cross beam 292
which extends the length of rod 290. Downwardly extending from each
end of beams 292 are connecting members 294, disposed substantially
perpendicularly to beam 292 to link rod 290 and rails 246 of
balancing apparatus 244. The opposite end of connecting members 294
are attached to rails 246 by fasteners 296.
[0049] Pivots 28 of the first embodiment are positioned at the
lower surface of balancing apparatus 26 which causes saw blade 46
to be forced further into rail 20 as blade 46 is oscillated
downwardly. By pivoting power saw 10 from a point above balancing
apparatus 244, saw blade 46 is drawn backwards, away from rail 20
as it moves down into rail 20 rather than being forced forward into
rail 20. In many situations, this configuration provides saw 10
with a better angle of attack on rail 20 which reduces stress of
saw blade 46 and provides rail 20 with a smoother cut surface.
[0050] Pulley assembly 266 (FIGS. 16 and 17) of the second
embodiment includes linear chain 268 that is fixed at each end 270
and 272 to cross beams 274 and 276, respectively. Chain 268 is
engaged on pulley 278 which is rotatably mounted to beam 280
secured to the outer edges of stationary rails 246 (FIG. 19). As
saw support plate 24 and counterbalance 146 advance in opposite
directions, the length of chain 268 between pulley 278 and beam 276
lengthens, shortening the length of chain 268 between pulley 278
and beam 274.
[0051] Even though not shown in the figures, covers are provided to
protect the inside of saw 10 underneath saw support plate 24 and
balancing apparatus 26 as well as covers for the upper portion of
saw blade 46 and drive belt 48. Further, a hydraulic cylinder (not
shown) may be arranged near end 238 (FIG. 1) of rail 20 to force
end 238 away from the rest of rail 20 as it is being cut. When the
hydraulic cylinder is actuated, it would open up the cut, reducing
pressure on saw blade 46. Advancing power saw 10 is not limited to
cutting steel railroad rails 20, it may be used to cut other metals
such as stainless steel. Power saw 10 may also be adapted with
coolant jets to reduce the temperature of rail 20 during the
cutting operation. Referring to FIG. 14, a plurality of coolant
jets 242 may be arranged on both sides of saw blade 46 at
45.degree. and 90.degree. angles to blade 46 to provide adequate
coolant to reduce the temperature of rail 20.
[0052] In operation railroad rail 20 is brought a desired distance
along supports 240 such that the point at which rail 20 is to be
cut aligns with saw blade 46. Drive motor 44 starts rotating drive
belt 48 and thus shaft 118 to begin rotation of saw blade 46.
Oscillating motor 50 begins to operate driving plate 60 back and
forth in the direction of arrow 62 causing connecting arm 54 and
plate 78 to actuate in the direction of arrow 80. This creates
contact at point 112 which raises saw support plate 24 and saw
blade 46 begins the up and down motion of saw blade 46 in the
direction of arrow 42. When saw blade 46 is operating at the proper
speed and is oscillating in a continuous motion, rod 186 of
hydraulic cylinder 184 begins to push saw support plate 24 towards
rail 20. Simultaneously, counterbalance 146 of balancing apparatus
26 begins to move away from saw blade 46 so as to balance blade 46
and reduce vibrations in saw 10 during the cutting operation (FIGS.
11-13). Once saw blade 46 is completely through rail 12 as shown in
FIG. 13, rod 186 of hydraulic cylinder 184 retracts bringing saw
blade 46 and the balancing apparatus 26 closer together towards the
initial position (FIG. 11). Oscillating motor 50 is shut off as is
drive motor 44 so that advancing power saw 10 returns to the
initial position of FIG. 11.
[0053] In the exemplary embodiment of power saw 10, the overall
dimensions of saw 10 are approximately 10 to 12 feet long and 4 to
6 feet wide. The width of power saw 10 is dependant on the width of
balancing apparatus 26, including pulley assembly 194, taken from a
fork lift truck. A 125 horsepower motor is used to rotate drive
belt 48 and thus saw blade 46 at a speed appropriate to cut through
rails 20. Oscillation motor 50 is shown in the Figures as a 3
horsepower motor. Springs 32 of the exemplary embodiment shown in
FIG. 2 are used to facilitate oscillations of saw blade 46 and are
the springs used as shock absorbers in a truck. Pivot supports 28
are positioned at one end of platform 14 to support balancing
apparatus 26 at a point approximately one-third the distance of
balancing apparatus 26 from end 148. The opposite end of balancing
apparatus 26 is supported by oscillating mechanism 30 which in
relation to saw blade 46 is approximately one-third the distance of
saw support plate 24 from the end of plate 24. Counterbalance 146
supported at end 148 of balancing apparatus 26 is in a range
between 400 and 1500 pounds which is dependant on the amount of
vibrations produced during the cutting operation. The
counterbalance moves about 1/2 the amount of the corresponding
movement of the saw blade in the exemplary embodiment.
[0054] While this invention has been described as having an
exemplary design, the present invention may be further modified
within the spirit and scope of this disclosure. This application is
therefore intended to cover any variations, uses, or adaptations of
the invention using its general principles. Further, this
application is intended to cover such departures from the present
disclosure as come within known or customary practice in the art to
which this invention pertains.
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