Partial press apparatus and method for glass sheet bending

A glass sheet is supported on a shaping rail and conveyed through a heating lehr. A press assembly moves along with the glass such that there is no relative horizontal movement between the glass sheet and press assembly and shapes a selected portion of the sheet. A rail support membe moves along with the press assembly to maintain the shaping rail configuration during the shaping operation.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates to sag bending of glass sheets on bending molds and 
in particular to a method and apparatus for press bending selected 
portions of the glass sheets on bending molds while moving through a 
heating lehr. 
2. Technical Considerations 
In the practice of sag bending to form shaped glass windows for automobiles 
and the like as disclosed in U.S. Pat. No. 4,375,978 to Reese, glass 
sheets are positioned on and supported by a skeletal bending mold. The 
shaping rail of the mold has a shape and configuration similar to that of 
the shaped glass sheet at a location slightly inboard of its peripheral 
edge. The bending molds are then conveyed in succession through a heating 
lehr where the glass sheet is heated to its deformation temperature such 
that it begins to sag by gravity until the glass sheet conforms to the 
configuration of the shaping rail. After the glass sheet is shaped, the 
mold is conveyed through an annealing zone where the glass sheet is cooled 
in a controlled manner from its deformation temperature through its 
annealing range to anneal the glass sheet. The glass sagging technique has 
been the method used to bend two glass sheets, or doublets, simultaneously 
which sheets are subsequently laminated together to form a laminated 
automobile windshield. The windshield is curved to conform and blend into 
the shape of an automobile vehicle in which it is installed. 
A critical shape parameter of curved glass sheets used for windshields is 
the approach angle of the glass sheets along the A post of the vehicle 
body. The approach angle is the angle at which the windshield meets the 
vehicle body at the generally vertically extending A-posts of the window 
frame. It has been found that in sag bending glass sheets with deep sag or 
reverse curvatures, there is a tendency for the sheets to draw glass from 
their longitudinal end sections. As a result, the glass sheets may tend to 
lift off the shaping rail of the outline bending mold and have reduced 
curvature causing the sheets to deviate from the desired shape and 
tolerances. This deviation may be caused by overheating the glass sheet 
along the outer edge of its longitudinal sections to achieve the desired 
curved configuration. 
As automotive stylists strive for more aerodynamic designs, the windshields 
are assuming more complex and deeper bend configurations. In addition, the 
windshield edges are approaching the A-post of the vehicle at a more flush 
fashion to provide a smoother transition between the windshield surface 
and the vehicle body surface. As the windshield designs become more 
complicated with compound and complex curvatures, these shapes are 
becoming increasingly more difficult to control during conventional sag 
bending operations. 
It would be advantageous to develop a method of forming glass sheets and 
incorporating conventional sag bending techniques with other shaping 
techniques so as to form and maintain the desired curvatures required for 
proper vehicle assembly. 
PATENTS OF INTEREST 
U.S. Pat. No. 3,220,819 to Jenderisak teaches a hold down device for a 
glass bending mold. Glass doublets are positioned on an outline mold and 
hold down devices mounted along a selected edge of the bending mold extend 
over the glass doublet edge and hold the peripheral portion of the glass 
doublet against the underlying shaping rail. As the glass sheet is heated, 
the end section of the mold pivots relative to the main portion to shape 
the heat softened glass sheets while the hold down device maintains the 
glass doublet edge against the shaping rail. 
U.S. Pat. No. 4,265,650 to Reese et al. teaches the press bending of 
windshield doublets using a pair of vertically aligned upper and lower 
full surface press faces. Glass sheets are positioned on an outline 
shaping mold and conveyed through the heating lehr wherein the glass sags 
by gravity to conform with the mold outline. The mold is then stopped and 
positioned between the press faces. The lower press face lifts the glass 
sheets off the outline mold and sandwiches the sheets against the upper 
press face. After shaping, the lower press redeposits the glass sheets on 
the outline mold for continued downstream movement. 
U.S. Pat. No. 4,496,386 to Hymore et al. teaches a method and apparatus for 
bending glass sheets. The apparatus includes a lower outline press member 
having an array of spaced apart shaping rail elements mounted to pass 
upwardly between adjacent conveyor rolls to contact and support the lower 
surface of a heat softened glass sheet. A second array of shaping rails is 
disposed above the conveyor rolls and mounted for movement into and out of 
association with the spaces between the spaced apart lower shaping rail 
elements. As the glass sheet is raised by the lower shaping rail and 
pressed against an upper shaping mold, the second array of shaping rails 
contacts the lower surface of the glass sheet between the first shaping 
rails to press the peripheral edge of the glass sheet against the upper 
shaping mold. 
U.S. Pat. No. 4,501,603 to Frank et al. teaches a method and apparatus for 
shaping glass sheets to complicated shapes. Heat softened glass sheets are 
lifted off conveying rolls by a lower, slotted lifting mold and pressed 
against a full surface upper vacuum mold. A movable shaping rail mounted 
on the upper vacuum mold engages the lower surface of the end portion of 
the hot glass sheet to sandwich the latter against a corresponding end 
portion of the upper vacuum mold to shape the glass sheet in the desired 
complicated configuration. 
U.S. Pat. No. 4,804,397 to Stas et al. teaches a partial press for shaping 
heat softened glass sheets. The glass sheets are supported on a bending 
mold and conveyed through a heating lehr while a press member contacts 
selected portions of the glass sheet. The press member moves with the 
glass sheet so that there is no relative horizontal movement between the 
press member and the glass as the glass sheet is conveyed through the 
lehr. 
SUMMARY OF THE INVENTION 
This invention provides an apparatus for shaping heat softened glass sheets 
supported on a shaping rail of a bending mold with a pivoting end section. 
The apparatus includes a biasing arrangement acting on a pressing member 
and a rail engaging member positioned on a frame. The biasing arrangement 
moves the pressing member and rail engaging member from first positions 
wherein the pressing member is spaced from selected portions of the glass 
sheet surface supported by the mold end section and the rail engaging 
member is spaced from selected portions of the shaping rail of the mold 
end section, to second positions wherein the pressing member is biased 
against the selected portions of the glass sheet surface and the rail 
engaging member is biased against the selected portions of the shaping 
rail. In the preferred embodiment of the invention, an outline bending 
mold with the glass sheet supported thereon is conveyed downstream through 
a heating lehr. The frame supporting the pressing and rail engaging 
members is provided with a sliding arrangement that moves downstream with 
the bending mold supported glass sheet. The movement of the pressing and 
rail engaging members on the frame is synchronized with the movement of 
the glass sheet such that there is no relative horizontal movement between 
the glass sheet and the members in the direction in which the bending mold 
is moved through the lehr when the members are in contact with the 
selected portions of the glass and rail. 
In one particular embodiment of the invention, a first cylinder pivots a 
rail support arm to move the rail engaging member into contact with a 
selected portion of the rail of the mold end section. A second cylinder 
then rotates a press member support arm such that the press member 
contacts the selected surface portions of the heated softened glass sheet. 
The upward pressure provided by the first cylinder prevents the mold end 
section of the bending mold from pivoting downward when contacted by the 
press member. A controller controls the downstream movement of the 
assembly and the pivoting action of the press member and rail support 
arms, so as to insure that there is no relative horizontal movement 
between the members and the glass sheet. 
This invention also provides a method of shaping selected portions of a 
glass sheet supported on a shaping rail of a segmented pivoting bending 
mold. The mold is conveyed through a heating lehr to heat the sheet to its 
deformation temperature, wherein the glass sheet sags by gravity and the 
perimeter of the glass sheet substantially conforms to the shape of the 
shaping rails positioned slightly inboard of the glass sheet perimeter. 
During heating, the pivoting end section of the mold rotates from an 
opened to closed position to provide a generally continuous shaping rail 
that supports the heat softened glass sheet. An additional shaping member 
having a sheet engaging surface corresponding to the desired shape of a 
selected portion of the glass supported by the mold end section is biased 
against the selected portion to conform the glass sheet surface to the 
sheet engaging surface of the shaping member while a rail support member 
engages the shaping rail of the mold end section to maintain the position 
of the rail. The members are conveyed along the lehr such that there is no 
relative horizontal movement between the shaping and rails support members 
and the mold supported glass sheet in the direction in which the glass 
sheet is conveyed through the lehr as a shaping member contacts the glass 
sheet.

DETAILED DESCRIPTION OF THE INVENTION 
Referring to FIGS. 1a and 1b, there is shown a heating, shaping, and 
annealing lehr for shaping glass sheets. The lehr begins downstream with a 
loading zone 10 and includes an initial heating zone 12 of tunnel type 
configuration, a gravity bending zone 14 downstream of the initial zone 
12, an annealing zone 16, and a cooling zone 18 in end to end relation in 
the downstream portion of the lehr. An unloading zone 20 is positioned 
beyond the lehr. 
A conveyor, comprised of a plurality of stub rolls 22 disposed in 
transversely opposing, longitudinally spaced relation, extends the entire 
length of lehr and defines a path of movement along a longitudinal 
reference line. As illustrated in FIG. 2, each stub roll 22 is mounted on 
a shaft that extends through a side wall of the lehr and is connected to a 
conveyor drive means (not shown). The conveyor may be divided into a 
number of sections, each driven from its own drive means or the conveyor 
sections may be driven from a common drive through clutches in any manner 
well known in the art. 
A plurality of glass support molds 24, one of which is shown in FIG. 2, 
which supports one or more glass sheets G as the glass moves through the 
lehr. Although not limited in the present invention, the mold 24 
illustrated in FIG. 2 is similar to the mold disclosed in U.S. Pat. Nos. 
4,626,267 to Reese and 4,804,397 to Stas et al., which teachings are 
herein incorporated by reference, and in particular is an articulating 
mold with pivoting end sections. The mold 24 is provided with opposed, 
spaced apart central shaping rails 26 (only one shown in FIG. 2) and two 
pivoting end sections 28, each of which includes an end rail section 30. 
Each end section 28 also includes an outrigger 32 attached to the under 
surface of the end rail section 30. The outrigger 32 extends outward of 
the end section 28 towards a pivot on post 34 and is attached to the 
weighted lever arm 36. As the glass sheet G supported on rails 26 and 30 
is heated, the lever arm 36 moves downward under the force of gravity 
against the lessening opposing force of the glass sheet G as it becomes 
heat softened, to provide a closing pressure that pivots the end sections 
28 upward to a closed position as shown in FIG. 2. In this closed 
position, the upper edges of the rails 30 form continuations of the 
shaping surface provided along the upper edges of the central shaping 
rails 26 so that the shaping rails 26 and 30 form a continuous outline 
shaping surface conforming in elevation and outline to the desired shape 
of the glass sheet G slightly inboard of the glass sheet parameter. 
FIG. 2 shows press assemblies 38 and 40 which are the subject of this 
invention as they are positioned in the lehr relative to the support mold 
24 while supported on a carriage 42. The assemblies 38 and 40 are similar 
in construction. The following discussion will be directed to the assembly 
38 with the understanding that the discussion is applicable to assembly 40 
unless otherwise indicated. 
Referring now to FIGS. 3 and 4, the press assembly 38 includes pressing 
device 44 to shape a pair of glass sheets G, a positioning and biasing 
means 46 to maintain the pressing device in contact with the glass sheets 
G, an actuating means 48 to activate the pressing device 44 and 
positioning and biasing means 46, and a support stand 50. 
The pressing device 44, which shapes glass sheets G while they move through 
the lehr supported on the mold 24, is inserted into the lehr through 
opening 52 in the lehr wall 54 and includes a glass contacting press 
member 56 supported by mount 58 on an upper arm 60 and a rail support 62 
mounted on plate 64 of lower arm 66. The upper arm 60 and lower arm 66 are 
pivotally connected to a bracket 68 on sliding base 70 of support stand 
50. Arms 60 and 66 are moved by positioning and biasing means 46 to shape 
the glass sheets G, as will be discussed later. 
Although not limiting in the present invention, in the particular 
embodiment illustrated in FIG. 3, the press member 56 is a curved 
cylindrical member 72 constructed from a heat resistant material such as 
stainless steel, which contacts upper one of the glass sheets G as viewed 
in FIG. 3 along a contact line to impart additional shape to the glass 
sheets G. The glass sheet contacting surface 74 of the pipe member 72 
corresponds to the desire curvature of the glass sheets G along the 
contact line. It should be appreciated that the glass sheet contacting 
surface 74 of pressing member 56 may be such that it contacts extended 
surface portions of the upper one of the glass sheets G as viewed in FIG. 
3 and if required, the entire glass sheet surface. 
The mount 58 which supports the press member 56 is secured to the end of 
arm 60 and includes a positioning plate 76 which is attached to the pipe 
member 72 and is pinned to an arm 78 at support pin 80. Plate 76 includes 
a slot 82 that receives positioning bolt 84. In operation, the pipe member 
72 is positioned by rotating it about the support pin 80 and sliding slot 
82 along bolt 84. Tightening bolt 84 captures plate 76 between bolt 84 and 
arm 78 and secures member 72 in position. 
As an alternative, the member 56 may be pinned to a bracket (not shown) at 
the end of arm 60 such that it may rotate about a horizontal axis 
generally perpendicular to the longitudinal axis of the member 56 while 
being prevented from being rotated about a vertical axis at the end of the 
arm 60, as shown in U.S. Pat. No. 4,804,397. This pinned connection allows 
the members 56 to be self aligning as it contacts the upper one to the 
glass sheets G as viewed in FIG. 3 so that the press member 56 will 
operate effectively even if the entire contacting surface 74 of the press 
member 56 does not contact the upper one of the glass sheets G as viewed 
in FIG. 3 surface simultaneously. 
Arms 60 and 66 are pivoted about bracket 68 by positioning and biasing 
means 46 to move the press member 56 and rail support 62, respectively. 
This movement is initiated by activating means 48, as will be described 
later. In the particular embodiment of the invention illustrated in FIGS. 
3 and 4, the positioning and biasing means 46 includes cylinders 86 and 
88. As viewed in FIG. 3, the lower end of cylinder 86 is pinned to arm 66 
with piston rod 90 of the cylinder 86 pinned to adjustable connecting rod 
92 which is secured to arm 60. The lower end of cylinder 88 is pivotally 
mounted on sliding base 70 with piston rod 96 of the cylinder 88 pinned to 
adjustable connecting rod 98 which is secured to arm 66. Cylinder 86 
operates to move press member 56 downward into contact with the glass 
sheet G surface as cylinder 88 operates to move rail support 62 upward 
into contact with rail 30 of the mold 24, to prevent end section 28 from 
pivoting downward in the direction of the movement of the pressing member 
56 during the pressing operation, as will be fully discussed later. Based 
on the teachings of this disclosure, it would be obvious that as an 
alternative, rail support 62 can contact outrigger 32 or any other portion 
of the end section 28 to maintain the end section 28 in the closed 
position shown in FIG. 2. 
Although the cylinders 86 and 88 are preferably pneumatic or hydraulic 
cylinder, it is obvious to one skilled in the art that other positioning 
and biasing means may be used. 
With continued reference to FIGS. 3 and 4, support stand 50 further 
includes a support carriage 102 having post members 104, sliding rail 
support members 106 and 108, and shaft support blocks 110 mounted on 
support members 108 to support sliding rails 112. The rails 112 extend in 
a longitudinal, downstream direction relative to the lehr and are slidably 
captured by collars 114 mounted to the bottom of the sliding base plate 
70. Pillow blocks 116 are mounted on members 106 to support drive shaft 
118 of the press assembly drive arrangement 120. Drive shaft 118 includes 
a gear 122 which meshes with gear rack 124 secured to the underside to the 
sliding base plate 70. Motor 126 drives shaft 118 so that the base plate 
70 supporting pressing device 44 and positioning and biasing means 46 of 
the press assembly 38 moves longitudinally along the rails 112. The motor 
126 of drive arrangement 120 is preferably a reversible drive which is 
capable of driving the base plate 70 both upstream and downstream relative 
to the lehr. As an alternative, multiple motors or a clutch arrangement 
may be used to move the press assembly 38 along the lehr. 
As an alternative to the drive arrangement shown in FIGS. 3 and 4, the 
stand 50 can be driven directly from the stub roll drive (not shown) so 
that any change or variation in the lehr conveying speed will be directly 
transferred to the movement of the stand 50. 
Posts 104 are mounted on wheels 128 which ride on rails 130 which are 
generally perpendicular to the lehr. This arrangement allows the press 
assembly 38 to be moved farther into or withdrawn from the lehr so as to 
properly position the press member 56 relative to the traveling glass G. 
As an alternative, the post 104 can be fixed and sliding base 70 and drive 
assembly 120 may be positioned on slides positioned perpendicular to the 
direction of the lehr to allow for the adjustment of press assembly 38 
into and out of the lehr. Furthermore, controller 132 may be connected to 
drives (not shown) to automatically move the press assembly 38 into or out 
of the lehr. Sensors (not shown) may be positioned in the lehr to locate 
the position of the carriage 42 relative to the centerline of the lehr and 
controller 132 can automatically reposition the press assembly 38 in 
response to the sensor signals. 
Actuator means 48 initiates the pressing cycle. Although not limiting in 
the present invention, the actuator means 48 in the particular embodiment 
illustrated in FIGS. 3 and 5 is similar to that disclosed in U.S. Pat. No. 
4,804,397, and includes an elongated L shaped pivoting trip arm 134 
mounted to the underside of base plate 70. As the mold carriage 42 is 
conveyed through the lehr, tip portion 136 of trip arm 134 contacts a trip 
plate 138 mounted on the downstream end of the carriage 42, causing the 
trip arm 134 to rotate and initiate a timing sequence in controller 132 
(shown in FIG. 3 only). The controller 132 controls the movement of the 
press assembly 38 via motor 126 and the pivoting action of the arms 60 and 
66 via cylinders 86 and 88 as the mold 24 continues to move through the 
lehr with the heat softened glass sheets G supported thereon. 
It would be obvious to one skilled in the art that there are other sensing 
devices and arrangements, well known in the art, to activate the cylinders 
86 and 88 and motor 126 rather that using a trip arm 134. For example, 
light or temperature sensors may be used to locate the exact position of 
the support carriage 42 within the lehr and initiate a timing sequence to 
activate and deactivate cylinders 86 and 88 as well as activate and reset 
the drive arrangement 120. 
The press assembly drive arrangement 120 moves the pressing device 44 along 
with the moving mold 24. The controller 132 matches the speed of the 
sliding base plate 70 with the mold support carriage 42 as it travels 
through the lehr so that there is no relative movement between the 
pressing device 44 and the glass sheets G. In glass sheet configurations 
where it is critical that the press member 56 contact the upper one of the 
glass sheets G as viewed in FIG. 3 at a precise location on the upper one 
of the glass sheets G as viewed FIG. 3, the mold 24 with the glass sheets 
G supported thereon may be aligned and squared within the lehr prior to 
being contacted by the pressing member 56. The mold 24 may be aligned in 
any convenient fashion such as that disclosed in U.S. Pat. No. 4,290,796 
to Reese et al., which teachings are herein incorporated by reference. 
As discussed earlier, the heat softened glass sheets G tend to draw glass 
from the longitudinal end portions during sag bending. As a result, the 
peripheral portions of the glass sheets G tend to flatten out i.e. the 
curvature of the glass sheets about their periphery, and in particular 
along the A-post is reduced. Referring to FIG. 6, line 140 represents the 
curvature of a glass sheet G after a conventional sag bending operation. 
As taught in the present invention, selected portions of the glass sheet 
may be contacted by the press member 56 to urge the glass sheet downward 
as indicated by arrow 142 so as to conform the glass sheet to the desired 
configuration as shown by line 144. As a result of this pressing action, 
the edge 146 of the glass sheet G rotates upward, i.e. counterclockwise as 
viewed in FIG. 6, increasing its approach angle 148 to that required for 
proper installation and resultant aerodynamics of the vehicle. 
In operation, glass sheets G are positioned on the shaping rails 26 and 30 
of the glass support mold 24, serially conveyed through the lehr on the 
mold carriages 42 and heated to their heat deformation temperature so that 
the glass sheets G sag by gravity so as to conform with the shaping rails 
26 and 30. As the heat softened glass sheets G on mold 24 approach 
assemblies 38 and 40, piston rod 96 is drawn into cylinder 88 and piston 
rod 90 is extended from cylinder 86 to provide the required clearance 
between pressing member 56 and rail support 62 and allow the end section 
28 of the mold 24 to pass therebetween as shown in FIG. 7. As the mold 
carriage 42 continues downstream in the lehr, tip 136 of the trip arm 134 
contacts trip plate 138 which initiates the shaping sequence by the 
controller 132. Motor 126 is activated and sliding base plate 70 with arms 
60 and 66 and pressing member 56 and rail support 62, respectively, 
mounted thereon moves downstream on rails 112 at the same rate of travel 
as the mold carriage 42. The cylinder 88 extends piston arm 96 causing arm 
66 to rotate counterclockwise about bracket 68 as shown in FIG. 8 so that 
rail support 62 contacts the lower side of the rail 30 of end section 28. 
End section 28 will have already pivoted to an upward position as 
discussed earlier. Thereafter cylinder 86 retracts piston rod 90 causing 
arm 60 to rotate clockwise about bracket 68 as shown in FIG. 9 thus 
lowering pressing member 56 into contact with the upper major surface of 
the glass sheets G on the rail 30. The cylinder 86 provides a pressing 
force so as to insure that the glass sheets G conform to the shape of the 
contacting surface 74 of the pressing member 56 while cylinder 88 prevents 
end section 28 of mold 24 from pivoting downward and opening the mold 24. 
After a predetermined time interval of contact between the pressing member 
56 and the glass sheets G, the cylinders 86 and 88 return to their 
original positions, rotating arm 60 upward and arm 66 downward so that the 
pressing assemblies 38 and 40 are no longer in contact with the glass 
sheets G or mold 24. The motor 126 then reverses direction and moves 
sliding base plate 70 along rails 112 back to its original position to 
wait the next mold carriage 42. 
As an alternative, the operating sequence discussed may be modified to 
account for variations in the height of mold 24 and in particular, the 
rail 30 as the molds 24 are conveyed through the lehr. In the modified 
sequence, cylinder 88 would raise arm 66 to move rail support 62 to a 
position near to but below rail 30. Cylinder 86 would then lower arm 60 to 
contact the glass surface G with pressing member 56. Additional movement 
of lower arm 66 via cylinder 88 would be coordinated with cylinder 86 to 
raise arm 66 and allow cylinder 86 to "squeeze" the rail supported glass G 
between pressing members 56 and rail support 62. 
It is understood that although the present invention teaches a traveling 
press arrangement, as an alternative the mold carriage 42 may be stopped 
and pressed by a stationary press assembly. Although such an arrangement 
would eliminate the need for the rail mounted sliding base plate 70, it 
would increase the cycle time within the lehr by requiring the molds 24 to 
stop and be aligned (if necessary) prior to pressing and restart to 
continue through the lehr. 
Although not limiting in the present invention, the pressing assemblies 38 
and 40 are placed at the beginning of the annealing zone 16. At this point 
the glass is soft enough to be formed by the pressing member 56 and yet it 
hardens quickly as the pressing assemblies 38 and 40 enter the annealing 
zone 16. 
In addition, it would be obvious to use multiple pressing assemblies along 
each side of the heating lehr if the desired shape required a difficult 
curved configuration. 
FIG. 10 illustrates an alternative embodiment of the invention which allows 
the upper and lower arms of the press assemblies to move independently of 
each other. Specifically, upper arm 150 and lower arm 152 are supported on 
base 154 by a bracket 156. The positioning and biasing means 46 includes a 
cylinder 158 with a lower end pivotally mounted on the base 154 with a 
piston rod 160 of the cylinder 158 pinned to a connecting rod 162 in the 
lower arm 152. Means 46 also includes cylinders 164 (only one shown in 
FIG. 10) positioned on either side of the upper arm 150. The lower ends of 
the cylinders 164 are pivotally mounted on the base plate 154 with piston 
rods 166 of cylinder 164 pinned to connecting rods 168 of mounting bar 170 
which in turn is secured to the upper arm 150. With this arrangement, the 
movements of the lower arm 152 via the cylinder 158 and the upper arm 150 
via cylinders 164 are independent of each other. It is apparent to one 
skilled in the art, that based on these teachings, one of the cylinders 
164 may be replaced with a guide and/or slide arrangement to help direct 
the movement of the upper arm 150. 
As another alternative, both the upper arm 60 and lower arm 66 shown in 
FIG. 3 may be individually mounted on separate brackets (not shown) to the 
base 70 of the support stand 50 so that each may operate independently of 
the other. 
The present invention provides a positive means for shaping heat softened 
glass sheets G on an outline mold as they are conveyed through a heating 
lehr. The pressing assemblies of the present invention precisely shape the 
glass sheet at a localized area without changing conveying rates or 
adversely affecting the curvature or other portions of the glass sheet. 
The forms in the invention shown and described in this disclosure represent 
preferred embodiments and it is understood that various changes may be 
made without departing from the scope of the invention as defined in the 
claims that follow.