Method for molding trim strips by extrusion molding in an open mold

Automotive trim strips are molded in an open-faced mold cavity by extruding a ribbon of plastic therein and moving a shaping roller thereover to compression mold the viewing surface of the trim strip into conformity with the surface of the mold cavity and to shape the non-viewing with the shaping roller.

BACKGROUND OF THE INVENTION 
Heretofore, plastic automotive trim strips have been manufactured either by 
injection molding or by extrusion molding of the part desired to be 
affixed to the viewing surface of an automotive vehicle. As a general 
rule, extrusion molding is preferred as it is significantly less expensive 
than injection molding. However, extrusion molding has certain limitations 
including the fact that the side edges of the article as extruded will be 
straight and parallel and the ends of each cut-to-length strip will show 
the cross sectional interior of the extruded material unless such ends are 
reworked or have separately molded end caps applied. 
Additionally, certain parts such as those for trim around the wheel wells 
have more complex shapes and are typically formed by injection molding. 
A method of extrusion molding and automotive trim strip is disclosed in 
U.S. Pat. No. 4,722,818. Under such patent, the trim strip is made by 
extruding a thermoplastic material through an extrusion passageway, 
passing a film strip through a guide passageway in a novel die assembly 
and then bonding the film strip and the thermoplastic material into 
engagement. 
U.S. Pat. No. 4,719,067 discloses a method of forming an end piece by 
injection molding onto a previously formed trim strip. 
U.S. Pat. No. 4,489,019 discloses a method for producing longitudinal 
moldings with non-uniform sections without the use of an injection molding 
machine. Under the invention disclosed therein, one part of the molding is 
formed by extrusion molding and another part is remolded or reshaped to 
the desired cross-sectional configuration. U.S. Pat. No. 4,489,019 
discloses another method for forming a molding in part by extrusion 
molding and in part by remolding or reshaping. 
It is the object of the present invention to provide a new and noval method 
and apparatus for molding plastic articles. 
It is a further object of the present invention to form a new and molded 
plastic trim strip. 
It is yet another object of the present invention to provide a method and 
apparatus for molding plastic trim strips and other plastic articles such 
that shapes not attainable with extrusion molding may be molded at a cost 
significantly lower than the cost of injection molding a similar part. 
SUMMARY OF THE INVENTION 
This invention relates to a method and apparatus for forming automotive 
trim strips by extruding a ribbon of heated plastic material into an 
open-faced mold having a molding surface and compressing a rotary forming 
mechanism against such ribbon to force the plastic material into 
conformity with the molding surface while simultaneously shaping the 
opposite side of the trim strip with the forming mechanism and to an 
article formed by such method.

DETAILED DESCRIPTION OF THE INVENTION 
Referring to FIG. 1, there is shown an automotive vehicle A having two of a 
wide variety of shapes of trim strips formed according to the present 
invention. Thus, the automotive vehicle A has a wheel well trim strip W 
and a rear/side trim strip R. As will be appreciated from the following 
description, the wheel well trim strip W as affixed to the vehicle A has 
substantially the same shape as it had upon removal from the mold. In 
contrast, the trim strip R is flat as molded but becomes curved when 
wrapped around the corner joining the side S and back B of the vehicle A. 
As can be seen from FIG. 1 and also from FIG. 5, the wheel well trim strip 
W has a viewing surface 1, a non-viewing surface 2 intended to face the 
vehicle A, an upper or outer edge 3 and an inner edge 4 which includes an 
inwardly extending flange 5. The wheel well trim strip W, as molded, 
follows a curved path generally matching that of the wheel well of the 
vehicle A. 
Referring now to FIGS. 2-5, there is shown an extruder generally designated 
by the numeral 10 having an hopper 11 for receiving pellets or granules of 
thermoplastic material such as polyvinyl chloride (PVC) or other suitable 
plastic, and feeding it to an elongated barrel 12 having a heater for 
melting the plastic material and a screw (not shown) for feeding the 
melted plastic material through the barrel 12. The hopper 11 and barrel 12 
are supported on a support stand 13. 
Secured to the end of the barrel 12 is a downwardly extending neck 15 to 
which is attached a die head 16 for receiving the heated and plasticized 
PVC or other plastic material from the barrel 12. The die head 16 includes 
an outlet orifice 17 from which plastic material is extruded in the form 
of a ribbon 18. As will be appreciated by those skilled in the art, the 
orifice 17 may have any one of a wide variety of shapes and configurations 
with the result that the ribbon 18 of plastic material as extruded may 
have a wide variety of cross sectional configurations. 
In order to form the wheel well trim strip W having the inwardly extending 
flange 5, the ribbon 18 preferably has a cross-sectional configuration 
which includes a substantially horizontal bottom portion 19, a 
substantially vertical edge portion 20 which will provide plastic material 
for shaping the flange 5 and an upturned portion 21 approximating the 
shape of the outer edge 3 of the wheel well trim strip W. It should be 
understood, however, that the ribbon 18 may have any one of a wide variety 
of cross sectional configurations. It is the final shaping of the plastic 
material according to the method to be described that determines the final 
contour of the finished trim strip W, the non-viewing surface 2 as well as 
the viewing surface 1. Thus, although it is preferred that the ribbon 18 
have a cross-sectional shape approximating the shape of the finished wheel 
well trim strip W, it could have other configurations so long as there is 
a sufficient amount of plastic material to form all portions of the trim 
strip W. 
In close proximity to the extrusion die head 16 is a shaping roller 
mechanism generally designated by the numeral 25 rotationally supported on 
an axle 26 supported at each end by a pair of downwardly extending arms 27 
fastened to an outwardly extending support arm 28. The support arm 28 may 
be rigidly connected to a rotatable shaft 22 extending from a gear box 29. 
A motor 24 powers the gear box 29 to rotate the shaft 22 slightly in a 
clockwise direction when it is desired to raise the shaping roller 
mechanism 25 and in a counterclockwise direction when it is desired to 
lower it. Other types of support means may be utilized for supporting the 
shaping roller mechanism 25; however, as will become clear from a 
description of the molding operation, it is preferred that the shaping 
roller mechanism 25 be yieldingly urged downwardly. 
Positioned beneath the die head 16 is a mold 30 having an open faced mold 
cavity 31 conforming to the desired exterior or viewing surface 1 of the 
trim strip W. The mold cavity 31 follows a curved path from one end 31A to 
the other end 31B having generally the contour of the wheel well of the 
vehicle A. 
The mold 30 is mounted on a table 35 having a mechanism (not shown) for 
moving the mold 30 rotationally and/or eccentrically and/or in a straight 
line path depending upon the specific end to end configuration of the mold 
cavity 31. Thus, the mold 30 is moved beneath the orifice 17 of the die 
head 16 so that the mold cavity 31 is positioned directly thereunder to 
receive the ribbon 18, starting with the one end 31A and then throughout 
the remainder of the mold cavity 31 to the opposite end 31B. Obviously, if 
the mold cavity 31 from end to end is in the shape of an arc of a circle, 
the mold 30 will be required to move only in a circular path beneath the 
die head 16. If the end to end configuration of the mold cavity 31 is 
other than an arc of a circle, it will be necessary to provide a suitable 
cam mechanism to control the path followed by the mold beneath the die 
head 16 to insure that the mold cavity 31 is positioned beneath the 
orifice 17 throughout the complete extrusion phase of the molding 
operation. The use of cams to determine movement of a body mold or other 
is not new and does not form a part of the present invention. 
It is within the scope of the present invention that the mold be fixed and 
the die head 16 be movable in order to extrude the ribbon 18 throughout 
the length of the cavity 31. 
Referring now to FIGS. 3-5, immediately after the ribbon 18 of heated and 
moldable PVC or other plastic material is deposited in the mold cavity 31, 
the shaping roller 25 passes thereover to compress the still hot moldable 
plastic material firmly into the mold cavity 31. Obviously, if the trim 
strip being molded has a flat or planar non-viewing surface, the roller 25 
could have a simple cylindrical shape. However, in this embodiment of the 
present invention, since the wheel well trim strip W has a cross-sectional 
configuration in which the non-viewing or attaching surface 2 is contoured 
rather than flat, the shaping roller mechanism 25 must be contoured. Thus, 
as may be seen in FIG. 5, the shaping roller mechanism 25 is formed with 
separate roller segments 25A, 25B, 25C, 25D, 25E and 25F which are 
independently mounted on the axle 26. Each of such roller segments has a 
different shape or contour and each abuts the adjacent segment so that as 
the roller mechanism 25 is rotated against to the extruded ribbon 18, it 
shapes the plastic material into conformity with the mold cavity 31 to 
form the viewing surface 1 and into conformity with the exterior surfaces 
of the respective roller segments 25A, 25B, 25C, 25D, 25E and 25F to form 
the non-viewing surface 2. As can be seen, the flange 5 is formed between 
the side of roller segment 25E and the opposing surface of the mold cavity 
31 with the free end of the flange 5 formed by the roller segment 25F. The 
upper or outer edge 3 is formed by the roller segment 25A. As can also be 
seen in FIG. 5, the outer roller segments 25A and 25F, in addition to 
shaping the outer edge 3 and free end of the flange 5, respectively, also 
ride across the upper surface of the mold 30. This coupled with the 
downward urging of the shaping roller mechanism insures that the 
non-viewing surface 2 is molded to the designed contour. 
In operation, the mold 30 is initially positioned with the mold cavity end 
31A lying directly under the die head 16 and the shaping roller mechanism 
25 positioned beyond the end 31A and resting upon the face of the mold 30. 
As previously described, the roller mechanism 25 is preferably yieldingly 
urged downwardly and may ride up on the surface of the mold 31 when 
positioned beyond the end 31A of cavity 31. Immediately upon extrusion of 
the initial portion of the ribbon into the mold cavity of 31, the mold 30 
is caused to move rotationally or in other appropriate direction so that 
the ribbon 18 is deposited into the mold cavity throughout the full length 
thereof to the opposite end of 31B. The ribbon 18 of thermoplastic 
material is shaped by the roller mechanism 25 passing over the newly 
deposited ribbon 18 throughout the full length of the mold cavity of 31. 
FIGS. 6-9 show apparatus for molding an article such as the rear/side trim 
strip R which is intended to be molded flat but bent around a corner when 
applied to the vehicle A. 
As will be appreciated by those skilled in the art and as can be seen in 
FIG. 1, the surface to which rear/side trim strip R is to attached follows 
a curved path extending from the back B to the side S around the corner. 
Additionally, as can be seen in FIG. 1, the back of the vehicle A is 
disposed at an angle or taper in the area to which the trim strip R is to 
be attached. A trim strip such as the trim strip R when wrapped around the 
back to the side of a vehicle will follow a curved path through a bend of 
approximately ninety degrees. If those portions of the surface of the 
vehicle A to which the trim strip R is to be attached defined a shape in 
which all such portions from top to bottom were parallel to a vertical 
axis, it would be possible to simply form a straight, elongated trim strip 
and wrap it around the corner of a vehicle from one side to the rear. This 
could be readily accomplished on that type of surface even though the trim 
strip was straight as molded and fairly wide, for example, 2-4 inches. 
However, those portions of automotive vehicles to which trim strips are 
attached usually do not follow a path in which all portions are parallel 
to a vertical axis. Rather, they more frequently follow an path such as 
that shown in FIG. 1 in which that portion of the back B to which the 
rear/side trim strip R is attached bends or curves inwardly toward the 
center of the vehicle A, from top to bottom of the trim strip R. 
Desirably, the trim strip R, when affixed to the vehicle A, will be 
horizontal or parallel to the bottom. As will be appreciated, in order for 
the trim strip R to snugly match the attached surface of vehicle A, when 
wrapped around the corner of a vehicle A having such contour, the upper 
edge of such trim strip R must be longer than the lower edge. This is 
accomplished by molding the trim strip R to follow a curved path such as 
that shown in FIG. 6. 
As can be seen in FIGS. 6-9, the trim strip R may have a substantially 
planar non-viewing surface 101 and a contoured viewing surface 102. As in 
the previous embodiment, an extruder 10 and shaping roller mechanism 125 
are positioned above a mold 130. The mold 130 has an open-faced cavity 131 
which follows a straight path at each end with a curved path in the center 
joining the ends. Thus, the mold cavity extends from one end 131A, along a 
straight path to a curved section 131C, and then along a straight path in 
a different direction to the opposite end 131B. If desired, the molding 
surface of the mold cavity 131 may be contoured as at 132. The mold 130 
has a short knife 133 encircling the mold cavity 131. (See FIGS. 8 and 9). 
The knife 133 extends upwardly from the face of the mold approximately 
0.015 inches and terminates in a cutting edge 134. The knife 133 severs 
excess plastic material introduced into the mold cavity 131 from the die 
head 16. Thus, although it is possible to obtain commercially satisfactory 
parts by extruding into the mold cavity 131 the precise amount of plastic 
material necessary to form the trim strip R, controlling the flow of the 
ribbon 18' of plastic material into the mold cavity 131 to such a precise 
degree on a production basis can be difficult. Accordingly, it has been 
found that consistently superior results can be obtained by extruding a 
greater amount of plastic into the mold cavity 131 than is necessary to 
form the finished trim strip R. Such excess will be squeezed out of the 
mold cavity in the form of flash 136 which must be removed to form the 
finished trim strip R. Although the flash 136 could be removed in a 
separate trimming operation, the use of a mold having a knife 133 will 
permit the trimming to be done during the shaping operation as will become 
clear from the following description. 
The mold 130 is mounted on a table 135 having a mechanism (not shown) for 
moving the mold 130 initially in a straight line path then in a curved 
path following the path of the curved section 131C and finally in a 
straight line path. Thus, the mold 130 is moved beneath the orifice 17' of 
the die head 16 so that the mold cavity 131 is positioned directly 
thereunder to receive the PVC or other plastic material starting with the 
one end 131A and then throughout the remainder of the mold cavity 131 to 
the opposite end 131B. 
Since the non-viewing surface 101 of the trim strip R molded pursuant to 
this embodiment has a planar configuration, the die head 16 may have an 
orifice 17' shaped to extrude a ribbon 18' having a generally rectangular 
configuration. 
Additionally, as can be seen in FIG. 9, there is provided a shaping roller 
mechanism 125 having a cylindrical configuration. Since the mold 130 will 
follow a curved path as the mold cavity curved section 131C passes beneath 
the shaping roller mechanism 125, it is desirable that the shaping roller 
mechanism 125 have independently rotatable roller segments 125A, 125B, 
125C and 125D. The outer roller segments 125A and 125D extend beyond the 
opposite sides of the mold cavity 131 and engage the cutting edge 134 of 
the knife 133. 
In operation, the mold 130 is initially positioned with the mold cavity end 
131A beneath the extrusion die head 16 and with the roller mechanism 125 
contacting the face of the mold beyond the end 131A of the mold cavity 
131. A ribbon 18' of plastic material is extruded from the orifice 17' and 
deposited throughout the length of the mold cavity 131 as the mold 130 
moves beneath the die head 16. Preferably, the amount of plastic material 
deposited in the cavity 131 will be slightly in excess of that needed to 
form the trim strip R. Immediately after the ribbon 18' of heated and 
moldable PVC or other plastic material is deposited in the mold cavity 
131, the shaping roller 125 passes thereover to compress the still hot 
moldable plastic material firmly into the mold cavity 131. The excess 
plastic material will be squeezed out of the mold cavity 131 to form flash 
136. Those roller segments overlying the cutting edge 134, namely, 
segments 125A and 125D in FIG. 9, will engage the cutting edge 134 to trim 
the flash 136 from the finished trim strip R. As the shaping roller 
mechanism 125 contacts the ends 131A and 131B, respectively, the 
intermediate segments 125B and 125C will engage the cutting edge 134 and 
trim the flash in those areas. 
Referring now to FIGS. 10 and 11, there is shown a modified embodiment for 
producing a trim strip which is straight but which is tapered. In this 
embodiment, there is provided an elongated mold 145 having a mold cavity 
146 extending from a first end 146A of a given width to an opposite end 
146B which is substantially narrower. The mold 145 is mounted on a table 
147 having a pair of guide channels 148. The mold 145 may be moved from a 
position at which the end 146A underlies the die head 16 to a position at 
which the opposite end 146B underlies the die head 16. 
In this embodiment a cylindrical roller 225 is mounted on an axle 226 
supported in a support mechanism 227. As will be appreciated, the 
operation of this embodiment is substantially the same as the previous 
embodiment in that the roller 225 urges the heated and moldable plastic 
material firmly into the mold cavity 146 to form the finished article. 
Many modifications will become readily apparent to those skilled in the 
art. For example, the embodiments shown in FIGS. 3-5, 10, and 11 could 
also utilize a mold having a knife partially or completely encircling the 
mold cavity in order to trim any flash. Accordingly, the scope of this 
invention should be determined by the scope of the appended claims.