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Claims  |
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The embodiments of the invention in which an exclusive property or
privilege is claimed are defined as follows:
1. In a vehicle bed assembly having a horizontally-enlarged one-piece
monolithic floor pan member constructed from a thin metal sheet and having
a plurality of generally parallel and sidewardly-spaced stiffening ribs
extending longitudinally thereof, said stiffening ribs being of generally
downwardly-opening channel-like cross sections which are deformed so as to
project upwardly from the sheet, and a horizontally elongated sill member
having a top wall positioned at least partially under and fixedly secured
to a transversely extending rear portion of said pan member, said rear
sill member being elongated in a direction generally perpendicularly with
respect to the longitudinal direction of said pan member, comprising the
improvement wherein said stiffening ribs project longitudinally throughout
the entire length of said pan member so as to terminate at front and rear
free edges of said pan member, said front and rear free edges of said pan
member each having a corrugated configuration, said rear sill member
having a plurality of rib-end projections projecting upwardly from the top
wall thereof, said rib-end projections being disposed in a row extending
in the elongated direction of the rear sill member and spaced apart at
intervals corresponding to the spacing between adjacent ribs on said floor
pan member, the transversely extending rear portion of said floor pan
member being positioned on the top wall of said rear sill member so that
rear free edges of said ribs align with and substantially abut the
respective rib-end projections on the sill member for closing off said
ribs.
2. A vehicle bed assembly according to claim 1, wherein each said rib-end
projection includes a rear rib part which is fixedly and integrally joined
to a front guide part, said rear rib part projecting upwardly from said
top wall and substantially abutting the rear free edge of the respective
rib on the pan member for closing the end of the rib and constituting an
extension of the rib, the respective front guide part projecting
interiorly into the respective rib through a small longitudinal extent.
3. A vehicle bed assembly according to claim 2, wherein the top wall of the
rib, in the vicinity of the rear free edge thereof, and the respective
front guide part are directly spot welded together.
4. A vehicle bed assembly according to claim 2, wherein the rib-end
projection is stamped from the top wall of said rear sill member.
5. A vehicle bed assembly according to claim 2, wherein said front guide
part has an exterior size and cross sectional configuration which
substantially corresponds to the interior size and cross sectional
configuration of the respective rib in the vicinity of the rear free edge
thereof.
6. A vehicle bed assembly according to claim 1, wherein the top wall of the
rear sill member is provided with front and rear top wall portions which
are slightly vertically offset from one another and are joined together by
a shoulder, said front wall portion being vertically displaced downwardly
from the rear top wall portion so that said shoulder faces forwardly and
is adapted to substantially abut the rear free edge of said pan member.
7. A vehicle bed assembly according to claim 6, wherein said rear sill
member is roll formed in the elongate direction thereof.
8. A vehicle bed assembly according to claim 6, wherein said rib-end
projection includes a rib-defining end part which projects upwardly from
said rear top wall portion and which defines thereon a generally
forwardly-facing edge surface which aligns with and substantially abuts
the rear free edge of the respective rib.
9. A vehicle bed assembly according to claim 8, wherein each rib-end
projection includes a front guide part which projects upwardly from the
front top wall portion and is integrally joined to and projects forwardly
from the respective rib-defining end part, said front guide part being
positioned to nest interiorly within and substantially engage the inner
surface of the respective rib throughout a small longitudinal extent
thereof adjacent the rear free edge thereof.
10. A vehicle bed assembly according to claim 9, wherein said front top
wall portion is vertically offset downwardly relative to said rear top
wall portion by a distance which is of similar magnitude to the thickness
of the metal sheet defining said pan member.
11. A vehicle bed assembly according to claim 9, wherein said rib-end
projections are stamped from said top wall and have hollow interiors which
open downwardly, and said pan member being fixedly secured to said rear
sill member by a plurality of spot welds which are disposed adjacent said
rear free edge, said plurality of spot welds including a first series of
spot welds which cooperate directly between the front top wall portion and
said metal sheet at regions thereof defined between said ribs, and a
second series of spot welds which cooperate directly between top walls of
said ribs and the underlying respective front guide parts.
12. A process for forming a unitized bed assembly for a vehicle such as a
pickup truck, comprising the steps of:
providing a wide and horizontally elongated flat sheet of thin metal;
forming said flat metal sheet to define a plurality of generally parallel,
sidewardly-spaced, channel-like stiffening ribs therein with said
stiffening ribs extending longitudinally throughout the entire length of
the formed metal sheet so as.to terminate at and define corrugated front
and rear free edges on the formed sheet;
providing an elongate rear sill member having a generally flat top wall
provided with a plurality of rib-end defining projections projecting
upwardly from said top wall at intervals spaced therealong corresponding
to the spacing between the ribs in said formed sheet;
then positioning said formed sheet so that a rear portion thereof, directly
adjacent the rear free edge, is positioned directly over and supportingly
engaged with said top wall so that said rib-end defining projections are
aligned directly adjacent and close off rear free ends of the ribs on said
formed sheet; and
then fixedly securing said formed sheet to said rear sill member.
13. A process according to claim 12, wherein the forming of the flat metal
sheet occurs by moving the flat metal sheet through a roll forming mill
which causes the plurality of stiffening ribs to be roll formed into the
sheet throughout the entire longitudinal length thereof without causing
any significant reduction in the thickness of the sheet material.
14. A process according to claim 13, wherein the formed sheet and rear sill
member are fixedly secured by a series of spot welds which connect between
the top wall of the rear sill member and the rear portion of the formed
sheet at regions thereof located between adjacent ribs.
15. A process according to claim 13, wherein the rib-end defining
projections on said rear sill member are provided with a rear rib-end part
which at a forward end thereof has a configuration which substantially
corresponds to and substantially abuts the adjacent free end of the
respective rib and which slopes rearwardly and downwardly for merger with
the top wall, and the rib-end defining projection also being provided with
a front guide part which projects upwardly from the top wall and forwardly
from the rear rib end part and which projects longitudinally into the
interior of the adjacent rib.
16. A process for forming a unitized vehicle bed assembly, such as for a
pickup truck, comprising the steps of:
providing a generally horizontally elongate rolling mill having a plurality
of sequentially positioned rolling stations each defining opposed upper
and lower rolls which cooperate to define therebetween a series of
cooperating annular peripheral ribs and grooves;
providing a horizontally wide and substantially continuous and horizontally
elongate flat sheet of thin metal;
feeding said substantially continuous and horizontally elongate flat sheet
of thin metal into and through said rolling mill to effect roll forming of
a plurality of generally parallel, sidewardly-spaced, channel-like
stiffening ribs therein to create a substantially continuous formed sheet
having said stiffening ribs extending longitudinally throughout the entire
length thereof as said formed sheet discharges from the rolling mill;
thereafter severing the continuous formed sheet into formed sheet members
of predetermined longitudinal length having said stiffening ribs extending
longitudinally throughout the entire length thereof so that the formed
sheet member has corrugated front and rear free edges thereon;
forming a rear sill member which is longitudinally elongated and has a
generally flat wall which is elongated and has a length which at least
substantially equals the width of the formed sheet member;
providing the flat wall of said rear sill member with a plurality of
rib-end projections projecting upwardly therefrom at intervals spaced
therealong corresponding to the spacing between the ribs in said formed
sheet member;
positioning the elongate rear sill member transversely relative to and
closely adjacent the rear free edge of said formed sheet member so that
the rib-end projections on said rear sill member are aligned directly
adjacent and substantially close off rear free ends of the ribs on said
formed sheet member; and
fixedly securing said formed sheet member to said rear sill member.
17. A process according to claim 16, wherein the flat wall of said sill
member is provided with front and rear flat wall portions which are
closely adjacent and extend in the elongate direction of the sill member
with said front wall portion being spaced vertically downwardly a small
distance from the rear wall portion and joined thereto by a
frontwardly-facing shoulder, said rib-end projections projecting upwardly
from said rear wall portion and defining thereon forwardly-facing
channel-shaped shoulders.which are substantially vertically aligned with
said first-mentioned shoulder and are adapted to substantially abut the
adjacent free end of the respective rib.
18. A process according to claim 16, including the step of roll forming
downwardly-projecting side flanges along each longitudinally-extending
side edge of said formed sheet member as the metal sheet is moved through
the roll forming mill.
19. A process according to claim 18, wherein the flat sheet as supplied to
the roll forming mill has a width which is about four to about six inches
greater than the transverse horizontal width of the formed metal sheet
upon discharge from the roll forming mill, whereby further longitudinal
severing of the longitudinal edges of the formed sheet member is not
required.
20. A process according to claim 19, including the steps of roll forming a
plurality of cross support rails of a generally upwardly-opening
hat-shaped cross section, positioning a plurality of said cross rails in
perpendicularly extending relationship beneath the formed sheet member in
longitudinally spaced relationship from the rear free edge of the sheet
member, and thereafter fixedly securing said formed sheet member to said
cross rails. |
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Claims |
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Description |
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FIELD OF THE INVENTION
This inventions relates to the construction of a truck bed, such as a
pickup truck bed, and in particular relates to an improved construction of
the bed floor and rear sill, and an improved constructional method.
BACKGROUND OF THE INVENTION
A box of a truck, such as a pickup truck, is illustrated in FIG. 1. This
box 11 conventionally includes a horizontally enlarged floor or bed
assembly 12 which extends sidewardly between and is joined to generally
parallel and upwardly extending side panels or walls 13. The side panels
13 conventionally have wheelwell housings 14 formed therein, the latter
typically projecting at least inwardly a small extent into the interior of
the box. The front end of the floor assembly 12 is also rigidly joined to
an upwardly projecting front wall or panel 15, the latter extending
between and being rigidly fixed to the side panels 13. The rear of the box
is normally closed by a rear panel 16, the latter conventionally being an
openable tailgate 16 which is conventionally hingedly joined to the box
and can swing into an open generally horizontal position wherein it is
substantially flush with the floor assembly to provide access to the
interior of the box.
This box 11, and specifically the floor or bed assembly 12, conventionally
includes a horizontally enlarged main bed member 17, commonly referred to
as the floor pan, which defines the actual floor of the box and extends
lengthwise between the front and rear ends of the box, and has a width
which normally substantially spans the width of the opening between the
wheelwell housings. This main floor pan 17 is supported on a front cross
rail 18, several intermediate cross rails 19, and a rear cross rail or
sill member 21, the latter all extending transversely under the pan and
being fixedly secured thereto, such as by spot welding. Some of these
cross members, such as the front rail 18, the frontmost intermediate rail
19 and the rear sill 21 are typically fixedly secured to the vehicle frame
(not shown) in a conventional manner.
The bed assembly 12 also normally includes secondary bed or floor pan
members 22, the latter being positioned adjacent and fixedly joined to
opposite longitudinal edges of the main floor pan 17 so as to occupy the
regions of the bed disposed forwardly and rearwardly of the wheelwell
housings 14.
In the pickup box 11 as conventionally constructed, the main floor pan 17
is provided with stiffening ribs 23 which project upwardly from the pan,
with a plurality of such ribs being generally uniformly sidewardly spaced
apart across the width of the pan and extending longitudinally of the pan
over a majority of the length thereof. These ribs, which are deformed
upwardly from the pan to define a downwardly-opening channel-like cross
section, generally extend rearwardly from the front free edge of the main
pan 17 but the ribs normally terminate in tapered rib ends 24 which merge
downwardly into the planar profile of the pan 17 at a location disposed
close to but spaced forwardly a small distance from the rear free edge 25
of the pan. The rear edge portion of the main pan 17, namely the flat
portion thereof which is free of the ribs, is then normally seated within
a shallow recess formed in the top wall of the rear sill member 21 so as
to be substantially flush with the upper surface of the sill member, with
the rear pan and sill member then being suitably fixedly secured together,
such as by spot welding. This arrangement enables the groovelike regions
defined between adjacent ribs 23 to freely open outwardly through the rear
end of the bed assembly, and hence prevent creation of pockets or recesses
which would collect dirt or moisture.
A bed assembly having the structure described above has, for a very long
time, been constructed using individual members which have been stamped
utilizing large forming presses. That is, the main floor pan 17 as well as
the cross rails 18, 19 and 21 have been conventionally formed from flat
steel sheets by positioning a precut steel sheet in a forming press which
deforms the sheet to define the desired cross section of the finished
member. This stamping or press-forming technique, however, even though
extensively utilized for many years, possesses recognized disadvantages
which have nevertheless been long tolerated in view of the belief that
this was the best manner of constructing the bed assembly.
More specifically, and particularly with respect to the main floor pan 17,
the current and almost universally utilized technique of stamping the pan
has resulted in limitations which have restricted optimum construction of
the pan. For example, to stamp the main floor pan 17, a large rectangular
sheet must be precut in accordance with the size of the desired pan being
stamped. The sheet is initially of excess width so as to provide portions
along opposite edges of the sheet which can be used for clamping the sheet
and holding it in position when the sheet is positioned within the press
and subjected to the stamping operation. Further, during the actual
stamping operation, the material of the sheet is physically deformed by
the stamping die so as to permit creation of the longitudinal ribs. This
necessarily results in significant changes in thickness of the sheet
material due to the deformation which is caused during the rib formation
process. Not only does the sheet undergo significant changes in thickness,
but this change in thickness is also of varying amounts at different
locations across the rib, or through the cross section of the sheet
containing the ribs, so that the resulting stamped floor pan has a sheet
thickness which has significant variation therein. This thickness
variation can in some instances be as much as 40% to 50%. This stamping
process has also been observed to result in bends or corners which are
inconsistent in terms of both material thickness and included angle, and
have provided a finished exterior appearance which permits such
irregularities to be visually observed. This stamping operation also
requires, after the pan has been stamped, that the pan be subjected to a
further stamping or cutting operation which is effective for removing the
clamping strip portions on opposite sides of the sheet, which strip
portions are disposed of as scrap.
In view of the inherent but inconsistent thickness reductions which occur
during forming of the pan by the stamping or pressing process, the pan
must also be initially formed from a sheet material of greater thickness
than desired so as to compensate for the expected thickness reductions
which occur during the stamping operation. This increases the overall
weight of the pan. Further, in view of the significant size of the main
floor pan and the fact that it is deformed or stamped in basically a
single pressing operation, this also necessitates utilization of an
extremely large and high-capacity forming press in order to accommodate
both the size of the sheet and the significant pressing force encountered
during the simultaneous deformation of the numerous ribs which extend
longitudinally thereof. Further, these stamping operations necessarily can
normally be successfully carried out only if lower strength and softer
sheet steels are utilized since harder and higher strength steels will
typically split or crack if subjected to severe deformation of the type
encountered in the conventional pan stamping operation.
Accordingly, it is an object of this invention to provide an improved truck
bed assembly, and a method of manufacturing and assembling the primary
components of the truck bed assembly, so as to overcome many of the
disadvantages associated with the conventional and long-utilized stamped
bed assembly as described above.
More specifically, the present invention relates to an improved truck bed
assembly, and process of manufacture, which involves formation of the
floor pan by roll forming, with the floor pan having the strengthening
ribs thereof extending longitudinally throughout the entire length of the
floor pan so as to terminate at the front and rear edges thereof, with the
rear edge of the floor pan cooperating with a rear sill member which is
also preferably roll formed and has rib ends formed thereon and
cooperating with the ends of the ribs on the main floor pan for closing
off said ribs and creating a transition to a flat horizontal surface
defined on the rear sill member. The rib ends on the rear sill member also
preferably have portions which nest into and are fixedly secured to, as by
spot welding, the rearward ends of the ribs defined on the main floor pan.
With the improved truck bed assembly and construction method of the present
invention, as briefly summarized above, numerous constructional advantages
are achieved in relationship to the conventional construction. More
specifically, roll forming of the main floor pan permits utilization of
higher strength sheet steel than is typically usable with stamping; roll
forming permits the thickness of the formed pan to be substantially
uniformly maintained throughout the entire cross section, thus eliminating
the highly undesirable thickness variations created in the conventional
stamping process, and hence enabling the pan to be formed from sheet steel
of significantly smaller thickness, which reduction in thickness may be in
the order of 30% to 40%; roll forming of the main floor pan permits
creation of sharper corners or curvatures than is typically possible using
a stamping operation; roll forming the main floor pan permits
significantly higher consistency and uniformity in the rib structures
including the corners than is possible using a stamping operation; roll
forming of the pan provides better strength characteristics in the
resultant product, and minimizes the creation of numerous high stress
concentrations such as exists at the corners when the pan is stamped; roll
forming of the pan enables the finished pan to be formed from sheet
material which is originally of less width and in fact permits the pan to
be formed from sheet material of a width which is all substantially used
in forming the pan, whereas in contrast the stamping operation requires
significantly wide edge portions which are clamped during the stamping
operation and are then cut off and disposed of as scrap, such scrap edge
portions not be necessary when the pan is roll formed; roll forming
enables formation of the entire pan cross section including not only the
strengthening ribs but also the securing flanges which project downwardly
along opposite longitudinal edges of the main pan, whereas in contrast the
stamped pan typically requires that the side flanges be formed separate
from the main stamping operation, and in fact the stamping operation also
often requires a restamping of the entire part so as to compensate for the
spring back of the part created by the initial stamping operation; and
roll forming of the pan and the ability to use thinner steel sheet and
higher strength steel permits the overall weight of the pan assembly to be
significantly reduced, such as by up to about 35%, thereby enabling
reduction in the overall vehicle weight and hence improvement in fuel
economy.
The present invention, in addition to the improvements and advantages
briefly summarized above, is also believed to provide significant cost
savings with respect to the overall manufacturing process, and permits
creation of cross sections or shapes in the bed which is not possible with
a stamping operation, including the creation of sharper corners having a
higher consistency with respect to both curvature and thickness of bends.
Other objects and purposes of the invention will be apparent to persons
familiar with structures and processes of this general type upon reading
the following specification and inspecting the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a top plan view of a conventional pickup truck box which
illustrates a well known construction of the bed assembly.
FIG. 2 is an exploded perspective view illustrating the basic components
which comprise the improved bed assembly of this invention.
FIG. 3 is an enlarged, fragmentary perspective view which illustrates the
structure of and cooperation between the main floor pan and rear sill
according to the present invention.
FIG. 4 is a fragmentary top view which illustrates the structural
connection of the main floor pan to the rear sill member.
FIGS. 5, 6 and 7 are enlarged, fragmentary sectional views respectively
taken along lines 5--5, 6--6 and 7--7 in FIG. 4.
FIG. 8 is a flow diagram which diagrammatically illustrates the forming
equipment and process utilized for roll forming of the main floor pan and
the securement thereof to the cross rails.
FIG. 9 is a fragmentary, sectional elevational view which diagrammatically
illustrates some of the features associated with a typical roll forming
station, such roll forming station being generally conventional.
Certain terminology will be used in the following description for
convenience in reference only, and will not be limiting. For example, the
words "upwardly", "downwardly", "rightwardly" and "leftwardly" will refer
to directions in the drawings to which reference is made. The word
"upwardly" will also be used in reference to an exposed top surface of the
floor pan of the bed assembly. The words "inwardly" and "outwardly" will
refer to directions toward and away from, respectively, the geometric
center of the box or bed assembly, or designated parts thereof. Said
terminology will include the words specifically mentioned, derivatives
thereof, and words of similar import.
DETAILED DESCRIPTION
The present invention will now be described, particularly with reference to
the structure shown by FIGS. 2-7. The floor or bed assembly 30 according
to the present invention employs a main bed or floor pan 31 which
cooperates with and has the rear edge thereof supported on a rear cross or
sill member 32. The main pan 31 is also supported on a front cross rail 38
and several (three in the illustrated embodiment) intermediate cross rails
39.
The main floor pan 31 is formed (preferably roll formed as described
hereinafter) from a thin sheet 33 of steel, preferably high strength steel
having a thickness of about 0.8 mm, so that the main pan 31 is of an
integral and monolithic one-piece construction with the pan having
substantially uniform thickness throughout the transverse cross sectional
extend thereof. The main pan 31, due to the deforming of the thin sheet
33, has a plurality of longitudinally-elongate stiffening ribs 34
projecting upwardly from the plane of the plate 33. These ribs 34 are
generally uniformly sidewardly spaced apart in the transverse or widthwise
direction of the pan 31, with the ribs 34 extending longitudinally of the
pan in generally parallel relationship. The ribs 34 have a generally
inverted channel-like or U-shaped cross section, whereby each adjacent
pair of ribs define an elongate valley therebetween as defined by the
original planar plate 33. The ribs 34 project longitudinally throughout
the entire length of the floor pan 31 so as to terminate at the respective
front and rear free edges 35 and 36 of the plate 33. These ribs result in
the main floor pan having a substantially uniform transverse corrugated
cross section throughout the entire longitudinal length thereof.
The main floor pan 31 also has an edge flange 37 extending longitudinally
along each side edge and projecting downwardly, which edge flange 37 is
integrally joined to and is bent downwardly from the main plate 33. This
edge flange 37 is provided so as to permit securement, such as by spot
welding, to a similar adjacent edge flange formed on the secondary bed
members 22 (FIG. 1). This edge flange 37 is also provided with cutouts or
notches (not shown) to accommodate therein the front cross rail 38, the
frontmost intermediate rail 39 and the rear sill 32. This flange 37
projects downwardly directly adjacent the remaining two intermediate cross
rails 39 which are of shorter length and positioned generally between the
wheelwell housings.
The rear cross or sill member 32 is defined by a one-piece channel-like
member 41 which is of a generally downwardly-opening channel- or U-shaped
cross section. This channel-like member 41 is of a length so as to extend
transversely across the entire rear edge of the truck bed and terminates
adjacent the opposite side panels of the truck box.
The channel-like member 41 defining the rear sill 32 includes downwardly
projecting front and rear sidewalls 42 and 43, respectively, the latter
terminating in lower free edges which are significantly spaced apart so as
to define an open mouth which extends longitudinally of the member to
hence provide upward accessibility into the interior of the channel-like
member. The sidewalls 42 and 43 are rigidly joined together by a top wall
which includes rear and front top wall portions 44 and 45, respectively.
The top wall portions 44 and 45 are both generally horizontally planar
walls, and the front top wall portion 45 is vertically offset downwardly a
small distance from the rear top wall portion 44, whereby a
forwardly-facing shoulder 46 is defined at the offset between the wall
portions 44 and 45. The top wall as defined by portions 44-45 defines a
generally shallow Z-shaped transverse cross section.
The offset top wall portions 44-45, and the shoulder 46 defined
therebetween, extend longitudinally throughout the entire length of the
rear sill member 32, and the sill member is preferably roll formed to
permit formation of the desired channel-like cross section.
The vertical offset between upper surfaces of the wall portions 44-45
preferably substantially equals the thickness of the main plate 33 so
that, when the rear portion of the main plate 33 is supportingly engaged
on the front top wall portion 45, the upper surfaces of the valleys in the
main plate 33 will be substantially coplanar with the upper surface of the
rear top wall portion 44.
The rear sill member 32 also has a plurality of rib-end projections 47
fixed to and projecting upwardly from the top wall 44-45 of the channel
member 41. The plurality of rib-end projections 47 are disposed in
uniformly spaced relationship along a row which extends generally
longitudinally of the rear sill member, with the number of and spacing
between the rib-end projections 47 corresponding to the number of and
sideward spacing between the strengthening ribs 34 provided on the main
pan 31.
Each rib-end projection 47, as illustrated by FIGS. 3-7, includes a rear
part 48 which projects upwardly from the rear top wall portion 44, and a
front part 49 which projects upwardly from the front top wall portion 45.
The rear and front parts 48 and 49 define a forwardly-facing shoulder 51
therebetween, which shoulder in effect constitutes an extension of the
shoulder 46.
The rear projection part 48 functions as a rib-end, and in the vicinity of
the shoulder 51 has an exterior cross section (i.e., upper or outer
exposed surface) which corresponds to the exterior surface defined on the
rib 34 at the rear free edge 36. This rear rib part 48, however, at and
more preferably slightly rearwardly from the shoulder 51, is provided with
an end wall 52 which joins to the top of the rib and then slopes
downwardly as it projects rearwardly for merger with the upper surface of
the rear top wall portion 44.
The front part 49 of the rib-end projection 47 functions as a supportive
guide, and is adapted to telescopically nest within the rearward end of
the respectively adjacent rib 34 as defined on the main floor pan 31. For
this purpose, the front part 49 has an exterior cross section (that is, an
outer wall) which has a size and configuration which substantially
corresponds to the interior cross section (that is, the inner wall) of the
rib 34. Hence, when the rear portion of the main plate 33 is supportively
engaged on the front top wall portion 45 of the rear sill 32, the front
guide part 49 on each rib-end projection 47 projects a limited extent into
the end of the respectively adjacent and aligned rib 34 to provide both
proper alignment and interior support for the rib 34 adjacent the rear
free edge 36. When so engaged, the rear free edge 36 of the main plate 33
is adapted to be disposed closely adjacent and substantially abut the
elongate shoulder structure defined by shoulders 46 and 51. When thus
assembled, then the pan 31 is fixedly secured to the rear sill member 32
by suitable spot welds, which spot welds preferably are provided not only
at the valleys of the pan but also at the top of the ribs, such spot welds
being indicated at 53 in FIG. 4. Any remaining crack or crevice between
the rear free edge 36 of the main pan 31 and the shoulder formed on the
rear sill member 32 will be filled with a suitable sealant or caulk.
As illustrated by FIGS. 5-7, the rib-end projections 47 are preferably
hollow and open downwardly through the interior of the channel-like sill
member 32, with these rib-end projections 47 being of thickness similar to
and integrally and monolithically joined to the top wall 44-45. To achieve
this desired structure, the channel member is preferably initially roll
formed, and then subjected to a pressing or stamping operation which
deforms the top wall so as to create the rib-end projections 47.
The front rail 38 and the intermediate rails 39 are also preferably roll
formed, and each are of a generally upwardly-opening U-shaped or
channel-shaped cross section. In fact, the three intermediate cross rails
39 are all preferably of identical cross sections, which cross section is
generally hat-shaped in that it includes a generally upwardly-opening
U-shaped cross section having generally horizontal top flanges which
project outwardly in opposite directions from the upper edge of each leg,
which top flanges directly engage the bottom surface of the pan 31 and are
fixedly secured thereto, such as by spot welds. The three intermediate
rails 39 are of identical cross section, with the only difference being in
their lengths. The front cross rail 38 also has top flanges similar to the
rails 39, but one of the top flanges also has an additional forwardly and
downwardly projecting flange for securement to the front panel of the box.
The bed assembly of this invention utilizes and is constructed from the
main floor pad 31, the rear sill 32, the front cross member 38 and the
intermediate cross members 39, all of which are suitably fixedly secured,
as by spot welding, and all of which are preferably formed primarily by
roll forming. In addition, the bed assembly is completed by provision of
secondary bed members similar to the members 22 of FIG. 1, which members
can be constructed in a conventional manner, such as by being stamped if
desired, so as to define the regions of the bed positioned forwardly and
rearwardly of the wheelwell housings. The rearmost secondary bed members
22 will also be dimensioned so as to engage the end portions of the rear
sill 32, such as the portion designated 55 in FIG. 3, which portion is
free of rib-end projections, so as to substantially abut against the
shoulder 46 to hence permit spot welding to the front top wall portion 45.
These secondary bed members 22 will typically have the ribs stamped
therein so as to terminate short of the rear edge thereof, as illustrated
by FIG. 1, whereby the portion 55 of the rear sill 32 need not be provided
with rib-end projections 47. However, it will be understood that these
secondary bed members 22 and the portions 55 of the rear sill 32 can be
formed with ribs and rib-end projections in the same manner as the main
pan 31 if desired, although such is believed unnecessary.
Referencing now FIG. 8, there is diagrammatically illustrated a plan view
of the apparatus and process for forming the bed assembly, specifically
the main floor pan 31 and the securement thereof to the cross rails.
The main floor pan 31 is formed from thin steel sheet which during the
forming process is a substantially continuous sheet supplied from a large
coil. The width of the steel sheet is selected based on the desired
finished dimensions of the formed floor pan 31 so as to permit creation of
the corrugated floor pan including formation of the side edge flanges 37
thereon, whereby trimming of the sheet or finished pan, and hence creation
of sheet material waste, is unnecessary. The initial width of the flat
steel sheet, as provided in the coil, substantially corresponds to the
width of the finished floor pan 31 if flattened out into a planar
condition.
The steel sheet is normally supplied in the form of a large coil 61 as
provided on a coil feed rack 62 which can be positioned adjacent a cradle
63 onto which the coil 62 can be transferred for support during the
manufacturing operation. The cradle 63 has conventional structure
associated therewith to effect straightening of the sheet material as it
is discharged therefrom in the form of a substantially continuous sheet
64. The sheet material is fed through a combined end shear-welder which
trims the leading and trailing ends of each coil and welds the trimmed
trailing end of one coil to the leading trimmed end of the next coil so as
to permit a substantially continuous sheet 64 to be feed into and through
the subsequent manufacturing stations.
After passing through the shear/welder 65, the continuous steel sheet 64
progressively moves through a roll mill 66 which progressively reforms the
steel sheet so that, while the steel sheet is substantially flat when
entering the leading end of the roll mill 66, the steel sheet has been
suitably formed so as to have the finished cross section of the floor pan
31 when leaving the discharged end of the mill 66. This progressive
reforming of the steel sheet as it passes through the mill 66 is
diagrammatically illustrated by the progressive decreasing width of the
steel sheet as it moves longitudinally through the mill.
Upon leaving the roll mill 66 the continuous steel sheet 64 has now been
formed so as to have the corrugated cross section of the pan 31
substantially as illustrated by FIG. 3, and this continuous corrugated
steel sheet is then feed into and through a cut-off press 67 which cuts
the corrugated steel sheet at desired spaced distances corresponding to
the desired lengths of the finished floor pan 31. The now separate floor
pan 31 is then transferred to a conveyor 68 which passes the floor pan
through an inspection station 69 which carries out the desired inspection
process, much of which will be accomplished by laser inspection devices.
The inspected floor pan 31 is then transferred to a press 71 which carries
out secondary stamping operations on the floor pan. Such secondary
stamping operations include the stamping of notches in the side edge
flanges 37, and the stamping of bolt holes vertically through the floor
pan, which bolt holes are used for subsequent securement of the bed
assembly to the truck frame. The floor pan 31 is then transferred to a
further inspection station 72 which carries out further inspection with
respect to the stamping operations, this again | | |
