U.S. patent application number 13/573180 was filed with the patent office on 2014-03-06 for multi-mode tape-applying striping machine and methods.
The applicant listed for this patent is Ralph Arnold. Invention is credited to Ralph Arnold.
Application Number | 20140064849 13/573180 |
Document ID | / |
Family ID | 50187821 |
Filed Date | 2014-03-06 |
United States Patent
Application |
20140064849 |
Kind Code |
A1 |
Arnold; Ralph |
March 6, 2014 |
Multi-mode tape-applying striping machine and methods
Abstract
A tape-applying striper, and related methods, by which
commercially-available pavement marking tape is
mechanically-applied and pressure-retained on highways, roadways
and parking lots to mark lanes and parking stalls at designated
locations, wherein the striper is dirigible either by the operator
walking behind the striper and manually displacing the striper, or
by motor driving the dirigible striper, as the operator rides.
Inventors: |
Arnold; Ralph; (Salt Lake
City, UT) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Arnold; Ralph |
Salt Lake City |
UT |
US |
|
|
Family ID: |
50187821 |
Appl. No.: |
13/573180 |
Filed: |
August 28, 2012 |
Current U.S.
Class: |
404/75 ;
404/94 |
Current CPC
Class: |
E01C 23/185 20130101;
B29L 2031/723 20130101; E01C 23/16 20130101 |
Class at
Publication: |
404/75 ;
404/94 |
International
Class: |
E01C 23/16 20060101
E01C023/16; E01C 7/00 20060101 E01C007/00 |
Claims
1. A striper for applying marking tape to pavement at desired
locations comprising: a carriage mounted on pavement-engaging
wheels; the carriage rotatably supporting a spool, the spool
adapted to rotatably carry at least one roll of tape for rotatably
dispensing the tape, the tape onto the pavement, having a top
non-adhesive side and a bottom adhesive side; operator-activated
structure for mechanically causing the adhesive side, at a leading
end of the tape, to be selectively displaced from above the
pavement generally downwardly into contiguous adhering relation
with the pavement so that the adhesive side of tape is accurately
and progressively superimposed upon the pavement in adhering
relation as the striper is displaced.
2. A striper according to claim 1 further comprising: at least one
pressure-applying roller by which force is selectively contiguously
and progressively applied to the exposed non-adhesive side of the
tape superimposed upon the pavement to insure enhanced adherence
between the pavement and the concealed adhesive side of the
tape.
3. A striper according to claim 1 further comprising a motorized
unit upon which an operator rides and by which the striper is
power-displaced along the pavement.
4. A striper according to claim 3 wherein the motorized unit
comprises a separate motorized vehicle pivotably connected to and
propelling the carriage.
5. A striper according to claim 1 wherein the operator-activated
structure comprises an operator control, linkage and tape
displacement structure which pivots into limited adherence with a
leading end of the tape and moves the leading end generally
downward into adherence with the pavement and, thereafter, causing
release of the limited adherence.
6. A striper for applying marking tape to pavement at desired
locations comprising: a carriage mounted on pavement-engaging
wheels; at least one roll of tape rotatably carried by the
carriage; a tape feed path through the striper, the tape feed path
being juxtaposed a tape-cutting blade; operator-activated structure
by which the cutting blade is selectively displaced to accurately
cut the tape being applied to the pavement thereby creating a free
tape end above the pavement.
7. A striper for applying marking tape to pavement according to
claim 6 further comprising: operator-activated structure for
mechanically causing the cut free end of the tape to be selectively
displaced from above the pavement downwardly so that an adhesive
side of the tape at the free end becomes contiguous and accurately
adhered to the pavement followed by progressively applying a length
of the tape accurately in superposition upon the pavement as the
striper is displaced.
8. A striper according to claim 6 wherein at least one roll of tape
comprises two side-by-side rolls of tape and the operated-actuated
cutting structure comprises blade displacement structure by which
the operator selectively causes the blade to reciprocate to cut
both side-by-side tapes simultaneously or causes the blade to pivot
from one side and reciprocate to cut only one of the two tapes or
causes the blade to pivot from a second side and reciprocate to cut
the other of the two tapes.
9. A dirigible striper for applying marking tape to pavement at
designated locations comprising: a carriage mounted on pavement
engaging wheels; tape-dispensing and tape-cutting components
carried by the carriage; the wheels comprising a single central
front wheel associated with a selectively operable latch by which,
when the latch is closed, the front wheel is locked and the striper
tracks linearly and, when the latch is closed, the front wheel is
unlocked and the striper tracks along a curvilinear path.
10. A dirigible striper for rapidly and accurately applying marking
tape to pavement at desired locations comprising: a
tape-dispensing, tape-applying and tape-cutting carriage comprising
a carriage front and a carriage rear, the carriage being mounted on
pavement-engaging idler wheels. a motorized vehicle having a
vehicle front and a location upon which an operator rides, the
front of the vehicle being pivotably connected to the rear of the
carriage whereby movement of the vehicle displaces and steers the
carriage at relatively rapid speeds to accurately deposit the tape
on the pavement.
11. A striper for applying and securing marking tape to pavement at
desired locations comprising: a carriage mounted on
pavement-engaging wheels, the carriage comprising a carriage front
and a carriage back; at least one pavement marking tape roll
rotationally held by tape-holding structure of the carriage, the
tape having a top non-adhesive side and a bottom adhesive side;
tape-dispensing structure, tape-applying structure and tape-cutting
structure mounted on the carriage by which the bottom adhesive side
of the tape is accurately and progressively made contiguous with a
top surface of the pavement at the desired locations as the striper
is displaced; at least two spaced compression rollers mounted to
the carriage so as to rotatably contiguously and compressing engage
the top surface of the tape to significantly enhance adherence
between the tape bottom and the pavement as the carriage moves; one
compression roller at the front of the striper being disposed below
and adjacent to the carriage front, the one compression roller
exerting substantial downward pressure on the pavement-engaging
tape when superimposed on the non-adhesive side of the tape over
which it passes; the other compression roller at the rear of the
striper being below and adjacent to the carriage rear, the other
compression roller exerting substantial downward pressure on the
pavement-engaging tape when superimposed on the non-adhesive side
of the tape as the other compression roller passes over the
tape.
12-13. (canceled)
14. A striper according to claim 11 further comprising an
operator-carrying motorized vehicle pivotably connected at a front
location of the vehicle to a rear location of the carriage, the
vehicle displacing the carriage as tape is progressively applied to
the pavement, the carriage comprising controls exposed at the rear
of the carriage by which the tape is selectively mechanically cut
using at least one control to create two free ends with one free
end being mechanically displaced into adhering contact with the
pavement surface, the carriage comprising a seat for an operator,
which seat is located to accommodate manual manipulation of the
controls by the operator while seated.
15. A method of applying marking tape to pavement comprising the
acts of: unrolling tape from a moving carriage progressively onto
the pavement in adhering relation; cutting the tape at least one
location above the pavement to create a non-adhering free tape end;
displacing the carriage to create a gap in the tape on the
pavement; mechanically displacing the free tape end from a location
above the pavement downward into contiguous adhering superimposed
relation upon the pavement and, thereafter, unrolling a length of
tape progressively onto the pavement in adhering relation as the
carriage is displaced.
16. A method of applying marking tape to pavement comprising the
acts of: placing tape-dispensing, tape-applying and tape-cutting
components on a carriage mounted on wheels, the wheels comprising a
single front wheel; selectively locking the single front wheel into
a fixed position thereby accommodating linear displacement of the
carriage across the pavement; selectively unlocking the single
front wheel into a rotatable position thereby accommodating
curvilinear displacement of the carriage across the pavement.
17. A method of applying marking tape to pavement comprising the
acts of: unrolling tape along a feed path from a spool through a
carriage adjacent to a blade and progressively depositing the tape
accurately onto the pavement in adhering relation;
operator-activating the cutting blade to cut the tape at a desired
location to create two free tape ends from the same length of tape,
one becoming adhered to the pavement and the other being
temporarily suspended above the pavement.
18. A method of placing marking tape on pavement comprising the
acts of: dispensing tape from a moving carriage progressively onto
the pavement in adhering relation; a vehicle propelling the
carriage under control of an operator riding on the vehicle, the
vehicle being pivotably connected to the carriage.
19. A method of placing marking tape permanently on pavement
comprising the acts of: dispensing tape from a roll mounted on a
moving carriage progressively onto pavement by mechanically feeding
the tape in a first forward direction non-adhesively over an idler
roller disposed in front of the tape roll, in a second downward
direction in front of the tape roll, and in a third rearward
direction non-adhesively around and under a front compression
roller causing the tape to forcibly and stationarily adhere to a
top surface of the pavement; the stationary tape thereafter being
forcibly and stationarily compressed a second time by a rear
compression roller.
20. A striper according to claim 11 wherein the one front
compression roller continually exerts pressure on the non-adhesive
side of tape causing the tape to adhere to the pavement surface
when superimposed over the tape and continually exerts pressure on
the pavement surface when not superimposed on the tape.
21. A striper according to claim 20 wherein at least one of the
compression rollers is resiliently biased downwardly so as to be
upwardly displaceable through a limited distance.
22. A striper according to claim 11 further comprising an idler
roller interposed forward of the tape roll between the tape roll
and the one front compression roller, the idler roller contiguously
engaging the non-adhesive side of the tape as the tape travels over
the idler roller and downwardly in a predominately vertical
direction.
23. A method according to claim 19 further comprising the acts of
selectively displacing the carriage linearly at times and
curvilinearly at other times, linear and curvilinear displacement
being accommodated by latching and unlatching a front steering
wheel carried by and supporting the carriage.
24. A method according to claim 19 further comprising the act of
selectively mechanically cutting the tape at a front site below the
idler roller and above the front one compression roller to create a
free end of the tape.
25. A method according to claim 24 further comprising the act of
mechanically displacing the cut free end of the tape downwardly
into adhering contact with the surface of the pavement immediately
in front of the front compression roller.
26. A method according to claim 19 further comprising the act of
jointly dispensing tape from two side-by-side rolls.
Description
FIELD OF THE INVENTION
[0001] The present invention relates generally to machines by which
tape is applied to pavement to mark lanes on highways and roadways
and also to mark parking stalls and, more particularly, to
stripers, and related methods, where the tape is mechanically
caused to adhere and be pressure-retained in accurate positions and
wherein the operator may either walking behind and manually steer
the striper, usually in smaller localized areas, or the striper may
be motor-driven, usually for longer distances, including, but not
limited to, use of a separate but drive-connected motorized
vehicle, on which the operator rides, the vehicle including a
steering mechanism, which accurately displaces the striper and
accurately and securely causes the striper to apply the tape to the
pavement in desired locations linearly or curvilinearly, at
surprisingly rapid speeds.
BACKGROUND
[0002] In lieu of striping pavement with painted lines, such
striping is also advantageously done using rolls of tape applied
selectively to pavement locations to create lines on highways,
roadways and parking lots. In most ways, use of paint and tape
involves different technologies.
[0003] Striping with tape, in the past, has relied solely on the
glue or bonding agent on the underside of the tape to secure the
tape to the pavement.
[0004] Also, prior art tape-applying stripers have mandated the
operator walk behind the machine, independent of whether the
machine is manually displaced or self-propelled. In both cases,
taping is slow, rest times for the operator are frequent, and
errors often occur, especially as fatigue negatively affects the
operator, when, for example, the pavement has a significant slope
and/or covers long distances over a protracted interval of
time.
BRIEF SUMMARY AND OBJECTS OF THE INVENTION
[0005] In brief summary, the present invention comprises
tape-applying stripers, and related methods, by which commercially
available pavement marking tape is mechanically-applied and
pressure-retained on highways, roadways and parking lots to mark
lanes and parking stalls at designated locations, linearly and
curvilinearly, wherein the stripers are dirigible either by the
operator walking behind the striper, and manually displacing the
striper, usually in small areas, or by motor-driving the dirigible
striper with a vehicle, as the operator rides, typically for longer
distances.
[0006] With the foregoing in mind, it is a primary object of the
present invention to provide novel tape-applying striping machines,
and related methods.
[0007] Another dominate object is provision of novel stripers, and
methods, for mechanically-applying to and pressure-retaining tape
on pavement, at designated locations.
[0008] A further paramount object is provision of novel and
versatile tape-applying stripers, and related methods, which
selectively accommodate both facile manual use and rapid motorized
vehicle use controlled by an operator riding on the vehicle.
[0009] An additional object is provision of novel tape-applying
stripers, and related methods, wherein the affect of human fatigue
is greatly negated, accuracy is increased and the speed of accurate
tape deposition is substantially increased.
[0010] Further objects include a novel tape-cutting feature, a
novel tape-applying feature and a novel wheel control feature.
[0011] These and other objects and features of the present
invention will be apparent from the following detailed description
taken with reference to the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0012] FIG. 1 is a perspective of a presently preferred
tape-applying striper in accordance with the principles of the
present invention;
[0013] FIG. 2 is a fragmentary perspective illustrating the
trailing end of the striper rotatably connected to a motorized
vehicle, by which the striper is displaced to apply marking tape to
pavement;
[0014] FIG. 3 is an enlarged fragmentary perspective of the
tape-cutting mechanism forming a part of the striper of FIG. 1;
[0015] FIG. 4 is a fragmentary perspective illustrating the
mechanism for displacing a free end of marking tape from above the
pavement generally downwardly into contiguous adhering relation
with the pavement;
[0016] FIG. 5 is a diagrammatic representation of the path
traversed by marking tape from a roll carried by the striper of
FIG. 1 along a tape displacement path into adhering relation with
the pavement;
[0017] FIG. 6 is a diagrammatic representation of the manner in
which the mechanism of FIG. 4 displaces a free end of the tape from
a location above the pavement into contiguous adhering relation
with the pavement;
[0018] FIG. 7 is a fragmentary perspective showing one of two
pressure-applying rollers forming a part of the striper in FIG.
1;
[0019] FIG. 8 is a top view of the tape cutting mechanism,
including the displaceable blade by which one or both lengths of
tape are accurately cut into segments; and
[0020] FIG. 9 is a bottom view of the front wheel, the front wheel
caster frame and a releasable latch mechanism, by which the front
wheel is caused to follow a linear path or accommodate displacement
along a curvilinear path.
DETAILED DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS
[0021] In detail, as set forth more extensively hereinafter, this
specification is directed to tape-applying stripers by which tape
is accurately applied to pavement to mark lanes on highways and
roadways and also to mark parking stalls. The tape, at the leading
end, is mechanically caused to engage and adhere and, thereafter,
the tape is pressure-retained in accurate positions on the top
surface of the pavement. The operator may either walk behind the
striper and manually steer the striper, typically where markings
are being placed on smaller localized areas, such as to mark stalls
on parking lots. The striper is most often motor-driven, where
longer distances are involved, using a separate motorized vehicle
which is rotatably connected to the rear of the striper and on
which the operator sits to control both the vehicle and the
striper, resulting in accurate and extraordinarily rapid placement
of marking tape on the pavement.
[0022] The vehicle may comprise a commercially available vehicle
comprising a motor, a steering mechanism, a brake system and a
drive mechanism for selectively displacing the vehicle in forward
and reverse directions. LINEDRIVER by Graco is a suitable vehicle,
although other commercially available vehicles may be used. The
striper progressively applies one or two lengths of tape to
pavement at a rapid speeds up to 15 miles per hour (300 feet in 30
seconds), on straight-a-ways. The striper is equally accurate and
effective in placing tape in a curvilinear pattern, as it is
placing tape in a linear pattern. With the operator riding on the
vehicle, the negative effects of fatigue are neutralized and,
accordingly, accuracy is maintained as the tape is applied rapidly.
The striper comprises a front wheel control feature, herein
described in greater detail, accommodating both curvilinear
displacement and linear displacement, where operator involvement is
minimized.
[0023] The striper comprises a carriage mounted on
pavement-engaging wheels. The carriage rotatably supports a spool
on which one or two rolls of tape are mounted for rotatable
dispensing of the tape, from a tape roll, through a tape feed path
in the striper to the pavement, so that the adhesive side of the
tape is progressively and accurately superimposed upon the
pavement, as the striper is displaced.
[0024] Two spaced pressure-applying rollers, mounted to the
carriage, are disclosed, by which force (pressure) is selectively
and contiguously applied to the non-adhesive top side of the tape,
after it has been initially superimposed upon the pavement, to
insure reliable and strong adherence of the tape to the pavement.
The striper is equipped with an operator control by which linkage
and tape displacement fingers, flaps or paddles engage in a limited
way the adhesive side of a free end of the tape, above the
pavement, after the tape has been cut or when initial tape
placement occurs. The fingers have limited contact with tape and
move the tape generally downward, causing the free leading end to
adheringly and accurately engage the pavement, after which the
fingers are lifted and the limited adherence of the fingers is
negated.
[0025] The operator is provided with an actuator by which the tape
may be mechanically cut at desired locations to accommodate, in
effect, placement of a segmented, dotted or broken line of tape, by
which drivers are informed that lane changes are permitted. In some
settings, where two rolls of tape are being simultaneously used,
both may be continuously applied to the pavement in side-by-side
relation, without cutting, or both may be applied in segments,
utilizing the cutting mechanism, or one may be continuously applied
and the other tape cut into segments, depending on the roadway
specification.
[0026] The cutting blade is mounted to the carriage in such a way
that it can be linearly reciprocated, when both lengths of tape are
to be cut. In the alternative, cutting blade may be advanced
pivotably from one edge or the other to cut only one or the other
of the two tapes being dispensed and placed upon the pavement. Tape
cutting is controlled by the operator in compliance with the
roadway specification.
[0027] The wheels upon which the striper is mounted comprise a
single front central wheel, which is associated with a latch
mechanism by which the front wheel can either be locked in a single
position for linear displacement of the striper or unlocked so that
the front wheel, the carriage and the striper track along a
curvilinear path, where the roadway specification requires. Thus,
the striper is dirigible, under the control of the operator, who
rides on the vehicle.
[0028] Adherence of the tape to the pavement is substantially
enhanced by utilization of two spaced compression rollers, each
carried by the carriage at separate locations.
[0029] Reference is now made to the drawings wherein like numerals
are used to designated like parts throughout. FIG. 1 illustrates a
presently preferred tape-applying striper, generally designated 20.
The striper 20 comprises a rigid carriage, generally designated 22.
The carriage is mounted upon three idler wheels, i.e. two opposed
larger diameter tire-carrying rear wheels 24 and one front
tire-carrying wheel 26. Idler rear wheels 24 are rotatably mounted
upon right and left axles 28 in a conventional way, each of the two
axles 28 being rigidly secured to the carriage 22 so the axles 28
are stationary and the wheels 24 rotate in a fixed pattern on the
axles 28. Thus, wheels 24 are not per se dirigible, although they
trail the front steering caster wheel 26, as explained herein in
greater detail. The steering caster wheel 26 is rotatably mounted
upon an axle 30, secured by a nut 32 on each side. The axle 30 is
connected to a caster bracket 34 in a conventional way, the bracket
34 being pivotably joined to the carriage 22 at mounting mechanism
36. Specifically, the caster bracket 34 is pivotably supported at
pin 38, where selective rotation is available, as explained
hereinafter in greater detail. The caster wheel 26 and caster
bracket 34 are controlled by the operator so as to accommodate
either a fixed linear rotation or a curvilinear rotation, as
explained in greater detail herein.
[0030] The carriage 22 comprises a U-shaped front frame member
generally designated 40, preferably having a hollow rectangular
cross section and being formed of steel, although other shapes and
materials could be used. The U-shaped front frame 40 carries a
pointer mechanism, generally designated 42, by which the striper
follows a conventional offset string line, as the striper applies
one or two lengths of tape to the pavement, as explained herein in
greater detail. The pointer mechanism 42 comprises an adjustable
cross bar 44, which passes under the front frame 40 and through
slots in right and left adjustable inverted U-shaped couplers 46.
The couplers 46 are formed of steel. Each coupler 46 threadedly
receives, through a threaded aperture, a set screw 48 manually
turned by an exposed handle 50. When the set screws 48 are
tightened against the top surface 41 of the frame 40, the brackets
46 pull the crossbar 44 up into firm non-displaceable relation with
the lower surface 52 of the front frame 40. Thus, the pointer
crossbar 44 is held in a fixed position. When the set screws 48 are
loosened, the crossbar 44 may be displaced transverse to the axis
of the striper 20 to adjust the bar location and, accordingly
adjust the pointer 54 to accommodate use of the pointer 54 to
follow the string line. Conventionally, the string line is
positioned in offset relation, at a known distance, from the
location where tape is to be applied to the pavement by striper
20.
[0031] For minor adjustments, the pointer 54 is pivotably mounted
at its upper end 50 to one end of the cross bar 44 so that the tip
56 of the pointer 54 can be rotated to adjust the position of tip
56 is directly over the string line.
[0032] The carriage 20 further comprises two centrally located
spaced steel plates 60. The rearwardly directed ends of the front
frame 40 are respectively welded to spaced gusset plates 62, at
sites 64. Plates 62 are in turn bolted, respectively, at sites 66,
to a forward portion of the associated plate 60. Thus, the front
frame 40 is rigidly and non-rotatably connected to both space side
plates 60.
[0033] The space side plates 60 are secured one to another and held
in the desired rigid positions in spaced vertical planes by a
plurality of cross support bars 70. Cross supports bars 70 are
secured rigidly to both plates 60 by welding or use of conventional
fasteners. Any suitable number of cross support bars 70 may be used
to provide structural rigidity and ample support.
[0034] The carriage 22 further comprises a rear U-shaped frame,
generally designated 80, which is substantially similar to the
front frame 40, though of reverse orientation. Thus, the rear frame
80 is preferably formed of steel and is of hollow rectangular cross
section. The rear frame 80 is rigidly fastened to both side plates
60 at the free ends 82 of the rear frame 80, at weld sites 84.
Thus, the plates 60 and the rear frame 80 are rigidly
integrated.
[0035] The axle 28 for each wheel 24 is rigidly non-rotatably
carried within the hollow of an associated axle housing 90. The
wheels 24 turn rotatably upon their associated axle 28. The axle
housings 90 are welded at sites 92 to the lower surface of the rear
frame 80 and are superimposed in welded relation at sites 93 upon
cross bar 94. Cross bar 94 thus rigidly supports both axle housings
90.
[0036] Upwardly-directed rear handle bars 90 are rigidly welded to
the rear frame 80 at sites 91. The handle bars 90 are gripped by
the operator at covered ends 94 for manual control.
[0037] The carriage 22 supports both a cutting mechanism, generally
designated 100, and a tape end displacement mechanism, generally
designated 102. The cutting mechanism 100 is operator-controlled,
using one or both pedals 104, as hereinafter explained in detail.
The tape end displacing mechanism 102 is operator-controlled, using
the displacable handle 106, as explained in greater detail
hereinafter.
[0038] Along the top edge 110 of each side plate 60 is disposed
three open rounded slots 112. The sets of slots in the two plates
60 are aligned in pairs so as to be in perpendicular alignment in
respect to the longitudinal axis of the striper 20. The rounded
slots 112 accommodate rotatable gravity insertion of and support
for a tape shaft 114, which is non-rotatably connected to a tape
spool 116. While one roll of tape 118 may be placed on the spool
116, FIG. 1 illustrates placement of two spaced rolls of tape 118.
The two rolls tape 118 accommodate facile placement of spaced
lengths of tape in parallel relation on pavement, which often is
mandated by the controlling specification. Even though two rolls
118 of tape are illustrated, it is to be appreciated that tape
displacement may be from one or two rolls, under control of the
operator.
[0039] The tape may be any suitable commercially available tape,
which comes in four, six, eight, twelve and twenty four inch
widths. For example, one suitable tape is the high performance tape
identified by the notation STAMARK, manufactured by Minnesotta
Mining and Manufacturing, Inc. (3M).
[0040] One or both of the tapes 120 from tape rolls 118 are fed,
from spool 116, as spool shaft 114 turns, through the tape path
illustrated in FIG. 5 into initial and subsequent accurate
adherence with the pavement 122. Thus, the tape is contiguously
displaced around idler roller 124, as roller 124 turns. During
continuous tape placement, tape adherence to the pavement and
striper displacement unrolls tape from the spool 116. Tape feed
idler roller 124 is supported for rotation upon a stationary cross
shaft 126 (FIG. 5). Cross shaft 126 is fixed at its ends to both
spaced plates 60. Thus, the roller 124 rotatably turns on the
stationary shaft 126. The tape 120, as is conventional, comprises
one high-wear non-adhesive surface 128, which surface contiguously
and non-adhesively engages the roller 124. The tape 120 also
comprises a second adhesive surface 130. Surface 130 has
significant adhesive characteristics. The tape 120, in its
displacement path, extends, from roller 124 downwardly and
rearwardly past a portion of the tape end displacement mechanism
102, through the cutting mechanism 100 and around the outer surface
132 of a compression roller, generally designated 134. See FIG.
5.
[0041] Roller 134 applies substantial pressure to the non-adhesive
top surface 128 of the tape, as the tape contiguously engages the
pavement 122 at its bottom adhesive surface 130 during striper
displacement. During tape displacement from one or both tape rolls
118 onto the pavement 122, as depicted in FIG. 5, only the
non-adhesive surface 128 of the tape 120 contacts the outer surface
of idler roller 124 and the outer surface 132 of pressure roller
134. The pressure-applying roller 134 is rotatably supported at its
two ends by the space plates 60, in U-shaped slots 136 (FIG. 1), to
accommodate limited up and down movement. A pair of springs similar
to the one depicted in FIG. 7, exert on the roller shaft 140 a
downward force to enhance initial adherence of the adhesive side
130 of the tape 120 to the pavement 122, while allowing limited up
and down movement of the roller 134.
[0042] Sometimes the tape 120 applied to the pavement along a
predetermined location is continuous and sometimes segments of the
tape are spaced, requiring that the tape be cut. Furthermore,
sometimes parallel lengths of tape 120 are applied continuously to
the pavement and sometimes one length of tape is continuous, while
the other is cut into segments and sometimes both lengths of tape
require cutting into segments.
[0043] When the cuffing mechanism 100 is activated by operator
displacement of one or both pedals 104, a cutting blade 150 is
displaced against cutting bar 215 (FIGS. 3 and 5) to sever one or
both tapes at a desired location. This causes one or both lengths
of tape 120 to be severed transversely, creating a free tape end
160 (FIG. 6), which is located above the pavement 122.
[0044] To return the free cut end or ends of tape or tapes 120 to a
contiguous adhering relation with the pavement 122, the operator
displaces control handle 162 of the tape displacing mechanism 106,
located near the handles 94, thereby displaced two spaced fingers
or paddles 164 causing the back surface of the two paddles to
engage the adhesive side 130 of the tape 120 so as to create
limited or nominal adherence and to thus displace the free end 160
of the tape or tapes rearwardly and downwardly, as depicted in
solid and dotted lines in FIG. 6, such that the adhesive side 130
at the free end of the tape is caused to once more adhere to the
pavement at a predetermined accurate location. Thereafter, the
roller 134, at surface 132, again become superimposed upon and
applies pressure to the non-adhesive side 120 of the tape, first at
the free end 160 and, thereafter, along the length of the tape, as
the striper 20 moves and the tape is progressively and contiguously
applied to the pavement 122 during striper displacement. The exact
way in which operator displacement of the actuator 162 causes the
paddles or fingers 164 to move, as described above, will be set
forth in greater detail hereinafter.
[0045] The carriage 20 supports a second traverse roller for
applying even a greater force or pressure to the non-adhesive
surface 128 of the pavement-engaging tape 120, specifically larger
compression roller, generally designated 180. See FIGS. 1 and 7.
Just as roller 134 comprises an elastomeric layer 182 at the
outside thereof, so too does roller 180 have an outside annular
layer 184 formed of elastomeric durable material. The interior of
the pressure roller 180 comprises a steel cylinder 186, which may
be filled with high density particles to increase its weight and
the pressure applied to the tape, in the manner shown in FIG.
7.
[0046] In addition to or in lieu of high density material within
the cylinder 186, each end of the roller 180, comprising fixed
cylindrical shafts 188 may be biased, by a suitable compression
spring 190, shown to be rigidly attached at its lower end to a
collar 192. The collar 192 is rotatably mounted to the shaft 188.
The spring 190, at its upper end is rigidly attached to plate 60.
Pressure-applying roller 180 is an idler roller and is shown, in
FIG. 7, as being mounted to associated plate 60, with each shaft
188 passing through a U-shaped slot 194, to permit limited up and
down movement of the shaft 188 and roller 180. The roller 180, by
applying pressure to the non-adhesive side 128 of the tape 120,
significantly increases the strength of adherence between the
adhesive side 130 of the tape 120 and the pavement 122.
[0047] Except for local areas where manual displacement of the
striper 20 is necessary, the striper 20 is driven by a motorized
operator controlled vehicle 200 of commercially-available type.
FIG. 2. Vehicle 200 comprises, under control of the operator, an
engine, a drive train for forward and rearward displacement, a
braking system and a pivotal connection to the rear of the striper
20, shown best in FIG. 2. The striper 20 comprises a rearwardly
extending tongue, upon which a ball connector hitch is rigidly
mounted.
[0048] The vehicle at 200 comprises two spaced motor-driven wheels
202, a seat 204, upon which an operator sits. The operator controls
both the vehicle 200 and the striper 20. Rigidly mounted to the
vehicle 200 is a front tongue 206 upon which a socket hitch 208 is
carried at the forward end thereof. The socket 208 fits over the
connecting ball at the trailing end of the striper 20 and is
releasably locked in the connected position by a standard hitch
clamp. When the vehicle 200 is so connected to the striper 20, as
illustrated in FIG. 2, the motorized vehicle 200, with the operator
seated upon seat 204, will displace and the operator will control
accurately the displacement of the striper 20 so that lengths of
tape 120 are adhereingly superimposed and compressed upon the
pavement precisely in the desired locations, as set forth in the
roadway specification. The vehicle-caused displacement of the
striper 20 may be linear or curvilinear, depending upon whether the
front wheel 26 is locked or unlocked. The vehicle is able to
displace the striper 20 at speeds up to 15 miles per hour, while
tape placement is secure and precise, a rate greatly in excess of
the speed at which prior tape-applying stripers have been operated.
Since the vehicle 200 is commercially available, no further
description is necessary for one skilled in the art to understand
its modes of operation.
[0049] In reference to FIG. 3, the tape-cutting mechanism 100
comprises a reciprocable cutting blade 150, which has a sharp
cutting edge 218 extending toward the rear. The blade 150, at each
end thereof, is connected to a reciprocable slider block 212. Each
slider block 212 comprises a slot 214 accommodating front to rear
sliding displacement of the blocks 212 along the top surface of a
cutting bar 215, which is rectangular in shape and comprises a
central slot or opening 217. The forward part of cutting bar 215
comprises an undulating or serrated surface 218, which prevents any
substantial adherence between the serrated surface 218 and the
adhesive side 128 of tape 120 passing through the slot 217.
[0050] When both pedals 104 are simultaneously depressed by the
operator, both blocks 212 move in unison toward the rear at the
same rate of speed, causing both tapes 120, disposed in slot 217,
to be cut by cutting blade 150. When only one length of tape is
extending through the slot 217, the pedal on the side where the
tape is most closely associated is activated, causing the blade 150
to move in a rearward direction with a pivotal action around the
non-activated block 212, so that only one tape is cut on the side
where the pedal is activated and a second tape extending through
slot 217 remote from the tape being cut is not cut. See FIG. 8.
When the pedal on the other side is solely activated, the
corresponding block 212 is advanced and rotated while the other
block 212 accommodates the rotation while otherwise remaining
essentially stationary. This allows the tape adjacent to the
displaced block 212 to be cut, while the second tape extending
through slot 217 is not cut.
[0051] In respect to FIG. 3, the linkage attached to each pedal 104
is identical so only one needs to be described. The linkage 100
comprises an L-shaped member 220 rigidly connected to the
associated pedal 104. The L-shaped link 220 is spring biased
upwardly by spring 224, which is connected at one end to stud or
pin 222. Pin 222 is rigidly connected to the L-shaped member 220
somewhat off center. The upper end of spring 224 is connected to
stud or pin 226, which is rigidly anchored to the adjacent plate
60, at reinforcing gusset plate 225. Thus, the link 220 is
displaced, counter to the bias of spring 224, when the associated
pedal 104 is depressed and returns to the position of FIG. 3 when
the depressed pedal 104 is released by the operator. Link 220 at
its forward end is connected to sleeve 228. Sleeve 228 connects to
an adjacent end of link 230. Link 230 is pivotally connected at
site 234 to link 232. Link 232 is rotatably connected at pin 211,
which is rigidly attached to associated block 212. This
accommodates reciprocation of the block 212 between the at rest
position of the blade 150 and the cutting position of the blade
150, when the associated pedal 104 is depressed.
[0052] Since the linkage 100 for the cutting system biases the
cutting blade 150 into its non-cutting position, as illustrated in
FIGS. 1 and 3, release of the activated pedal 104 will cause the
return springs 224 to re-position the cutting blade in the inactive
location, shown in FIG. 3. Accordingly, when one or both pedals 104
are depressed by the operator, the cutting motion of the blade 150
is counter to the forces exerted by both return springs 224.
[0053] With reference to FIG. 4, the tape end feeding system,
comprising paddles 164, is spring biased into the inactive position
by spring 250 so that manual activation of the activating crossbar
162 will cause the paddles to displace the free end of one or both
tapes 120 from above the pavement into adhering relation with the
pavement, as explained above in conjunction with FIGS. 5 and 6.
When the pivotable actuating arm 162 is released by the operator,
the associated linkage 102 returns the paddles 164 to their
inactive at rest position shown in FIGS. 1 and 5.
[0054] More specifically, in respect to FIG. 4, the two paddles
164, which are formed of steel and are non-rotatably mounted on a
rod 260 are in the inactive position when bar 162 is not depressed.
In this position, the curved tips 262 of the paddles 164 are spaced
away from the adhesive side 130 of the tape 120. As shown in FIG.
5, the interior top portion of both flaps 164 comprises serrations
264, which substantially limit any contact between the flaps 164
and the adhesive side 130 of the tape 120, with the exception of
limited tape contact with the tips 262. The linkage 102 between the
paddles 164 and the actuator 162, which is preferably formed of
steel, comprises an angular link 266 rotatably connected at pin
site 268 to the pin 260. Link 266 is also pin connected at 270 to
the adjacent plate 60, accommodating rotation of the link 266 in a
counterclockwise direction when the actuator 162 is depressed by
the operator. This causes the paddles 164 to move, as described in
conjunction with FIG. 6. The motion in question is counter to the
bias of return spring 250. The trailing arm 272 of the link 266 is
rotatably connected at pin 274 to a diagonal link 276. Link 276, at
its upper end, is pin connected, at 278, to bar 280, which, in
turn, is rigidly connected, at site 282, to crossbar actuator
162.
[0055] Thus, when the crossbar actuator 162 is pushed downwardly,
the angular link 266 is rotated, thereby displacing the paddles 164
in the manner explained in conjunction with FIG. 6.
[0056] The upper end of bar 280 is pin connected at 284 to a
stationary support frame comprising members 286 and 288. The lower
end of member 286 of the stationary frame is rigidly secured to
frame member 288 at weld location 287, while the lower end 190 of
member 291, an extension of member 288, is rigidly fastened to
frame member 22.
[0057] Reference is now made to FIG. 9, which illustrates a latch
mechanism for the front wheel 26, i.e. at the top of caster frame
34. Caster frame 34 comprises a notch 300 into which a retainer 302
of latch 304 selectively extend, when the latch to secure the wheel
26 and caster frame 34 in a fixed position to accommodate lineal
displacement during intervals of time when tape is being placed on
the pavement in a straight line. The latch 304 is pivotably
supported by the caster frame, at pin 306, accommodating pivotal
rotation of the latch 304 between the closed dotted line position,
shown in FIG. 9, and the open solid line position, shown also in
FIG. 9. In the absence of other forces, a spring may be associated
with the latch 304 to bias the latch toward the dotted line
position of FIG. 9. However, when the rotatable handle 310 (FIGS. 1
and 4), is squeezed toward the adjacent handle grip 94, cable 312
retracts the latch 304 from the dotted to the solid line position
of FIG. 9, counter to the spring bias, allowing the caster frame 34
and the wheel 26 to rotate. In this way, the striper 20 may be
turned in a curvilinear path to deposit tape onto the pavement in a
curvilinear, accurate pattern.
[0058] The invention may be embodied in other specific forms
without departing from the spirit of the essential characteristics
thereof. The present embodiments, therefore, are to be considered
in all respects as illustrative and not restrictive, the scope of
the invention being indicated by the appended claims rather than by
the foregoing description, and all changes which come within the
meaning and range of equivalency of the claims are therefore
intended to be embraced therein.
* * * * *