Note: Descriptions are shown in the official language in which they were submitted.
1~52464
LEVER-SECTOR GEAR SHEET DISPENSER
WITH MECHANIC,P,L ~lOTION MAGNIFIER
TECHNICAL FIELD
This lnvention relates to a dispenser for sheet material, in
which the sheet material passes through a nip formed by a drive
5 roller and a pressure roller, and in which rotation of the drive
roller causes the sheet to be dispensed from the cabinet. In
particular this invention ;s directed to the apparatus that
causes rotation of the drive roller. The invention is particularly
uset'ul for dispensing paper towels from a cabinet.
C 10 BACKGROUND ART
One prior art, lever operated, sheet dispenser wherein the
sheet material is dispensed through a nip ~ormed by a drive
roller and a pressure roller is described in U.S. Patent 3,45~,353-
Taylor. In Taylor, a manually operated lev~r and a toothed
15 quadrant mem~er have a common center of rotation. Th~ drlve
ro11er has a sha~t to wh7ch Is attached a ~ear that Ts~ driven by
th- quadrant member. I nterposed between the ~3ear and the drlve
roller 1~ a one-way clutch mechanism which allows the rotational
motion o~ the ~ear to be transmitted to the drive roller for only
20 one direction o~ rotation of the ~ear. STnce the sheet is dispensed
whcn the lever travels in one direction and is not dispensed when
the lever travels in the other direction, it is generally necessary
to use a drive roller tha~ has a relatlvely larS~e diameter In
order to dispense a desired len3th o~ the mater;al ~or a sinS3le
25 operatlon o1 the lever. Since the force applied to the lever
must overcome the force appl;ed to the drive roller by the pressure
roller, it would be desirable to employ a drive roller with a
relatively smaller diameter and to increase the angular rotation
of the drive roller during a sir-gle operation o~ the lever in
30 order to dispense t~e desired leng1h of the sheet material.
One prior art approach for increasing the angular rotation
o~ a drive roller in a lever operated dispenser is described in
U.S. Patent 3,606,125-Tucker et al. Tucker et al discloses a
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towel dispenser in which a manually-operated lever and
a pair of toothed quadrant members all have the same
center of rotation. The drive roller shaft has attached
thereto first and second gears, one of the gears being
driven by one quadrant member when the lever travels
in one direction and the other gear being driven by the
other quadrant member when the lever travels in the other
direction so as to dispense toweling during both the
advance and return strokes of the lever.
Other lever-operated towel dispensers that
employ a gear driven drive roller are described in U.S.
( Patents 1,229,533-Shattuck and 3,107,957-Batlas et al.
In those patents the gear means are driven by a pawl
and ratchet assembly which limits the drive roller to
a single direction of rotation.
There ls another advantage to having the lever
rotate through a relatively small angle in order to dispense
a desired length of toweling. If the lever must rotate
through a very large angle, then the lever must either
be mounted on the side of the cabinet, or if mounted
on the front of the cabinet may prove to be too cumbersome
during operation or servlcing of the cablnet. If the
( lever rotates through a small angle, lt can be mounted
80 that only the end of the lever pro~ects through the
front wall of the dispenser.
Lever-operated dlspensers generally employ
some type of spring means for returning the lever to
a starting posltion. As the lever is moved away from
the starting position, the force of the return sprlng
acting on the lever increases with the distance of the
lever from the startlng position. It would, therefore,
be desirable to have the mechanical advantage of the
feed roller drive mechanism increase as the lever moves
away from the starting position which would, at least
in part, compensate for the increased force on the lever
resulting from the return spring.
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SUMMP~RY OF THE INVENTION
An aspect of the invention is as follows:
An apparatus for feeding sheet material
through a nip formed with a rotatably mounted drive
S roller comprising:
(a) first gear means;
(b) means, operably connected to the first
gear means, for reciprocating the first gear means;
(c) a movable gear, engaged by the first gear
means; and
(d) second gear means operative'y onnected
to the drive roller, wherein the movable gear is moved
into driving engagement with the second gear means to
feed the sheet materlal through the nip when the first
gear means moves in one direction, and wherein the movable
gear is moved and is disengaged from the second gear
means when the first gear means moves in the opposite
direction.
It is an object of an aspect of this invention
to provide an improved sheet materlal dispenser.
It is an ob~ect of an aspect of this invention
to provlde an improved sheet material dispenser whereln
the sheet material is fed through a nlp formed by a drive
roller and a pressure roller.
An object of an aspect of this inventlon is
to provide a lever-operated sheet material dlspenser
whereln the lever mechanical advantage increases as the
lever mo~es away from the startlng posltion.
An object of an aspect of thi~ lnvention is
to provide a lever-operated sheet material dispenser
in which the sheet material passes through a nip formed
by a drlve roller and a pressure roller and which uses
a simple mechanism for removing the drive from the drive
roller when the lever is moving in the return direction.
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BRIEF DESCRIPTION OF THE DRAWINGS
While the specification concludes with claims
particularly pointing out and distinctly claiming that
which is regarded as the present invention, the objects
and advantages of this invention can be more readily
ascertained from the following description of a preferred
embodlment when read in conjunction with the accompanying
drawings in which:
Fig. 1 is a side elevation view of the dispensing
cabinet with portions of the cabinet walls being cut
away to illustrate the lever operated dispensing apparatus
of this invention;
Fig. 2 is a partial side elevation view illustrating
the dispensing action when the lever is depressed;
Fig. 3 is a partial side elevation of the gearing
for the drive roller illustrating how the gearing is
disengaged from the drive roller during the return stroke
of the lever;.
il52464
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Fig. 4 is a partial side elevation view of the drive
mechanism illustrating means for preventing excessive force
applied to the lever from being transmitted to the gearing means;
and
Fig. 5 is a partial side elevation view of a pedal
operated version of the dispensing apparatus.
BEST MODE FOR CARRYING OUT THE INVENTION
For the sake of convenience, an element depicted in more
than one figure will retain the same element number in each
fi~ure. Referring now to Fig. 1 of the drawings, a dispensing
cabinet 10 is shown with a portion of its front and side walls
removed to re~eal the dispensins mechanism of this invention.
Shown within the cabinet is a roll 12 of a sheet material, such
as a sanitary paper towel, that is wound on a core 13. A pair of
spaced-apart support members 22 are mounted within the cabinet 10
and are adapted to extend into the ends of the core 13 so as to
ro~tatably support the roll 12 The leading end 14 of the roll of
sheet material i~ fed into and through a nip formed by a pressure
roller 16 and a drive roller 18. Althou~h the sheet has been
descrlbed as passin~ through a rollln3 nip, it is clear that
1' pressure rotler 16 could be replaced, for example, by a statlonary,
~mooth surtace. It is preferred that the surface of one of the
rollers 16, 18 have a greater coefficient of friction than the
other surface. In one embodiment, pressure roller 16 is made out
of wood which has a relatively smooth surface and drive roller 18
is made out o- rubber which has a frictional surface. In a
preferred embodiment, as best shown in Fig. 3, the drive roller 18
is mounted so that it has a fixed axis of rotation while the
pressure roller 16 is mounted so that its axis of rotation can
move toward and away from the axis of rotation o~ the drive
roller 18. To accomplish this, the ends 17 of pressure roller 16
are mounted in brackets 19, and coil springs 21, also housed in
brackets 1~, exer~ a force on the ends 17 of the pressure roller 16
causing pressure to be applied to the sheet material 14 in the
nip formed by the pressure roller 16 and the drive roller 18.
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Referring now to Fig~ 1, one mechanism for applying drive to
the drive roller 18 ~'Jill now be described. A lever 24 having a
knob 25 that projects through the front wall 11 of the dispenser
10 is mounted for rotation about a shaft 34 within the dispensing
S cabinet 10. An actuator 26 is also mounted for rotation about
shatt 34. A portion 43 of the actuator 26, bent over in the
direction of the lever 24, acts as a stop that limits the relative
rotation of the lever 24 with respect to the actuator 26. A
spring 32, having one end hooked in5o a notch 31 in actuator 26
~0 and having the other end hooked into a hole 33 in the lever 24,
biases the upper edge of the lever 24 against the stop portion 43
of the actuator 26. It may be decirable to assemble the lever 24,
the actuator 26 and the spring 32 into a subassembly which can
then be assembled as a unit into the d7spenser 10. For that
15 purpose, the actuator 26 can be fabricated with an arcuate slot 30
having a curvature that is concentric about a mounting hole for
shaft 34. A shoulder rivet 28 extending through the arcuate
slot 30 and riveted to the lever 24 maintains a fixed spaced
relationship between the lever, 24 and the actuator 26, but when
20 assembled into the dispenser 10, allows lever 24 to rotate with
respect to actuator 26 through an àngle as determined by the
len~7th ot arcuate slot 30.
A gear se~ment 36 havin~ a plurallty of ~ear teeth 38 abo,ut
its pariphery is mounted ~or rotation about a shaft 49. The ~ear
25 ~egmont 36 includes a projection 44 which, at the return position,
rests against a cushioned stop 46 that limits the rotation of the
~ear se~ment 36 in one direction. A return spring 50 which is
5upported by an extended hub 48 of the gear se~ment 36 has one
~nd held by a retainer tab 52 located on a wall member within the
30 d1spensing cabinet 10 and has the other end located in a similar
retainer tab 54 located on the gear segment 36. Return spring S0
biases gear segment 36 at the return position against the cushioned
stop 46.
A portion of the actuator 26 is bent over in the direction
35 of the gear segment 36 to provide a flange surface 40. Gear
segment 36 includes a raised, radiused section 42 which contacts
the flange surface 40 of actuator 26. When the ;<rlob 25 of the
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lever 24 is depressed, both the actuator 26 and the lever 24 will
rotate about shaft 34, and due to the pressure applied by the
flange surface 40 on the raised portion 42, gear segment 36 is
caused to rotate about shaft 49. When the knob 25 is released,
return spring 50 will cause the gear segment 36, and the actuator 26
and lever 24 subassembly to go back to the return position.
The gear teeth 38 of gear segment 36 engage a floating idler
gear 56. The shaft 57 of idler gear 56 is mounted in slots 58
which are aligned generally parallel to the gear teeth 38 on the
periphery of gear segment 36. When shaf. 5~ of idler gear 56 is
located at the end of slots 58 near the drive roller 18, the
idler gear 56 is in driving engagement with a gear 60 mounted on
a shaft 61 of the drive roller 18. When shaft 57 of idler gear
56 is located at the end of slots 58 remote from the drive roller
18, as shown Tn Fig. 3, the idler gear 56 is disengaged from the
~ear 60 mounted on shaft 61 of the drTve roller 18.
As best illustrated in F;g. 1, it may be desirable to provide
a number of different stop positions for lever 24 in order to
select the ler,~th of the sheet material 14 that is dispensed
through the opening 20 of dispensing cabinet 10. Thus, when the
lever 24 is depressed so that the knob 25 coincides with the
dashed position 25C, the bottom eds~e 63C of the lever 24 hits a
cushloned stop 62 mounted within the dispensing cabinet 10 Two
other stop positions, illustrated by dashed outlines 25A and 25B
of the handle 25 of lever 24, can be provided by inserting a
retainin~ pin 64 into either holes 66 or holes 68 in interior
sidewalls within the dispensing cabinet 10.
In operation, the operator causes the gear segment 36 to
reciprocate between cushioned stop 46 and a stop, such as stop
pin 64. Under normal dispensing conditions, the lever 24 and the
actuator 26 are biased at the stop 43 by spring 32 and rotate as
a single unit. As the lever 24 is depressed and caused to rotate
about shaft 34, the flange 40 of act-lator 26 which bears against
the raised, radiused portion 42 of gear segment 36 causes gear
segment 36 to rotate in a counter clockwise direction about shaft
49. Since the gear teeth 38 of gear segment 36 engage the teeth
of floating idler gear 56, as the gear segment 36 begins to
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rotate it causes floating idler gear 36 to rotate and to move
along slot 58 towards and into engagement with gear 60 mounted on
the shaft 61 of drive roller 18. Continued counterclockwise
rotation of gear segment 36 results in rotation of drive roller
5 18 Tn a counter-clockwise direction. Due to the combined action
of pressure roller 16 pressing the end of the sheet material 14
in the nip against the surface of drive roller 18 and the coefficient
of friction between the sheet material 14 and the surface of
drive roller 18, as drive roller 18 rotates it dri~_s the sheet
10 material 14 through the nip. As best shown in Fig. 2, when lever
24 has reached ~he end of its downward travel, which occurs when
the lower edge 63 of lever 24 contacts the stop pin 64 inserted
In stop holes 66, the desired length of the sheet material 14 has
bee~ dispensed through the opening 20 in the front wall of the
15 dispensing cabinet 10. The sheet material 14 can be removed by
pulling it against a cutter edge (not shown) mounted in the
bottom portion of the dispensing cabinet 10.
When the operator releases the knob 25 of lever 24, return
spring 50 will cause the gear seS3ment 36 and the Jever 24 and
20 actuator 26 subassembly to return to the startin~ posltlon, as
Illustrated in Fig 1. When the gear segment 36 rotates in the
clockwlse direction, It is necessary to remove the driving force
~rom ~ear 60 mounted to the shaft 61 o~ drive roller 18 in order
to prevent the drive roller 18 from pulling the free end of the
25 sheet material 14 through the nip and back into the dispensing
cablnet 10. As best shown in Fig. 3, as ~ear segment 36 begins
to rotate in a clockwise direction, it c3uses the floatin~ idler
gear 56 to begin rotatin~ in the counter-clockwise direction and
also causes the shaft 57 o~ floating idler gear 56 to move in
30 slots 58 in the direction away from drive roller 18 which disengages
the floating idler ç3ear 56 from ç7ear 6~ thereby removin~ drive
~rom the drive roller 18 while the gear segment 36 is rotating
towards the return position.
On occasion, one of the geared members may ~ecome jammed and
35 be unable to rotate, which could occur, for example, if the sheet
material 14 bunched up within the nip formed by 1:he pressure
roller 16 and the drive roller 18 thereby preventing rotation of
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the drive roller 18. Under these conditions, an operator may try
to force the dispensing of the sheet material by applying an
excessive force on the knob 25 of lever 24. The actuator 26,
lever 24 and spring 32 subassembly prevents excessive shock
forces from being transmitted to the gear teeth 38 on gear segment
36 or to the floating idler gear 56 or to the gear 60 mounted on
the shaft 61 of drive roller 18 which may strip the gear teeth of
thos¢ members or otherwise damage the drive mechanism. Spring 32
normally biases the upper edge of lever 24 against the stop 43 of
the actuator 26. When the drive mechanism is jammea and th
operator moves the knob 25 of lever 24 down in the dispensing
direction, the jammed cond;tion prevents gear segment 36 from
rotating in the counter-clockwise direction and a force is developed
~t the contact between the raised portion 42 of the gear segment
36 and the flange surface 40 of actuator 26 that tends to rotate
actuator link 26 in the clockwise direction. If the downward
pressure applied by the operator on knob 25 of lever 24 exceeds
the force of spring 32 that biases lever 24 aç1ainst the stop 43
ot actuator 26, the sprin~ 32 will expand to allow relative
rotation of the lever 24 with respect to actuator 26. Spring 32
In so expanding absorbs some of the energy of the excesslve shock
load and limits the shock load that is applied to the gear segment
36 whlch may tend to strip the gears or otherwise damage the
drlve mechanism.
Fl~. 5 illustrates a pedal-operated version of the dispenser
10. Mounted at the rear of the cabinet are brackets 77 which
support the shaft 76 of a pulley 74. A cable 72 having one end
secured in hole 70 in the gear segment 36 passes over the pulley
74 and down to a foot pedal (not shown). When the operator steps
on the foot pedal, cable 72 causes çlear segment 36 to rotate
which causes the sheet material 14 to be dispensed through the
nlp formed by pressure roller 16 and drive roller 18 as previously
described. When the operator steps off the foot pedal, the
return spring 50 causes gear segment 36 to rotate back to the
starting position against cushioned stop 46. Some adjustment in
the amount of paper dispensed and pedal force reguired to operate
the dispenser is provided by having several holes 70 spaced at
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different radial distances from the center of rotation 49 of gear
segment 36.
It may be desirable in a pedal operated version of the
dispenser 10 to support sha~t 76 of pulley 74 on springs 78,
5 which would act as overload shock absorbers, mounted within the
brackets 77. If the dispenser 10 were jammed and gear segment 36
were unable to rotate, an excessive force applied to the foot
pedal woùld cause compression of the springs 78 thereby preventing
the full shock load from being transmitted to the gearing mechanism.
There are several advantages to having the gear segment 36
rotate about one point such as shaft 49 and having the lever 24
and actuator 26 assembly rotate about a different point such as
shaft 34. When the distance from the center of rotation 34 of
the lever 24 and actuator 26 assembly to the contact point between
15 tlan~e 40 and raised portion 42 of ~ear se~ment 36 is greater
than the distance between the center of rotation 49 of the gear
segment 36 to the contact point between flange 40 and raised
portion 42, rotation of the lever 24 will cause ~ear se3ment 36
to rotate throu~3h an angle that is greater than the angle of
20 rotation of the lever 24. In one constructed embodiment, when
the lever 24 rotates through an angle of about 40, the gear
segment 36 rotates through an angle o~ about 70. Another advantage
ot having the ~ear segment 36 rotate about one point and havin~
the lover 24 and actuator 26 assembly rotate about a second point
25 Is that as the lever 24 rotates, the contact point of the raised
portion 42 of gear segment 36 against the flange 40 of actuator
26 moves back toward the center of rotation of the lever 34.
This increases the mechanical advantage of the lever 24 and
actuator 26 subassembly, and, Tn part compensates tor the increased
30 force of the dispensing mechanism due to the action of the return
spring 50.
While the present invention has been described with reference
to a specific embodiment thereof, it will be obvious to those
skilled in the art that various changes and modifications may be
35 made without departing from the invention in its broader aspects.
For example, although the embodiment depicted in Fig. 1 employs a
subassembly comprising lever 24, actuator 26 and spring 32 to
l~SZ~64
effect rotation of the gear segment 36, it will be apparent to
those skilled in the art, that the actuator 26 and the spring 32
are not essential for causing the gear segment 36 to rotate. If
the shock absorbing feature were not desired, the actuator 26 and
the spring 32 would not be required. In that case, a portion of
the lever 24 could be bent over to provide a flange surface that
is equivalent to the flange 40 of actuator 26 and wnich would
contact the raised portion 42 of gear segment 36.
Furthermore, although the gear segment 36 includes a raised
portion 42 that is radiused in its upper surface for contacting a
flange 40 of actuator 26, equally satisfactory operation would be
obtained if the actuator 26 included a radiused portion which
contacted a flat surface of gear segment 36. Other arrangments
could also be provided to cause rotation of the gear seament 36,
such as, replacing the raised, radiused portion 42 by a roller to
reduce the friction between the actuator 26 and the gear segment
36.
Also, although the idler gear 56 has been described as
mounted in a slot 58, it will be clear to those skilled 7n the
art that the important feature is that the idler gear 56 can move
into and out of engagement with gear 60 connected to shaft 61 of
drive roller 18. This motion could, for example, also be provided
by mounting the idler gear 56 in an arm member mounted for limlted
rotatlon about shaft 49.
From the above discussion Tt can be seen that there is an
advantage, in a lever operated sheet material dispenser that
Inciudes a gear segment for dispensinç~ the sheet material, to
having the lever rotate about one point and to have the gear
segment, which is actuated by the lever, rotate about a second
polnt. By proper selection ot the point of contact between the
lever and the gear segment, the gear segment can be caused to
rotate through a greater angle than the angle of rotation of the
lever. Another advantage of the dispenser of this invent70n is
that the mechanical advantage provided by the lever increases as
the lever is depressed thereby compensating in part for the
increased resistance to dispensing caused by any return spring
mechanism .
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1152464
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This invention also provides a very simple means in the form
of a movable floating idler gear that is engaged by the gear
segment, for rota1;ing the drive roller only during one direction
of travel of the lever.
