Towel dispenser

Abstract

An improved towel dispenser includes a rotatable driveshaft mounted in a one-way clutch bearing fitted with a pinion which engages a vertically oriented press bar assembly including at its lower portion a rack which engages the pinion to advance paper towel through a dispensing nip upon pivotable motion of the press bar assembly. A dispensing chute located below the dispensing nip includes a lower shelf configured to direct web forwardly toward the front portion of a dispenser. The gear rack is preferably an internal gear rack integrally formed with a unitary press bar assembly member. The dispensing chute is configured such that an angle between a cutting-blade and the outer lip of the shelf makes an angle with a vertical of at least about 25.

Claims

1. A dispenser for dispensing sheet material from a roll, comprising: a feed roller rotatably mounted to a housing to thereby dispense sheet material from the roll; a press bar assembly having a first orientation that is generally vertical, the press bar assembly being pivotably mounted to the housing so as to be pivotable about a pivot axis extending through the press bar assembly, the press bar assembly comprising a rack operatively connected to the feed roller to cause the feed roller to be rotated when the press bar assembly pivots about the pivot axis; and a handle extending from the housing and oriented in the first orientation, the handle being in engagement with the press bar assembly and configured to be pushed by a user generally into the housing of the dispenser, such that the press bar assembly pivots about the pivot axis, wherein the handle comprises an upper end portion in vertical proximity to the pivot axis and an opposed lower end portion in vertical proximity to the rack, wherein the press bar assembly has a top and a bottom separated by a distance and the rack is disposed more than about 65% of that distance from the top of the press bar assembly toward the bottom of the press bar assembly, and wherein the top of the press bar assembly is aligned with an upper end of the upper end portion of the handle.

2. The dispenser of claim 1, wherein the first orientation is perpendicular to an axis of the feed roller.

3. The dispenser of claim 1, further comprising a pinion in engagement with the rack, the pinion being coupled to a driveshaft in engagement with the feed roller, such that rotation of the pinion causes rotation of the feed roller.

4. The dispenser of claim 3, wherein the driveshaft is mounted in a one-way clutch bearing, such that the driveshaft advances only when the press bar assembly is pushed inwardly.

5. The dispenser of claim 1, further comprising a spring engaging the push arm assembly to normally bias the push arm assembly to a rest position.

6. The dispenser of claim 1, further comprising a pivot pin that supports the press bar assembly.

7. The dispenser of claim 1, wherein the handle comprises a concave contact surface.

8. The dispenser of claim 1, wherein the handle comprises a contact surface having a width that is less than a width of a front portion of the housing, such that the handle is configured to be pushed into the front portion of the housing.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) The invention is described in detail below with reference to the various figures wherein:

(2) FIG. 1 is a perspective view of a first embodiment of a towel dispenser constructed in accordance with the present invention;

(3) FIG. 2 is a schematic diagram showing various parts of the inventive dispensers;

(4) FIG. 2(A) is a schematic diagram illustrating the angle between the lower lip of the dispenser chute and the cutting blade;

(5) FIG. 3 is a schematic detail showing interaction of the clutch bearing and push bar assembly of the present invention;

(6) FIG. 4 is a schematic detail showing the unitary support member including a molded-in rack of the press bar assembly;

(7) FIG. 5 is a schematic front interior view in elevation of the dispenser of FIG. 1;

(8) FIG. 6 and FIG. 7 illustrate operation of the cradle roll transfer mechanism which is utilized in connection with the dispenser of FIG. 1;

(9) FIG. 8 is a perspective view of another embodiment of a towel dispenser which may be constructed in accordance with the present invention;

(10) FIG. 9 illustrates the drive mechanism for rotating the drive roll of a dispenser of the class shown in FIG. 8;

(11) FIG. 10 is a schematic front view in elevation of the interior of the dispenser of FIG. 8;

(12) FIG. 11 illustrates a sensor drive transfer mechanism with a yoke adapted to alternately couple respective drive rolls of the dispenser of FIGS. 8-10 to a driveshaft of the dispenser;

(13) FIG. 12 is a perspective view of yet another dispenser in accordance with the present invention;

(14) FIG. 13 is a cross-sectional view taken along line XIII-XIII in FIG. 12;

(15) FIG. 14 is a cross-sectional view taken along line XIV-XIV in FIG. 12;

(16) FIG. 15 is a cross-sectional view taken along line XV-XV in FIG. 13;

(17) FIG. 16 is an exploded perspective view of an actuator unit and adjoining framework of the dispenser;

(18) FIG. 17 is a partial perspective view of the interior of the actuator unit;

(19) FIG. 18 is a side view of the interior of the actuator with the contact portion of the push arm and the drive gear support omitted;

(20) FIG. 19 is a partial perspective view of the side member supporting the drive gear;

(21) FIG. 20 is a side view of a drive unit secured to a side member of the casing;

(22) FIG. 21 is a perspective view of an assembled driveshaft and drive stem of the present invention;

(23) FIG. 22 is an exploded perspective view of the driveshaft and drive stem;

(24) FIG. 23 is a partially assembled dispenser with the casing fit into the housing;

(25) FIG. 24 is a perspective view of the rear of the dispenser framework illustrating the attachment of the casing in the housing; and

(26) FIG. 25 is a perspective view of a side of the dispenser framework illustrating the attachment of the casing in the housing.

DETAILED DESCRIPTION

(27) The present invention is described in detail below in connection with several embodiments for purposes of illustration only. Modifications to such embodiments, within the spirit and scope of the appended claims, will be readily apparent to those of skill in the art.

(28) Referring generally to FIGS. 1 through 7, there is shown a first embodiment of a towel dispenser 10 constructed in accordance with the present invention. The towel dispenser of FIGS. 1 through 7 is a towel dispenser of the class for sequentially dispensing a primary roll of paper towel and a reserve roll of paper towel. Most preferably, the paper towel defines a bearing receptacle to releasably hold it in the upper position shown in FIG. 2 as noted above. Dispenser 10 includes a housing 12 defining an enclosure 14 with an enclosure front portion 16 and enclosure sidewall portions 18, 20 and an enclosure upper portion 22 and an enclosure lower portion 24. The dispenser optionally includes an inner, modular chassis indicated at 25 to mount the various parts as is known in the art and may be made of any suitable material, typically plastic.

(29) A dispensing nip 26 in the lower portion of the housing is defined in part by a drive roll 28 with first friction surface 30 defined by drive disks 36 about the shaft of drive roll 28 and a nip-defining roll 32 having a second friction surface 34 whereby dispensing nip 26 is defined therebetween.

(30) At upper portion 22 of housing 12 there are provided hubs indicated at 38 and 40 for rotatably mounting a roll of paper towel in the upper portion of enclosure 14 above dispensing nip 26.

(31) A roll 42, a continuous web of paper towel, is fed downwardly where the web is gripped between drive roll 28 and nip roll 32 by virtue of their friction surfaces. The friction surfaces may be continuous or may be formed with a plurality of disk-shaped members such as members 36. These may be made of any suitable material which provides friction which has a high coefficient of friction, such as a soft rubber roll or a tracked plastic roll and so forth as is known in the art.

(32) A cradle 44 for supporting roll 42 of paper towel in the lower portion of said enclosure is located behind dispensing nip 26 and configured so that the web may be fed forwardly to the dispensing nip after the roll has dropped to the cradle as can be seen in FIG. 6.

(33) A lever member 46 coupled to cradle 44 is mounted for rotation about a fulcrum 48 wherein cradle 44 is disposed rearwardly with respect to the fulcrum 48, and lever member 46 extends forwardly of the fulcrum 48 and a lower portion of the dispenser and includes a tucker element 50.

(34) The cradle and the lever member are configured as shown, such that when the cradle supports a roll of paper towel that has not been substantially depleted, the tucker element is raised above the dispensing nip as shown in FIG. 6. When a roll disposed on the cradle has been substantially depleted or the absence of a roll of towel on the cradle, the tucker element advances downwardly toward the dispensing nip in order to introduce paper towel thereto as is shown in FIG. 7.

(35) This action is known in the art as is shown for example in the above-mentioned U.S. Pat. No. 4,807,824 to Gains et al., the disclosure of which has been incorporated herein.

(36) The drive roll is mounted for rotation about a driveshaft mounted in a one-way clutch bearing as is further discussed below.

(37) A vertically oriented press bar assembly 52 with an upper press bar assembly portion 54 is mounted pivotably about its upper portion for inward and outward motion with respect to enclosure 14. Vertically oriented press bar assembly 52 includes at its lower portion 56 a molded-in rack 58 which engages pinion 60 coupled to drive roll 28 by way of a one-way clutch bearing 70 and a driveshaft 62. Driveshaft 62 is mounted in the one-way clutch bearing 70 which has pinion 60 secured (preferably press-fit) thereabout such that the driveshaft advances only when the press-bar assembly is being pushed inwardly from its rest position as will be appreciated from the various Figures. The one-way clutch bearing is preferably a needle clutch bearing as noted above. One-way clutch bearings and their application are further discussed in U.S. Pat. No. 4,635,771 to Shoji et al; U.S. Pat. No. 5,655,722 to Muckridge; as well as U.S. Pat. No. 6,336,542 to Mintonye, II, the disclosures of which are hereby incorporated by reference. As used herein the term lower portion of the press bar assembly refers to the fact that rack 58 is located toward the lower extremity of the press bar assembly as shown in the drawing. That is to say, the rack is vertically more than half way toward the bottom of the press bar assembly 52 and preferably more than about 65% of the distance from top 66 to bottom 68 of the press bar towards its lower portion in order to maximize mechanical advantage. A particularly preferred embodiment includes a unitary support member 72 with a molded-in rack as seen particularly in FIG. 4. Member 72 may include a plurality of tabs 74, 76, for example, to receive a press bar handle 78.

(38) Handle 78 is coupled to the drive roll via press bar assembly 52 and driveshaft 62 such that the drive roll will advance web 42 through dispensing nip 26 upon pivotable motion of press bar assembly 52 about its pivot point indicated at 80.

(39) There is further provided a spring 82 to bias the press bar towards the front of the dispenser such that the press bar projects outwardly therefrom in a rest position as shown in FIG. 1. That is to say spring 82 biases the press bar assembly 52 to its rest position, whereas upon inward motion of the press bar assembly, rack 58 engages pinion 60 and drives drive roll 28 to advance the paper as will be appreciated from the drawings. Upon outward motion of assembly 52, rack 58 still engages pinion 60; however, since bearing, 70 is a one-way clutch bearing pinion 60 is freewheeling and does not turn driveshaft 62.

(40) A dispensing chute 84 located below dispensing nip 26 is provided with a lower arcuate shelf 86 configured to direct web 42 forwardly toward front portion 16 of dispenser 10.

(41) A cutting blade 90 is disposed below the dispensing nip above lower shelf 86 of dispensing chute 84.

(42) It should be noted that nip roll 32 defines the second friction surface 34 of dispensing nip 26 at a lateral portion 92 of the dispenser. This location is generally at a lateral extremity 94 of dispensing nip 26 adjacent a sidewall 18 of the dispenser, preferably between disks 36 as shown. Tucker element 50 is located adjacent this lateral friction surface to provide for feeding a reserve roll of paper towel. There is additionally provided a damper mechanism 98 coupled to lever member 46 wherein damper mechanism 98 includes a cam 100 mounted for pivotable movement as well as a cam follower 102. Cam 100 is mounted for rotational movement about a pivot 104 with the tucker element coupled to follower 102 as shown. The cam is positioned as shown such that cam 100 engages sheet material 42 as it is dispensed from cradle 44 with the result that the force of sheet material 42 is transferred by the cam to the cam follower by a roller 96 such that tucker element 50 is maintained in the raised position shown in FIG. 6. This feature is provided so that the reserve roll is not fed to the dispensing nip until the primary roll is exhausted, whereupon tucker element 50 descends to the position shown in FIG. 7 to feed the reserve roll to dispensing nip 26.

(43) Preferably rack 58 is an internal rack configured to engage the pinion along a lower circumferential position 105 with respect to an axis of rotation 106 of the pinion, which is the same as the axis of driveshaft 62. That is to say, rack 58 generally has a radius of curvature whose center is on the same side of the rack as the gear teeth thereof. As noted above clutch bearing 70 is preferably a one-way needle clutch bearing. An appropriate clutch bearing is Model No. HFZ 640 708E available from INA of Germany.

(44) Lower shelf 86 of dispensing chute 84 extends forwardly with respect to cutting blade 90 over a distance 108 such that a line between an outer lip 110 of shelf 86 and cutting blade 90 makes an angle 91 of at least about 25 with respect to a vertical 93. Preferably that angle is at least about 30 with respect to the vertical, shown schematically in FIG. 2(a). This feature is important to prevent unwanted dispensing inasmuch as the clutch bearing is only locked upon inward motion of the press bar. So also, press bar assembly 52 comprises the unitary support member 72 with the molded-in rack 58, and press bar handle 78 is preferably press fit to the support member, whereas chute 84 has a plurality of optional ridges 85 to reduce static.

(45) There is shown in FIGS. 8 through 11 another embodiment of the present invention.

(46) FIG. 8 is a perspective view of a double side-by-side dispenser 210 wherein rolls of paper towel to be dispensed are mounted in co-axial side-by-side position for sequential dispensing. In FIGS. 8-11 parts corresponding to those in FIGS. 1-7 are sometimes numbered 200 numerals higher for convenience. Dispenser 210 includes a housing 212 defining an enclosure 214 with an enclosure front portion 216 and enclosure sidewall portions 218 and 220 and enclosure upper and lower portions 222 and 224. A first dispensing nip 226 in lower portion of housing 212 is defined in part by a first drive roll 228 and further includes a passive nip roll 230. A second nip 232 in the lower portion of the housing is defined in part by a second drive roll 234 and further includes a second nip roll 236. As can be seen from the various figures first and second dispensing nips 226 and 232 are generally co-axial lined with respect to one another. So also there are provided mounting hubs such as hubs 238, 240 for rotatably mounting first and second rolls of paper towel in upper portion 222 of enclosure 214 such that rolls such as roll 242 are co-axially aligned such that the towel may be fed downwardly therefrom to first and second dispensing nips 226 and 232, respectively.

(47) First drive roll 228 and second drive roll 234 of dispensing nips 226 and 232 are rotatably mounted at 244-250. There is further provided a rotatable driveshaft 252 mounted in a one-way clutch bearing 275 which has a drive pinion 256 secured thereabout. Rotatable driveshaft 252 is coupled to an elongate metal shaft 253 extending through both drive rolls 228 and 234 and is selectively coupled thereto as described further below.

(48) A vertically oriented press bar assembly 260 with an upper press bar assembly portion 262 is pivotably mounted about an axis indicated at 264 for inward and outward motion with respect to said enclosure 214. Press bar assembly 260 includes at its lower portion 266 a rack at location 268 which engages pinion 256 which, in turn, is coupled to driveshaft 252. Driveshaft 252 thus rotates upon pivotal motion of the press bar by virtue of the fact it is coupled thereto by way of pinion 256 as will be appreciated by one of skill in the art because the one-way bearing imparts rotation only upon inward motion of the press bar since the bearing rotates freely upon return of the press bar to its rest position. In other words, the drive mechanism generates substantially the same as discussed in connection with dispenser 10 above.

(49) The driveshaft is selectively coupled to either first drive roll 228 or second drive roll 234 such that the dispenser is adapted to sequentially dispense paper towel from first roll 242 and upon depletion thereof, from a second roll. This may be accomplished by any suitable means such as by way of sensor arms which include a cam surface 270 which activates yoke 272 to switch the dispenser from one roll to the other as is known in the art and is shown in the various diagrams. A spring loaded sensor arm such as arm 282 will engage a roll of split-core towel and be retained backwardly when the roll is being dispensed. When the split core towel is depleted and the core falls from its retaining bearings, arm 282 is biased so that it swings forwardly as shown in FIG. 10 at 283, so that cam surface 270 engages a corresponding cam surface 284 on yoke 272. Yoke 272 (FIG. 11) selectively moves clutch members such as clutch members 286, 288 into engagement with drive plates 290, 292 which, in turn, drive either one or the other off the drive rolls of the dispenser. That is, clutch members 286, 288 are coupled to tubular drive rod 253 which coaxially runs along the length of both roll 228 and 234 and is coupled to driveshaft 252 as shown in FIG. 9.

(50) Here again means for biasing press bar assembly 260 toward front portion 216 of dispenser enclosure 214 includes a spring as noted above in connection with the embodiment of FIGS. 1 through 7.

(51) A dispensing chute 274 located below dispensing nip 226 with a lower shelf 276 is configured to direct the web forwardly towards the front portion of the dispenser as shown. Optionally provided are ridges 277. A cutting blade is here again disposed below the dispensing nips and above lower shelf 276 of dispensing chute 274. So also, the rack at 268 is preferably an internal gear rack having a radius of curvature upwardly into the enclosure and configured to engage pinion 256 along a lower circumferential position at 268 with respect to an axis of rotation 280 of pinion 256. The one-way clutch bearing 275 is preferably a one-way clutch needle bearing as noted above and the construction and arrangement of chute 274 and the press bar assembly are as described above in connection with dispenser 10.

(52) In FIGS. 12 through 25 still yet another dispenser 310 includes a housing 312 having a front housing portion 312a and a back housing portion 312b and framework 316 that supports and encases a pair of rolls 314a, 314b side by side (FIG. 13). The rolls each preferably consist of a continuous web of sheet material such as paper toweling, but could be tissue, napkins or other materials that can be easily rolled for subsequent dispensing. Roll supports 318a, 318b engage roll cores 319a, 319b to support the rolls for free rotation (FIG. 13). Feed rollers 320a, 320b and pinch rollers 322a, 322b extend across the front of the housing for dispensing sheet material to the user. An actuator unit 323 having a casing 324 and an actuator 326 is secured inside one sidewall 327 of housing 312 (FIGS. 12-14).

(53) Casing 324 includes a pair of molded side members 328a, 328b that each forms half of a container for the actuator. The side members preferably include a plurality of coupling members 330a, 330b that interconnect to hold the side members securely together. Coupling members 330a extend between the side members 328a, 328b and define apertures for receiving complimentary stem-shaped coupling members 330b. An adhesive preferably secures coupling members 330b within coupling members 330a. Nevertheless, other coupling members and other constructions for interconnecting the side members could be used. At least one pair of the interconnected coupling members 330, and preferably two spaced apart pairs of interconnected coupling members, extend across a mid-portion of the casing to at least partially define guides 332a, 332b to, as described below, provide the push arm with enhanced stability and support.

(54) Casing 324 defines an opening 334 along its front side to receive therethrough a contact portion 335 of push arm 336 (FIGS. 12, 16 and 23). Push arm 336 includes a pivot hole 338 that is preferably received over one other of the interconnected coupling members 330 defining a pivot pin 340. A bushing 342 is preferably received over pivot pin 340 for easier swinging of push arm 336 (FIG. 17). Alternatively, the pivot pin could be formed by other means extending between the side members 328a, 328b. The exterior contact portion 335 projects out the front wall 346 of housing 312 to be operated by the user (FIG. 12). The front face 348 of contact portion 335 is preferably angled outward or provided with a concave curve that extends outward along the bottom to provide an enhanced support for the user and an easy, ergonomical front surface for pushing the push arm inward. Nonetheless, front face 348 could have other shapes if desired.

(55) Push arm 336 further includes at least one slot, and preferably two spaced apart slots 350a, 350b, for receiving guides 332a, 332b (FIGS. 16-18). As the push arm swings inward under pressure by the user, guides 332a, 332b slide along the length of slots 350a, 350b. The guides, then, stabilize the motion of the push arm for a more even swinging action so that the push arm is unlikely to stick, become jammed, or break. The provision of the guides within the slots helps to support the push arm and lessen the stresses that may develop within the push arm during use. While using guides such as those shown at 332a, 332b is preferred for economy and ease of manufacture, the guides could be formed by other means.

(56) In the preferred construction, push arm 336 also includes an elongated opening 354 for receiving a spring 356 (FIG. 14). More specifically, spring 356 is attached to a hook 358 fixed to push arm 336 at the rear end of opening 354 and a hook 360 fixed to side member 328a (or side member 328b). When push arm 336 is depressed, spring 356 is stretched to bias the push arm back to its projecting rest position for another actuation. The spring could be positioned elsewhere within casing 324 so long as it naturally biases the push arm to the projecting rest position when the user releases the push arm.

(57) Push arm 336 is preferably hollow to receive therein a support 362 for a drive gear 364 (FIG. 15 and following). In the preferred construction, support 362 is stabilized by guides 332a, 332b and a driveshaft 366. As seen in FIG. 17, guides 332a, 332b, in a preferred construction, are slightly undersized relative to slots 350a, 350b because support 362 is received over the guides and fill the clearance between the guides and slots.

(58) Drive gear 364 is exposed along the bottom of support 362 to engage a rack 368 fixed to push arm 336. In the rest position of push arm 336, drive gear 364 engages the rear end of rack 368 (FIG. 14). As the push arm is depressed, rack 368 translates rearward to rotate drive gear 364. Drive gear 364 is secured to driveshaft 366 via a conventional one-way bearing 363. The one-way bearing rotates driveshaft 366 with drive gear 364 when the push arm 336 is depressed, but permits the drive gear to rotate freely on driveshaft 366 when the push arm moves forward under the bias of spring 356. Such bearings are available from INA (Germany), a suitable bearing being INA Model No. HFZ 040 708E as noted above. Other one-way bearings are disclosed in U.S. Pat. No. 4,635,771 to Shoji et al., U.S. Pat. No. 5,655,722 to Muckridge, and U.S. Pat. No. 6,336,542 to Mintonye, II, all of which are herein incorporated by reference. Other orientations of the drive gear and rack are possible. A rear stop 365, preferably composed of rubber or other elastomer, is secured to side member 328a (or 328b) to abut the push arm and define a fixed end to its swinging motion when depressed. Similarly, a front stop 367 abuts a ledge 369 on push arm to set the projection, rest position for push arm 336.

(59) Driveshaft 366 is coupled to drive stem 370 so that the drive stem rotates with the driveshaft. Specifically, in the preferred construction, drive stem 370 includes a hole 371 for receiving one end 373 of driveshaft 366. Detents 372 on driveshaft 366 are received within pockets 374 adjacent hole 371. A cap 380 is secured to the base 382 of drive stem 370 to hold detents 372 in pockets 374 and prevent release of driveshaft 366 from drive stem 370. A groove 384 is formed on the free end of driveshaft 366 for receiving a clip 386 for securing the driveshaft to support 362. One end 391 of an elongate shaft 392 for driving the feed rollers is fit over drive stem 370 and secured thereto by a press pin 389 in hole 395 and a corresponding hole 402 in the elongate shaft 392 (FIG. 15). Nevertheless, other coupling arrangements could be used.

(60) Casing 324 and actuator 326 define a self-contained actuator unit 400 that can be easily assembled into housing 312 for an easy, quick and economical manufacture of the dispenser (FIGS. 23-25). Specifically in the preferred construction, the outer sidewall 328b of casing 324 defines a T-shaped groove 394 that slideably receives a complementary tongue 399 formed on the inner surface of sidewall 327 when the casing is inserted into the housing to hold the casing against sidewall 327; although the groove and tongue could be reversed, replaced with grooves and tongues having other shapes (e.g., dovetail) so long as their interconnection holds the casing to the housing, and/or moved to hold the casing to a different part of the housing. In any event, the casing is simply slid into the housing to preliminarily retain the actuator unit within the housing. A rib is preferably provided along a bottom portion of housing 312 to ensure proper positioning of the casing 324. A single screw (not shown) passed through housing 312 and secured within opening 397 on a rear side of the casing is all that is needed to hold the casing within housing 312. Nonetheless, two additional screws are preferably passed through holes 397 to secure the casing to framework 316 (FIGS. 24, 25). Further, additional screws, screws extending through sidewall 327 or other parts of the housing, other latching means, and/or other fasteners could be used to secure casing 324 within housing 312. The separate construction of actuator unit 400 and then fitting the actuator unit as a whole into the housing is easier, quicker and cheaper than assembly of the various components individually to the housing framework.

(61) Once the actuator unit is secured in the housing, the elongate shaft 392 can be coupled to the drive stem 370.

(62) The successive operation of feed rollers 320a, 320b by the elongate shaft is as disclosed in U.S. Pat. No. 4,260,117 to Perrin et al., which is hereby incorporated by reference. In general, elongate shaft 392 extends across the front of the dispenser within feed rollers 320a, 320b (FIGS. 13, 15). A spool 401 (FIG. 13) is encompassed about elongate shaft 392 in a central location between feed rollers 320a, 320b. The spool is secured to the elongate shaft so that the spool rotates with the elongate shaft, but can axially move along the elongate shaft. Spool 401 has teeth 403a, 403b on either end that selectively engage complementary teeth 405a, 405b on the end of either feed roller 320a, 320b. The spool shifts axially along elongate shaft 392 so that the spool engages only one of the feed rollers at a time. With spool 401 engaged with, for example, feed roller 320a, rotation of elongate shaft 392 (by depression of push arm 336) drives feed roller 320a to dispense a length of the paper (depending on the extent of the depression of the push arm). This action continues until roll 314a is exhausted.

(63) Cores 319a, 319b of rolls 314a, 314b are each split so as to break apart and fall out of roll supports 318a, 318b when the sheet material is exhausted. A spring-biased paddle 407a, 407b is biased to set against each roll 314a, 314b until the roll is depleted. Once the roll is depleted, the paddle will break the core apart if it does not split apart naturally. A lower portion of each paddle 407a, 407b includes a cam that pushes spring-biased arms 409 coupled to spool 401 between first and second positions. In particular, the arms are shifted past an over-center position as they move from one position to the other. In this way, the arms stay in either position until moved by one of the paddles 407a, 407b. The shifting of arms 409 functions to move spool 401 into engagement with either feed roller 320a or feed roller 320b.

(64) Accordingly, in one example arms 409 are in a first position with spool 401 engaged with feed roller 320a. Depression of push arm 336 causes rotation of drive gear 364. The one-way bearing supporting the drive gear causes rotation of driveshaft 366, which via drive stem 370, rotates elongate shaft 392. The elongate shaft rotates spool 401, which in turn rotates feed roller 320a for dispensing the sheet material. The rotation ends when depression of the push arm is stopped, i.e., typically when the push arm abuts rear stop 365 (FIG. 19). Dispensing of the sheet material in this way continues until roll 314a is exhausted. At this time, core 319a falls or is pushed out of supports 318a and paddle 407a moves downward and shifts arms 409 to its second position. This movement of the arms causes spool 401 to shift from its engagement with feed roller 320a to engagement with feed roller 320b. The dispenser, then, dispenses sheet material from roll 314b until it is exhausted. During the time sheet material is dispensed from roll 314b, a maintenance worker will place a new roll in roll supports 318a to be ready for dispensing when roll 314b is exhausted. In this way, transfer of the feeding operation from one roll to the other can be accomplished in a reliable and easy manner. The users, then are not frustrated with having no sheet material to use until the next maintenance time. Moreover, the maintenance worker is not required to waste the end portions of the rolls by replacing the rolls early.

(65) When the web is dispensed from, for example, roll 314a (or roll 314b) it passes from the gap between feed roller 320a and pinch roller 322a, through discharge chute 411 and out of housing 312. The discharge chute 411 preferably has a generally C-shaped configuration with an upstream segment 413 that extends downward and rearward from feed roller 320a, and a second segment 415 that extends downward and forward. A cutting blade 421 (FIG. 14) is provided at the inner apex 423 of discharge chute 411 to sever the continuous web into a discrete sheet length for use by the operator of the dispenser. Specifically, when the user pulls on the free end of the dispensed web, the web is pulled taut and against the cutting blade to sever the free end length from the continuous web as noted in connection with the embodiment described above. The position of cutting blade 421 also operates to prevent the user from simply pulling the sheet material from the dispenser once a free end of the sheet material is exposed. In the preferred construction, the blade forms the only means for preventing direct pulling of the sheet material from the dispenser. This is an easy, reliable means, without moving parts, by which to prevent direct pulling by the user. As discussed above, the use of an actuator to feed out a certain length of the toweling tends to limit the usage of the sheet material and minimize waste and abuse of the dispenser.

(66) The C-shaped discharge chute 411 also prevents access to the feed rollers by a user. The position of the cutting blade 421 at the apex of the chute further functions to inhibit one from reaching into the dispenser. Hence, the risk of contamination of the feed rollers is low. While, the cutting blade is preferably the only means for preventing directly pulling of the sheet material from the dispenser, anti-milking means such as disclosed in the '117 patent, or alternatively other means, could be used in addition or in lieu of the cutting blade. If other means are used to inhibit pulling of the paper from the dispenser, the cutting blade could be oriented differently in the dispenser.

(67) While the invention has been described in connection with numerous embodiments, modifications thereto within the spirit and scope of the appended claims, will be apparent to those of skill in the art.