The present invention relates to embodiments of an apparatus and method for dispensing elongated material, such as tape, from a roll of the material and a method for automatically splicing the tail portion of one material, such as tape, to the leading portion of another from a set of cascaded staged rolls of material.
Modern consumer and industrial packaging often includes reinforcing tapes or tear tapes as part of their construction. Various tape dispensers have been devised to dispense such tapes into corrugator and packaging equipment. Over the years, various methods have been introduced to increase the efficiency and speed of these tape dispensing systems.
For example, one way to increase efficiency is to increase the size of the tape rolls being used. By using “oversized” or large rolls of material the amount of tape that can be dispensed before needing to stage additional rolls can be increased. However, these oversized rolls of material typically weigh more than 40 pounds, which exceeds the weight that many companies allow workers to safely handle or lift and may exceed the weight restrictions regulated by the government. In such cases, the material would be required to be handled by a mechanical lifting apparatus when movement or staging is required. For example, Marotech, a Canadian company, has a two-tape system called MaroCrate™. The system provides rolls of material that weigh approximately 100 pounds each. This system is described in more detail in Canadian Patent 2,447,498 and U.S. Pat. No. 7,121,497.
In addition, because of the increased inertia, larger rolls are harder to accelerate and stop. Moreover, these larger rolls experience excessive tension during acceleration and tape overrun during braking. During splicing with the current MaroCrate™ technology, operators must slow the corrugator to approximately 600 feet per minute to prevent splice failures and even at that speed, roll-to-roll splice failures can occur.
Another limitation to using relatively large rolls of material is that if a quality defect is found on one of these large material rolls, the scrap or waste factor potential increases dramatically.
Other systems include one or more staged rolls to increase efficiency and reduce down-time of the machine. For example, U.S. Pat. No. 4,917,327 (“the '327 patent”) to Asbury et al., the entire disclosure of which is incorporated herein by reference, discloses a system for automatically splicing together the trailing end portion of a spool, or roll, of tape to the leading end portion of a new spool of tape without interrupting the dispensing process. To prevent the tape from breaking under the strain caused by the inertia of the new spool of tape (which is initially at rest), the tape path is provided with a tension-control mechanism. In response to an increase in tension in the tape, the tension-control mechanism moves to shorten the length of the tape path, thereby relieving the increased tension in the tape. As the new spool comes up to speed, the tension-control mechanism, under the influence of a biasing mechanism, returns to its initial position to increase the path of the tape length.
Another known method of splicing the trailing end of one roll of material to the leading end of another roll of material is the multiple roll splice system known as the Adalis RPT® System, which is manufactured and sold by Adalis Corporation. The RPT® System dispensing apparatus is relatively long in length because of the required horizontal staggering of various rolls, which can be a significant disadvantage since corrugators typically have limited space available to place the tape dispensers when running.
The Adalis RPT® System approach also does not have a means to prevent the active roll of material from inadvertently and prematurely pulling a staged roll of material into motion before the active roll is depleted of tape, which can occur if an imperfection on the running tape, such as a glob of glue, catches the splicing device on the staged roll.
The present invention is directed to various embodiments of an apparatus and method for dispensing elongated material, such as tape, from a spool of such material and for auto-splicing the tail portion of one tape to the leading portion of another on cascaded staged rolls.
In one embodiment, an apparatus for dispensing elongated material from a roll of material is disclosed. The apparatus comprises a first running spool of elongated material, and at least second and third spools of elongated material. The first running spool of elongated material has a trailing end portion and a first obstacle element secured to its trailing end portion. The second spool of elongated material has a leading end portion and a first catching mechanism secured to the leading end portion. The second spool also has a trailing end portion with a second obstacle element secured to its trailing end portion. The third spool of elongated material has a leading end portion and a second catching mechanism secured to its leading end portion. A support member is configured to at least partially support and separate the leading end portions of both the second and third spools and prevent them from contacting and adhering to each other and the running spool of material. The first obstacle element is sized to engage the first catching mechanism when the first obstacle element and the first catching mechanism are brought into contact with each other, and the second obstacle element is sized to engage the second catching mechanism when the second obstacle element and the second catching mechanism are brought into contact with each other.
In one specific implementation, the apparatus further comprises a fourth spool of elongated material having a leading end portion and a third catching mechanism secured to its leading end portion. The third spool further comprises a trailing end portion with a third obstacle element secured to its trailing end portion, and the third obstacle element is sized to engage the third catching mechanism when the third obstacle element and the third catching mechanism are brought into contact with each other. The support member is configured to at least partially support the leading end portion of the fourth spool and prevent it from contacting and adhering to the leading end portion of the third spool. In another specific implementation, the support member is movable from a first position to a second position. In another specific implementation, the support member is movable from the first position to the second position by rotating the support member about a pivot member.
In another implementation, the support member further comprises at least one holding member configured to releasably hold at least one of the first catching mechanism and the second catching mechanism until the catching mechanism engages an obstacle from a preceding roll of material. In another implementation, the support member is positioned within an outer envelope, the outer envelope comprising a perimeter defined by the outer edges of the first, second, and third spools of elongate materials.
In another embodiment, an apparatus for dispensing elongated material from a roll of material is provided. The apparatus comprises a first running spool of elongated material having a trailing end portion and a first obstacle element secured to its trailing end portion; and a second spool of elongated material having a leading end portion and a first catching mechanism secured to the leading end portion. The second spool also has a trailing end portion with a second obstacle element secured to its trailing end portion. The apparatus also includes a support member configured to at least partially support the leading end portions of both the second and third spools. The support member further comprises a holding member configured to releasably hold the first catching mechanism. The first obstacle element is sized to engage the first catching mechanism when the first obstacle element and the first catching mechanism are brought into contact with each other when the first spool becomes depleted. When the obstacle engages the catching mechanism, the holding member releases the catching mechanism and allows the apparatus to dispense material from the second roll.
In specific implementations, the holding member is configured to apply a holding force to the first catching mechanism. The holding force is overcome when the first obstacle element engages the first catching mechanism. In another specific implementation, the holding member is a spring clip.
In another embodiment, an apparatus for dispensing elongated material from a roll of material is provided. The apparatus comprises a first running spool of elongated material disposed on a first spindle. The first spool has a trailing end portion and a first obstacle element secured to its trailing end portion. The apparatus also comprises a second spool of elongated material disposed on a second spindle. The second spool has a leading end portion and a first catching mechanism secured to the leading end portion. The second spool also has a trailing end portion with a second obstacle element secured to its trailing end portion. The apparatus also comprises a resisting member moveable between a first configuration and a second configuration. In the first configuration the resisting member applies a force to the second spindle to resist the rotation of the second spool of material, and in the second configuration the resisting member does not apply a force to the second spindle or applies a force that is smaller than the force applied in the first configuration. The first obstacle element is sized to engage the first catching mechanism when the first obstacle element and the first catching mechanism are brought into contact with each other to splice the material from the first roll to the material from the second roll. The pulling force of the splice is sufficient to overcome the resistance of the resisting member and allow the apparatus to dispense material from the second spool. In specific implementations, the resisting member comprises a bumper that engages with the second spindle. In other specific implementations, the resisting member is pivotable between the first configuration and the second configuration.
In another embodiment, a method of splicing elongate material in a dispenser is provided. The method comprises providing a first spool of elongate material in a first position on a dispenser, the first spool having a trailing end portion and a first obstacle element secured to its trailing end portion. The method further comprises dispensing material from the first spool and providing a second spool of elongate material in a second position, the second spool having a leading end portion and a first catching mechanism secured to the leading end portion, the second spool also having a trailing end portion with a second obstacle element secured to its trailing end portion. The method further comprises providing a third spool of elongated material having a leading end portion and a second catching mechanism secured to its leading end portion. The method further comprises placing the first catching mechanism of the second spool around material being dispensed from the first spool, and placing the second catching mechanism of the third spool around the leading end portion of the second spool. The method further comprises positioning the first and second catching mechanisms in a splicing area, the splicing area being defined by an outer envelope, the outer envelope comprising a perimeter defined by the outer edges of the first, second, and third spools of elongate materials.
In one specific implementation, the act of positioning the first and second catching mechanisms in the splicing area includes supporting the leading end portions of the second and third spools on a support member in the splicing area. In other specific implementations, the act of positioning the first and second catching mechanisms in the splicing area further comprises temporarily attaching the first and second catching mechanisms to one or more holding members on the support member.
The foregoing and other features and advantages of the invention will become more apparent from the following detailed description, which proceeds with reference to the accompanying figures.
Referring to
Apparatus 1 in the illustrated embodiment includes a frame 2. Mounted on the frame 2 for rotational movement are a first spindle 3, second spindle 4, third spindle 5, and fourth spindle 6. The first spindle 3 supports a first spool of tape 7, the second spindle 4 supports a second spool of tape 8, the third spindle 5 supports a third spool of tape 9, and the fourth spindle 6 supports the fourth spool 10 of tape. Tape from one of the first, second, third, and fourth spools 7, 8, 9, 10 is routed over a fixed roller 11, down to a tensioning roller 12 of a tension-control mechanism 13, over a fixed roller 14, down to a tensioning roller 15 of a tension-control mechanism 16, and over a fixed roller 17 and then is fed to downstream equipment (e.g., corrugator or packaging equipment), as indicated by arrow A.
In the illustrated embodiment, apparatus 1 is shown dispensing tape from the first spool 7. When the tape from the first spool 7 is depleted, the trailing end portion of the tape from the first spool 7 can be spliced to the leading end portion of the tape from the second spool 8; when the tape from the second spool 8 is depleted, the trailing end portion of the tape from the second spool 8 can be spliced to the leading end portion of the tape from the third spool 9; and when the tape from the third spool 9 is depleted, the trailing end portion of the tape from the third spool 9 can be spliced to the leading end portion of the tape from the fourth spool 10 to provide a continuous feed of tape.
While tape is being dispensed from the fourth spool 10, new, full spools of tape can be loaded onto each of the third spindle 5, the second spindle 4, and the first spindle 3. The leading end portion of the tape from the new spool on the third spindle 5 can then be spliced to the trailing end portion of tape from the fourth spool 10 (which is on the fourth spindle 6); the leading end portion of the tape from the new spool on the second spindle 4 can then be spliced to the trailing end portion of tape from the new spool on the third spindle 5; and the leading end portion of the tape from the new spool on the first spindle 3 can then spliced to the trailing end portion of tape from the new spool on the second spindle 4.
After reloading the first, second, and third spindles 3, 4, 5, the system can proceed with dispensing tape from the fourth spindle 6. The tape can then be dispensed as described above, except that the tape dispenses from one spindle to another in reverse order from that described above. For example, after the tape from the fourth spindle 6 is dispensed, the trailing end portion of the tape from spool on the fourth spindle 6 can be spliced to the leading end portion of the tape from the new spool on the third spindle 5. After tape from the new spool on the third spindle 5 is dispensed, the trailing end portion of the tape from the spool on the third spindle 5 can be spliced to the leading end portion of the tape from the new spool on the second spindle 4. After tape from the spool on the second spindle 4 is dispensed, the trailing end portion of the tape from the spool on the second spindle 4 can be spliced to the leading end portion of the tape from the new spool on the first spindle 3. While tape is being dispensed from the new spool on the first spindle 3, new, full spools of tape can be loaded onto each of the second spindle 4, the third spindle 5, and the fourth spindle 6.
Thus, when there is only tape from one spool remaining, the other three spindles can receive new, full spools of tape. This process can be repeated as necessary with any number of spools.
Any suitable splicing technique can be implemented in the embodiments of dispensing apparatus described herein to splice the trailing end portion of one spool of tape to the leading end portion of a succeeding spool of tape. For example, the systems and methods disclosed herein can be used with various obstacle and obstacle catching systems and methods, which permit splicing of tape from two different spools. For example, one such obstacle and catching mechanism is disclosed in U.S. Pat. No. 4,917,327, the entire disclosure of which is incorporated herein by reference. As described in the '327 patent, the rolls of material can be spliced via an obstacle and passageway means that include a pin and loop from a piece of string or similar material. U.S. Patent Publication No. 2007/0018030, the entire disclosure of which is also incorporated herein by reference, discloses another example of an obstacle and catching system for splicing tape from two different spools together. Instead of a simple loop formed by a string, the catching mechanisms disclosed in U.S. Patent Publication No. 2007/0018030 include relatively more rigid, self-supporting materials such as plastic that may be opened or closed.
As used herein, the phrase “automatic splicing” or “automatically splicing” refers to splicing operations in which the trailing end portion of a first spool is caused to splice to the leading end portion of a second spool while substantially maintaining the rate at which tape is supplied to downstream equipment.
The tension-control mechanisms 13 and 16 (or guide members) are movable in two directions (upwardly and downwardly, as indicated by double-headed arrow B, in the illustrated embodiment) along upright rails 18, 19 to vary the path length of the tape in response to changes in tension in the tape. The tension-control mechanisms 13 and 16 are pulled downwardly by an elongated biasing member 20 and upwardly by the tension in the tape. Thus, when tape tension is high (i.e., when the current spool is providing tape slower than is required by downstream equipment, such as at the beginning of a spool), the tension-control mechanism is elevated. The upward movement of the tension-control mechanisms 13 and 16 shortens the tape path so that tape can be fed to downstream equipment without requiring the spool to dispense a corresponding length contemporaneously. Conversely, when tape tension is low (i.e., when the current spool is providing tape faster than is required by downstream equipment), the biasing member 20 causes the tension-control mechanisms 13 and 16 to assume a lower position to increase the length of the tape path.
In particular embodiments, the biasing member 20 is a piece of elastic material, such as an elastic hose (e.g., surgical tubing), although other elastic materials can be used, such as an elastic band or equivalent devices. The illustrated biasing member 20 has a first end 21 connected to the tension-control member 13 and a second end 22 secured to lever 24. Lever 24 is mounted for pivoting movement about a pivot pin 23, as indicated by double-headed arrow C.
Referring to
A similar brake assembly 33 can also be used to apply a controlled braking force to the third and fourth spindles 5, 6, respectively. The brake assembly 33 in the illustrated configuration includes a brake band 36 that extends about portions of spindles 5, 6 and serves to retard their rotation. An upper end portion 37 of the band 36 is affixed to the frame, as at 37a, and therefore is stationary. A lower end portion 38 of the band 36 is coupled to extension 39 of frame 2 by a spring 35. Spring 35 exerts a biasing force on band 36 that causes the band to apply a quiescent braking force to the spindles 5, 6. In the illustrated embodiment, for example, the spring 35 is a compression spring and is operable to push upwardly on the lower end portion 38 of band 36 to cause the band 36 to tighten around spindles 5, 6. In alternative embodiments a tension spring can be used to apply a braking force to the spindles. In addition, biasing mechanism other than springs can be used to tension the brake band around the spindles. Such biasing mechanism can include, for example, a piece of elastic material, such as an elastic band or hose, or any of various other elastic or resilient articles.
The lower end portions 27 and 38 of bands 25 and 36, respectively, are coupled to a first end portion 31 of the lever 24 by connecting members 32 and 34. Connecting members 32 and 34 can be formed of various materials and can be, for example, steel cables. The brake assemblies 30 and 33, lever 24, tension-control mechanisms 13 and 16, and biasing member 20 cooperate to form a feedback mechanism, by which the brake assemblies 30 and 26 applies a controlled braking force in response to changes in the tension in the tape. More specifically, when tape tension is high, the tension-control mechanisms 13 and 16 travels upwardly, which in turn causes a second end 22 of the lever 24 to move upwardly and the first end 31 of the lever 24 to move downwardly. This movement is coupled to the brake assemblies 30 and 33 by connecting members 32 and 34, which pulls against the springs 29 and 35, thereby reducing tension in the brake bands 25 and 36 and causing a decrease in braking force so that the dispensing of tape can be accelerated. Conversely, when tape tension is lowered, the tension-control mechanisms 13 and 16 travels downwardly under the biasing force of biasing member 20, which in turn allows the first end 31 of the lever 24 to move upwardly. This motion permits the springs 29 and 35 to reapply more tensioning force to the brake bands 25 and 36, thereby causing a corresponding increase in the braking force to reduce the rate at which tape is being dispensed.
Referring again to
As the second spool 8 accelerates to the required speed, the tension in the tape decreases, thereby allowing the tension-control mechanisms 13 and 16 to be pulled downwardly by the biasing member 20. This movement activates the brake bands 30 and 33 (
The diameter of the tape on the spool decreases as tape is removed (dispensed) from the spool. The feedback mechanism provided by the brake assemblies 30 and 33, lever 24, tension-control mechanisms 13 and 16, and biasing mechanism 20 compensates for the diametrical change of the spool by gradually decreasing the braking force to ensure substantially uniform tension during the dispensing of an entire roll. Without such a feedback system, the tension in the tape would increase in proportion to the change in radius of the spool from which the tape is dispensed.
Referring to
However, if the braking torque on a spindle is too high, the upward pulling force of the tension-control mechanisms 13 and 16 (caused by an increase in tension) may not be sufficient to overcome the spring 29 to permit the spindle to accelerate to the required speed. Hence, the braking torque desirably should be great enough to prevent over-acceleration at a desired dispensing rate without adversely affecting the ability of the system to overcome the biasing mechanism (e.g., spring 29) that retards rotation of the spindles.
In particular embodiments, the brake bands (e.g., brake bands 25 and 36) can be configured to apply a maximum braking torque of about 30 to 100 in-lbs., with 40 in-lbs. being a specific example. Embodiments having a braking torque of up to 100 in-lbs. have been found to permit splicing at dispensing rates up to about 1500 feet per minute. The ability to provide an increased braking torque is a consequence of coupling the biasing member 20 to the lever 24. More specifically, biasing member 20 pulls upwardly on the second end 22 of lever 24 when the tension-control mechanisms 13 and 16 are pulled upwardly in response to an increase in tape tension. The pulling force of biasing member 20 on the lever 24 is greater than the upward pulling force that the tape exerts on the tension-control mechanisms 13 and 16. In this manner, tension-control mechanisms 13 and 16 serves as a force divider for reducing the force that is transferred to the lever 24 from the tension-control mechanisms 13 and 16 by the biasing member 20. Hence, the mechanical advantage provided by two tension-control mechanisms 13 and 16 can be used to compensate for an increase in braking torque over prior systems.
Apparatus 1 is desirably constructed so that it is modular. Thus, one or more apparatus 1 can be positioned side-by-side, as shown in
Referring now to
In alternative embodiments, apparatus 100 can have additional dispenses mounted onto another side of frames 101 and 102. Thus, each dispenser 104 can also be mounted in a side-by-side relationship with an adjacent dispenser 104′. Components of dispensers 104′ that are identical to corresponding components of dispensers 104 are given the same respective reference numerals, except that the reference numerals for the components of dispensers 104′ are followed by an apostrophe (′). As shown in
As best shown in
As shown in
As best shown in
Biasing members 126, 126′ can be coupled to tension-control members 134, 134′, respectively, and to levers 138, 138′ in any suitable manner. As shown in
As shown in
As shown in
As best shown in
In use, tension spikes, which can occur following splicing, can transfer excessive forces to the spring 174′, causing damage or failure of the spring due to over-actuation. A stop mechanism may be provided to prevent such over-actuation of the spring. For example, a rigid sleeve can be disposed on rod 170′ between bracket 172′ and washer 176′. Compression of the spring 174′ therefore is limited to the distance between the washer 176 and the adjacent end of the sleeve. In this manner, the sleeve and washer 176′ serve as a stop mechanism to prevent over-actuation of the spring 174′.
Each dispenser 104 (104′) can have a similarly configured brake assembly, which is shown in
As shown in
Dispensers 104, 104′ can operate in a manner similar to the embodiment shown in
As shown in FIGS. 6A and 6B of U.S. Pat. No. 7,007,883 (which has been incorporated by reference herein) and described in detail in U.S. Pat. No. 7,007,883, braking systems used connection with a tension-control mechanism in a feedback system, can reduce tension in the tape paths and increase efficiency of the tape dispensing system.
Referring again to
Each bar 202 can be configured to support a leading end portion of a staged spool of tape. For example, as shown in
Catching mechanism 218 can be any kind of catching mechanism, including a loop as described in U.S. Pat. No. 4,917,327 (which has been incorporated by reference herein) or another flexible member as described in U.S. Patent Publication No. 2007/0018030 (which has also been incorporated by reference herein). Catching mechanisms 218 can be integrated with (or otherwise attached to or associated with) a leading end portion of tape from the staged spools.
The relative positions of tape from the three staged spools will now be discussed. Tape 220 from the second spool 8 is pulled (or otherwise positioned) around fixed roller 222 and then around fixed roller 224. After passing roller 224, the leading end portion of tape 220 passes over one of the extension members 204 and terminates at the catching mechanism 218 associated with tape 220. Catching mechanism 218 desirably surrounds at least a portion of tape 212. Since the leading end portion of tape 220 passes over one of the extension members 204 (desirably, the extension member positioned on the left in
Tape 226 from the third spool 9 is pulled (or otherwise positioned) around fixed roller 228 and then around fixed roller 230. After passing roller 228, the leading end portion of tape 226 passes over another of the extension members 202 (desirably, the extension member positioned in the center in
Tape 232 from the fourth spool 10 is pulled (or otherwise positioned) around fixed roller 234 and then around fixed roller 236. After passing roller 236, the leading end portion of tape 232 passes over another of the extension members 204 (desirably, the extension member positioned on the right in
When tape is being dispensed from the first spool 7 and spools 8, 9, and 10 are configured as staged (non-active) spools, the support member 200 is generally positioned at an angle from the horizontal. For example, as best seen in
Support member 200 is also preferably movable, so that the angle of the bar 202 can be adjusted. Small adjustments can be desirable to maintain proper positioning of the extension members 204 relative to the leading end portions of tape (and the related catching mechanisms 218). In addition, support member 200 is preferably movable so that the angle of the bar 202 can be reversed. Support member 200 can be movable in any manner, but is desirably rotatable about a pivot member 207.
As discussed in detail above, the dispensing apparatus shown in
In the second configuration, the angle of the bar 202 is desirably reversed from that which is shown in
Moreover, as shown in
Support member 200 is desirably positioned within either (or both) the outer envelope 223 and/or smaller outer envelope 227. By positioning support member 200 within either or both outer envelopes 223, 227 it is possible to achieve a relatively small distance from each spool to the support member 200, which not only helps reduce the likelihood that tape from the various spools will interfere with each other, it also simplifies loading of the spools onto the apparatus.
Because of the configuration of support member 200, the length of the system can be significantly reduced. By arranging the leading end portions of tape from stand-by (staged) spools on the support member 200 as described above, two rolls can be positioned underneath two upper rolls rather than spacing all four rolls horizontally along the length of the dispenser. This can result in a length reduction of approximately 50% per 4-cascade splicing station. The support member 200 supports and separates the tapes from the different rolls so that the rolls can be supported in the compact arrangement shown in
In addition, the support member 200 can be configured to support any number of leading end portions of tape from stand-by spools. Thus, as shown in
As shown in
Thus, the holding member 240 can hold catching mechanism 218 while tape 242 (which is being actively dispensed) passes through the catching mechanism 218. Holding mechanism 240 can comprise a flexible metal or plastic clip with an opening to receive the catching mechanism 218. Holding member 240 can be sized and configured such that when the catching mechanism 218 is positioned within the opening, the holding member applies an inwardly directed holding force against the sides of the catching mechanism, and the holding force holds the catching mechanism in the opening. The holding force is large enough to hold the catching mechanism 218 in place and prevent premature splicing if imperfections in the running tape 242 pass through and contact the catching mechanism 218. Such imperfections or unintentional obstacles can include, for example, glue “globs” or other irregularities that may impact the catching mechanism. In addition, it is possible that mere friction between the tape and the catching mechanism can cause the catching mechanism to move with the running tape, thereby bringing tape from the staged spool into motion.
The holding force of the holding member 240, however, desirably is less than the force that the catching mechanism 218 encounters when the active spool of tape is depleted and an obstacle impacts the catching mechanism as discussed above. Accordingly, the holding member 240 holds the catching mechanism in position upon extension member 204 until the active spool of tape 242 becomes depleted and the obstacle from the active spool of tape 242 impacts the catching mechanism 218. At that time, the catching mechanism 218 is pulled out of the holding member 240 and tape 244 from the staged spool is dispensed.
Holding member 250 comprises a catching-mechanism-receiving portion 252 and capturing elements 254. Capturing elements 254 can comprise spring members which are biased to exert a force towards the catching mechanism 218 when it is positioned in the receiving portion 252. The force of the biased capturing elements 254 is desirably sufficient to hold the catching mechanism 218 in receiving portion 252 until an obstacle impacts the catching mechanism 218 to begin dispensing tape from the next staged spool.
Another example of a holding member 255 is shown in
Thus, when a catching mechanism 218 (associated with tape 242 from the active roll) is positioned between the two inner faces of the leg portions 251, the inner faces contact and hold (at least temporarily) the catching mechanism 218 in the holding area 253. The inwardly directed force of the leg portions 251 contacting the catching mechanism 218 is desirably sufficient to hold the catching mechanism 218 in the holding area 253 until an obstacle impacts the catching mechanism 218 to begin dispensing tape from the next staged spool. When an obstacle impacts the catching mechanism 218, the catching mechanism is pulled from the holding area 254, pulling with it tape 244 from the staged spool.
Depending on the application and the amount of temporary holding force desired, the shape and number of pins (and corresponding openings) can be varied. However, as discussed above, the retaining force provided by the fit of the pin 279 into the opening 281 is desirably sufficient to hold the catching mechanism 218 on the plate 279 until an obstacle impacts the catching mechanism 218 to begin dispensing tape from the next staged spool.
Holding members, such as those discussed above, can be formed in a variety of configurations, shapes, and orientations (relative to the active tape and support member), as long as they are capable of releaseably holding the catching mechanisms. In addition, it should be understood that any number of holding members 250 can be used, and that such holding members can be used to hold some or all of the catching mechanisms present in the dispensing apparatuses disclosed herein.
In order to reduce the likelihood that an unintentional obstacle will begin drawing tape 263 from the spool 264, a rotation resisting member 270 can be positioned to apply a force to the spindle 265. The resisting member 270 can comprise, for example, an arm 271 and a bumper 272 that is biased towards the spindle 265 to frictionally engage the spindle 265 and resist rotational movement of the spindle 265. The arm 271 can be pivotably mounted to a pivot member 273. The amount of force applied to the spindle 265 by the resisting member 270 can vary, but is desirably a sufficient amount to prevent the spindle 265 from rotating (and thus dispensing tape) until the obstacle 262 engages the catching mechanism 268. Thus, if unintentional obstacles impact the catching mechanism 268, the resisting member prevents the impact of the unintentional obstacle from rotating spindle 265 and dispensing tape 263 from the staged spool 264.
The resisting member 270 can be formed in a variety of configurations and shapes, so long as they are capable of limiting or resisting rotation of a spindle until a sufficient amount of force is applied to tape of a staged spool to overcome the holding force of the resisting member 270. For example, the resisting member could be configured to apply a force to a flat surface on an end of the spindle rather than to the curved portion of the spindle as shown in
The systems and methods disclosed herein can also be used with a tension control mechanism such as that disclosed in U.S. Pat. No. 7,007,883, the entire disclosure of which is incorporated herein by reference. The '883 patent discloses a tension control method that can help to prevent the tape material from going slack when dispensing is slowed or stopped.
In view of the many possible embodiments to which the principles of the disclosed invention may be applied, it should be recognized that the illustrated embodiments are only preferred examples of the invention and should not be taken as limiting the scope of the invention. Rather, the scope of the invention is defined by the following claims. We therefore claim as our invention all that comes within the scope and spirit of these claims.
This application claims the benefit of U.S. Provisional Application No. 61/199,782, filed on Nov. 19, 2008. The entire disclosure of U.S. Provisional Application No. 61/199,782 is considered to be part of the disclosure of the following application and is hereby incorporated by reference.
Number | Name | Date | Kind |
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1464463 | Wood | Aug 1923 | A |
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Number | Date | Country |
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2447498 | Nov 2003 | CA |
Entry |
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Adalis™ Installation, Operations & Parts Manual for Adalis™ RPT System published 2002. |
Number | Date | Country | |
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20100123037 A1 | May 2010 | US |
Number | Date | Country | |
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61199782 | Nov 2008 | US |