US3821875A - Container sealing apparatus - Google Patents

Container sealing apparatus Download PDF

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Publication number: US3821875A
Authority: US; United States
Prior art keywords: conveyor; container; containers; frame; flap portions
Prior art date: 1973-02-15
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.): Expired - Lifetime

Application number

US00332693A

Other languages

English (en)

Inventor

G Paxton

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

SANGER WORKS FACTORY Inc A CORP OF

SWF Companies Inc

Original Assignee

SWF Companies Inc

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

1973-02-15

Filing date

1973-02-15

Publication date

1974-07-02

1973-02-15 Application filed by SWF Companies Inc filed Critical SWF Companies Inc

1973-02-15 Priority to US00332693A priority Critical patent/US3821875A/en

1974-01-28 Priority to GB390374A priority patent/GB1444313A/en

1974-01-28 Priority to CA191,074A priority patent/CA1002496A/en

1974-01-31 Priority to AU65053/74A priority patent/AU493477B2/en

1974-02-04 Priority to IL44128A priority patent/IL44128A/xx

1974-02-14 Priority to IT48327/74A priority patent/IT1002906B/it

1974-02-14 Priority to JP49018087A priority patent/JPS5025386A/ja

1974-02-15 Priority to DE19742407358 priority patent/DE2407358A1/de

1974-02-15 Priority to FR7405273A priority patent/FR2217217B1/fr

1974-07-02 Application granted granted Critical

1974-07-02 Publication of US3821875A publication Critical patent/US3821875A/en

1982-04-30 Assigned to SANGER WORKS FACTORY, INC. A CORP. OF CA reassignment SANGER WORKS FACTORY, INC. A CORP. OF CA ASSIGNMENT OF ASSIGNORS INTEREST. Assignors: SWF MACHINERY, INC., A CORP. OF CA

1987-03-09 Assigned to FLEET NATIONAL BANK, 111 WESTMINSTER STREET, PROVIDENCE, RHODE ISLAND 02903 A NATIONAL BANKING ASSOCIATION reassignment FLEET NATIONAL BANK, 111 WESTMINSTER STREET, PROVIDENCE, RHODE ISLAND 02903 A NATIONAL BANKING ASSOCIATION SECURITY INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: SANGER WORKS FACTORY, INC., D/B/A SWF MACHINERY, INC.

1991-07-02 Anticipated expiration legal-status Critical

Status Expired - Lifetime legal-status Critical Current

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Classifications

- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65B—MACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
- B65B7/00—Closing containers or receptacles after filling
- B65B7/16—Closing semi-rigid or rigid containers or receptacles not deformed by, or not taking-up shape of, contents, e.g. boxes or cartons
- B65B7/20—Closing semi-rigid or rigid containers or receptacles not deformed by, or not taking-up shape of, contents, e.g. boxes or cartons by folding-down preformed flaps

Definitions

An apparatus for sealing containers having u longitudinal and transverse flap portions, th tus having a conveyor for the motivation of therealong in spaced intervals; a foldin having tucking fingers and folding arm spaced relation to the conveyor and s therewith verse flap portions and the arms to fold the lon nal flap portions to overlay their res during passage along the conveyor; an adhesive a cator mounted adjacent to the folding mechanism for the application of adhesive to selected areas of the flap portions; and pressure rollers mounted ad to the applicator to fold the selected areas of the flap portions into contact with the container and to maintain such Contact during passage of the container along the conveyor until the adhesive sets.
the present invention relates to a sealing apparatus and more particularly to such a sealing apparatus which is adaptable to fold and adhesively seal containers having upstanding longitudinal and transverse flap portions and to do so with a maximum of dependability and a minimum of power and which is adjustable with a minimum of effort for the selected handling of containers of varying configurations.
a wide variety of types of container folding and sealing machines are currently in use in industry. Such conventional machines are deficient in several important respects. Many containers have upstanding flap portions which must be folded in a preselected configuration relation to each other normally with corresponding opposite flap portions folded toward each other and the other flap portions subsequently folded so as to overlay the first flap portions. This operation is conventionally done in two stages often requiring each container to be individually manipulated and reoriented as it passes along the assembly line thus slowing production. Such machines are expensive to maintain, susceptible to breakdown and wasteful of energy.
Still another deficiency existent in conventional container folding and sealing machines is the inefficient use of power to accomplish the work to be performed. Where several types of work are performed in such a machine, it is frequently the practice to utilize a different source of power for each of the types of work performed. Thus, a different motor may be employed to operate each of the conveyors used and frequently hydraulic or pneumatic manipulating systems are used for folding or gluing operations. While such a plurality of power sources may accomplish the work objectives, it is extremely inefficient and makes the apparatus susceptible to breakdown at a plurality of different points thereby multiplying the chances that shutdown will occur. Furthermore, where such a plurality of power sources is employed, the relative adjustment of the power sources for synchronous operation of the machine is often difficult and thus expensive.
a sealing apparatus capable of sealing containers 2 having upstanding flap portions which is easily and dependably adjustable to handle containers of a variety of configurations on an assembly line basis and which utilizes a single power source for synchronously driving the related work performing systems of the apparatus so as to minimize the opportunity for breakdown.
Another object is to provide such an apparatus which is adjustable for the sealing of containers of a variety of configurations and sizes.
Another object is to provide such an apparatus which is capable of performing both folding and tucking actions with respect to containers having upstanding flap portions in one synchronous operation as the containers are motivated in spaced intervals through the apparatus.
Another object is to provide such an apparatus which utilizes a single major source of power for the operation of the various related systems of the apparatus so as to minimize malfunction and breakdown.
Another object is to provide such an apparatus which utilizes a single major source of power so as to maximize the efficiency with which work is performed as containers are motivated along the apparatus.
Another object is to provide such an apparatus which has a staging mechanism for precisely positioning containers in spaced intervals during transportation through the apparatus for the synchronous perform- 7 ance of work with respect thereto.
Another object is to provide such an apparatus which is capable of performing all of its work during passage of the containers through the apparatus without the necessity of removing the containers or otherwise reorienting the containers with respect to the apparatus for the performance of the work to be done.
Another object is to provide such an apparatus which automatically applies adhesive to selected areas of the flap portions of the container and subsequently folds the areas into contact with the container maintaining pressure thereagainst during passage along the apparatus sufficient for the adhesive to set.
Another object is to provide such an apparatus which has several conveyors which may be simultaneously conditioned for the handling of containers of different sizes and shapes by means of a simple adjustment.
Another object is to provide such an apparatus which minimizes the frequency with which readjustment of the apparatus is required once initially adjusted to handle containers of different configurations and sizes.
a further object is to provide such an apparatus which is of relatively simplified construction so as to facilitate repair and adjustment of the apparatus.
a still further object is to provide such an apparatus which is of durable and dependable construction so as to maximize operating efficiency.
FIG. 1 is a side elevation of the sealing apparatus of the present invention.
FIG. 2 is a top plan view of the sealing apparatus.
FIG. 3 is a fragmentary front elevation of the apparatus with a portion thereof removed for illustrative convenience.
FIG. 4 is a fragmentary rear elevation of the apparatus.
FIG. 5 is a somewhat enlarged fragmentary top plan view of the apparatus.
FIG. 6 is a fragmentary longitudinal vertical section of the apparatus.
FIG. 7 is a fragmentary transverse vertical section taken from a position indicated by line 7-7 in FIG. 6.
FIG. 8 is a fragmentary transverse vertical section taken from a positionindicated by line 88 in FIG. 6.
FIG. 9 is a fragmentary transverse vertical section taken on line 9-9 in FIG. 1.
FIG. 10 is a fragmentary perspective view of the apparatus showing a container having upstanding longitudinal and transverse flap portions received for movement therealong.
FIG. 11 is a somewhat enlarged fragmentary longitudinal vertical section taken on line 1111 in FIG. 2.
the sealing apparatus of the present invention is generally indicated by the numeral 10 in FIG. 1.
the apparatus is adapted to handle containers or boxes 11 such as that shown in FIG. 10.
the box shown and herein described is known in the trade as aa Bliss-type cardboard box which is characterized by having one pre-cut integral blank which is scored and folded in such a manner as to provide the bottom and at least two sides for the box.
the apparatus is capable of handling a variety of types and configurations of boxes.
Each of the boxes 11 has a rectangular bottom wall 12 having a pair of upstanding opposite side walls 13 continuous therewith.
a pair of opposite end walls 14 is secured on the bottom wall and interconnects the side walls in spaced relation so as to form a receptacle 15 for the receipt of the material to be packaged I therein.
the side walls individually afford upstanding longitudinal flap portions 16.
the end walls individually mount coextensive upstanding transverse flap portions 17.
Each of the longitudinal flap portions provides a pair of oppositely extending tab portions 18.
the sealing apparatus 10 has a pair of spaced, substantially parallel upright frames or frame housings of their respective housing for engagement with the surface.
Two pair of mounting brackets 40 are affixed on the brackets of each pair of brackets on both frame housl0- ings are disposed in a pair of parallel common planes.
a screw threaded adjustment shaft 41 is threadably received in each pair of brackets extending in substantially vertical relation therebetween.
Each shaft has a remote end 42 which extends a short distance below the lower bracket of each pair of brackets.
a sprocket 43 is mounted on the remote end of each shaft for rotational movement with the shaft.
a pair of conveyor support rods 44 having opposite internally threaded ends 45 defining axes normal to the rods and upper surfaces 46, are screw threadably received on the corresponding adjustment shafts of each housing adjacent to defining an entrance end 26 on the left and an exit end 27 on the right, as viewed in FIG. 1, with work stations situated therebetween as will subsequently be more fully described.
Each of the housings has an upper surface 28 and an opposite lower edge 29.
the housings each provide spaced parallel interior and exterior walls the peripheries of which extend below the lower edge the entrance end and exit end thereof.
the support rods extend transversely of the apparatus 10 and are disposed in a common substantially horizontal plane. It will be seen that the support rods are vertically, screw threadably adjustable by the simultaneous rotation of the adjustment shafts.
Each support rod has a central threaded bore 47 extending into its upper surface.
a sealing section or stationary conveyor is generally indicated by the numberal 55 in FIG. 1 extending substantially horizontally from the entrance end 26 to the exit end 27 of the frame housings 25 extending through the work stations.
the conveyor consists of a pair of right-angled conveyor bars 56 rested in spaced parallel relation on the conveyor support rods 44 facing inwardly, as best shown in FIG. 2.
Each of the conveyor bars has a back portion 57.
the conveyor bars are secured on the support rods 44 by means of width adjustment bars 58 of selected length.
the width adjustment bars are fastened between the conveyor bars and above each of the support rods with bolts 59 screw threadably extended through the width adjustment bars and into the central threaded bore 47 of each support bar.
a pair of bolts 60 are individually received through the back portions of the conveyor bars and inwardly into the ends of the width adjustment bars so as firmly to secure the right-angled conveyor bars in the precise desired position on the support rods 44. It will be seen that through the use of width adjustment bars of the length desired the stationary conveyor 55 will always be mounted precisely centrally of the apparatus and be of the precise desired width so as to minimize the possibility for human error.
a slide bar 61 is mounted on each of the right-angled conveyor bars in a predetermined position spaced from the entrance end 26 of the frame housings 25 and extending longitudinally thereof a predetermined distance.
a plurality of idle wheel rollers 62 are rotationally secured on the back portions 57 of each of the conveyor bars in alignment throughout the entire length thereof with the exception of the area in which the slide bar is mounted.
a brace is mounted on the interior walls 30 of the frame housings 25 extending transversely therebetween inwardly spaced from the exit end 27 of the housings.
a tension sprocket 71 is rotationally mounted on the brace extending therebelow midway between the interior walls of the housings and defining a common plane with the sprockets 43.
An adjustment chain 72 is operably extended about the sprockets 43 and inwardly about the tension sprocket 71, as best shown in FIG. 2.
An adjustment handle 73 is extended upwardly from the screw threaded adjustment shaft 41 adjacent to the entrance end 26 of the housings 25. It will be seen that by rotation of the handle, the sprockets 43 are simultaneously caused to be rotated by the adjustment chain 72 to in turn correspondingly rotate all four adjustment shafts 41 so as vertically to adjust the stationary conveyor 55 on the support rods 44.
a driven conveyor, indexing mechanism, or conveying mechanism is generally indicated by the numeral 80 in FIG. 1 extending longitudinally about the stationary conveyor 55.
the mechanism affords two pairs of sprockets 81 individually secured on the interior walls 30 of each frame housing 25 adjacent to the entrance end 26 thereof in spaced vertically aligned relation.
a drive shaft 82 is rotationally mounted on the interior walls 30 so as to interconnect the frame housings 25 and extends transversely of the apparatus adjacent to the exit end 27 thereof spaced from the upper surface 28 of the housings.
a pair of enlarged drive sprockets 83 are mounted for rotation with the drive shaft in spaced relation thereon so as individually to define common vertical planes with the corresponding pairs of sprockets 81 of each frame housing.
An upper sprocket 84 is mounted on the interior wall of each frame housing in horizontal alignment with the upper sprocket of each pair of sprockets 81 and in vertically spaced relation to their respective drive sprockets 83, as best shown in FIG. 1.
a chain guide 85 is mounted on the interior wall of each frame housing extending horizontally between the top of the upper sprocket of each pair of sprockets 81 and the top of the upper sprocket 84 of that frame housing.
a conveyor chain 86 is operably extended about the pair of sprockets 81, the upper sprocket 84 and the drive sprocket 83 of each frame housing.
a plurality of flight bars 87 are mounted on the chains so as to interconnect the chains and extend transversely of the apparatus 10 in precise, predetermined spaced relation as will subsequently be more clearly described.
a delivery section or staging conveyor is generally indicated by the numeral 95 in FIG. 1 operably mounted on the frame housings 25 at the entrance end 26 thereof and defining a passage between it and the stationary conveyor 55.
a pair of mounting plates 96 each having a mounting arm 97 and a lower end 98, are mounted in spaced parallel relation on the stationary conveyor 55.
the mounting arms are attached to respective opposite ends of the conveyor support rods 44.
a roller 99 is mounted on the lower end of each mounting plate and extends outwardly therefrom so as to contact the entrance end 26 of the adjacent frame housing 25.
a staging conveyor drive shaft 105 is rotationally mounted in the mounting plates 96 extending transversely therebetween immediately adjacent to the entrance end 26 of the frame housings 25.
the shaft has a drive end 106 extending through the mounting plate outwardly thereof to the extreme left, as viewed in FIG. 9.
a drive sprocket 107 is mounted on the drive end of the shaft for rotational movement therewith.
a pair of conveyor sprockets 108 is mounted in spaced relation on the drive shaft for rotational movement therewith.
a friction wheel 109 of somewhat larger diameter than sprockets is mounted outwardly of each of the sprockets for rotational movement with the drive shaft.
a pair of guides 116 having upwardly extending portions 1 17 are connected to the drive shaft in nonrotational spaced relation.
Each guide is inwardly bent opposite to its upwardly extending portion and then upwardly bent parallel to the upwardly extending portion so as to enclose its respective conveyor sprocket 108 and friction wheel 109, as best shown in FIG. 9.
the guides extend in parallel relation to the left, as viewed in FIG. 1, away from the entrance end 26 of the frame housings 25 and have remote ends 118.
a vertically adjustable support assembly 119 having a horizontal cross bar 120, downwardly'extending adjustable legs 121, and connecting arms 122 is mounted on the entrance end 26 of the housings 25 with the cross bar in supporting relation to the remote ends 118 of the guides 116.
the assembly is connected to the housings by the arms.
the legs are engageable with the surface 32.
the cross bar affords a screw threaded bore 123 centrally thereof.
a width adjustment bar- 124 of the precise desired length is mounted on the cross bar with a bolt 125 threadably extending through the ad- I justment bar and into the central bore of the cross bar.
a pair of bolts 126 is individually screw threadably received through the guides into the opposite ends of the adjustment bar to mount the guides in the precise desired spaced relation.
a pair of sprockets 127 is individually rotationally mounted in the remote ends of the guides.
a pair of endless conveyor chains 128 are individually extended about corresponding conveyor sprockets 108 and 127, as best shown in FIG. 2.
the guides and associated sprockets, friction wheels, and conveyor chains are adjustable to and from each other after removal and replacement of the width adjustment bar, as previously described, with respect to adjustment bar 58 and by loosening of the attachment of the sprockets 108 and friction wheels so as to permit slidable movement on the drive shaft 105.
a staging mechanism is generally indicated by the numeral 130 in FIG. 1.
the mechanism includes a lever shaft 131 mounted in fixed relation on the mounting plates 96 extending therebetween parallel to the drive shaft 105.
a pair of lock rings 132 is affixed in spaced relation on the lever shaft centrally thereof.
a sleeve 133 is rotationally received about the lever shaft between the lock rings.
An angularly bent lever arm 134 is secured on the sleeve so as normally to extend upwardly therefrom spaced from the drive shaft 105, as best shown in FIG. 11 and as will subsequently be more fully described.
the remote upwardly extending end of the lever arm is of such a length so as not to extend above the friction wheels 109 of the drive shaft 105.
An adjustable bolt 135 is fastened on the lever arm so as to extend therefrom substantially tangential tov the sleeve 133.
a pair of lock rings is secured in fixed, spaced 7 relation on the drive shaft 105 in precise alignment with the lock rings 132.
a sleeve 141 is rotationally mounted on the drive shaft between the lock rings.
a stop or control plate 142 having a downwardly bent abutment end 143 and an attachment end 144, is affixed on the sleeve 141 for rotation therewith.
a tension spring 145 interconnects the remote end of the adjustable bolt 135 and the attachment end of the control plate.
a rod 146 is mounted on and extends downwardly from the control plate intermediate the sleeve and the abutment end of the control plate.
An angled flange 147 is affixed on the sleeve 133 and has a borehole 148 at the remote end thereof.
the rod is extended through the borehole and a nut 149 is threadably secured on the remote end of the rod so as to maintain the staging mechanism 130 in the relationship shown in FIG. 11.
the angled flange has an opposite end 150 remote from the borehole which contacts the sleeve 141 of the drive shaft to restrain the lever arm 134 against further clockwise rotation as viewed in FIG. 11.
a compression section or discharge conveyor is generally indicated by the numeral 155 in FIG. I mounted on the frame housings at the exit end 27 thereof defining a passage between it and the stationary conveyor 55.
the discharge conveyor has a. pair of parallel mounting plates 156, having mounting arms 157 and lower ends 158.
the mounting plates are secured at the remote ends of their mounting arms on the opposite ends of the conveyor support rod 44 adjacent to the exit end 27 of the frame housings 25.
a pair of rollers 159 is individually fastened on the lower ends of the plates so as to engage the exit ends of the frame housings.
a pair of parallel shafts 160 is affixed on the mounting plates so as to extend transversely of the discharge conveyor at the uppermost portions of the mounting plates.
An idle roller conveyor 161 is secured on the pair of shafts intermediate the mounting plates in substantial alignment with the stationary conveyor 55.
the conveyor consists of a pair of bars 162 which is individually mounted on the shafts so as to be positionalby to and from each other.
Each of the bars has a plurality of idle rollers 163 rotatably mounted thereon with their upper peripheries extending above their respective bar. Since the discharge conveyor is mounted on the conveyor support rods 44, as with the staging conveyor 95 and as previously described, use of the adjustment handle 73 simultaneously vertically adjusted the stationary conveyor 55, the staging conveyor, and the discharge conveyor.
a motor mounting plate 170 having a pivot shaft 171 extending in fixed, right angular relation therefrom, is mounted on the interior wall of the frame housing 25 on the right in FIG. 3 with the pivot shaft extending through the inner wall into the interior of the housing.
An arcuate passage 172 is provided in the interior wall spaced below the pivot shaft and substantially concentric thereto.
a split V-pulley 175 composed of two halves is affixed on the drive shaft of the electric motor within the interior of the frame housing.
the split V-pulley is spring loaded in the conventional fashion so that an increase in tension of a V-belt extended thereabout causes the halves of the pulley to separate against compression of the spring so as to reduce the operable diameter of the pulley and thereby increase the numbers of revolutions per minute supplied by the pulley to the V-belt.
a lever arm 180 is secured on the pivot shaft 171 of the mounting plate 170 inwardly of the interior wall 30 and has a control rod 181 pivotally connected to the remote end thereof, as best shown in FIG. 1.
the rod has a threaded upper end 182 which is extended through the upper surface 28 of the frame housing 25.
An internally threaded control nut 183 is rotationally mounted on the upper surface of the frame housing in screw threaded engagement with the threaded upper end of the control rod.
a second drive shaft 192 is rotationally mounted in the interior walls 30 of the frame housings 25 extending transversely therebetween parallel to the first drive shaft 82, as best shown in FIG. 1.
the second drive shaft has opposite ends 193 which extend into the interior of each of the frame housings.
a pulley 194 is secured on the opposite end of the second drive shaft within the frame housing mounting the electric motor 173.
a V-belt 195 is operably extended about the pulley and the split V-pulley 175 in driving relation.
a sprocket 196 is fastened on the other opposite end of the second drive shaft within the other frame housing for rotation with the shaft.
a pair of engaged drive gears 197 is individually mounted in driving engagement on the second drive shaft 192 and the first drive shaft 82 so as to supply power to the first drive shaft.
power is supplied from the electric motor to 0p erate the conveying mechanism which is driven off the first drive shaft by way of the pair of drive sprockets 83.
a drive sprocket 207 is affixed on the first drive shaft 82 within the frame housing 25 opposite that having the electric motor 173 mounted thereon.
a pair of tension sprockets 208 is mounted in closely spaced relation on the interior wall 30 within the same frame housing.
a drive chain 209 is operably extended about the drive sprocket 107 of the staging conveyor 95, over the tension sprockets 208 and about the drive sprocket 207, as best shown in FIG. 1.
the staging conveyor is driven from the electric motor 173 through the drive shaft 82.
a folding mechanism is generally indicated by the numeral 214 in FIG. I mounted in one of the work stations.
the folding mechanism has a pair of support housings 215 individually mounted on the upper surface 28 of the frame housings 25 in upstanding relation approximately midway between the entrance end 26 and the exit end 27 thereof.
each of the support housings is inwardly bent to define a pair of parallel mounting flanges 216 extending upwardly in vertical relation from the upper surface of the frame housing.
Mounting plates 217 are mounted in facing engagement on each support housing with the mounting flanges disposed therebetween. The plates are held securely in position by bolt assemblies 218 extending through the plates so as to bind the flanges therebetween.
each support housing provides a bearing 219 mounted centrally thereof so that both bearings of the support housings have a substantially horizontal axis extending transversely of the sealing apparatus 10.
a drive shaft 200 is rotationally received in the bearings so as to extend between the support housings.
the drive shaft has a drive end 221 extending into the interior of the support housing on the left as viewed in FIG. 3.
a drive sprocket 230 of relatively great diameter is mounted on the drive end 221 for rotation with the drive shaft 220.
Two pairs of tension sprockets 231 are mounted on the interior wall 30 of the frame housing 25 on the left as viewed in FIG. 3 in spaced relation.
a drive chain 232 is operably extended about the sprocket 196 of the first drive shaft 82, both pairs of tension sprockets 231, and about the drive sprocket 230.
the drive shaft 200 is operated by the electric motor 173 through the first drive shaft 82 and the drive chain 232.
a pair of folding arms 233 is secured on the drive shaft 220 in spaced relation extending substantially normal thereto. Each of the arms has a remote cam or arcuate folding portion 234 providing an are substantially concentric to the drive shaft.
a mounting bracket 240 is affixed on each of the support housings 215 in vertical relation extending toward the exit end 27 of the frame housings 25.
a mounting arm 241 is secured on the exit end of each frame housing extending upwardly therefrom, as best shown in FIG. 1.
Both the mounting bracket and arm of each frame housing has a plurality of vertically aligned adjustment holes 242 therein. Each hole is in horizontal alignment with the corresponding hole of the other brackets and arms.
a pair of slide supports or support bars 243 are individually mounted extending between corresponding adjustment holes 242 of the mounting brackets and corresponding holes of the mounting arms.
the support bars are secured in their respective positions by bolts 244 extending through the holes of their respective mounting arms and brackets endwise of the support bars. So mounted the support bars extend transversely of the sealing apparatus 10, as best shown in FIG. 2.
Each support bar has a central threaded bore 245.
a pair of sub frames or mounting bars 246 is mounted on the support bars 243 in predetermined spaced parallel relation extending longitudinally of the sealing apparatus 10, also as best shown in FIG. 2.
mounting bars are secured on the support bars by means of adjustable bracket assemblies 247. Precise spacing of the mounting bars is accomplished by the use of a pair of width adjustment bars 248 which, like the width adjustment bars 58 are of the precise length desired to separate the mounting bars.
the adjustment bars are individually secured transversely between the mounting bars on their respective support bars and maintained in position by bolts 249. One of the bolts of each bar is screw threadably received in the central threaded bore 245 of that support bar. The other bolts individually extend through their respective mounting bars and into the ends of the adjustment bars.
a pair of gear boxes 255 having engaged bevel gears 256 operably mounted therein in connection with the drive shaft 220, is mounted on the drive shaft in nonrotational relation spaced outwardly from the folding arms 233.
a sleeve 257 interconnects each of the gear boxes and the end of the adjacent mounting bar 246 nearest the entrance end 26 of the frame housings 25.
Each of the sleeves extends in nonrotational vertical relation therebetween.
a drive shaft 258 is rotationally received in the sleeve in driven engagement with the bevel gears 256 at one end thereof and having a lower end 259 extended downwardly through the end of the mounting bar.
a tucking mechanism or finger 260 is mounted in fixed relation on the lower end of each of the drive shafts extending normal thereto for rotation in a substantially horizontal plane.
the tucking fingers 260 and the folding arms 233 are mounted in cooperative rotational relation as will subsequently be more fully explained.
a pair of guide brackets 265 are afflxed on and extend below each of the mounting bars 246 in spaced relation.
a guide bar 266 is mounted on the downwardly extending ends of the guide brackets extending in horizontal relation in alignment with the right angled conveyor bars 56 of the stationary conveyor 55 and immediately above the conveying mechanism 80, as best shown in FIG. 6.
a guide or compression arm 267 having opposite ends 268, is fastened on each of the mounting bars 246 extending therebelow. The arms are angled downwardly as shown in FIG. 6 and are individually connected to their respective mounting bars at the end thereof nearest the entrance end 26 of the frame housings 25 by slotted pivotal connection 269 and adjacent to the other end thereof by a floating linkage 270.
Linking arms 271 are individually mounted on the guide brackets 265 adjacent to the entrance end of the frame housings and at the other of their ends to the compression arms 267 intermediate their opposite ends by pivotal connections 272.
a pair of compression spring assemblies 273 interconnect the mounting bars 246 and their respective linking arms 271 and are adapted to reduce. upward pressure against the compression arm.
a guide finger 274 is fastened on each compression arm in a position adjacent to the floating linkage and extends a short distance inwardly of the apparatus from the compression arm.
An adhesive dispensing mechanism is generally indicated by the numeral 280 in FIG. 7 mounted in one of the work stations.
the mechanism consists of a pair of adhesive containers 281, each having an extension 282 extending inwardly between the guide bar 266 and compression arm 267.
Each of the containers is mounted intermediate the compression spring assembly 273 and floating linkage 270 of the compression arm 267, as shown in FIG; 6 by connection of the extension to its respective linking arm 271.
each adhesive container is adapted for vertical floating movement with its respective linking arm.
a nozzle 283, adapted to dispense adhesive is affixed on the upper surface of the extension remote from the container.
a metering wheel 284 is operably mounted in the extension adjacent to the nozzle and adapted to contact the tab portion 18 of a box 11 being transported along the stationary conveyor 55 and to dispense adhesive through the nozzle during such contact.
a heating unit 285 is fastened on the adhesive container and connected to a source of power, not shown, adapted to heat adhesive received within the container to .a selected optimum temperature.
a compression roller assembly 290 is mounted on each of the mounting bars 246 above the discharge conveyor 155.
Each of the roller assemblies mounts a plurality of pressure rollers 291 extending downwardly therefrom in parallel relation in approximate individual vertical alignment with the adjacent bar 162 of the idle roller conveyor 161 and slightly oblique to the intended direction of movement of the containers 11 along the stationary and discharge conveyors 55 and 155 respectively.
the sealing apparatus is most advantageously employed in an assembly line for successively sealing successive boxes 11 transported along the assembly line subsequent to being packed.
the boxes are delivered to the sealing apparatus in the configuration shown in FIG. 10 having upstanding longitudinal and transverse flap portions 16 and 17 respectively.
the boxes are delivered to the sealing apparatus oriented so that the longitudinal flap portions of the boxes are extending transversely of the apparatus as shown in FIG. 10.
the sealing apparatus is oriented with respect to the assembly line so that the staging conveyor 95 is in box receiving relation to the immediately preceding conveyor.
the electric motor 173 is operated to drive the second drive shaft 192 and the first drive shaft 82 by way of the V-belt 195.
the staging conveyor 95 is operated through the drive chain 209 to rotatethe pair of conveyor chains 128 in a clockwise direction, as viewed in FIG. 1.
the folding mechanism 214 is operated through the drive chain 232 to rotate the folding arms 233 in a counterclockwise direction as viewed in FIG. 1.
the tucking fingers 260 are rotated through the drive shafts 258 and gear boxes 255.
the tucking finger in the lower portion of FIG. 2 is rotated in a clockwise direction while the tucking finger in the upper portion of FIG. 2 is rotated in a cooperative counterclockwise direction.
the conveying mechanism 80 is driven from the first drive shaft 82 to rotate the conveyor chains 86 and interconnecting flight bars 87 in a clockwise direction, as viewed in FIG. 1.
the conveyor chains l28 motivate the boxes therealong until the lead box contacts the abutment end 143 of the control plate 142.
Timing of the passage of the boxes through the apparatus 10 is controlled by the positioning of the flight bars 87 of the rotating conveying mechanism 80.
a passing flight bar contacts the lever arm 134 and pivots the arm in a counterclockwise direction. This causes the angled flange 147 to rotate with the sleeve 133 pulling the control plate to a horizontal position allowing the box to pass over the control plate carried by the conveying mechanism 80.
the lever arm is pivotally returned to the position shown in FIG.
the forwardmost longitudinal flap portion l6 of the box contacts the compression arm 267 as the box is carried along by the flight bar.
the gradual downward slope of the compression arm causes the forwardmost longitudinal flap portion to be folded downwardly in covering relation to the receptacle.
the folding arms 233 rotating in a counterclockwise direction, as viewed in FIG. 6, contact the rearwardmost longitudinal flap portion of the box folding it forwardly in covering relation to the receptacle.
the longitudinal flap portions overlay both the receptacle and the transverse flap portions of the box.
the slope of the compression arms 267 insures that the longitudinal and transverse flap portions 16 and 17 respectively of the box are folded flat in covering relation to the receptacle 15 and securely maintained in this position.
the slotted pivotal connections 269, the floating linkages 270 and the pivotal connections 272 permit the compression arms to float upwardly and downwardly on the boxes passing therebeneath to accommodate limited variation in box height.
the tab portions 18 extend outwardly from the box as shown in dashed lines in FIG. 7.
the downward slope of the compression arms 267 at this point causes the tab portions of the box to be brought in contact with the metering wheel 284 of the adhesive dispensing mechanism 280.
Such contact causes the metering wheel to be rotated and to pump heated adhesive through the nozzle 283 from the adhesive container 281 so as to apply the adhesive to the underside of the tab portions of the box during such passage.
the guide fingers 274 contact the tab portions 18 of the box 11 after the box leaves the adhesive dispensing mechanism 280 folding them downwardly against the opposite end walls 14 of the box as passage of the box continues through the apparatus 10. At this point the box 11 passes out the exit end 27 of the frame housings 25 andonto the idle roller conveyor 16] of the discharge conveyor 155.
the compression roller assemblies 290 press the tab portions inwardly against the opposite end walls 14 of the box after having been introduced thereto by the fingers 274.
the box continues to rest on the idle roller conveyor until the next sealed container is discharged from the exit end of the frame housings and is forced against the previous box by its flight bar thereby driving the previous box farther along the discharge conveyor.
Adjustment of the sealing apparatus 10 to handle boxes 11 of different sizes and configurations is readily accomplished.
Rotation of the adjustment handle 73 causes simultaneous vertical adjustment of the stationary conveyor 55, staging conveyor 95, and discharge conveyor 155.
Adjustment of the support assembly'l9 accommodates vertical repositioning of the staging conveyor so as adequately to support the remote ends 118 of the guides 116.
Vertical adjustment of the folding mechanism 214 is accomplished by loosening the bolt assemblies 218 to loosen facing engagement of the mounting plates 217 thereby permitting vertical repositioning of the plates and associated drive shaft 220 on the mounting flanges 216.
Adjustment of the width of the stationary conveyor is accomplished by removal of the bolts 59 and in the width adjustment bars 58 and replacement of the bars with other adjustment bars to delimit the precise desired width. Subsequently, reinsertion of the bolts 59 and 60 insures precise spacing of the right angled conveyor bars 56. Similarly, adjustment of the spacing of the guides 116 and conveyor chains 128 of the staging conveyor is accomplished by removal of the bolts and 126 and replacement of the width adjustment bar 124 with a bar of the precise length desired for spacing of the guides. Since the peripheries of the rollers 163 of the discharge conveyor extend above the upper edges of the bars 162 on which they are mounted, spacing of the bars need not be performed although it can be readily accomplished by simply sliding the bars on the shafts 160. The positioning of the central threaded bore 47 on the upper surface 46 of the conveyor support rods 44 and of the threaded bore 123 of thecross bar 120 insures that the stationary conveyor and staging conveyor respectively will be positioned precisely centrally of the apparatus 10.
bracket assemblies 247 are then loosened to allow repositioning of the mounting bars with the adjustment bars 248 disposed therebetween.
the bolts 249 are then reinserted so as to mount the adjustment bars in position insuring that the mounting bars are the precise desired distance apart and are mounted centrally extending longitudinally between the frame housings 25.
the bracket assemblies 247 are then again tightened.
the container sealing apparatus of the present invention efficiently and dependably folds and seals containers having upstanding flap portions as they are motivated along an assembly line, is quickly adjustable to permit the folding and sealing of containers of different configurations and sizes while minimizing the danger of improper adjustment, and utilizes a single source of power and simplified work systems so as to minimize malfunction and breakdown.
An apparatus for sealing containers having upstanding flap portions comprising a substantially horizontal stationary conveyor adapted to permit containers to be motivated therealong; means mounted in spaced relation to the conveyor for successively folding said flap portions of each container in overlapping, sealing relation to the container; a drive mechanism mounted on the apparatus synchronizing the movement of containers along the conveyor at predefined intervals cooperative with the folding means to permit the folding means to contact and fold the flap portions of each container during the interval said container passes between the folding means and the conveyor, said drive mechanism including a driven conveyor mounted on the apparatus extending longitudinally of the stationary conveyor, said driven conveyor mounting bars transversely thereof predetermined distances apart adapted to motivate the containers over the stationary conveyor between the stationary conveyor and the folding means; said stationary conveyor being mounted on the apparatus on adjustment shafts for vertical adjustment with respect to the driven conveyor and the folding means to permit adjustment of the apparatus for the folding and sealing of containers of a different selected size; said folding means including a guide and a folding arm individually cooperatively mounted on the apparatus above the driven conveyor for folding the forward and rearward upstanding flap portions of each
An apparatus for sealing preformed containers having upstanding longitudinal and transverse flap portions, the longitudinal flap portions having laterally extending tab portions comprising a frame; a stationary conveyor mounted on the frame for vertical adjustment, having entrance and exit ends and adapted to permit the transport therealong of the containers oriented so that their longitudinal flap portions extend transversely of the apparatus; an endless driven conveyor mounted on the frame for movement longitudinally about the stationary conveyor and having flight bars extending transversely thereof at predetermined intervals; a folding arm mounted on the frame above the stationary conveyor adapted for the completion of a downward sweep toward the stationary conveyor corbar so as to contact and fold the rearwardmost longitudinal flap portion so as to overlay its respective container; a pair of guides secured on the frame in transversely spaced relation between the folding arm and the exit end of the conveyor adapted to contact and fold the forwardmost longitudinal flap portion so as to overlay its respective container; a pair of tucking fingers mounted in transversely spaced relation in the frame for cooperative rotational movement with the folding arm adapted to fold the transverse flap portions of each container inward
a container sealing apparatus adjustable to accommodate containers of different sizes and configurations comprising a frame, an elongated conveyor mounted substantially horizontally in the frame for adjustable elevational movement in positions of parallelism, slide supports mounted in the frame substantially horizontally transversely of the conveyor, sub frames mounted on the slide supports on opposite sides of the conveyor for adjustable spacing, and container closing and sealing means individual to the sub frames adjustably spaced by adjustable spacing of the sub frames to accommodate containers of different widths and the responding with the passage therebelow of each flight conveyor being adjustable to accommodate containers of different thickness.
a container sealing apparatus adjustable to accommodate containers of different sizes and configurations ocmprising a frame, an elongated conveyor mounted substantially horizontally in the frame for adjustable elevational movement in positions of parallelism, slide supports mounted in the frame substantially horizontally transversely of the conveyor.
sub frames mounted on the slide supports on opposite sides of the conveyor for adjustable spacing, container closing and sealing means individual to the sub frames adjustably spaced by adjustable spacing of the sub frames to accommodate containers of different widths and the conveyor being adjustable to accommodate containers of different thickness, a supply conveyor aligned with said elongated conveyor, means connecting an end of the supply conveyor to said elongated conveyor for elevational movement therewith, a compression conveyor aligned with said elongated conveyor, and means connecting an end of the compression conveyor to said elongated conveyor for elevational movement therewith.
a container sealing apparatus adjustable to accommodate containers of different sizes and configurations comprising a frame, an elongated conveyor mounted substantially horizontally in the frame, slide supports mounted in the frame substantially horizontally transversely of the conveyor, sub frames mounted on the slide supports on opposite sides of the conveyor for adjustable spacing, and container closing and sealing means individual to the sub frames adjustably spaced by adjustable spacing of the sub frames to accommodate containers of different widths.
the container closing and sealing means includes top flap closing guides individual to the sub frames mounted for individual floating movement on said sub frames automatically to accommodate containers of mixed thickness.
the apparatus of claim 12 including a dispensing mechanism mounted on at least one of the top flap closing guides for floating elevational movement therewith adapted to apply adhesive to containers of mixed thickness accommodated by the guides.
the apparatus of claim 13 having means mounting the conveyor in the frame for adjustable elevational movement in positions of parallelism to accommodate containers of different thickness.
the apparatus of claim 14 including a supply conveyor aligned with said elongated conveyor, means connecting an end of the supply conveyor to said elongated conveyor for elevational movement therewith, a compression conveyor aligned with said elongated conveyor, and means connecting an end of the compression conveyor to said elongated conveyor for elevational movement therewith.
An apparatus for sealing preformed containers having upstanding longitudinal and transverse flap portions, the longitudinal flap portions having laterally extending tab portions comprising a frame; an elongated substantially horizontal conveyor mounted on the frame having entrance and exit ends and adapted for the transport therealong of the containers oriented so that their longitudinal flap portions extend transversely of the apparatus; a folding arm mounted on the frame above the conveyor for reciprocal movement between an upwardly retracted position and a lower flap closing position operated synchronously with the passage therebelow of each container so as to contact and fold the rearwardmost longitudinal flap portion of each container so as to overlay its respective container; a pair of guides secured on the frame in spaced relation transversely of the conveyor between the folding arm and the exit end of said conveyor adapted to contact and fold the forwardmost longitudinal flap portion of each container so as to overlay its respective container; and a pair of tucking fingers mounted in the frame in spaced relation transversely of the conveyor for synchronous movement with the folding arm adapted to fold the transverse flap portions of each container inwardly under the longitudinal
An apparatus for sealing preformed containers having upstanding longitudinal and transverse flap portions, the longitudinal flap portions having laterally extending tab portions comprising a frame; an elongated substantially horizontal conveyor mounted on the frame having entrance and exit ends and adapted for the transport therealong of the containers oriented so that their longitudinal flap portions extend transversely of the apparatus; a folding arm mounted on the frame above the conveyor for reciprocal movement between an upwardly retracted position and a lower flap closing position operated synchronously with the passage therebelow of each container so as to contact and fold the rearwardmost longitudinal flap portion of each container so as to overlay its respective container; a pair of guides secured on the frame in spaced relation transversely of the conveyor between the folding arm and the exit end of said conveyor adapted to contact and fold the forwardmost longitudinal flap portion of each container so as to overlay its respective container; a pair of tucking fingers mounted in the frame in spaced relation transversely of the conveyor for synchronous movement with the folding arm adapted to fold the transverse flap portions of each container inwardly under the longitudinal flap portions during
Col. 7 lines 44 and 45, after "vertically” and before “the” delete "adjusted” fand insert ---adjusts-- I Col. 9, line 11, after “shffl'and before “is” delete "200” and insert ---22o- Col. 13, lines 15 and 16, after "assembly” and before “accommodates” delete "l9” and insert --ll9---.

Landscapes

Engineering & Computer Science (AREA)
Mechanical Engineering (AREA)
Making Paper Articles (AREA)
Closing Of Containers (AREA)
Package Closures (AREA)
Auxiliary Devices For And Details Of Packaging Control (AREA)

US00332693A 1973-02-15 1973-02-15 Container sealing apparatus Expired - Lifetime US3821875A (en)

Priority Applications (9)

Application Number	Priority Date	Filing Date	Title
US00332693A US3821875A (en)	1973-02-15	1973-02-15	Container sealing apparatus
GB390374A GB1444313A (en)	1973-02-15	1974-01-28	Container sealing apparatus
CA191,074A CA1002496A (en)	1973-02-15	1974-01-28	Container sealing apparatus
AU65053/74A AU493477B2 (en)	1973-02-15	1974-01-31	Container sealing apparatus
IL44128A IL44128A (en)	1973-02-15	1974-02-04	Container sealing apparatus
JP49018087A JPS5025386A (de)	1973-02-15	1974-02-14
IT48327/74A IT1002906B (it)	1973-02-15	1974-02-14	Apparecchio per piegare le falde e chiudere scatole a falde pieghevoli
DE19742407358 DE2407358A1 (de)	1973-02-15	1974-02-15	Behaelter-verschliessvorrichtung
FR7405273A FR2217217B1 (de)	1973-02-15	1974-02-15

Applications Claiming Priority (1)

Application Number	Priority Date	Filing Date	Title
US00332693A US3821875A (en)	1973-02-15	1973-02-15	Container sealing apparatus

Publications (1)

Publication Number	Publication Date
US3821875A true US3821875A (en)	1974-07-02

Family

ID=23299423

Family Applications (1)

Application Number	Title	Priority Date	Filing Date
US00332693A Expired - Lifetime US3821875A (en)	1973-02-15	1973-02-15	Container sealing apparatus

Country Status (8)

Country	Link
US (1)	US3821875A (de)
JP (1)	JPS5025386A (de)
CA (1)	CA1002496A (de)
DE (1)	DE2407358A1 (de)
FR (1)	FR2217217B1 (de)
GB (1)	GB1444313A (de)
IL (1)	IL44128A (de)
IT (1)	IT1002906B (de)

Cited By (11)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US4079577A (en) *	1977-06-21	1978-03-21	Durable Packaging Corporation	Apparatus for sealing containers
FR2370639A1 (fr) *	1976-11-15	1978-06-09	Mead Corp	Machine d'emballage
US4170095A (en) *	1978-03-27	1979-10-09	S.W.F. Machinery, Inc.	Apparatus for handling containers and the like of varying dimensions
US4317320A (en) *	1979-09-17	1982-03-02	Johns-Nigrelli-Johns, Inc.	In-line carton slitting, flap folding and flap gluing apparatus
US4744195A (en) *	1986-11-25	1988-05-17	Reed Gerald W	Apparatus for discriminately treating containers and the like
US4815252A (en) *	1987-01-02	1989-03-28	Box-O-Matic, Inc.	Random size carton sealer
WO1991010594A1 (en) *	1990-01-19	1991-07-25	Ab Matfors Hydraulservice	A method and an arrangement to form a package for paper pulp bales by wrapping, folding and glueing
US5807223A (en) *	1995-06-07	1998-09-15	Sanger Works Factory, Inc.	Container forming method and apparatus
US20030070400A1 (en) *	2001-10-17	2003-04-17	Pitney Bowes Incorporated	Envelope moistener with temperature adjusting apparatus
US20110065559A1 (en) *	2009-09-14	2011-03-17	Thiele Technologies, Inc.	Systems, apparatuses, and methods for forming a container
US11186398B2 (en)	2019-08-06	2021-11-30	United States Gypsum Company	Automated carton closing and conveying device

Families Citing this family (2)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
FR2596634B1 (fr) *	1986-04-07	1988-05-06	Arques Verrerie Cristallerie	Recipient isotherme en verre
CN103158278B (zh) *	2013-01-15	2015-01-21	浙江大胜达包装有限公司	瓦楞线胶带实时自动封边专用设备及生产方法

Citations (5)

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Publication number	Priority date	Publication date	Assignee	Title
US1815571A (en) *	1926-11-30	1931-07-21	Standard Knapp Corp	Carton sealing machine
US3187483A (en) *	1960-12-01	1965-06-08	Packaging Corp America	Carton sealing apparatus
US3237364A (en) *	1961-09-29	1966-03-01	Clifford R Mack	Method of packaging articles in a tube
US3426502A (en) *	1965-09-16	1969-02-11	Nat Equip Corp	Box-treating apparatus
US3623293A (en) *	1966-12-08	1971-11-30	Textron Inc	Carton flap closing mechanism

1973
- 1973-02-15 US US00332693A patent/US3821875A/en not_active Expired - Lifetime
1974
- 1974-01-28 CA CA191,074A patent/CA1002496A/en not_active Expired
- 1974-01-28 GB GB390374A patent/GB1444313A/en not_active Expired
- 1974-02-04 IL IL44128A patent/IL44128A/xx unknown
- 1974-02-14 JP JP49018087A patent/JPS5025386A/ja active Pending
- 1974-02-14 IT IT48327/74A patent/IT1002906B/it active
- 1974-02-15 FR FR7405273A patent/FR2217217B1/fr not_active Expired
- 1974-02-15 DE DE19742407358 patent/DE2407358A1/de not_active Ceased

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US1815571A (en) *	1926-11-30	1931-07-21	Standard Knapp Corp	Carton sealing machine
US3187483A (en) *	1960-12-01	1965-06-08	Packaging Corp America	Carton sealing apparatus
US3237364A (en) *	1961-09-29	1966-03-01	Clifford R Mack	Method of packaging articles in a tube
US3426502A (en) *	1965-09-16	1969-02-11	Nat Equip Corp	Box-treating apparatus
US3623293A (en) *	1966-12-08	1971-11-30	Textron Inc	Carton flap closing mechanism

Cited By (14)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
FR2370639A1 (fr) *	1976-11-15	1978-06-09	Mead Corp	Machine d'emballage
US4079577A (en) *	1977-06-21	1978-03-21	Durable Packaging Corporation	Apparatus for sealing containers
US4170095A (en) *	1978-03-27	1979-10-09	S.W.F. Machinery, Inc.	Apparatus for handling containers and the like of varying dimensions
US4317320A (en) *	1979-09-17	1982-03-02	Johns-Nigrelli-Johns, Inc.	In-line carton slitting, flap folding and flap gluing apparatus
US4744195A (en) *	1986-11-25	1988-05-17	Reed Gerald W	Apparatus for discriminately treating containers and the like
US4815252A (en) *	1987-01-02	1989-03-28	Box-O-Matic, Inc.	Random size carton sealer
WO1991010594A1 (en) *	1990-01-19	1991-07-25	Ab Matfors Hydraulservice	A method and an arrangement to form a package for paper pulp bales by wrapping, folding and glueing
US5807223A (en) *	1995-06-07	1998-09-15	Sanger Works Factory, Inc.	Container forming method and apparatus
US5876319A (en) *	1995-06-07	1999-03-02	Delaware Capital Formation, Inc.	Container forming method and apparatus
US20030070400A1 (en) *	2001-10-17	2003-04-17	Pitney Bowes Incorporated	Envelope moistener with temperature adjusting apparatus
US6708467B2 (en) *	2001-10-17	2004-03-23	Pitney Bowes Inc.	Envelope moistener with temperature adjusting apparatus
US20110065559A1 (en) *	2009-09-14	2011-03-17	Thiele Technologies, Inc.	Systems, apparatuses, and methods for forming a container
US8323165B2 (en)	2009-09-14	2012-12-04	Thiele Technologies, Inc.	Method for forming a container
US11186398B2 (en)	2019-08-06	2021-11-30	United States Gypsum Company	Automated carton closing and conveying device

Also Published As

Publication number	Publication date
FR2217217B1 (de)	1978-07-07
DE2407358A1 (de)	1974-08-22
FR2217217A1 (de)	1974-09-06
GB1444313A (en)	1976-07-28
JPS5025386A (de)	1975-03-18
IL44128A0 (en)	1974-05-16
IT1002906B (it)	1976-05-20
IL44128A (en)	1976-10-31
CA1002496A (en)	1976-12-28
AU6505374A (en)	1975-07-31

Legal Events

Date

Code

Title

Description

1982-04-30

AS

Assignment

Owner name: SANGER WORKS FACTORY, INC. A CORP. OF CA

Free format text: ASSIGNMENT OF ASSIGNORS INTEREST.;ASSIGNOR:SWF MACHINERY, INC., A CORP. OF CA;REEL/FRAME:003979/0939

Effective date: 19820413

1987-03-09

AS