The present disclosure relates to recycling technologies and in particular to a method and apparatus for removing glued-on labels from wine and beverage bottles and other containers for re-use.
Used wine bottles are frequently collected for recycling. However, removal of the glued-on labels is typically a labour intensive manual process that makes it difficult to re-use such bottles. It is generally not considered cost-effective to prepare such bottles for re-use by removing the labels. Instead, used containers are usually recycled by crushing, thereby resulting in a loss of economic value as well as increased energy consumption and environmental harm caused by the processes and steps involved in re-forming the crushed glass into new bottles.
Although automated systems for removing bottle labels have been proposed, the cost and difficulty of label removal from wine bottles is exacerbated by the wide variety of bottle shapes, as well as the wide variety in type, number, positioning and composition of the labels and the multiple types of adhesive used. Various mechanical or solution-based systems and devices have been proposed for this purpose, such as those disclosed in U.S. Pat. Nos. 5,679,210 and 3,946,750, and published U.S. patent application no. 2009/0255603A1.
Many vineyards, wine producers and other beverage bottling operations, in particular small-scale operations, would benefit from a relatively simple and compact device or system for removing labels from used wine bottles and other containers, in order to permit their re-use.
According to one aspect, the present invention is based on the discovery that glued-on labels on glass bottles can be efficiently removed by dry brushing, preferably with a wire brush that can remove the label without scoring the container. The remaining adhesive residue can then be removed in a subsequent solvent-applying step. The invention is directed primarily to glass containers, but may be adapted for use with other containers.
According to another aspect, the invention relates to a system for removing a glued-on label from exterior surface of a glass bottle or other container, comprising multiple stations and an indexing system for conveying used bottles between the stations in a step-wise manner between stations for sequentially performing a sequence of label-removing and cleaning steps.
According to a further aspect, the system comprises: a brushing station for removal of a substantial portion of the label by brushing (including by dry-brushing), the brushing station comprising at least one brush which may consist of a rotationally-driven cylindrical brush, such as a metal wire brush; a solvent station for applying a liquid solvent for removal of adhesive from the container, which may also comprise a brush as described above; optionally, a rinsing station for rinsing the solvent from the bottle; a container support for retaining a container; a drive for imparting relative motion between the brushes and a container when aligned with the brushing station, such as a rotary drive for the brushes and a further rotary drive for rotating the container; and an indexing system for providing relative motion between the support and said stations whereby the container is sequentially brought into alignment and contact with the brushing station and solvent station for sequential mechanical and solvent-based label removing stages. The indexing system may comprise a conveyor for conveying containers while the stations remain stationary, such as a carousel-type conveyor which conveys the bottles in a circular pattern around a series of stations arranged in a ring. The indexing system may comprise a first drive for conveying containers between the stations in a first direction of motion, and a second drive for urging the containers into the stations in a second direction of motion. In the embodiment wherein the indexing system comprises a rotating carousel comprising a plurality of bottle supports, the second drive may move the bottle supports in a radial direction to urge the containers towards the respective stations, when aligned therewith.
The terms “indexing” and “indexed” as used herein refer to a mode of operation wherein the conveyor is only in motion when the bottles are being delivered from one station to the next, and ceases movement while bottles are within respective stations for treatment. An “indexed” system is one wherein conveyor movement is step-wise and occurs in discrete increments only when shifting the bottles between stations. The spacing between stations is arranged wherein one step-wise movement of the conveyor shifts all of the bottles engaged in the system simultaneously from one station to the next, where they dwell for a predetermined and equal period of time.
In another aspect of the system, the container support permits reciprocal vertical movement of a container mounted thereon, such as a spring-loaded telescoping shaft. At least one station further comprises a reciprocating drive member for contacting said container and imparting a vertical reciprocating movement thereto when aligned with said station.
In another aspect, the indexing system comprises a rotatably driven turntable with an array of radially-extending rails or other elongate supports thereon. The container supports consist of carriages slideably secured to said supports wherein radial travel of said carriages brings said carriage into contact with one of said stations when aligned therewith. Drives are provided to both rotate the turntable in incremental fashion between the stations and to advance the carriages along the rails. Further drives may be provided with each carriage to rotate the bottles mounted thereon, for contact with the brushes and other station treatments while rotating the bottles.
In another aspect, the system includes a controller configured to incrementally advance the turntable to sequentially align the container supports with said stations, and to advance and retract the container supports radially at said stations for treatment at respective ones of said stations for a predetermined duration.
In another aspect, the bottles are pre-soaked and the initial brushing step that is performed on pre-soaked bottles. The bottles can also be subject to an internal rinse and cleansing step within a station of the system.
According to another aspect, the invention relates to a method for removing a label secured to an exterior surface of a container by adhesive, comprising the steps of loading a container onto an indexing system, which may comprise the elements described above; conveying the container in an indexed manner to a sequence of stations for sequential application of label-removing steps, comprising contacting the container with a brush and brushing at least a substantive portion of the label from the container, and applying a solvent to the exterior surface of the container and optionally the interior surface of the container for removing said adhesive and optionally other debris from the container; and optionally rinsing the container in a rinsing station. The brushing step may be performed with the bottles dry or pre-soaked.
According to another aspect of the invention, the method comprises subjecting the bottles to a preliminary soaking step to soften the label prior to the initial brushing step.
Directional and geometric references herein are generally used for convenience of description and are not intended to limit the invention, unless otherwise specified. For example, terms such as “vertical”, “circular” and the like include departures from the strict meanings of such terms unless otherwise specified.
Like reference numerals are used in the drawings to denote like elements and features.
Circular conveyor 5 comprises a turntable assembly 6, which is supported on a base 22. Base 22 comprises legs 24, horizontal supports 26 and optionally other frame elements. Legs 24 may be bolted to the workshop floor for stability. Turntable assembly 6 comprises a central solid platform 30 that is rotatably mounted to base 22, as described below. An array of six equi-spaced horizontally-disposed arms 32 project radially outwardly from platform 30 in a spoke-like fashion and connect platform 30 with a hexagonal rim 34. Arms 32 project radially outwardly past rim 34 to support a plurality of bottle holder assemblies 20 at the distal end of each arm. Rotation of turntable 6 cycles bottle holders 20 between stations 11, 12, 14, 16, 17 and 18, which are arranged in a ring around the perimeter of conveyor 5.
System 10 is described herein as comprising six container supports, which permits simultaneous processing of up to 6 bottles and results in a hexagonal configuration of conveyor 5. This configuration also permits the indexing of holders 20 with up to six stations. However, it will be seen that other configurations of the system permit a greater or less number of stations and container supports, for example a 4, 5, 7, 8 or other number of container supports and stations, with consequential alterations of the system configuration.
Base 22 comprises a central upper plate 42 and an outer rim 44. An array of horizontal arms 46 connect plate 42 with rim 44. Rim 44 is hexagonal, with a diameter greater than rotatable rim 34. Rim 44 consists of six straight segments 48, meeting at vertices 50. As seen in
Platform 30 is supported on a turntable 52, which in turn is supported on and mounted to a star-shaped spinner disk 53, seen in
Bottle holder assemblies 20, seen in detail in
Turning to the processing stations 11-18, these are each independently supported on a frame 120 that has a generally chair-like configuration, consisting of a table 122 and an upright portion 124 projecting upwardly at an end thereof, as shown in
At certain of the stations, a clamping/reciprocating mechanism 100 is provided to urge the bottle downwardly so as to clamp the container onto post 72 to prevent unwanted movement or release. Mechanism 100 is also configured to reciprocate bottle 1 vertically so as to improve the contact between the surface of the bottle and brushes 90. As seen in
In addition to the downward force for clamping the bottle, plunger 102 can also be reciprocated for moving bottle 1 in a reciprocating vertical movement, whereby downward movement is applied by plunger 102 and upward movement is driven by compression spring 78.
Operation of the ram or other actuator is controlled by central controller 400, described below.
As seen in
Frame 120 comprises a swing-arm support 130 for mounting a brush assembly and/or a liquid dispensing assembly or other bottle processing component. Support 130 comprises a pair of spaced apart horizontal arms 132, consisting of upper arm 132a and lower arm 132b. Arms 132 are connected together by vertical members 134. The proximal ends of arms 132 are pivotally mounted to frame portion 124 by hinge mounts 136. Pivotal movement of support 130 is actuated by a horizontal linear actuator (which may comprise a hydraulic or pneumatic cylinder), whereby expansion of the actuator pivots mounts 130 outwardly, and contraction thereof withdraws mount 130 towards frame portion 124.
It will be seen that although in the described embodiment the stations remain stationary while the bottle-holding system cycles the bottles, the system may also be configured such the bottle holding system remains stationary while the processing stations are transited.
The first in line station comprises a bottle loading station, wherein used bottles are loaded one at a time onto exposed posts 60 as these are presented in the station.
Next in line is brushing station 12, shown schematically in
In operation, a bottle holder 20, bearing bottle 1 in inverted position, is rotated into alignment with station 12, following which support 130 is pivoted outwardly to contact 1. At this location, bottle 1 is aligned vertically with plunger 102, which is actuated to travel downwardly to clamp bottle 1 onto post 70 to limit lateral movement. Bottle 1 is then rotated by actuating motor 84, while also rotating brush 90 in a counter-direction, thereby brushing the exterior of bottle 1 in a dry brushing process. The duration of the brushing stage and the pressure applied by brush 90 can be determined based on trial runs to determine the optimum conditions for the bottles being processed.
Brushing station 12 further comprises a vacuum nozzle 131, connected to a vacuum source and filter (not shown) adjacent to brush 90 for debris removal.
The next-in-line station comprises solvent station 14. Station 14 comprises a brush assembly 92 to provide additional mechanical scrubbing of the bottles. Station 14 further comprises at least one nozzle 138 for directing a solvent solution to brush 92 for contacting the exterior surface of the container. Nozzle 138 is connected to a pressurized source of adhesive-removal solvent, not shown. Nozzle 138 can be mounted on support 130 so as to dispense the solvent onto the brush 90 as this contacts bottle 1. Station 14 further comprises a vacuum nozzle 131.
The nature of the solvent will depend on the adhesive as well as additional considerations including economic and environmental. The solvent should be polar and/or water soluble, such that it can be fully cleansed by a water rinse. For removal of non water-soluble adhesives, a suitable solvent is “Goo Goner™”. In some cases, the label adhesive is water soluble, such that it can be removed purely with water or an aqueous solvent. Such solvents may also be used for the initial pre-soak stage described below.
Nozzle 138 is mounted to support 130, and may move upwardly or downwardly to dissolve adhesive affixing labels at different positions along the container. Alternatively, one or more nozzles 138 are mounted to frame 120.
Solvent station 14 comprises a catch basin to catch the used solvent. A conduit connects the basin to the solvent source for re-use, with a pump for pumping the solving into the source and pressurizing the solvent. A filter removes any solid debris from the solvent.
Operation of station 14 is similar to station 11, wherein a bottle 1 is introduced into station 14 and retained in position with plunger 102 whereby brush assembly 92 is brought into contact with bottle 1 The brushes and bottle are both rotated counter to each other, while solvent is dispensed onto the bottle via nozzle 138. Following this step, bottle 1 is cycled away from station 14, and into rinse station 16.
Rinse station 16 is similar in configuration to solvent station 14. One or more nozzle arrays 140 are mounted to frame 120 for directing streams of rinse water on bottle 1 when positioned in station 16. Station 16 includes a pressurized water tank connected to nozzle arrays 140, and a catch basin and filter similar to station 14. The rinse solution can be heated. Rinse solution is also sprayed into the interior of the container. For this purpose, an internal rinse nozzle (not shown) maybe provided in rinse station 16. The interior rinsing step is simultaneous with the exterior rinsing of the container. Rinse station 16 further comprises a brush assembly similar to assembly 92 to provide additional mechanical scrubbing of bottle 1.
Next-in-line from rinse station 16 is drying station 17. Station 17 may comprise heated air jets 150 for rapid drying of bottles 1.
The last in line station comprises unloading station 18, where the processed bottles are removed. The loading and unloading stations 11 and 18 may be combined into a single station. These stations may comprise merely an open space for an operator to manually load and unload bottles from the assembly.
As seen in
Lower frame 201 supports a rotating turntable assembly 220, which provides a rotating platform for bottle holders 260. As seen in
Each arm 226 supports a pair of parallel rails 230 mounted on the upper surface thereof. Rails 230 comprise supports for supporting and engaging a bottle holder assembly, as discussed below. Rails 230 are ceramic coated aluminum, resulting in a precise, smooth and friction free slidable engagement with the bottle holders mounted thereon. The distal end of assembly 226 comprises a vertical wall 236, which forms a stop member for limiting the distal travel of bottle holder assemblies 260, as will be discussed below.
Assembly 220 is rotatably mounted to lower frame 201 by a shaft rotatably journalled within a hub mounted to lower frame 201. A selectively actuated locking mechanism 244 (see
Mounted to the upper surface of base plate 262 is a circular block 274, which houses a 25 millimeter graphite plugged, bronze sleeve bearing (not shown), which permits post 280 to both rotate and move vertically with minimal impedance. Post 280 is coupled to an electric motor, not shown but similar to the configuration described in the first embodiment, wherein post 280 can reciprocate vertically while rotating freely. The upper portion of post 280 is configured for insertion into the neck of bottle 1, and is fabricated from a hard and rigid plastic (such as Delrin™). One or more O-rings 286 encircle post 280 and are relatively soft and compressible to provide a snug friction fit on the bottle. Multiple, spaced apart O-rings 286 have been found to provide a snug fit with the bottle, and to secure the bottle against tipping or misalignment while being conveyed from station to station.
In operation, turntable assembly 220 rotates in incremental fashion between the respective stations, whereby following each incremental rotation, each of arms 226 aligns with a corresponding station for processing therein. The respective processing stations are retained within a central frame 240, with the bottle carrying assemblies rotating around the exterior thereof. The initial processing station comprises brushing station 300, as seen in
A bottle mounted on a bottle holder 260 is urged against rotating brushes 302 and 304 by a slidable roller assembly 320, as seen in
In operation, turntable assembly 220 is rotated and locked into a position whereby an arm 226 is aligned with the brushing station. The bottle holder associated with the corresponding arm 226, with a bottle vertically retained in an inverted position thereon, is then urged radially inwardly against the brush assembly by roller assembly 320. Roller assembly 320 also causes the bottle to rotate about its vertical axis. Rotation of the drive roller 324a rotates the bottle, on contact therewith, which in turn rotates driven roller 324b. Rotation of the bottle causes the full exterior surface of the bottle, or at least a substantial portion thereof, to be brought into rotating contact with rollers 302 and 304. Contact for a suitable dwell time causes the label to essentially fully removed, apart from a small amount of glue or glue residue not removed by the wire brushes.
Returning to
The next-in-line station comprises a bottle removal station, where the bottle may be removed by the operator.
Operation of the present system is controlled by central controller 400, which communicates with the motors, actuators and other drive members of the present system. Controller 400 comprises a PLC (Programmable logic controller), which is programmed with a readable code. PLC 400 receives inputs, and is coded to output commands to every electronic controlled component of the system. PLC 400 is programmed to provide a 40 second dwell period within each station, whereby the turntable is rotated by ⅕ of a revolution every 40 seconds to increment the loaded bottles to the next-in-line station, and the container supports are urged towards the respective stations for treatment. For safety, a button is provided for the operator which must be pressed before the PLC will proceed with the turning of the table. There is also a start/stop button which activates the system.
The PLC is governed by the inputs it receives from the “proceed” button, the “start/stop” button, and a series of reed switches. The reed switches are limit switches placed on the pneumatic cylinders, which inform the PLC whether or not the cylinders are extended or retracted. Therefore, if something was to go wrong with a pneumatic cylinder the PLC will temporary cease operation of the system.
A series of solenoids are controlled by the PLC, which control the flow of air into the pneumatic cylinders which drive the system. By switching the air flow on or off, each pneumatic cylinder can be extended or retracted at any given time. By controlling the exact movement of the pneumatic cylinders, turntable 220 can be rotated as described above, by extending cylinder 240a, which rotates the turntable ½ of a step (36 degrees), and then retracting cylinder 240a and extending cylinder 240b. The extension of cylinder 240b rotates the turntable the final ½ step (36 degrees) to advance the conveyors from one station to the next, at which point the lock-actuating cylinder extends to actuate locking mechanism 244, securing the turntable into place.
These solenoids also control pneumatic cylinders 324a and b which are part of roller assembly 320. Once the PLC has completed rotating the table and locking it into place, these pneumatic cylinders are extended, pushing the bottles forward to the wire brushes. The vertically mounted solenoids are also set by the PLC to push the bottle up and down as it is brushed. The activation of each pneumatic cylinder is precisely controlled by the PLC to run on a specified timing interval which is programmed into the PLC.
During this cycling of pneumatic cylinders the flow of solvent and water circulating is also controlled via the PLC. As each bottle 1 is urged towards a brush assembly in a respective station, the PLC activates a relay which actuates a hydraulic valve. The relay is used because the PLC outputs a signal of 24V and the hydraulic valves run on 110 V. The relay has a 110V input and is switched on by the signal from the PLC, opening the hydraulic valve and redirecting the flow of liquid. These hydraulic valves are used in conjunction with continuously running pumps, simply changing the direction of the flow back into the tank, avoiding constantly starting and stopping the pump. The relays are only used in controlling these hydraulic valves as the PLC output is 24V and both the solenoids and motorized roller controls are operated via a 24V input.
According to another aspect of the invention, the bottles are subject to an initial soaking step prior to loading onto assembly 10. According to this aspect, the bottles may be soaked or otherwise contacted with a solution in any convenient fashion, including immersion in a bath or subjected to a spray while in a rack, bin or other storage location. The solution is selected from any liquid that provides a preliminary softening of the label and/or partial dissolution of the label glue/adhesive to improve the initial brushing step. For example, the solution can comprise water or an aqueous glue-softening solution. Persons skilled in the art will be aware of a number of such solutions that are suitable for this purpose. The duration of the soaking step can range broadly, and is dictated in part by the processing volume and speed of processing required, the type of solution that is used and the duration and abrasiveness of the subsequent brushing steps. Optionally, the soaking step can further comprise an internal rinse with a sterilizing solution. Optionally, the initially soaking and/or internal rinse can comprise an additional station on the assembly located in advance of the initial brushing station.
The various embodiments presented herein are merely by way of an example of the invention and are in no way meant to limit the scope of this disclosure. Variations of the innovations described herein will become apparent from consideration of this disclosure and such variations are within the intended scope of the present disclosure. In particular, features from one or more of the above-described embodiments may be selected to create alternative embodiments comprised of a sub-combination of features which may not be explicitly described above. In addition, features from one or more of the above-described embodiments may be selected and combined to create alternative embodiments comprised of a combination of features which may not be explicitly described above. Features suitable for such combinations and sub-combination will become readily apparent upon review of the present disclosure as a whole. The subject matter described herein and in the recited claims intends to cover and embrace all suitable changes in the technology.
This application is a continuation in part of Patent Cooperation Treaty Application no. PCT/CA2011/050331, filed on Jun. 1, 2011, which claims priority from U.S. Patent Application No. 61/350,166 filed on Jun. 1, 2010. The contents of said applications are incorporated herein by reference.
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20090255603 | Schiller et al. | Oct 2009 | A1 |
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0267619 | May 1988 | EP |
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Entry |
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International Search Report in PCT/CA2011/050331, mailed Aug. 22, 2011. |
Number | Date | Country | |
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20130087170 A1 | Apr 2013 | US |
Number | Date | Country | |
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61350166 | Jun 2010 | US |
Number | Date | Country | |
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Parent | PCT/CA2011/050331 | Jun 2011 | US |
Child | 13690384 | US |