Patent Grant
10751783
The present disclosure relates generally to systems, methods and devices for forming or processing an article of manufacture. More particularly, aspects of this disclosure relate to knockout ram assemblies for forming machines used in necking operations for shaping containers, such as bottles and cans.
In the container manufacturing industry, various approaches exist for fabricating and processing different container constructions, including bottles, cans and jars. For example, ram assemblies may be used to position and to shape a container that is being processed in a curling, cutting, expanding, necking, or other forming operation. Conventional ram assemblies comprise a cylindrical ram (piston), which moves axially relative to a turret shaft, and a plain bushing (housing), which is mounted to the turret shaft. The ram is moved, for example, by a turret barrel cam, in a reciprocating motion through the bushing. Historically, turret assemblies have operated by one ram assembly pushing a can, e.g., at a closed end of the can, into a forming head on a machine. A second, separate ram assembly then pushes a forming tool into or onto the can, e.g., at an open end of the can, to perform a forming operation.
Metal cans are often produced as “two piece” constructions, which consist of a cylindrical can body with an integral bottom wall and a can top. These cans are generally fabricated from thin aluminum or steel sheet metal. Aluminum cans, for example, are oftentimes used to package gas-pressurized liquids, such as beer and soda. For such applications, the can must exhibit a minimum predetermined strength so that it can withstand internal gas pressures generated by its contents, as well as the external forces from stacking, packaging and shipping, dispensing from machines, and handling of the can. However, the thickness of the sheet metal is a significant contributor to the overall cost of manufacturing such cans. If the thickness of the sheet metal can be reduced, while complying with strength requirements and other manufacturing tolerances, the cans can be produced at a decreased cost.
An example of a machine that forms the shape of the can body is known as a “necker” apparatus. Conventional neckers operate by applying mechanical pressure to the can body after it has been formed into its general body shape, e.g., a cylinder or multi-angular shape with an integral bottom wall. The necker is a type of tool-and-die apparatus in which the sheet metal is placed between a tool, having a protrusion, and a die, having a matching indentation. The tool and die are brought together, under pressure, forcing the sheet metal to assume the shape of the protrusion-indentation. A BELVAC™ (Belvac Product Machinery, Inc.) 595 Shaped Can Necker, for example, can form can bodies at speeds of up to approximately 2500 cans per minute. Can bodies are squeezed (“necked”) between opposite moving ram assemblies, namely a series of push rams which act as tools and an opposite series of knockout rams which act as dies. The can bodies, as they are progressed through the machine, are rapidly squeezed between a first pair of push and knockout rams, then a second pair of push and knockout rams, for as many as six or eight or more pairs of rams to complete the “necking” operation.
Each of the rams reciprocates back and forth at high speeds and with a relatively short travel distance of, for example, approximately 1-3 inches. Conventional necking rams are mechanically actuated, for example, by a “cam” mechanism, as air pressure actuators and electromechanical solenoid systems are oftentimes too fragile for the required high pressures and speeds and extreme shock loading. A cam is an elongated, raised rail with an oscillating (sinusoidal) track; each ram piston carries, at its rear end, wheels that fit on opposite sides of the cam track. As the cam track turns, it pulls and pushes the wheels of the ram causing the piston to move forward and backward. In addition to speed and travel, piston alignment is critical to ensure that the rams move with an exact timing and without binding. If a ram jams or becomes worn, it may fail and hold up the entire can production system. For that reason, rams are carefully lubricated, regularly inspected and, when necessary, replaced. Many modern machines use automatic lubrication, which typically involves running grease tubes to each ram assembly. For ram assemblies that are attached to a rotating turret, a special coupling for the grease supply line is necessary to distribute the grease to each ram. These couplings can wear out with time and use, allowing grease to escape. Even with proper lubrication, the rams may have to be inspected and replaced every few weeks, which is a large expense in terms of parts, machine down-time, time of skilled labor, and scrapped cans.
For some die neck progressions, the knockout (also known as a “knockout tool”) strokes thru the stationary die (also known as a “forming die”) to add support to the open end of a can during the reduction process. In addition to neck support, the knockout allows compressed air to enter the can to stabilize can position on a dome push plate, as well as to prevent the can from collapsing throughout the operation. A critical feature of a conventional ram assembly is an O-ring that is positioned on the outer diameter (OD) of the knockout. These O-rings aide in centering the knockout inside the stationary die to maintain consistent tool gaps, while allowing “float” for mobility with variations in incoming can wall thickness. The O-ring also helps to seal compressed air at the rear of the knockout, e.g., to prevent inadvertent venting, while maintaining maximum process support and minimizing utility requirements. O-rings also help to prevent grease, dirt and other contaminants common to neckers from entering the tooling thru the rear of the knockout proximate the tooling ram (also known as a “drive cylinder”). O-rings are typically staged in a dynamic setup with high-speed reciprocating motion and limited cross-sectional squeeze. In addition, the only lubrication an O-ring will typically see is residual mineral oil or wax used on the can for necking. As such, O-ring operational life expectancy is minimal and, thus, must be replaced on a regular basis to maintain function. This increases parts and labor costs which, in turn, increase overall manufacturing costs.
Disclosed herein are container forming machines, knockout ram assemblies, and methods for necking containers, such as bottles and cans. By way of example, a forming ram assembly is disclosed which includes an annular PTFE-based knockout guide that provides knockout support relative to the forming die. The knockout guide is captured between a front face of a ram and a rear face of a knockout tool, press-fit against the inside diameter (ID) of a die. With this arrangement, mechanical fasteners and adhesives, while optional, are not required to maintain position of the knockout guide. The knockout guide is seated on a complementary step at the rear of the knockout tool, positioned on top of the O-ring, which helps to minimize compressed air loss and prevent contaminants from entering through the back of the tooling set. The knockout guide can be “stage-specific,” i.e., sized to run inside the die, and provided with an optional forward-facing approximately 45-degree ramped OD leading edge to ensure that the knockout guide remains in constant contact with the ID relief surface of the die. Extending continuously around the circumference of the knockout guide, e.g., along leading and trailing ID edges, are optional chamfered corners that help to simplify mounting of the guide onto the knockout tool. In this assembly, the knockout guide operates as the dynamic wear component for reciprocating motion of the knockout with respect to the die. With use of PTFE or other wear-resistant, friction-reducing polymeric materials, the operational life expectancy of the knockout guide will greatly exceed that of a standard O-ring in the same application. The O-ring can be positioned against the ID of the knockout guide, which allows the knockout to float within the tooling assembly. The O-ring, however, is implemented as a “static application” and, thus, will not wear as significantly from the necking process.
Aspects of the present disclosure are directed to automated forming machines for processing articles of manufacture. In an embodiment, a forming apparatus for modifying the shape of a container is presented. This forming apparatus includes, for example, a frame with a first base and a second base, and a drive shaft extending from the first base to the second base. A turret starwheel is coaxially mounted with the drive shaft and configured to receive and move the container during forming. Coaxially mounted with the drive shaft is a turret assembly with an elongated cam rail. A forming ram assembly is connected to the turret assembly. This forming ram assembly includes a cam follower that is rollably seated against the elongated cam rail. Connected to the cam follower is a forming die which moves in a reciprocating manner as the cam follower traverses the elongated cam rail. A knockout tool, which is movably mounted inside the forming die, includes an outer surface with a stepped segment. Connected to the knockout tool is a drive cylinder that is operable to move the knockout tool in a reciprocating manner relative to the forming die. An O-ring is seated inside a complementary channel defined in the stepped segment of the knockout tool. A knockout guide is seated on the stepped segment of the knockout tool, abutting the O-ring and the forming die to thereby generally fluidly seal the knockout tool with the forming die while allowing the two dies to move relative to one another.
Other aspects of the present disclosure are directed to ram assemblies for forming machines used in processing articles of manufacture. In an embodiment, a knockout ram assembly for a container forming machine is presented. This ram assembly includes, for example, a mounting rail that is configured to attach the forming ram assembly to a turret assembly of the container forming machine. A cam follower is movably mounted to the mounting rail and configured to rollably seat against a cam rail of the turret assembly. Connected to the cam follower is a cylindrical forming die. By connecting the two components, the cylindrical forming die moves in a reciprocating manner in response to the cam follower traversing the cam rail. Movably mounted inside the cylindrical forming die is a cylindrical knockout tool. The knockout tool includes an outer diameter (OD) surface with a stepped segment. A drive cylinder is connected to the cylindrical knockout tool and configured to move the knockout tool in a reciprocating manner within the cylindrical forming die. Seated inside a complementary channel defined in the stepped segment of the knockout tool is an O-ring. An annular knockout guide is seated on the stepped segment of the knockout tool, located between and abutting the O-ring and the forming die. This arrangement helps to generally fluidly seal the knockout tool with the forming die while allowing the two dies to move relative to one another. In addition, the operational life expectancy of the O-ring is increased and the need for lubricant is significantly decreased or otherwise eliminated.
Also disclosed are methods for making and methods for using ram assemblies for shaping an article of manufacture. In an embodiment, a method of assembling a forming ram assembly for a container forming machine is presented. This method includes, in any order and in any combination with any other hereinafter disclosed steps and features: connecting a forming die to a cam follower, the cam follower being configured to rollably seat against and traverse a cam rail of the container forming machine to thereby move the forming die; slidably mounting a knockout tool inside the forming die; connecting to the knockout tool a drive cylinder that is configured to move the knockout tool within the forming die; mounting an O-ring onto the knockout tool; and, seating a knockout guide on a stepped segment of the knockout tool such that the knockout guide presses against the O-ring and the forming die to thereby fluidly seal the knockout tool with the forming die while allowing the two dies to move relative to one another.
The above summary does not represent every embodiment or every aspect of the present disclosure. Rather, the foregoing summary merely provides an exemplification of some of the novel aspects and features set forth herein. The above features and advantages, and other features and advantages of the present disclosure, which are considered to be inventive singly or in any combination, will be readily apparent from the following detailed description of the illustrated examples and the modes for carrying out the present invention when taken in connection with the accompanying drawings and the appended claims
The present disclosure is susceptible to various modifications and alternative forms, and some representative embodiments have been shown by way of example in the drawings and will be described in detail herein. It should be understood, however, that the inventive aspects are not limited to the particular forms illustrated in the drawings. Rather, the disclosure is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.
This disclosure is susceptible of embodiment in many different forms. There are shown in the drawings, and will herein be described in detail, representative embodiments with the understanding that the present disclosure is to be considered as an exemplification of the principles of the present disclosure and is not intended to limit the broad aspects of the disclosure to the embodiments illustrated. To that extent, elements and limitations that are disclosed, for example, in the Abstract, Summary, and Detailed Description sections, but not explicitly set forth in the claims, should not be incorporated into the claims, singly or collectively, by implication, inference or otherwise. For purposes of the present detailed description, unless specifically disclaimed or logically prohibited: the singular includes the plural and vice versa; and the words “including” or “comprising” or “having” means “including without limitation.” Moreover, words of approximation, such as “about,” “almost,” “substantially,” “approximately,” and the like, can be used herein in the sense of “at, near, or nearly at,” or “within 3-5% of,” or “within acceptable manufacturing tolerances,” or any logical combination thereof, for example.
Referring now to the drawings, wherein like reference numerals refer to like features throughout the several views, there is shown in
Forming machine 100 is used to form, process, or otherwise perform a manufacturing operation on a container such that the shape of the container is modified from a first shape to a second shape. In a multi-stage line, a container is first fed into a first stage (e.g. a rotatable forming apparatus) to enter pockets in a spinning turret/starwheel. Each starwheel may have any number of pockets to hold containers for processing and transfer. For example, a starwheel may have six, eight, ten, twelve, fourteen, etc., pockets to hold six, eight, ten, twelve, fourteen, etc., containers, respectively, at a given time. A starwheel is capable of having a single pocket or, more commonly, any number of pockets suitable for the intended application. After exiting the first stage, the container may enter a second stage, then on to a third stage, and so forth, depending on the configuration of the multi-stage line. Once fed into the multi-stage line, the container is processed through any number of stages, e.g. a necking stage, a curling stage, an expansion stage, or any other suitable processing or forming stage. When the container passes through all process/forming stages, the container is discharged from the machine. The multi-stage line may be a recirculating system or an in-line system, for example.
Forming machine 100, as shown, includes a rigid outer frame 102 stowing therein one or more forming turret assemblies, two of which are visible but only one of which is designated 104 in
The central, longitudinal axis of the fixed turret 116 extends in the vertical direction, generally parallel to and concentrically aligned with the drive shaft 110. Fixed turret 116 is “fixed” in that the orientation (e.g. bottom line) of each container that enters and exits the forming machine 100 relative to the infeed and discharge conveying system, which helps move the containers through all stages of the rotatable forming machine 100, does not change. This typically allows for easier setup and control of the forming operation. For at least some optional configurations, the push ram assemblies 120 may be movably mounted to the movable turret 115 while the forming ram assemblies 140 may be movably mounted to the fixed turret 116. Moreover, the number of ram assemblies 120, 140 mounted to a turret 115, 116 can be varied from that which is shown in the drawings.
As best seen in
Also extending in the vertical direction is the central, longitudinal axis of the movable turret 115, which is concentrically aligned with the drive shaft 110 and the fixed turret 116. Multiple forming ram assemblies 140 are mounted to and circumferentially spaced around the moveable turret 115. Each forming ram assembly 140 communicates with a cam 142 that circumscribes drive shaft 110, and is oriented by a key connection with an upper bearing housing. Rotation of the drive shaft 110 causes the moveable turret 115 to rotate which, in turn, causes the forming ram assemblies 140 to rotate around the cam 142. Moveable turret portion 115 may include a mechanical adjustment mechanism for adjusting the positioning of the turret portion 115 in the vertical direction along the drive shaft 110 with respect to the fixed turret 116 so as to configure the forming turret assembly 114 for containers of different lengths.
As seen in
With continuing reference to
Forming ram assemblies 140, once assembled with tooling components, each includes a drive cylinder 146, a knockout tool 152 (or “knockout” for short), and a forming die 154. In the illustrated example, the drive cylinder 146, which may be referred to as a knockout cylinder, takes on the form of a pneumatic cylinder actuator. The drive cylinder 146 may move in a downward vertical direction due to gravity and airline pressure variation due to air path resistance. The drive cylinder 146 receives airline pressure variation from an air manifold assembly that fixes to and rotates with the drive shaft 110. Once a container contacts the knockout tool 152, the drive cylinder 146 moves in the vertical direction that results from the forming die following the cam 142, thereby allowing the container to go over the knockout tool 152 while forming of the container occurs. Pressure is kept inside the container while forming occurs to help with the forming operation.
The forming die 154 is coupled to the cam followers 144, e.g., via adapter arm 158 and bracket 168, such that the forming die 154 moves in the vertical direction and satellite rotation to follow the cam 142 profile. For some embodiments, the forming dies 154 of each forming ram assembly 140 for a particular moveable turret 115 may all be the same, for example, in an in-line system. Comparatively, the forming dies 154 of some forming ram assemblies 140 may differ from the ram assemblies 140 of other moveable turrets 115 in the rotatable forming apparatus 100 such that the shape of a container is altered a first way by a first movable turret 115 and is altered a second way by a second moveable turret 115 with which the container interacts. In a recirculating system, the forming dies 154 of the forming ram assemblies 140 may all differ from stage to stage. For example, the first, third, fifth, etc., forming dies 154 may be the same while the second, fourth, sixth, etc., forming dies 154 may differ from the first, third, fifth, etc., forming dies. The forming die 154 in both an in-line and recirculating system may first neck the container and then expand the container along the system.
The knockout tool 152, which is coaxial with the forming die 154, helps to release containers from the forming die 154 after the forming die 154 necks each container. The knockout tool 152 catches a leading edge of the container while the container is being necked by the forming die 154 to prevent the container from having an irregular shape. Drive cylinder 146, which is selectively operable to cause axial movement of the knockout tool 152 within the forming die, is configured to operate independently of the forming die 154. The drive cylinder 146 includes an elongated, hollow drive cylinder shaft 160 that extends parallel to the drive shaft 110 of forming turret assembly 104. Bolt 162 extends into an opening in a proximal end of the forming die 154 and connects the knockout tool 152 to the drive cylinder shaft 160. A proximal end of knockout tool 152 contacts an inner surface of the container during the forming operation. Knockout tool drive cylinder shaft 160 is coaxial to and extends into a guide cylinder shaft 164. When the drive cylinder 146 receives air, e.g., via air input conduit 166, the drive cylinder shaft 160 moves axially with respect to forming die 154 due to incoming airflow that causes a differential pressure, thereby causing the knockout tool 152 to move, e.g., in the vertical direction, along the drive shaft 110. As the drive cylinder air shaft 160 receives air, air is passed into a container that interacts with the forming die 154 so that the container does not collapse upon itself when the shape of the container is modified by the forming die 154.
A leading edge of the knockout tool body 171 has a rounded nose 177 that leads to a forward-facing ramped surface 175. Rounded nose 177 extends continuously around the proximal opening 173 of the knockout tool 152 and functions to engage containers during each forming operation. At a rear end of the knockout tool body 171, formed on the OD surface of knockout tool 152 around the distal opening 175, is a stepped segment 179 for mating with the O-ring 170 and knockout guide 172. The stepped segment 179 is defined by a toroidal rim 181 that is generally perpendicular to a continuous flange wall 183. O-ring 170 is seated inside a complementary channel 185 that is defined in the stepped segment 179 of the knockout tool 152, recessed into the rim 181. This complementary channel 185 extends continuously around the OD surface of the knockout tool body 171. The knockout guide 172, in turn, is seated on the stepped segment 179 of the knockout tool 152, covering and concomitantly compressing the O-ring 170, as seen in
According to the illustrated example, the knockout guide 172 is an annular, single-piece body 187 which extends continuously around the perimeter of the stepped segment 179 of knockout tool 152. It is desirable, for at least some embodiments, that the knockout guide 172 be fabricated from a polytetrafluoroethylene (PTFE) fluoropolymer compound or other wear-resistant, friction-reducing polymeric material. In cross-section, the knockout guide 172 has a polygonal geometry with flat primary and secondary sides, as best seen in
With reference again to
The present invention is not limited to the precise construction and compositions disclosed herein; any and all modifications, changes, and variations apparent from the foregoing descriptions are within the spirit and scope of the invention as defined by the appended claims. Moreover, the present concepts expressly include any and all combinations and subcombinations of the preceding features and aspects.
This application is a U.S. National Stage of International Application No. PCT/US2016/041868, filed on Jul. 12, 2016, which claims priority to U.S. Provisional Patent Application No. 62/198,915, filed Jul. 30, 2015, both of which are hereby incorporated by reference herein in their entireties.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/US2016/041868 | 7/12/2016 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2017/019291 | 2/2/2017 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 4280353 | Murphy | Jul 1981 | A |
| 4519232 | Traczyk | May 1985 | A |
| 10166591 | Babbitt | Jan 2019 | B2 |
| 20050252264 | Shuey | Nov 2005 | A1 |
| 20150082849 | Babbitt | Mar 2015 | A1 |
| Number | Date | Country |
|---|---|---|
| 1207063 | Feb 1999 | CN |
| 201572836 | Sep 2010 | CN |
| 202893985 | Apr 2013 | CN |
| 204486618 | Jul 2015 | CN |
| 2179284 | Mar 1987 | GB |
| H01-210135 | Aug 1989 | JP |
| H05-305374 | Nov 1993 | JP |
| H09-327737 | Dec 1997 | JP |
| 2006-150426 | Jun 2006 | JP |
| 2013070199 | May 2013 | WO |
| Entry |
|---|
| International Search Report from International Application No. PCT/US2016/041868 dated Oct. 27, 2016. |
| Number | Date | Country | |
|---|---|---|---|
| 20180207705 A1 | Jul 2018 | US |
| Number | Date | Country | |
|---|---|---|---|
| 62198915 | Jul 2015 | US |
