巴西专利BR112014016331B1 method and system for manufacturing a metal container

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专利摘要:
SYSTEM AND METHOD FOR FORMING A METALLIC BEVERAGE CONTAINER USING BLOW MOLDING. A system and method of manufacturing a metal container may include providing a preform, formed from a cold-formed hardened metal, which includes an open portion, a closed end portion, and a body portion. The body portion of the preform can be preheated in a manner that limits heat by being applied to the open and closed end portion of the preform. The preheated preform can be blow molded.
公开号:BR112014016331B1
申请号:R112014016331-6
申请日:2012-12-31
公开日:2020-07-21
发明作者:John Adams；Rajesh Gopalaswamy；Karina Espinel
申请人:The Coca-Cola Company；
IPC主号:

专利说明:

[0001] This application claims priority to US interim pending Patent Applications 611581,860 filed on December 30, 2011, entitled System and Method for Forming a Metal Beverage Container; 611586.995 deposited on January 16, 2012, entitled Metal Beverage Container Preform, and 611586,990 deposited on January 16, 2012 Hot Preform Blow Formation; whose contents are hereby incorporated by reference in their entirety. TECHNICAL FIELD
[0002] This disclosure concerns the manufacture of beverage containers. BACKGROUND
[0003] Metal containers can be used to store drinks. Typical cans having a single piece and past design body or an open body at both ends with a separate closing member at the top and bottom generally have simple cylindrical vertical side walls. It may be desirable to form the side walls in different and / or more complex shapes, for reasons related to aesthetics and / or product identification. For example, it may be desirable to form a can, so that it resembles a glass bottle.
[0004] A metal preform ("preform") can be made from a sheet of metal (for example, aluminum foil, aluminum-based alloys, steel, etc.) having, for example, a recrystallized microstructure or recovered and with a gauge ranging from about 0.004 inches to about 0.015 inches. Thinner and thicker gauges are also possible, such as between about 0.002 inches and about 0.020 inches. The preform can be a closed-end tube made by, for example, a draw-redraw process or by reverse extrusion. The diameter of the preform may (but need not) be somewhere between the minimum and maximum diameters of the desired product container. Wires can be formed on the preform before subsequent forming operations. The profile of the closed end of the preform can be designed to assist in forming the bottom profile of the final product.
[0005] Since containers, such as those in the shape of a bottle, have certain axial strength criteria to prevent damage to the bottle during the bottle's life cycle, including filling, packaging, transportation, racking, and consumer use, the materials used for the containers are limited. Materials that are too soft are unsuitable due to axial strength criteria. In addition, material that is too thick, which would help to improve axial strength, is inadequate due to weight limitations and production and transportation costs for consumer products. The heating of certain metals can degrade the strength and structure of the final product, so that the selection and heating processes of the metal can be limited to produce metal containers in the form of glass or different bottles, too. SUMMARY
[0006] When performing blow molding, a method for making a metallic beverage container may include arranging a metal preform, having side walls and a dome shaped metal bottom portion or a closed end portion configured to support, for example, example, a pressure of at least 90 pounds per square inch, without plastically deforming, adjacent to a heat source (i) such that the heat from the heat source is transferred to the metal side walls to sufficiently soften the side walls metal to allow radial expansion of the metal side walls when subjected to fluid pressure of at least 30 bar and (ii) such that the heat within the metal side walls dissipates sufficiently before being conducted to the portion of the dome-shaped metal bottom to avoid compromising the ability for the dome-shaped metal bottom portion to withstand a pressure of at least 90 pounds per inch q square, without plastic deformation. The blow molding method may also include pressurizing the metal preform to radially expand the side walls by, for example, at least 15%.
[0007] One embodiment of a method and system for manufacturing a metal container may include providing a preform being a cold-hardened metal. The preform includes an open portion, a closed end portion, and a body portion. The body portion of the preform can be preheated in a way that limits the heat being applied to the open portion and closed end portion of the preform. The preheated preform can be inserted into a mold that includes multiple segments, and the multiple segments of the mold can be closed. The preform can be blow molded to make the preform take on a shape defined by the mold, and the preform of the mold can be removed from the mold.
[0008] Another embodiment of a system and method for manufacturing a metal container may include providing a preform to be formed of a cold-hardened metal, the preform having an open portion, a closed end portion, and body portion. The preform can be inserted into a mold that includes multiple segments, the preform being at room temperature. The multiple segments of the mold can be closed, and the preform can be blow-molded at room temperature, to make the preform take a shape defined by a mold. The molded preform can be removed from the mold.
[0009] When performing pressure molding, a system for molding a metal tubular preform can include a segmented mold configured to form a cavity when closed and at least one controller. The controller (s) can cause the preform to be pressurized in such a way that when the segmented mold closes around the preform to form the cavity, and at least partially to shape the preform shape (i.e., protrusions of the mold that extend inwards can contact the preform when closing), the cold deformation of the preform that results in shape defects of the preform is minimized. The controller (s) can also cause the mold to close around the preform in such a way that the preform is placed inside the cavity, and can use a significant pressure increase inside the preform to expand portions of the preform into the cavity. The controller (s) can also cause the preform to be pressurized with a first fluid. A significant increase in pressure within the preform can be used to expand portions of the preform in the cavity, and may include delivering a second fluid into the preform. The first fluid and the second fluid can be different. For example, the first fluid can be a gas and the second fluid can be a liquid. Alternatively, the first fluid can be a liquid and the second fluid can be a liquid. The preform may be unheated during the pressure molding process.
[0010] When performing pressure molding, a method for molding a metal tubular preform may include delivering a gas into the metal tubular preform to cause the preform to be pre-pressurized such that when a segmented mold closes around the preform to form a cavity, and at least partially molding the preform, the cold deformation of the preform results in a shape of the preform, which is not the complement of the cavity, is inhibited. The method may also include closing a mold segmented around the pre-pressurized preform such that the preform is placed inside the cavity and delivering a liquid into the preform to use a significant increase in pressure within the preform to expand portions of the preform into the cavity. The liquid can be delivered through the preform to cause a significant increase in pressure within the preform. The preform may be unheated during the pressure molding process. The segmented mold may include projecting portions that cause the preform to deform as the segmented mold closes around the preform, as described above.
[0011] One embodiment of a system and method of manufacturing a metal container may include inserting a preform into a mold that includes multiple segments, the preform being a cold-hardened metal. A pre-pressure can be applied to the preform at a first pressure level. The multiple segments of the mold can be closed, and the pressure being applied to the preform can be increased using a step function to a second pressure level, after the mold is closed. The increase in pressure from the first pressure level to the second pressure level causes the preform to take a shape defined by the mold. The molded preform can be removed from the mold. BRIEF DESCRIPTION OF THE DRAWINGS
[0012] Illustrative embodiments of the present invention are described in detail below with reference to the figures in the accompanying drawings, which are hereby incorporated by reference and in which: FIG. 1 is a schematic diagram illustrating operations for forming a metallic beverage container. FIG. 2 is a side, cross-sectional view of a segmented (open) and preform mold before the fluid is formed together with a controller and a fluid source used in the production of a molded metal container; FIG. 3 is a graph of the internal pressure of the preform generated by an oil piston pump system FIG. 4 is a graph of the internal pressure of the preform generated by an oil accumulator system FIG. 5 is a graph of the internal pressure of the preform generated by an air compressor system for the production of a metallic container, according to the principles of the present invention; FIG. 6 is a side, cross-sectional view of the segmented (closed) and preform of FIG. 2 before expansion; FIG. 7 is a side, cross-sectional view of the segmented (closed) and preform of FIG. 2 after expansion; FIG. 8 is an illustration of an illustrative side view of a partially processed metal preform and heating device for use in heating a portion of the preform according to the principles of the present invention; FIG. 9 is a flow diagram of an illustrative process for preheating and blow molding a metal preform; and FIG. 10 is an illustration of a side view of an illustrative unprocessed metal preform. DETAILED DESCRIPTION Pressure Molding Process
[0013] With reference to FIG. 1, a metal coil 102 can be processed by an embedding operation 104 to shape a portion of the metal coil 102 in a cup 106, as is understood in the art. Cup 106 can be processed by a body manufacturing operation 108, as is understood in the art, to be molded to form an isolated cylinder or bare tube 110 (metal preform or preform). Insulated cylinder 114 can only undergo the known / suitable printing and coating operations in step 112 to produce a coated cylinder 114 (coated preform). As explained in more detail below, the coated preform 114 (or preform 110) can by molding and finishing operations (or crushing and fluid formation) in step 116, form portions of a metal beverage container 118 resembling, for example, a glass bottle. The processes described in FIG. 1 have been used for a variety of different production uses. However, as a result of having to use some materials for the production of molded metal containers (for example, a molded container shaped like a glass bottle) that meet certain design criteria (for example, axial force threshold), the molding and finishing process 116, among other processes, can use non-conventional techniques, as described herein, to produce these molded metal containers.
[0014] With reference to FIG. 2, an illustrative molding system 200 includes a mold 202 formed from side segments 204A and 204B, and 204c of the lower segment (collectively 204), is configured to form a cavity 206 that defines a complement of the shape of the lower portion metal beverage container 118 (FIG. 1). Mold 202, in other embodiments, can have any desired number of segments. In the embodiment of FIG. 2, the cavity 206 formed by the side segments 204a and 204b (when closed) defines the complement of the form of "striations" or "ribs" found, for example, in the lower portion of glass beverage containers sold by the Coca-Cola company. Other configurations are also possible.
[0015] In one embodiment, projecting or protruding portions 208 of cavity 206 project to / collide with preform 114, when segments 204a and 204b close around preform 114 to form cavity 206. Projecting portions 208 partially deform / mold preform 114. Embedded portions 210 of cavity 206 do not protrude / collide with preform 114 when segments 204a and 204b close around preform 114 to form cavity 206. Fluid techniques moldings (e.g., hydro formation, etc.) can be used to expand / deform preform 114 into the recessed portions 210 of cavity 206.
[0016] Tests have shown that if the pressure within preform 114 is low enough (for example, less than 3 bar), shape defects in preform 114 may result when segments 204a and 204b close to form cavity 206. This Threshold pressure depends on the gauge of the preform 114, the diameter of the preform 114, the material comprising the preform 114, etc., and can be determined through tests, simulations, etc. That is, deformation, crushing, or wrinkling, which is not consistent with the complement of the shape molded by the cavity 206, can occur as the projecting portions 208 collide with the preform 114. To minimize or exclude these shape defects , preform 114 can be pre-pressurized. It should be understood that the diameter of the preform 114 may be greater than the diameter of the mold 202, when in the closed position, as a result of the material of the preform 114 having limited elasticity (for example, cold-hardened aluminum , such as 3000 series aluminum) and having a thin gauge (for example, between about 0.004 inches and about 0.020 inches) while preform 114 has limited expansion capacity, compared to other metals that are more elastic , such as metals and superplastic alloys. Alternative configurations of preform 114 can be used where the diameter of preform 114 is smaller than the diameter of mold 202 in a closed position, which can allow the mold not to come into contact with the preform when closing . Metals that can be used in accordance with the principles of the present invention can include alloys of beverage cans and volumetric aluminum, as is understood in the art. The type of metal, mold configuration, molding technique, etc., determine whether the mold will come into contact with the preform when closing. That is, if the metal of the preform is a relatively non-plastic metal, then the amount of stretching that is possible with the metal is limited, and, consequently, the mold is closer to the preform, including contacting the preform. -form when closing so that the preform can contact all parts of the mold during the molding operation.
[0017] With reference to FIG. 3, an illustrative pressure waveform 300 generated by an oil piston pump system is shown to illustrate a pressure waveform that can provide insufficient or unacceptable results in the production of a metal container for use according to the principles of the present invention. As predicted, a preform can be pressurized before closing a mold segmented around the preform. The pressure at which the preform is first pressurized must be sufficient to minimize or prevent defects in the manner described above. In the embodiment of FIG. 3, this first pressure threshold (pre-pressurization threshold) is 5 bar. Other thresholds, however, can be used depending on the gauge of the preform, the diameter of the preform, the material of the preform, etc. Any suitable fluid (for example, water, oil, air) can be used to pre-pressurize the preform. In one embodiment, the pre-pressure that uses air as a liquid is not compressible. That is, the use of liquids, such as water, can be used to create higher pressures (for example, about 40 bar or more), with a rapid movement, as additionally described here (see FIGS. 4 and 5 ).
[0018] Once a segmented mold has closed around the preform, the pressure inside the preform can be increased by introducing fluid (eg, water, oil, air) to a second pressure threshold (final pressurization threshold ) to fluidly form the preform in recessed portions of the cavity. This second pressure threshold is approximately 40 bar, in the embodiment of FIG. 3. Other thresholds, however, can be used (for example, 35-160 bar), depending on the gauge of the preform, the diameter of the preform, the material of the preform, the fluid used to pressurize the pre- shape, etc. It should be understood that more plastic metals or other materials, including aluminum or superplastic alloys, tend to use less pressure with comparable gauge, because they are more flexible. However, such materials tend not to achieve sufficient strength, at least axial force, for use in consumer beverage products. In one embodiment, pressurization is done at room temperature (that is, without a heat source applying heat to the preform, before or during the molding process. Once the forming is complete, the fluid (s) inside the preform they can be evacuated, and the preform can be further processed as desired.
[0019] The tests also revealed that the rate at which the pressure within the preform is increased from the first pressurization level to the final pressurization level can fatigue the preform in an undesirable manner. As is evident from FIG. 3, the second pulse order of the pressure waveform 300 is observed during the increase of approximately 10 seconds to the final pressurization threshold (i.e., the pulsar pattern shown in the pressure waveform 300 from the moment on the mold closes to maximum pressure). This pulsar results from the way in which the compressor (for gas) or accumulator (for liquid) operates to increase the pressure of the preform and the results in cyclic loading of the preform, which can erode the metal of the preform. A relatively slow rate of pressure increase causes the compressor, for example, to experience mini cycles of pressure increase and decrease as the compressor operates to increase the pressure within the preform. It is to be understood that a slower pressure increase can be used for materials with alternative parameters (for example, upper plastic, thicker gauge, etc.) than those used according to the principles of the present invention. As explained below with respect to FIGS. 4 and 5, the pulse of the pressure wave 300 can be reduced by reducing the time for the pressure to rise.
[0020] With reference to FIGS. 4 and 5, illustrative pressure waveforms 400 and 500 produced using an oil accumulator system and an air compressor system, respectively, provide two alternative pressure profiles that can be applied to a preform for the production of a molded metal container. As shown, the time during which the pressure is increased from the first pressurization level (P1) to the final pressurization level (P2) has been reduced. The accumulator and compressor systems of FIGS. 4 and 5, respectively, facilitate a step change in pressure over a relatively short period of time (e.g., about 0.2 seconds or less) to minimize pulsation and, therefore, preform fatigue. The reduced fatigue results from the limitation of the metal's ability in gauge, elasticity, temperature, etc., from the preform to react in order to avoid expansion through a short pressure transition. As shown in FIG. 4, the pressure waveform 400 stops at an intermediate pressure level 402, while transiting between the first and second pressure levels P1 and P2 as a result of not being transitioned fast enough between the first and second pressure levels P1 and P2. As a result of the hesitation at the intermediate pressure level 402, metal containers that are formed by the pressure waveform 400 can result in imperfections (e.g., tears or wrinkling).
[0021] As shown in FIG. 5, pressure waveform transitions 500 between the first and second pressure levels P1 and P2 are fast enough (for example, less than about 0.2 seconds, or significantly less than 0.2 seconds). This rapid increase in pressure does not allow the accumulator and compression systems to experience the minicycles described above. Any suitable period of pressurization time (for example, 0.1-1 seconds) that is, however, fast enough to prevent damage to the metal container, can be used. As described above, the maximum pressure can be 40 bar or higher for a strong metal, such as cold deformed aluminum. In one embodiment, the cold-hardened aluminum may be a 3000 series aluminum, such as aluminum alloy 3104. A surprising result that the metal preform was not damaged as a result of the rapid pressure transition from a low pressure to a high pressure, at room temperature, was found. It has been found that the rapid pressure transition in the form of a step, as described above, at room temperature, has the best results in terms of not damaging the preform, since cold-hardened aluminum in gauges to be used for the preform, has no opportunity to react to the pressure transition, thereby minimizing discontinuities or uneven expansion of the preform material.
[0022] Referring again to FIG. 2, a fluid source 212 is arranged so as to be in fluid communication with preform 114 before segments 204A and 204B close. Fluid source 212 can be configured to supply gaseous (e.g., air, etc.) and / or liquids (e.g., water, oil, etc.) fluids to preform 114. In the embodiment of FIG. 2, fluid source 212 includes an air tank and a water tank arranged through valves and pipes suitable for supplying air and / or water to preform 114. Preform 114 is, of course, sealed from any known / proper manner so that you can maintain the pressure. Other arrangements are, however, also possible.
[0023] A pressure sensor 214 can be arranged within preform 114 or within the valve and piping system by fluidly connecting preform 114 and fluid source 212 to detect pressure within preform 114. As a As a result of including pressure sensor 214, an operator and / or controller 216 can control the pressure to be applied to preform 114 before, during, and after performing a molding operation on preform 114.
[0024] Mold 202, fluid source 212 (tanks, valves, piping, duct (s), etc.), and pressure sensor 214 may be in communication with / under the control of one or more controllers 216 (collectively, " controller"). The controller 216 can be configured to control the opening / closing of the mold 202 and the delivery of fluid to the preform 114 through a conduit 213. The conduit 213 can be a tube or other hollow member that allows the fluid to flow between the fluid source 212 and the cavity 206 of the mold 202. With the preform 114 properly positioned in segment 204c and between open segments 204a and 204b, controller 216 can cause fluid source 212 to provide, for example, to create an air supply pre-pressurization, for example, to preform 114 until an internal pressure of preform 114 reaches a pre-pressurization, such as approximately 5 bar. In one embodiment, controller 216 can control fluid source 212 to create, or otherwise release, the liquid to cause pressure to rise in preform 114. Alternatively, the controller can cause one or more valves ( not shown) attached to conduit 213 are adjusted (for example, open, closed, or partially open / closed) to release fluid to cause pressure to increase in preform 114. By causing the pressure to be increased in pre-form Form 114, controller 216 may be configured to communicate electrical signals to cause an electromechanical device, such as a valve, to be adjusted, as is understood in the art.
[0025] With reference to FIG. 6, controller (s) 216 may cause segments 204a and 204b to close around preform 114 to form cavity 206 after the internal pressure of the preform reaches 5 bar, for example . As described above, this internal pressure minimizes / prevents defects in shape of the preform since the projecting portions 208 deform the preform.
[0026] With reference to FIG. 7, controllers 216 can cause fluid source 212 to supply, for example, water or oil to the preform until the internal pressure of the preform reaches about 40 bar, in a similar manner to that described with reference to FIGS. 4 and 5. This forming operation, in the example of FIG. 7, expands the preform to the recessed portions 210 of cavity 206. Once the molding of preform 114 is complete, controllers 216 can cause the fluid (s) inside to be evacuated in a way that the molded preform 118 can be further processed as desired. Although liquid, such as oil or water, can be used to generate pressure, air or other gas can be used to create pressure, thus eliminating cleaning and / or drying steps.
[0027] The preform illustrated in FIGS. 2, 6 and 7 is not heated. That is, a heating operation need not be performed before segments 204A and 204b close or during fluid formation. Depending on the material of the preform, as previously described, preheating can weaken the preform, thereby causing damage to the preform during the molding process, or after that. As provided in FIG. 1, the preform 110 may have printing and coatings applied to it in the creation of the preform 114. The heating of preforms, before or during the molding process 116 is generally at temperatures of 200 degrees Celsius or more for the metals, such as superplastic metals. In addition to weakening the preform 114, such temperatures can cause damage to the printing and / or coating of the preform 114. Thus, by carrying out the molding and finishing process 116 at room temperature, the damage to the printing and / or coating of preform 114 can be avoided and the preform can remain as strong as possible. In an alternative embodiment, it may be possible to preheat the preform to temperatures below 200 degrees Celsius that do not weaken the metal or negatively impact coatings or printing on the preform. Blow Molding Process
[0028] Blow molding techniques can be used to form the metal, for example, in the form of a glass bottle. A blow molding apparatus can be loaded with a metal preform, for example, a cylinder having an open end and a closed end. Fluid under pressure can then be delivered into the preform via the open end to expand the preform into a surrounding mold. The maximum radial expansion of the preform, in such circumstances, is in the range of 8% to 9% for 3000 series aluminum, for example. It has been found, however, that a cold deformed preform with certain gauges as previously described has the ability to expand upwards by 20% at room temperature. Therefore, if the diameter of the finished container should be about 58 millimeters, the initial diameter of the preform should be less than about 53 millimeters. In cases where the preform has a smaller diameter than the smaller diameter of the mold, then a pre-pressurization may not be necessary since the preform is not deformed by closing the mold. For larger expansions, such as up to 40%, selective or localized preheating can be performed to further increase the expansion of the preform, as additionally described here. Such increased expansion can be used in cases where the mold has portions where the preform will extend to create a final blow molded product.
[0029] A metallic bottle-shaped beverage container often has a top or finish portion formed near the open end of the container. To facilitate drinking from the container, the diameter of the upper portion is generally smaller than the initial diameter of the associated preform. The diameter of the upper portion, for example, can be approximately 28 millimeters. Up to 35 to 40 stretching operations (or the like) may need to be performed to reduce the initial diameter of the preform by lowering it to the desired final diameter of the upper portion. Performing this number of operations contributes to a considerable part of the overall manufacturing time of the containers and limits productivity. In addition, several (expensive) stretching machines are required to support this number of operations.
[0030] It has been found that selectively heating portions of a metal preform before blow molding can increase the maximum radial expansion of the preform by up to 15% to 25% or more, and possibly up to 40% or more. Therefore, if the maximum diameter of the finished container is to be approximately 58 millimeters, the initial diameter of the preform can be as small as approximately 45 millimeters or smaller. This reduction in the initial diameter of the preform can reduce the number of drawing operations under pressure (or the like) required to reach the desired final upper diameter by as much as 50%. Fewer such operations reduce overall container fabrication time and the number (and cost) of pressure drawing machines required to support these operations. In addition, a wide range of container shapes, including asymmetric container shapes, is possible, given the increased ability to radially expand the preform.
[0031] With reference to FIG. 8, an illustrative environment 800 in which a metal preform 802 having an open end portion 804, a molded closed end (or bottom) portion 806, and a body portion 808. The bottom portion 806 can be configured as a dome, which expects to withstand a pressure of at least 90 pounds per square inch, without plastic deformation. The body portion 808 is shown to be positioned close to a heating device 810, which can be a heating element, heat lamp, hot air gun, or any other heat source. Preform 802 may pass near heating device 810 before a blow molding process to cause heat 812 from heating device 8 to soften body portion 808. In one embodiment, pipes or other collector configuration ( (not shown) can be used to direct heat from heating device 810 to body portion 808 and out of open and lower end portions 804 and 806 of preform 802. In one embodiment, a blowing device (not shown ), like a fan, can be used to cause heat 812 to be directed to preform 802. As shown, preform 802 is positioned relative to heating device 810 so that the end portions open and closed 804 and 806 are not subject to the same amount of direct heat as the body portion 808 of the preform 802. Because the open end portion 804 eventually forms an upper portion of a shaped container With a small diameter bottle, there is no need to intentionally heat this section, as it will not be subjected to blow molding, and therefore does not have a need to be softer for stretching purposes. Because heating can soften the metal preform and thus reduce its strength, intentional heating of the closed end portion 806 is avoided to minimize losses in the bottom strength of the container. However, unintentional heating of the open and closed end portions 804 and 806 may occur, due to the conduction of heat along the body portion 808 of the preform 802.
[0032] When preheating the preform 802, an 814 controller, which may include one or more processors, may be in communication with the 816 machinery or equipment. The 816 machinery may be standard equipment for use in the processing and manufacturing of cans and / or metal flasks, as is understood in the art. However, machinery 816 can be modified to perform preheating, if preheating is used to selectively preheat the preform 802 prior to the blowing process, and as further described below with respect to step 904 of FIG. 9. In one embodiment, pre-pressurization can be applied to the mold before the mold is closed, thus minimizing damage to the preform, if the preform has a radius greater than the smallest radius of the mold, as previously described.
[0033] The bottom strength of the closed end portion 806 is based on a combination of its final geometric design, metallic thickness, and compressive strength. Reductions in the bottom strength of the container can result in undesirable bulging or deformation when subjected to pressure from a beverage stored in it. Such undesirable bulging or deformation is much less likely to occur at body portion 808, due to the bowing force associated with the geometry of the container walls.
[0034] It may be desirable to maintain the ability of the bottom portion to withstand, for example, a pressure of at least 90 pounds per square inch, without bulging or alternatively without deforming plastically (permanently) during the process of heating the preform. The distance between the closed end portion 806 and the heating device 810, which allows heat within the side walls of the body portion 808 to dissipate sufficiently before being conducted to the dome-shaped metal bottom portion 806, in order to avoid compromising its ability to withstand, for example, a pressure of at least 90 pounds per square inch, without bulging or plastic deformation, depends on factors such as (i) the material and thickness of the preform, (ii) the heating device temperature 810, (iii) the target temperature for body portion 808, and so on, and can be determined for any particular configuration, through tests, simulations, etc. In addition, cooling air (or other fluid) can be directed along the lower portion 806 to facilitate heat dissipation.
[0035] Initial thickness and diameter of the preform, as well as the desired maximum radial expansion can influence the extent to which the body portion 808 of the preform is heated. For example, a preform, with an initial diameter of 45 millimeters and a desired radial expansion of 20% can be blow molded at room temperature or need to be heated to a temperature, such as below 200 degrees Celsius, to allow the complete stretching expansion of the metal of the preform during blow molding. A preform having an initial diameter of 38 millimeters and a desired radial expansion of 42% may need to be heated to a higher temperature (for example, at least 280 degrees Celsius) to allow complete stretching expansion of the preform metal during blow molding, etc. In addition, the times associated with the transfer of preforms from the heating station to the blow molding station can further influence the heating strategy, as the preforms can cool during this transfer. Decreases in temperature of the preform in the order of 100 degrees Celsius, for example, were observed during a transfer time of 6 seconds.
[0036] It should be understood that temperature ranges from approximately 100 degrees Celsius to approximately 250 degrees Celsius can be used, depending on the material, gauge, heating time, and so on. Desired temperatures for various portions of a given preform design, as well as heating times, etc., can be determined through tests or simulations. Contrary to the pressure molding process described above which is not preheated or preheated to a temperature of 200 degrees Celsius or higher, the preform can be coated after the blow molding process, as provided in FIG. 9, thus preventing the coating from being damaged during the heating process, if the heating process has to be at least about 200 degrees Celsius. As understood in the art, applying a coating to a molded preform is possible, but it is technically more difficult and expensive than applying a coating to a preform before molding.
[0037] With reference to FIG. 9, a flow diagram 900 of an illustrative process for blow molding a metal container is shown. Process 900 begins at step 902, where a metallic preform can be provided. The metal preform can be a cold-deformation hardened metal, such as aluminum from the 3000 series. In step 904, the metal preform can be heated as described above (ie the heat of the body portion and not the open and closed ends of the preform) before a blow molding operation in operation 906. In operation 906, the preheated preform is blow molded to form portions of the preform in a desired shape. In one embodiment, the desired shape may be the shape of a glass bottle. The pressure within the preform can be increased, for example, to 40 bar, in approximately 0.5 seconds using fluid at room temperature or heated to an elevated temperature (for example, 200-300 degrees Celsius) to expand the portions of the preform within a surrounding mold. Other situations, of course, are contemplated. Further processing of the molded preform can then be carried out.
[0038] Process 900 can be carried out using at least a partially automated process. In carrying out process 900, controller 814 may be in communication with machinery 816 to cause preform 802 to be heated by heat 812 being generated by heating device 810. For example, controller 814, in communication with machinery 814, can cause the preform 802 to pass near the heating device 810, causing the heating device 810 to pass near the preform 802, causing the heating device 810 to be applied to the preform 802, causing the heat from the heating device 810 to be applied through a conduit that can be movable and / or valveed (i.e., open valve applies heat, closed valve prevents heat from being applied) to the 802 preform, or by causing the heat of the heating device 810 to be applied to the preform 802 in any other way, as is understood in the art. Controller 814 may be in communication with heating device 810 to cause heating device 810 to generate heat. In one embodiment, the heating device 810 can be configured for a specific temperature by controller 814. While represented that the heating device 810 is in close proximity to the metal preform 802, it should be understood that the heating device 810 can be positioned from metal preform 802 and that a conduit (not shown) extending from heating device 810 to preform 802, as suggested above, can be used to apply heat to preform 802 while positioned at a station, such as at a molding station, or while being passed between stations by a conveyor, loader, or other machinery, as understood in the art. In another embodiment, the mold itself can be configured to apply heat or have heat applied to it before and / or during the molding process.
[0039] It has also been found that certain initial preform geometries improve the performance of the heated blow molding process described above. That is, the containers formed by means of heated blow forming from these preforms have less cases of wrinkles, tears or other defects.
[0040] With reference to FIG. 10, a tubular metal preform 1000 was formed from a sheet of metal having an initial thickness or gauge, for example, in the range of 0.025 inches or less. Preform 1000 has an open end portion 1002, a closed end portion 1004, and a body portion 1006. Preform 1000 further has a thickness, T, a maximum width, D, and a height, H The thickness, T, can vary over the height, H, of the 1000 preform and has, for example, a nominal value of 0.010 inches. The closed end portion 1004 has a flat portion 1008 (to promote stability during transport) having a maximum width, d, and a curved portion defined by an effective radius of curvature, R, connecting the flat portion and a vertical wall of the body portion 1006. In other examples, R can be a composite ray (two or more rays mixed in an arc that is tangent to the flat portion and vertical wall).
[0041] Experimentation and simulations revealed that preforms that conform to at least some of the following ratios are generally well suited for the heated blow molding operations discussed above: D ≤ 2R + d (eq.1) d / D ≥ 0.3 (eq. 2) H / D ≥ 3 (eq. 3) For example, if D is 45 millimeters and H is 185 millimeters, then d can be 13.5 millimeters or greater, and R can be 15.75 millimeters or greater (or a compound radius can be used as desired. ).
[0042] Although exemplary embodiments are described above, these embodiments are not intended to describe all possible forms of the invention. The words used in the specification are words of description rather than limitation, and it is understood that various modifications can be made without departing from the spirit and scope of the disclosure. As previously described, the characteristics of several embodiments can be combined to form more embodiments of the invention that may not be explicitly described or illustrated. Although several modalities may have been described as providing advantages or being preferred over other modalities or implementations of the prior art, with respect to one or more desired characteristics, those skilled in the art recognize that one or more features or characteristics may be compromised to achieve the desired attributes of the global system, which depend on the specific application and implementation. These attributes may include, but are not limited to, cost, strength, durability, life cycle cost, marketability, appearance, packaging, size, maintenance, weight, manufacturability, ease of assembly, etc. As such, the modalities described as less desirable than other modalities or implementations of the prior art with respect to one or more features, are not outside the scope of the disclosure and may be desirable in specific applications.

权利要求:
Claims (18)
[0001]
Method of manufacturing a metal container (118), the method being characterized by the fact that it comprises: providing a preform (110, 114, 802, 1000) being formed from a cold deformed metal, the preform having an open portion (804, 1002), a closed end portion (806, 1008 ), and a body portion (808, 1006); preheat the body portion (808, 1006) of the preform (110, 114, 802, 1000) in a way that limits the heat being applied to the open portion (804, 1002) and the closed end portion (806, 1008) the preform (110, 114, 802, 1000); inserting the preheated preform (110, 114, 802, 1000) into a mold (202) that includes multiple segments (204a, 204b); applying a pre-pressure by supplying a fluid into the preform (110, 114, 802, 1000) at a first pressure level before closing the multiple segments of the mold (202); closing the multiple segments (204a, 204b) of the mold (202); blow mold the preform (110, 114, 802, 1000) by increasing the applied pressure using a step function to a second pressure level after the mold (202) is closed, increasing the pressure from the first pressure level to the second pressure level occurring in less than 0.2 seconds to cause the preform (110, 114, 802, 1000) to take the shape defined by the mold (202); and removing the preform (110, 114, 802, 1000) molded from the mold (202).
[0002]
Method, according to claim 1, characterized by the fact that the second pressure level is above 4 Mpa (40 bar).
[0003]
Method according to claim 2, characterized by the fact that preheating the body portion (808, 1006) of the preform (110, 114, 802, 1000) includes heating the body portion (808, 1006) of the preform -shape (110, 114, 802, 1000) at no more than 200 degrees Celsius.
[0004]
Method according to claim 1, characterized in that heating the body portion (808, 1006) of the preform (110, 114, 802, 1000) includes heating the body portion (808, 1006) of the preform -form (110, 114, 802, 1000) at between 200 degrees Celsius and 280 degrees Celsius.
[0005]
Method according to claim 4, characterized in that it further comprises the application of a coating to the preform (110, 114, 802, 1000) after blow molding of the preform (110, 114, 802, 1000).
[0006]
Method according to claim 1, characterized in that providing a preform (110, 114, 802, 1000) includes providing a preform (110, 114, 802, 1000) with a radius that is greater than 45 percent less than the maximum mold radius (202).
[0007]
Method according to claim 1, characterized in that providing a preform (110, 114, 802, 1000) includes providing a preform (110, 114, 802, 1000) with a gauge less than 0, 64 mm (0.025 inch).
[0008]
Method according to claim 1, characterized in that providing a preform (110, 114, 802, 1000) includes providing a preform (110, 114, 802, 1000) having a closed end portion ( 806, 1008) with the following parameters, where D is the maximum width, R is the effective radius of curvature and d is the maximum width of the flat base portion: D <2R + d (eq. 1) d / D> 0.3 (eq. 2) H / D> 3 (eq. 3)
[0009]
Method according to claim 1, characterized in that providing a preform (110, 114, 802, 1000) includes providing a preform (110, 114, 802, 1000) having a closed end portion ( 806, 1008) with a compound radius.
[0010]
System for the manufacture of a metallic container, the said system being characterized by the fact that it comprises: a heating device (810) for use in preheating a preform (110, 114, 802, 1000) being formed from a cold deformed metal, the preform (110, 114, 802, 1000 ) having an open portion (804, 1002), a closed end portion (806, 1008), and a body portion (808, 1006), the heating device (810) being configured to heat the body portion (808 , 1006) of the preform (110, 114, 802, 1000) in a way that limits the heat being applied to the open portion (804, 1002) and closed end portion (806, 1008) of the preform ( 110, 114, 802, 1000); a mold (202) including multiple segments (204a, 204b), and being configured to receive the preheated preform (110, 114, 802, 1000) when in an open position; a means for applying pre-pressure to the preform (110, 114, 802, 1000) by supplying a fluid into the preform (110, 114, 802, 1000) at a first pressure level before closing the multiple segments (204a, 204b) of the mold (202); and a blowing device configured for the blow mold (202) of the preform (110, 114, 802, 1000) when said mold (202) is in a closed position by increasing the pressure applied using a step function to a second level pressure after the mold (202) is closed, the pressure increase from the first pressure level to the second pressure level occurring in less than 0.2 seconds to make the preform (110, 114, 802, 1000 ) take a shape defined by the mold (202).
[0011]
System according to claim 10, characterized in that said means for applying a pre-pressure to the preform (110, 114, 802, 1000) is configured to reach the first pressure level which is at least 0 , 5 MPa (5 bar).
[0012]
System according to claim 10, characterized by the fact that the blowing device is configured to reach the second pressure level which is at least 4 MPa (40 bar).
[0013]
System according to claim 10, characterized in that said heating device (810) is configured to heat the body portion (808, 1006) of the preform (110, 114, 802, 1000) not more than about 200 degrees Celsius.
[0014]
System according to claim 10, characterized by the fact that it comprises the preform (110, 114, 802, 1000), in which the preform (110, 114, 802, 1000) has a radius that is greater than the smaller radius of the mold (202).
[0015]
System according to claim 10, characterized in that said heating device (810) is configured to heat the body portion (808, 1006) of the preform (110, 114, 802, 1000) between 200 degrees Celsius and 280 degrees Celsius.
[0016]
System according to claim 15, characterized by the fact that it comprises the preform (110, 114, 802, 1000), in which the preform (110, 114, 802, 1000) has a gauge less than 0 , 64 mm (0.025 inches), preferably between 0.1 mm and 0.51 mm (0.004 and 0.020 inches).
[0017]
System according to claim 10, characterized by the fact that the means for applying the pre-pressure to the preform (110, 114, 802, 1000) comprises a controller that causes the fluid to be supplied into the preform -form (110, 114, 802, 1000).
[0018]
System according to claim 17, characterized by the fact that the fluid is a first fluid, and in which the blowing device is configured to supply a second fluid to the preform (110, 114, 802, 1000).

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法律状态:
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优先权:

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