Insulating glass units (IGUs) are used in windows and doors to reduce heat loss from building interiors during cold weather. IGUs are typically formed by a spacer assembly sandwiched between glass lites. A spacer assembly has a frame structure extending peripherally about the insulating glass unit. A sealant material bonds the glass lites to the frame structure and a desiccant for absorbing atmospheric moisture within the unit, trapped between the lites. The margins or the glass lites are flush with or extend slightly outwardly from the spacer assembly. The sealant extends continuously about the frame structure periphery and its opposite sides so that the space within the IGUs is hermetic.
U.S. Pat. No. 5,361,476 to Leopold discloses a method and apparatus for making IOUs wherein a thin flat strip of sheet material is continuously formed into a channel shaped spacer frame having corner structures and end structures, the spacer thus formed is cut off, sealant and desiccant are applied and the assemblage is bent to form a spacer assembly.
U.S. Pat. No. 7,610,681 to Calcei et al. (hereinafter “the '681 Patent”) concerns spacer frame manufacturing equipment wherein a stock supply station includes a number of rotatable sheet stock coils, an indexing mechanism for positioning one of the coils, and an uncoiling mechanism. Multiple other processing stations act on the elongated strip of sheet stock uncoiled from the stock supply station. The disclosure of the '681 Patent is incorporated herein by reference.
U.S. Pat. No. 7,448,246 to Briese et al. (hereinafter “the '246 Patent”) concerns another spacer frame manufacturing system. As discussed in the '246 Patent, spacer frames depicted are initially formed as a continuous straight channel constructed from a thin ribbon of stainless steel material e.g., 304 stainless steel having a thickness of 0.006-0.010 inches. As noted, other materials such as galvanized, tin plated steel, or aluminum can be used to construct the spacer flame. The disclosure of the '246 Patent to Briese et al. is also incorporated herein by reference. Typical thickness for these other materials range from 0.006 to 0.025 inches in thickness.
A disclosed system and method fabricates window components such as a spacer frame used in making an insulating glass unit. One of a multiple number of possible materials is chosen from which to make the window component. An elongated strip of the chosen material is moved to a notching station where notches are formed at corner locations. The character of the notches is adjusted based on the selection of the strip material and more particularly to achieve bending of the material at the corner locations in an repeatable, attractive manner. Downstream from the notching station in the example of a spacer frame, the strip is bent into a channel shaped elongated frame member having side walls. Further downstream a leading portion of channel shaped material that forms a forwardmost spacer frame is severed or separated from succeeding material still passing through the notching and bending stations.
Different alternative example embodiments for controlling the quality of the corners produced at the notching station are disclosed. It is important to apply sufficient force to the weakened (coined) zone of a corner to facilitate proper folding characteristics. Too little force can result in the corner not folding properly or at all, and too much force can result in the weakened (coined) zone of a corner to become completely removed, or clipped out, from the elongated strip.
In one example embodiment the notching station punches corner locations using dies on opposite sides of the strip stock. A first adjustable die assembly includes a first die mounted for back and forth movement perpendicular to a strip stock path of travel to accommodate different width strip stock. A second die assembly includes a second die is positioned on an opposite side of the strip stock path of travel from the first die. A ram assembly controllably drives the dies into engagement with the strip stock to form a corner location. Accurate positioning of the first die is performed by fixing a reference surface in a position based on a width of the strip stock and trapping an adjustable width spacer element between the reference surface and a die assembly surface of the adjustable die assembly that is generally parallel to the reference surface.
In one specific example embodiment, the adjustable width spacer has a body portion that includes first and second outer cylindrical surfaces having a stepped region. A sleeve fits over a small diameter cylindrical surface of the body portion. One or more annular spacers define a spacing between one end of the sleeve and an opposite end of the body portion when abutting the sleeve and the stepped region of the body. This spacer is quite accurate in positioning the first or moveable die and does this positioning without any racking or misalignment of the spacer. This in turn results in reduced friction in the notching station and increases the consistency of corner formation. For example, guides which support and define the movement of the ram assembly with respect to the strip stock are located in prescribed positions reducing friction and misalignment.
In accordance with another example embodiment, a corner forming station has a dual acting fluid powered actuator for moving a die into contact with a surface of the strip stock at controlled corner locations along a length of the strip stock. The fluid actuator includes a variable release valve for relieving pressure at a controlled rate in one chamber white fluid is pressurizing a second chamber of the actuator. By regulating the release of the fluid from one pressurized chamber more consistency in corner formation is achieved regardless of the material passing through the corner forming station.
These and other features of the disclosure will become more fully understood by a review of a description of an exemplary system when reviewed in conjunction with the accompanying drawings.
The foregoing and other features and advantages of the present disclosure will become apparent to one skilled in the art to which the present disclosure relates upon consideration of the following description of the disclosure with reference to the accompanying drawings, wherein like reference numerals refer to like parts unless described otherwise throughout the drawings and in which:
Referring now to the figures generally wherein like numbered features shown therein refer to like elements throughout unless otherwise noted. The present disclosure provides both a method and apparatus for fabricating a spacer frame for use in making a window or door. More specifically, the drawing Figures and specification disclose a method and apparatus for producing elongated spacer frames used in making insulating glass units. The method and apparatus are embodied in a production line that forms material into spacer frames for completing the construction of insulating glass units. While an exemplary system fabricates metal frames, the disclosure can be used with plastic frame material extruded into elongated sections having corner notches.
An insulating glass unit (IOU) 10 is illustrated in
The assembly 12 maintains the lites 14 spaced apart from each other to produce a hermetic insulating space 20 between them. The frame 16 and the sealant body 18 co-act to provide a structure which maintains the lites 14 properly assembled with the space 20 sealed from atmospheric moisture over long time periods during which the unit 10 is subjected to frequent significant thermal stresses. A desiccant 22 removes water vapor from air, or other volatiles, entrapped in the space 20 during construction of the unit 10.
The sealant 18 both structurally adheres the lites 14 to the spacer assembly 12 and hermetically closes the space 20 against infiltration of airborne water vapor from the atmosphere surrounding the unit 10. One suitable sealant 18 is formed from a “hot melt” material which is attached to the frame 16 sides and outer periphery to form a U-shaped cross section.
The frame 16 extends about the unit's periphery to provide a structurally strong, stable spacer 12 for maintaining the lites 14 aligned and spaced while minimizing heat conduction between the lites via the frame. The preferred frame 16 comprises a plurality of spacer frame segments, or members, 30a-d connected to form a planar, polygonal frame shape, element juncture forming frame corner structures 32a-d, and connecting structure 34 (
The preferred frame 16 is elongated and has a channel shaped cross section defining a peripheral wall 40 and first and second lateral walls 42, 44. See
The frame 16 is initially formed as a continuous straight channel constructed from a thin ribbon of material. As described more fully below, the corner structures 32a-32d are made to facilitate bending the frame channel to the final, polygonal frame configuration in the unit 10 while assuring an effective vapor seal at the frame corners. A sealant is applied and adhered to the channel before the corners are bent. The corner structures initially comprise notches 50 and weakened zones 52 formed in the walls 42, 44 at frame corner locations. See
At the same time the notches 50 are formed, the weakened zones 52 are formed. These weakened zones 52 are cut into the strip, but not all the way through. The connecting structure 34 secures the opposite frame ends 62, 64 together when the frame 16 has been bent to its final configuration. The illustrated connecting structure comprises a connecting tongue structure 66 continuous with and projecting from the frame structure end 62 and a tongue receiving structure 70 at the other frame end 64. The preferred tongue and tongue receiving structures 66, 70 are constructed and sized relative to each other to form a telescopic joint. When assembled, the telescopic joint maintains the frame 16 in its final polygonal configuration prior to assembly of the unit 10.
The Production Line 100
As indicated previously the spacer assemblies 12 are elongated window components that may be fabricated by using the method and apparatus of the present invention. Elongated window components are formed at high rates of production. The operation by which elongated window components are fashioned is schematically illustrated in
The line 100 comprises a stock supply station 102, a punching station 104, a roll forming station 106, a crimper station 108, and a severing station 110 where partially formed spacer members are separated from the leading end of the stock. At a desiccant application station 112 desiccant is applied to an interior region of the spacer frame member. At an extrusion station 114 sealant is applied to the yet to be folded frame member. A scheduler/motion controller unit 120 interacts with the stations and loop feed sensors to govern the spacer stock size, spacer assembly size, the stock feeding speeds in the line, and other parameters involved in production. At an assembly station 116, the glass lites are affixed to the frame and sent to an oven for curing.
As described more fully in the Calcei et al. patent, elongated coils 130-139 (
The scheduler/motion controller unit 120 interacts with the stations and loop feed sensors to govern the spacer stock size, spacer assembly size, the stock feeding speeds in the line, and other parameters involved in production. A preferred controller unit 120 is commercially available from Delta Tau, 21314 Lassen St, Chatsworth. Calif. 91311 as part number UMAC.
The Punching Station 104
The punching station 104 accepts the stock S from a properly positioned coil at the stock supply station and performs a series of stamping operations on the stock as the stock S passes through the punching station. The punching station 104 comprises a supporting framework 238 (
The illustrated stock driving system 140 includes a pair of rollers 156, 158 secured to the framework at an entrance to the punching station 104. The rollers 156, 158 are selectively moveable between a disengaged position in which the drive rollers are spaced apart and an engaged position in which the drive rollers engage an end portion of the strip S at the entrance of the punching station 104. The rollers 156, 158 selectively feed the sheet stock into the punching station 104.
In the illustrated embodiment, a drive roller 156 is selectively driven by a motor coupled to a drive shaft 162 that is controlled by the controller 120. An idle roller 158 is pivotally connected to its support framework. In the illustrated embodiment, the roller 158 is an idler roller that presses the sheet stock S against the roller 156 when the drive roller 156 is in the engaged position. The motor is controlled to feed the sheet stock through the station 104. In the illustrated embodiment, a sensor is positioned along the path of travel near the stamping station and creates an output for verifying that stock S is being fed.
The controller moves the pair of rollers 156, 158 to the disengaged, spaced apart position and indexes or moves an appropriate or selected sheet stock coil from the plurality of coils 130-139. At the uncoiling position, a feed mechanism positions the sheet stock end portion between the pair of rollers 156, 158. The controller 120 moves the pair of rollers 156, 158 to the engagement position to engage the coil end portion, and rotates the drive roller to feed the sheet stock into the punching station. In one embodiment, the stock driving system 140 is also used to withdraw stock from the stamping station 104 when strip stock of a different thickness, width or material is to fabricated into spacer frames.
In the disclosed system, a stock driving system 145 on an output side of the punching station 104 engages the stock provided by the stock driving system 140. The stock driving system 140 then disengages. The subsequent downstream drive system 145 has rolls that define a nip for securely gripping the stock and pulling it through the station 104 past a number of stamping units 144, 146, 148, 148′, 150, 150′, 152, 154. The downstream drive system includes an electric servomotor to start and stop with precision. Accordingly, stock passes through the station 104 at precisely controlled speeds and stops precisely at predetermined locations, all depending on signals from the controller 120.
Each stamping unit 144, 146, 148, 150, 152, 154 comprises a die assembly and a die actuator assembly, or ram assembly. Each die assembly comprises a die set having a lower die, or anvil, beneath the stock travel path and an upper die, or hammer, above the travel path. The stock passes between the dies as it moves through the station 104. Each hammer is coupled to its respective ram assembly. Each ram assembly forces its associated dies together with the stock between them to perform a particular stamping operation on the stock.
Each ram assembly is securely mounted atop the framework 238 and connected to a fluid supply source 542 (
The stamping unit 152 punches the connector holes 82, 84 (
The stamping unit 148 forms the frame corner structures 32b-d but not the corner structure 32a adjacent the frame tongue 66. The stamping unit 148 includes a die assembly 280 (
The stamping unit 150 configures the leading and trailing ends 62, 64 of each spacer frame member. The unit 150 comprises a die assembly operated by a ram assembly. The die assembly is configured to punch out the profile of the frame member leading end 62 as well as the profile of the adjoining frame member trailing end 64 with a single stroke. The leading frame end 62 is formed by the tongue 66 and the associated corner structure 32a. A trailing frame end 64 associated with the preceding frame member is immediately adjacent the tongue 66 and remains connected to the tongue 66 when the stock passes from the unit 150. The ram assembly comprises a pair of rams each connected to a hammer.
The corner structure 32a is generally similar to the corner structures 32b-d except the notches 50 associated with the corner 32a differ due to their juncture with the tongue 66. The die assembly therefore comprises a score line forming a ridge like the die set forming the remaining flame corners 32b-d.
The stamping unit 146 forms muntin bar clip mounting notches in the stock. The muntin bar mounting structures include small rectangular notches. The unit 146 comprises a ram assembly coupled to the notching die assembly. An anvil and hammer of the notching die assembly are configured to punch a pair of small square corner notches on each edge of the stock. Accordingly the ram assembly comprises a single ram which is sufficient to power this stamping operation. A single stroke of the ram actuates the die set to form the opposed notches simultaneously and in alignment with each other along the opposite stock edges.
Each time a new strip passes through the stamping station 104, a scrap piece of stock is formed that is followed by a connected first spacer flame defining length of stock in a given series of multiple spacer frames. In one embodiment, the scrap piece is defined by the punching station 104 whenever a different coil is indexed to the uncoiling station and fed into the punching station 104. The stamping unit 144 configures a leading edge of the scrap piece and trailing end 64 of the last spacer frame member in a series of spacer frame members formed from a particular coil from which the strip unwinds. The trailing edge of the scrap unit is formed by the stamping unit 150 when the leading edge of the first spacer in the next series of spacers formed from this particular sheet stock coil is stamped. The unit 144 comprises a die assembly operated by a ram assembly. The die assembly is configured to punch out the profile of the scrap piece leading end as well as the profile of the end 64 of the last frame member in the series of spacer frame members with a single stroke. The ram assembly comprises a pair of rams each connected to a hammer.
At the end of a series of spacer frame members, the stamping unit 144 forms the trailing end of the last spacer frame member in the series and the leading end of the scrap piece. The stock is then indexed to a stamping unit 154 where the connection between the end of the last spacer frame member and the leading end of the scrap piece is severed. The unit 154 comprises a die assembly operated by a ram assembly. The die assembly punches the material that spans the respective stock edges to sever the stock. The ram assembly preferably comprises a ram connected to the upper die.
A sensor detects the end of the last spacer frame in a series of spacer frame members. Upon detection of the severed end of the last spacer frame, the controller 120 causes the stock feed mechanism 140 to move the roller 156, 158 to the engaged position. The controller then actuates the motor to cause the drive roller to pull or retract the stock S out of the punching station 104 and position the stock end at the entrance to the punching station. The stock that forms the last spacer frame member in the series is driven out of the machine by the downstream stock driving mechanism. The controller then moves the stock feed mechanism 140 to the disengaged position to release the stock end. The stock end remains secured by a clamping mechanism (not shown). The controller 120 may then index the next selected coil to the uncoiling position and place the end of this next selected strip between the rollers 156, 158. The controller 120 then controls the stock feed mechanism to start the next series of spacer frame units.
In order to accommodate wider or narrower stock passing through the station 104, the die assembly is split into two parts. In one embodiment, one side of each die assembly is fixed and the opposite side of each split die assembly is adjustably movable toward and away from the corresponding fixed die assembly to allow different width spacer frames to be punched. Also, each anvil is split into two parts and each hammer is likewise split.
Referring to
The illustrated actuating system is controlled by the controller 120 to automatically adjust the punching station 104 for the stock width provided at the entrance of the station. The width of the stock provided to the station 104 may be detected and the controller automatically adjusts the station 104 to accommodate the detected width. The illustrated actuating system 304 provides positive and accurate moveable die assembly section placement relative to the stock path of travel. The system 304 comprises a plurality of drivescrews 316, a drive transmission 318 coupled to the drivescrews, and die assembly driving members 319, 320, 321, 322, 323, 325 driven by the drivescrews 316 and 20 rigidly linking the drivescrews to the anvil parts. The drive transmission 318 is attached to a die spacer 465 (described below) which rigidly attaches to an anvil support.
The drivescrews 316 are disposed on parallel axes and mounted in bearing assemblies connected to lateral side frame members. Each drivescrew is threaded into its respective die assembly driving member 319, 320, 321, 322, 323, 325. Thus when the drivescrews rotate in one direction the driving members 319, 320, 321, 322, 323, 325 force their associated die sections (hammer and anvil) to shift horizontally away from the fixed die sections. Drivescrew rotation in the other direction shifts the die sections toward the fixed die sections. The threads on the drivescrews 316 are precisely cut so that the extent of lateral die section movement is precisely related to the angular displacement of the drivescrews creating the movement.
The hammer sections of the die assemblies are adjustably moved by the anvil sections. The guide rods 302 extending between confronting anvil and hammer die sections are structurally strong and stiff and serve to shift the hammer sections of the die assemblies horizontally with the anvil sections. The hammer sections are relatively easily moved along the upper platen guides or ways.
Once the strip S leaves the punching station 104, it enters a roll forming station 106 wherein a series of rolls contact the strip and bend it into a U-shaped channel or form 312 shown in
Controlled Corner Formation
As mentioned previously the ram assembly that forms part of the stamping unit 148 preferably comprises a pair of rams supported by the framework most preferably implemented using two air actuated drive cylinders 290, 292 commercially available from Festo Corp. under the designation or model number 13049375 or 13005438. An upper die assembly includes a drive plate 400 for at least two dies which move up and down (+/−⅜″) as along the y axis seen in the elevation view of
In an exemplary embodiment, the stamping unit has a first moveable die support 420 that supports one die for deforming one side of the strip S and a second moveable die support 422 that supports a second die for deforming an opposite side of the strip. These two die supports are coupled to the drive plate 400 for up and down movement with the drive plate in response to controlled actuation of the two air actuated drives 290, 292. In the embodiment of
The stamping unit 148 has first and second moveable anvil supports 430, 432 each supporting a stripping element 440 that the die passes through to come in contact the strip S and a die contact or backing element 442. A region between the stripping element and the die contact element 442 defines a slot 444 which accommodates movement of the strip S through the punching station 104. Guide rollers (not shown) route the strip stock S (along the z direction) into the region of the die with great accuracy (within 5 thousands of an inch) so that the strip just passes through the slot 440 without binding. The die contact element 442 has a flat upwardly facing surface 442a which the die and particular the die ridge 459 (
A representative die 450 is removably connected to respective die holders 451, 453 and is depicted in
In the illustrated example embodiment of
Die/Anvil Positioning
As mentioned above, the first and second anvil supports 430, 432 are coupled to their respective die supports 420, 422 by connecting guides 302. This arrangement is further depicted in
Unlike the example embodiment of
Two movable mounts 474, 475 are attached to the drive nuts 473a, 473b so that as rotation of the screw halves moves the drive nuts, the mounts 474, 475 move as well. Due to the reverse threads used in the screw halves, the mounts 474, 475 move in opposite directions along the x axis as that axis is defined in
Threaded connectors 476, 477 attach removable stops or posts 478, 479 to the mounts 474, 475 so that the stops move back and forth with the mounts as the screw halves are rotated. As seen also in
As seen in
As seen most clearly in
The spacers or shims are made of stainless steel and can be chosen from a kit of such spacers having different thicknesses of, for example, 0.002 inch. 0.005 inch, 0.010 inch, 0.020 inch, 0.025 inch and 0.030 inch. By adding shims together, a length of the adjustable spacer between the two surfaces 480, 481 can be chosen to be between 1.300 to 1.600 inches.
The body 482 has a throughbore 491 to accommodate an elongated threaded connector 490 having a hex head (
The removable stops 478, 479 and can be removed from the mount 474, 475. As discussed below, the ram stops 410 are generally cylindrical and have threaded bases that screw into openings in the anvil supports 430, 432. By removing the removable stop 478 and spacer 465 on one or both sides of the strip stock travel path, the anvil support 430 and corresponding die support 420 can be removed as a unit by sliding them through the fixed ways. The plate 494 extends the length of the punching station 104 and supports ways or guides for other die supports that form part of the punching station 104. An output end of the screw 470 supports a pulley wheel 496 that engages an aligned pulley wheel (not shown) by means of a pulley to transmit the rotation applied by the user to a separate drive for moving other die sets that form muntin bar notches and a leading frame end 62.
Exemplary ram limiting stops 410 have a fixed cylindrical portion or base 500 made of hardened tool steel attached to the anvil support 430 by means of a threaded part 415 of the base and a threaded opening in the anvil support. A thickness T of the removable top portion 510 is used to control a total length of the stop 410, and therefore, the extent of die movement and consequently deformation of the strip S. In the exemplary embodiment, the thickness of the removable cylindrical portion 510 varies over a range to adjust downward movement of the die by as much as 0.010 inch. (ten thousandths of an inch) Stated another way, for a stainless strip S a thickness of the removable portion 510 provides adequate deformation with a stop thickness T and for Tin Plate strip of the same thickness, a removable stop is chosen having a thickness T+0.004 inch to reduce the energy transmitted to Tin plate strip.
The exemplary removable portion 510 of the stop 410 is also made of hardened tool steel and a centrally located recess 512 which fits over a stud 514 in the fixed portion 500 of the stop. Two magnets 520, 522 that attract the steel top 510 fit into recesses 534, 526 of the fixed portion 500 of the stop and have top surfaces flush with a top surface 530 of the fixed stop portion 500.
An alternate implementation of a ram stop is depicted in
In the exemplary embodiment the punch drives for moving the plate 400 are air actuated drives. In an alternate embodiment, rather than precisely controlling a degree of length of travel the dies move in response to actuation of the air actuated drives, in accordance with an alternate embodiment, the pressure supplied to the air drive is adjusted by an output from the control station 120. In yet another alternative example embodiment, the drive cylinders 290 and 292 are hydraulically actuated cylinders energized by a supply pump and motor.
The exemplary system limits movement of the dies in a somewhat empirable fashion to achieve a best result of corner fabrication. The correct amount of energy is determined by the use of a fold force gage. A goal is to achieve the same fold force regardless of material, and make the adjustments to the stop height dimension to achieve that goal.
Rather than a use of adjustable height stops, the drive comes in contact, an alternate embodiment uses an eccentric drive having a cam follower so that the throw of the drive is readily adjustable. In this embodiment the die stops would not be used as previously described above. Rather the length of travel is controlled by the position of the crank arm on a crank hub. The crank arm converts rotary motion to a linear motion. If the position of the crank arm is further away from the center of rotation of the crankshaft then the length of travel will increase. If the crank arm position is closer to the center of rotation of the crankshaft then the length of travel will decrease. By controlling the crank arm position, the effective stroke and length of travel can be controlled.
Another alternate embodiment has a die support 420 constructed from two wedge shaped mating pieces. One of the wedge shaped pieces is driven in and out horizontally with a servomotor. This horizontal motion would result in a net increase or decrease in length of travel when the die support 420 comes in contact with stops 412
An alternate example embodiment of the punch station 104 is depicted in
Turning to
In the exemplary embodiment, the two air cylinders 290, 292 are connected to an improved quick exhaust 560 (
A goal of use of the flow control 562 is to not noticeably slow the speed of the dies but improve the consistency of the strikes by the die against the strip. Stated another way, the flow control 562 allows for a known or regulated control of the exhaust to allow for a substantially repeatable load force applied to the strip S by the dies and anvils of the punch station 104.
A study of the operation of the corner notching has led to a better understanding of how various factors affect corner fold quality. Generally, after a production line is converted from Tin Plate to Stainless Steel a range of fold force (forming the 90 degree angle between spacer frame segments 30 shown in
The die stroke is about ⅜ inch. The travel time from an up limit switch signal to a down limit switch signal is about 7 milliseconds. These limit switches are attached to the air cylinder body and detect when an inner piston is up (retracted) or/down (extended) position. During this 7 millesec time the acceleration and final velocity of the dies (in the downward punch direction) is affected by several factors. Gravity is accelerating the dies. Friction is resisting the acceleration. Air pressure coming into the cylinders is accelerating the load. Air pressure on the exhaust side of the cylinder is resisting acceleration. The shearing force required to notch the strip is trying to stop the load.
Gravity is a constant. Its force will not change over time. Friction should be fairly consistent over a relatively short time period. However, friction will change over time as wear takes place. Friction may also be sharply increased or decreased with press alignment and die binding. Adjustments to the press can be made which inadvertently apply a mechanical bind to the system. Air flow in and out of the cylinders will also be fairly consistent over a short time period. Air flow characteristics however can change dramatically over time. This change is experienced as mufflers or silencers become plugged, air flow is restricted.
When the air supply to the punch station 104 is removed, the dies will fall due to gravity. If the air supply is toggled on and off several times and one observes how the dies fall, one will see some variation in the manner in which the dies fall. Sometimes the die will fall quickly, and sometimes they may fall slower. In some cases they may only fall part way, pause and then fall the rest of the way. Using pneumatics to consistently accelerate a load that will freefall, leads to some small variations. Since air is a compressible fluid, small changes in external conditions such as mechanical binding or air flow restrictions can result in noticeable changes in the consistent delivery of energy to the punch driver system. Adding the flow control 562 after the quick exhaust achieves much greater consistency in both time and load applied to the strip S by the dies.
Set up of the flow control is to some degree empircle but can be simplified if the actual force of engagement between the die and the strip S is measured. This can be performed using a force gauge commercially available from GED Integrated Solutions Inc., assignee of the present invention. (part number 2-24472) The Exemplary flow control 562 has an adjustment feature. By turning a screw. The flow control has a tapered cone spaced from a mechanical seat. The closer the cone is to the seat, the more restricted is the airflow, on the control, the flow path through the control can be adjusted for maximum flow. Best results are obtained if the flow is somewhat restricted however, so that in one exemplary system best results were obtained by rotating the screw three turns, resulting in approximately 30% reduction in flow. The exemplary flow controls have about 10 full turns (360 degrees) from open to closed, so 3 turns from open would be about 30% restriction. The data in Table I below was obtained at this setting and measures the actual measured force applied to a gauge in ounces for twelve readings. Note the range from the maximum to the minimum is only 5 ounces compared to values measured of as much as 12 ounces for a non flow restricted exhaust. This data is obtained by using the 2-24472 fold force gauge.
Crimper Station 108
A crimper assembly 610 (
The carriages 614, 616 are connected by first and second horizontally extending rods 630, 632 that pass through openings in the carriages 614, 616. The rods are anchored to one carriage 616 and on an opposite side of the path of travel the rods pass through bearings 640, 642 supported by the carriage 614. This arrangement allows the spacer frame width created by the rollformer to be varied with only minor adjustments to the crimper assembly 610.
A first steel roller 644 mounted on the lower rod 632 supports the spacer frame 312 as it exits the roll former, Springs (not shown) engage ends of this roller and are compressed between two side plates 650, 652 and the roller. This arrangement keeps the roller centered regardless of the spacer size being formed. The height of the crimper assembly 610 in relation to the roll former is adjusted so that the lower roller 644 just touches the bottom of the spacer frame as the spacer frame exits the roll former.
Pivotally mounted on the upper rod 630 is a yoke 654 which supports an upper roller 656. The yoke pivots on the upper rod. The upper roller is directly above the lower roller. An air cylinder 660 is mounted to the yoke 654. The amount of force the cylinder 660 applies to the upper roller is controlled by a precision regulator. If the cylinder does not apply enough pressure on the roller, the roller will not engage the spacer frame corners. If the upper roller 656 does not have enough down force, the cross-travel of the crimper carriage will force the upper roller out of the groove of the spacer and hit late or not at all firmly enough and the crimp will be late or nonexistent. If the cylinder force is too high, the roller will lock into the front of the lead and the crimp will not be in the desired location.
The exemplary crimper assembly 610 also includes two horizontally oriented pneumatically actuated cylinders 670, 672. Crimping fingers 674, 676 are attached to output drive rods (Not Shown) of these cylinders. The crimping fingers 674, 676 are located so that their center line of action extends parallel to and intersections a region between the center lines of rotation of the rollers 644, 656. When the cylinders are extended the crimp fingers strike the corners or leads at their center.
A v-shaped contact 681 has a beveled underside 683 which extends from a concave shaped portion 679 of the fingers 674, 676. A top portion of the contact 681 comes into contact with the lateral walls 42, 44 of the frame structure 16 (see
The contact 681 further comprises an apex 685 extending to the contact's most distal point. The concave portion 679 includes two faces 701, 703, transversely located with the concave portion and spaced apart by the contact 681. The faces 701, 703 terminate at a proximal end of the contact 681. A cylindrical boss 707 extends from each of the faces 701 and 703 beyond the apex 685 of the contact 681. The cylindrical bosses 707 are received and supported by a cylindrical support opening 709 located in respective faces 701, 703 and extend beneath the concave portion 679 of the fingers 674, 676.
Securing the bosses 707 into the respective support openings 709 are respective fasteners 711. In one example embodiment, the fasteners 711 are socket head set screws. In another example embodiment, the cylindrical bosses 707 are supports sold by GED Integrated Solutions under part number 758-0220.
During operation, an apex 685 of the fingers 674, 676 centrally engages (along the z axis of
The apex 685 and bosses 707 bias the frame members into the channel bounded by the side walls of the frame and provide a controlled bending operation to form the spacer frame segments 30 (see
An extension spring 680 attached to the carriage 616 ties one side of the crimp assembly to a fixture 681 on a lower rollformer. This spring returns the crimp assembly 610 to a start position after a crimp operation. Two small shock absorbers 682 prevent bounce when the Crimp Assembly stops.
A pneumatic system for the crimper has four exhausts located at the ports of the crimping cylinders 670, 672. They help to achieve maximum speed from the cylinders. There are two solenoid valves. One raises and lowers the top roller. The other activates the Crimping fingers. There are two pressure regulators. A first regulator determines how hard the crimp cylinders pushes on the spacer. If this regulator is set too high it will break through the corners. If it is too low the corners will not be struck hard enough. 60 to 80 psi is the exemplary range for this regulator.
The second regulator is a precision regulator that determines how much pressure is applied to the top roller 656 by the cylinder 660. It is set properly when the roller locks into the corners and leads and the crimp is in the correct location. It is preferable when adjusting this regulator to start from the low end and increase the pressure until the desired results occur. If the crimper engages too early on the leads, the pressure is too high. If the crimps are late, the pressure is too low.
Sensor Components
When an ON/OFF switch (not shown) is set to the ON position power is supplied to the crimper assembly. After power is turned on the crimper fingers are disabled until there is material threaded through the roll former. A photoeye located near spacer frame 312 enables the crimper assembly once Material is present. If no Material is present the crimper fingers will not operate.
At the bottom of the crimper assembly on one side there are two proximity sensor switches. They are named MIN and MAX. The MIN switch 690 is the switch that is covered by a bottom surface of the side plate 614 when the Crimper Assembly is not engaged with the spacer frame. The MAX proximity switch 692 is near the end of the travel when the Crimper Assembly is engaged with the spacer frame. Relays (not shown) which are actuated under the control of the controller 120 are used to control the actions of the crimper fingers.
Operation
When the top roller engages into a corner or lead the movement of the spacer frame drags the Crimper Assembly off of the MIN proximity switch. When the MN switch is lost it causes the Crimper fingers to extend. When the Crimper Assembly triggers the MAX limit switch the Roller and Crimper fingers retract so that they are no longer touching the spacer. Once they are retracted the Crimper Assembly returns to the MIN switch position. During operation of the fingers, a crimp pressure is initially set to be at least 60 psi and a maximum pressure is set to 85 psi. A roller down pressure is set to a minimum starting pressure of 0.10 Mpa and a maximum pressure of 0.25 Mpa.
While an exemplary embodiment of the invention has been described with particularity, it is the intent that the invention include all modifications from the exemplary embodiment falling within the spirit or scope of the appended claims.
The present application is a continuation application claiming priority under 35 U.S.C. § 120 to U.S. nonprovisional patent application Ser. No. 15/013,392 that was filed on Feb. 2, 2016 and published as U.S. Publication number US-2016-0144421 on May 26, 2016, which claims priority under 35 U.S.C. § 121 to divisional patent application assigned Ser. No. 13/157,827 filed Jun. 10, 2011 entitled “AUTOMATED SPACER FRAME FABRICATION” and issued as U.S. Pat. No. 9,279,283 on Mar. 8, 2016, which claims priority under 35 U.S.C. § 119(e) from U.S. Provisional patent application Ser. No. 61/364,848 having a filing date of Jul. 16, 2010. The above-identified applications are incorporated herein by reference in their entireties for all purposes. The present disclosure relates to a method and apparatus for fabricating a spacer frame for use in making a window or door.
Number | Name | Date | Kind |
---|---|---|---|
3318235 | Hanni | May 1967 | A |
3333447 | Alspaugh | Aug 1967 | A |
3722337 | Brolund | Mar 1973 | A |
3918145 | Oglivie | Nov 1975 | A |
4377084 | Kaminski | Mar 1983 | A |
4457160 | Wunsch | Jul 1984 | A |
5245904 | Meyerle | Sep 1993 | A |
5295292 | Leopold | Mar 1994 | A |
5345678 | Ronnlund | Sep 1994 | A |
5361476 | Leopold | Nov 1994 | A |
5361749 | Smith et al. | Nov 1994 | A |
5365813 | Greene | Nov 1994 | A |
5394725 | Lisec | Mar 1995 | A |
5628114 | Stern | May 1997 | A |
5640869 | Takeda | Jun 1997 | A |
6173484 | McGlinchy | Jan 2001 | B1 |
6205740 | Ekerholm | Mar 2001 | B1 |
6360420 | Shah et al. | Mar 2002 | B2 |
6678938 | McGlinchy et al. | Jan 2004 | B2 |
7448246 | Briese et al. | Nov 2008 | B2 |
7610681 | Calcei et al. | Nov 2009 | B2 |
9279283 | Briese et al. | Mar 2016 | B2 |
20050028573 | Mologni | Feb 2005 | A1 |
20050120767 | Bair | Jun 2005 | A1 |
20060075720 | McGlinchy | Apr 2006 | A1 |
20060075869 | Calcei | Apr 2006 | A1 |
20140117069 | Alber | May 2014 | A1 |
20140260491 | Briese et al. | Sep 2014 | A1 |
20160144421 | Briese et al. | May 2016 | A1 |
Number | Date | Country |
---|---|---|
1643073 | Apr 2006 | EP |
2407626 | Jan 2012 | EP |
Entry |
---|
The Briese Declaration, signed Sep. 13, 2015 by Wiliam A. Briese, and entered into the record of grandparent U.S. Appl. No. 13/157,827 on Sep. 15, 2015, 3 pages. |
“Festo: Precision Adjustment and Control—With Flow Control Valves from Festo”; seventeen pages, Aug. 2005. |
Legible copy “Festo Precision Adjustment and Control—with flow control valves from Festo”, Published 2005, seven (7) pages. |
Machinery's Handbook 25th ed., pp. 1240-1243, copyright 1996. |
Mexican Office Action for Application No. MX/a/2011/007590 dated Oct. 18, 2018 (6 pages). |
European Office Action for EP 11173368.9 dated Dec. 20, 2018 (8 pages). |
European Search Report and Search Opinion dated Nov. 23, 2016 (9 pages). |
Canadian Office Action for CA 3,030,123 dated Nov. 28, 2019 which claims priority to U.S. Appl. No. 13/157,827, the parent of the present application. (4 pages). |
Canadian Office Action for CA 3,030,123 dated Jun. 22, 2020 which claims priority to U.S. Appl. No. 13/157,827, the parent of the present application. (3 pages). |
Number | Date | Country | |
---|---|---|---|
20190337045 A1 | Nov 2019 | US |
Number | Date | Country | |
---|---|---|---|
61364848 | Jul 2010 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 13157827 | Jun 2011 | US |
Child | 15013392 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 15013392 | Feb 2016 | US |
Child | 16517069 | US |