The present disclosure relates generally to adhesive application systems, and more particularly, to adhesive application apparatus and methods.
Laminated panel assemblies such as, for example, structural insulated panels, are often employed in buildings and other structures. Laminated panels typically include a foam or insulated core that is disposed between outer laminated panels. In some examples, the panels may be composed of metal and the core may be composed of a foam or insulating material. A bonding agent such as an adhesive or glue is typically used to adhere or otherwise couple the outer panels to the core.
Manufacturing facilities typically employ adhesive application systems to apply the adhesive or bonding agent to the outer panels and/or the core. The outer panels are then coupled to the core and are pressed via a pressing machine to form a laminated panel assembly.
Conventional adhesive application systems often employ a drip and wiper system. A drip and wiper system typically applies or drips separate components or materials of an adhesive or bonding agent onto a laminating surface of the outer panels and/or the core, and a wiper blade oscillates across the laminating surface to mix the adhesive components together. Also, adhesive volume application rates of known systems are usually adjusted based on an operator's visual inspection. As a result, an operator may tend to apply excessive amounts of adhesive to avoid the risk of de-lamination between the panels and the core. However, with the low volume adhesive application rates needed for some applications, for example, an operator may not be able to differentiate between an adhesive application rate or adhesive spread (e.g., an amount of adhesive per area) of 80 grams/meter2 and 130 grams/meter2. Although both adhesive application rates may be adequate to laminate a panel assembly such as, for example, an Expanded Polystyrene (EPS) panel, there is a significant cost difference between using the different adhesive application rates. For example, the cost difference between using an adhesive application rate or spread of 80 grams/meter2 and an adhesive application rate or spread of 130 grams/meter2 for a production line generating EPS panels may be approximately $100,000 per year.
The example adhesive application systems described herein provide a low maintenance system that may be used with panel assembly production lines (e.g., sandwich panel lines, Structural Insulated Panels (SIP) panel lines, etc.). Unlike many known adhesive application systems, the example adhesive application systems described herein can deliver a precise quantity of adhesive or an adhesive application rate to a spray area that result in significant cost savings. Also, the example adhesive application systems described herein provide a low pressure system to deliver consistent, uniform and/or evenly distributed amounts of adhesive to a spray area of a panel. Uniform delivery of precise amounts of adhesive over a spray area significantly reduces the risk of de-lamination due to voids or insufficient amounts of adhesive while preventing excessive application of adhesive to reduce costs.
The example adhesive application systems describe herein generally provide a low pressure system that can spray a bonding agent or adhesive composed from multiple different adhesive components. For example, the bonding agent may be composed of a two component polyurethane adhesive for the lamination of a core insulating material such as, for example, expanded polystyrene (EPS), mineral wool, polyurethane or polyiscoyanurate sheet, to upper and/or lower substrates including, but not limited to, pre-painted coil steel, aluminum, aluminum foil, glass reinforced plastic (GRP), cement board, Oriented Standard Board (OSB), particle board, etc.
Additionally, the example adhesive application systems described herein provide a low pressure system to prevent misting during application of the adhesive to form a laminated panel. Excessive misting may contaminate an area or environment surrounding the area in which a laminated panel is formed or manufactured. Such misting may cause damage to nearby equipment and/or products or pose health risks to operators. Unlike many known adhesive application systems, which rely on hydraulic pressure to atomize the adhesive into a spray pattern, the example adhesive application systems described herein do not use hydraulic pressure to create a spray pattern. Instead, the example adhesive application systems described herein employ a spray assembly having a pressurized air line adjacent a spray nozzle outlet to provide or improve a spray pattern of the adhesive to significantly reduce or prevent misting. As a result, for example, a spray nozzle of the spray assembly may be positioned (e.g., at a spray height or distance of) between approximately 85 millimeters and 120 millimeters relative to an area of a panel to be sprayed. In contrast, spray nozzles of known systems require at least a 300 millimeter spray height to function properly. An example spray nozzle described herein can spray pressurized air together with a quantity of adhesive at a spray rate of between approximately 240 grams/minute and 1,500 grams/minute during an adhesive application cycle.
Further, unlike many conventional systems in which an operator visually adjusts an adhesive application rate or volume, the example adhesive application systems described herein enable precise control or adjustment of an adhesive application rate or volume for a particular production run via, for example, a control system. For example, the system may automatically and continuously deliver a required or desired amount of adhesive per area (e.g., an adhesive application rate) to a spray area or surface of a laminated panel and may automatically adjust an adhesive flow rate (e.g., a mass flow rate through a spray nozzle) in response to changes in, for example, a speed of a production line to maintain a consistent and uniform adhesive application rate across the spray area. For example, with use of volumetric flow meters and an interface that detects a speed of a production line, the example system enables a user to set or input a desired adhesive coverage rate (an amount of adhesive per area) for a particular production run or panel and the system may automatically adjust the adhesive flow rate through the spray nozzle when the speed of the production line increases or decreases to provide a precise, uniform or consistent adhesive application rate across a spray area of a panel. For example, the example systems described herein can support low volume production lines that require adhesive application rates of between about 120 grams/meter2 and 220 grams/meter2 delivered at flow rates between about 360 grams/minute and 1,500 grams/minute. In contrast, many known systems often provide a relatively high pressure, high volume spray pattern that typically oversupplies an adhesive to a panel and, thus, are often not suitable for use with most standard, low volume production lines because these known systems cannot provide or deliver flow rates less than 750 grams/minute.
Additionally, the example systems described herein deliver a precise, proportionate mix of adhesive components. Thus, in contrast to known drip and wiper systems, the example systems described herein employ a static mixer to mix adhesive components prior to spraying on a spray area via the spray nozzle. By mixing the adhesive prior to spraying, the resultant adhesive provides greater or increased boding strength compared to adhesive mixed in the known drip and wiper systems. As a result, a smaller amount of adhesive may be applied due to the increased boding ability provided by the pre-mixed adhesive as compared to the bonding strength of the adhesive achieved via the drip and wiper method.
Additionally, the example adhesive application systems described herein employ a primed and self-cleaning system. The self-cleaning system may be automatically activated when a production line is stopped or a production run is complete. The self-cleaning system uses a cleaning agent or solvent to flush a spray nozzle and/or a mixing assembly to remove residual adhesive from the adhesive application system. As a result, no priming and no messy or time consuming clean-up is required. The example adhesive application system may also include fluid control devices (e.g., check valves) to prevent the adhesive from flowing to a spray assembly during non-use so that a spray nozzle and/or a mixing assembly remain primed and ready to start without preparation.
In the illustrated example, the example adhesive application system 102 may be placed between an uncoiler assembly 108 and a subsequent operating unit 110 such as, for example, a conveyor frame and/or a panel press bed. In this example, the uncoiler assembly 108 may include a first or upper uncoiler 108a to support a first panel or skin 106a (e.g., a metal panel, a plastic panel, etc.) and a second or lower uncoiler 108b to support a second panel or skin 106b. For example, the panels 106 move from the uncoiler assembly 108, through the adhesive application system 102, and to the subsequent operating unit 110 in a direction generally indicated by arrow 112. Although not shown, one or more rollers, conveyors or guides may be used to move the panels 106 toward the adhesive application system 102. The adhesive application system 102 applies an adhesive or a bonding agent to the panels 106 as the panels 106 move toward the subsequent operating unit 110. In particular, a first spray assembly 114 of the adhesive application system 102 applies or sprays a first quantity of adhesive to a first side or designated spray area 116 (e.g., an outer surface of an inner layer or an inner surface of an outer layer) of the panel 106a and a second spray assembly 118 of the adhesive application system 102 applies a second quantity of adhesive to a second side or designated spray area 120 (e.g., an outer surface of an inner layer or an inner surface of an outer layer) of the panel 106b.
In operation, the first spray assembly 114 moves relative to the spray area 116 of the panel 106a in directions indicated by arrow 122 and the second spray assembly 118 moves relative to the spray area 120 of the panel 106b in directions indicated by arrow 124. Thus, the spray assemblies 114 and 118 move generally perpendicular relative to the direction of travel 112 of the panels 106a and 106b as the spray assemblies 114 and 118 apply or distribute an adhesive to the respective spray areas 116 and 120 of the panels 106a and 106b. The system 102 includes volumetric flow meters to measure and/or adjust a flow rate of an adhesive being applied to the spray areas 116 and 120, which may vary depending on the speed of the production line 104, to ensure that a consistent, uniform or even amount or quantity of adhesive is applied to the spray areas 116 and 120. After the adhesive is applied to the panels 106, the subsequent operating unit 110 presses the panels 106 against a core to form a laminated panel assembly (not shown). The subsequent operating unit 110 may transport the laminated panel assembly to other subsequent operating units.
Referring to
The adjustment mechanism 302 includes a front guide track 310 and a rear guide 312 along which the spray assemblies 114 and/or 118 can be adjusted. In this example, the adjustment mechanism 302 includes a motor (e.g., a servo motor or linear actuator) to adjust or move the spray assemblies 114 and/or 118 relative to the frame 202 in the direction of arrow 308 (e.g., a vertical direction).
To move the spray assemblies 114 and 118 in the direction of arrows 122 and 124 relative to the respective spray areas 116 and 120 of the panels 106a and 106b as shown in
In operation, the pumps 210 and 212 pump the adhesive components 204a and 204b (
Each of the spray assemblies 114 and 118 also includes a purging and cleaning system 328. Following completion of a production run, the adhesive component supply or flow from the containers 206 and 208 to the mixing assembly 326 is stopped or prevented. For example, pneumatically actuated ball valves (not shown) positioned between the pumps 210 and 212 and the mixing assembly 326 may be moved to a closed position to prevent flow of the adhesive components 204a and 204b to the mixing assembly 326. Additionally, the drive system 316 of each spray assembly 114 and 118 may retract the spray booms 318 from the production line 108 to a purging position. A purging container or receptacle 332 (e.g., a clam shell-type container) captures or closes around the spray nozzle 320 of each spray assembly 114 and 118. The purging container 328 includes a rubber gasket or seal 334 to provide a substantially tight seal around the spray nozzle 320. Thus, when an upper portion of the purging container 332 moves to closed position to engage a lower portion of the purging container 332, the gasket 334 provides a substantially tight seal to prevent fluid from escaping the purging container 332 during a purging or cleaning operation.
During a cleaning cycle, a combination of air and cleaning solvent is flushed through each spray assembly 114 and 118 and/or the spray nozzles 320 to remove any adhesive (e.g., mixed glue) from the mixing assembly 326 and/or the spray nozzles 320. Thus, the spray nozzle 320 sprays a second quantity of adhesive remaining in the mixing assembly 326 into the purging container 332. After the cleaning cycle is complete, the system 102 is primed and ready for another production run. Thus, no priming or messy or time consuming cleanup is required. The waste material is drained from the purging container 332 to a waste containment unit (not shown) via, for example, a vacuum system. After the operations of the purging and cleaning system 328 are complete, the purging container 332 moves to an open position (e.g., an upper half of the container 332 moves away from a lower half of the container 332) to release the spray nozzle 320 and/or the spray boom 318. In some examples, a controller of the system 102 may activate the purging and cleaning system 328 when the production run is complete. However, in other examples, the purging and cleaning system 328 may be activated manually by an operator.
Referring to
As most clearly shown in
Thus, the pumps 212 and 214 pump or move the adhesive components 204a and 204b to the mixing chamber 412 of the spray assembly 114, where the components 204a and 204b are combined to begin the mixing process. The combined adhesive components 204a and 204b are then mixed in the spiral static mixing chamber 410 to form the resultant adhesive or bonding agent 322 that is sprayed on the panels 106. The mixing assembly 326 significantly improves the boding performance or strength of the adhesive 322, thereby requiring a lesser amount or volume of the adhesive 322 during the lamination process.
Further, unlike many known systems, the spray nozzle 320 provides a low pressure, low volume spray pattern 502 that can be used with sandwich panel lamination production lines requiring relatively low adhesive application rates (e.g., less than 700 grams/meter2). As a result, the spray nozzle 320 of the example system 102 can provide low volume, adhesive application rates or adhesive spreads of between approximately 120 grams/meter2 and 220 grams/meter2 delivered at flow rates between approximately 360 grams/minute and 1,500 grams/minute.
The example apparatus 700 may be implemented using any desired combination of hardware, firmware, and/or software. For example, one or more integrated circuits, discrete semiconductor components, and/or passive electronic components may be used. Additionally or alternatively, some or all of the blocks of the example apparatus 700, or parts thereof, may be implemented using instructions, code, and/or other software and/or firmware, programmable logic control (PLC), etc. stored on a machine accessible medium that, when executed by, for example, a processor system (e.g., the processor system 910 of
As shown in
The user interface 702 may be configured to receive (e.g., via user inputs) panel characteristics such as, for example, an area or size of the spray areas 116 and 120 of the panels 106a and 106b, the type of the panels 106 or core, a material of the panels 106 or core (e.g., aluminum, steel, etc.), the adhesive application rate or adhesive spread (e.g., an amount of adhesive per unit area), the speed of the production line 104, etc. For example, the user interface 702 may be implemented using a mechanical and/or graphical user interface via which an operator can input the characteristics the adhesive application rate to be applied to the spray areas 116 and 120.
The frame adjustor 704 may be configured to adjust the height or lateral (e.g., a vertical position) or lateral position of the spray nozzles 320 relative to the spray areas 116 or 120 of the panels 106a and 106b. For example, the frame adjustor 704 may be configured to obtain position values from the user interface 702 to adjust or set the lateral position of the spray nozzles 320 relative to the spray areas 116 or 120 of the respective panels 106a and 106b based on the panel characteristic(s) (e.g., the thickness of the panels 106, the material of the panels 106, the adhesive application rate, etc.). For example, the frame adjustor 704 may cause or initiate operation of the adjustment mechanism 302 to move the spray boom 318 in the direction of the arrow 308 to adjust a distance (e.g., the vertical distance) between the spray areas 116 or 120 and the spray nozzles 320.
The flow rate adjustor 706 may be configured to adjust the flow rate (e.g., a mass flow rate) of the adhesive 322 to be sprayed or dispensed by the spray nozzles 320 on the spray areas 116 or 120. The flow rate adjustor 706 may be configured to obtain the adhesive application rates (e.g., amounts of adhesive per unit area) or flow rate characteristics from the user interface 702. For example, an operator can select the adhesive application rate, adhesive spread or flow rate via the user interface 302. In some examples, the flow rate adjustor 706 may determine the flow rate value(s) by retrieving predetermined values from the storage interface 710 (e.g., via a look-up table) based on the characteristic(s) of the panels 106 and the speed of the production line 104 provided via the user interface 702.
To deliver the desired adhesive application rate, the flow rate adjustor 706 operates the pumps 210 and 212 to deliver the adhesive components 204a and 204b from the containers 206 and 208 to the mixing assembly 326 and the spray nozzles 320. To operate the pumps 210 and 212, the flow rate adjustor 706 causes or initiates operation of the motors 214 and 216, which are operatively coupled to a variable speed drive.
The flow rate detector 708 may be configured to detect a flow rate of the adhesive being sprayed or delivered to the spray areas 116 and/or 120 of the panels 106a and 106b through the spray nozzles 320. To detect the flow rate, the flow rate detector 708 may include one or more volumetric flow meters to measure the flow rate (e.g., a flow rate) of the adhesive 322 flowing through the spray nozzles 320. The flow rate detector 708 can then communicate the values measured by the volumetric flow meters to the comparator 712 and/or the storage interface 710.
The comparator 712 may be configured to compare the measured flow rates provided by the flow rate detector 708 with known calculated flow rates that provide the adhesive application rate or spread values received by the user interface 702 based on the speed of the production line. For example, if the comparison results obtained from the comparator 708 indicate that a measured flow rate provided by the flow rate detector 708 deviates by some threshold amount from the target adhesive application rate provided by the user interface 702, then the flow rate adjustor 706 adjusts (e.g., increases or decreases) flow rate of the adhesive. For example, the flow rate adjustor 706, may adjust the speed of the motors 214 and 216 that operate the pumps 210 and 212 based on the comparison results obtained from the comparator 712 to control the adhesive application rate or adhesive spread value to be substantially equal to (or within a predetermined tolerance of) the value provided by the user interface 702.
Alternatively, the flow rate adjustor 706 may adjust the flow rates of the adhesive 322 based on flow rates or adhesive application rates stored in a look-up table (not shown) in association with the characteristics of the panels 106 received from the user interface 702. The storage interface 310 may be configured to store data values in a memory such as, for example, the system memory 924 and/or the mass storage memory 925 of
The drive adjustor 714 may be configured to drive or move the spray nozzles 320 via the spray booms 318 in the direction of arrows 122 and 124 relative to the spray areas 116 and 120. For example, the drive adjustor 714 may cause or initiate the motor 408 of the drive system 316 to move the spray booms 318 of the spray assembly 114 across the spray area 120 in the direction of the arrow 122 as the panel 106b moves along the production line 104 in the direction of the arrow 124. The drive adjustor 714 may cause the spray assembly 118 to move across the spray area 116 independently and/or at a different speed than the spray assembly 114.
For example, the drive adjustor 714 may receive the panel characteristic(s) from the user interface 702 and/or may receive an area of coverage or the size of the spray areas 114 and 120 from the user interface 702 and/or the storage interface 710.
The spray atomizer interface 716 may be configured to provide the pressurized air flow 504 to the spray nozzles 320. The spray atomizer interface 716 may adjust an air flow characteristic (e.g., an air flow velocity, an air pressure, etc.). For example, the spray atomizer interface 716 may adjust the amount of air and/or the air flow rate to be introduced to the spray nozzles 320 to adjust or alter the spray pattern 502 of the adhesive 322 expelled from the spray nozzles 320. For example, the spray atomizer interface 716 may cause a pump or motor (not shown) to operate to provide the desired pressurized air flow 504 within the spray nozzles 320.
The reference speed detector 718 may be configured to sense a speed of the production line 104. The reference speed detector 718 may be communicatively coupled to an encoder or speed measurement device (e.g., a sensor) that measures a reference speed value of the production line 104. For example, the reference speed detector 718 may obtain, retrieve or measure a reference speed based on the speed of the panels 106 traveling through the adhesive application system 102 (e.g., a line speed). Additionally or alternatively, the reference speed detector 718 receives a reference speed of the production line 104 from the user interface 702. Additionally or alternatively, the reference speed detector 718 may be configured to send the reference speed measurement value to the comparator 712. Additionally or alternatively, the reference speed detector 718 may then send the reference speed measurement value to the flow rate adjustor 706 and may then cause the flow rate adjustor 706 to adjust the flow rate of the adhesive 322 flowing through the spray nozzle 320 to achieve the desired adhesive application rates or adhesive spread provided by the user interface 702 and/or the storage interface 710 based on the change in the production line speed value measured by the reference speed detector 718. Thus, the system 102 can automatically adjust the adhesive flow rates through the spray nozzle 320 with changes in the speed of the production line 104 to maintain or provide a substantially consistent, uniform or even amount of adhesive on the spray areas 116 and 120.
The fluid control interface 720 may be configured to prevent flow of the adhesive components 204a and 206b to the mixing assembly 326. For example, the fluid control interface 720 may cause a fluid control device (e.g., a pneumatically controlled ball valve) to move to a closed position to prevent fluid flow between the pumps 210 and 210 and the mixing assembly 326. To determine whether the fluid control device is to move to a closed position, the fluid control interface 720 may be configured to determine if the production run is complete or the production line 104 has stopped. For example, the reference speed detector 718 may send a signal to the fluid control interface 720 to indicate that a production run is complete or stopped based the measured speed value detected by the reference speed detector (e.g., a zero speed value).
The cleaner interface 722 may be configured to prime and clean the spray nozzle 320 and/or the mixing assembly 326 of the spray assemblies 114 and 118. For example, the cleaner interface 722 may be configured to receive a signal from the reference speed detector 718 that a production run is complete or has stopped. The cleaner interface 722 may then initiate a purging and cleaning cycle. The cleaner interface 722 may send a signal to, command or otherwise cause the drive adjustor 714 to position the spray nozzle 320 within the purging container 332 (e.g., a purging position). The cleaner interface 722 may cause an upper portion of the purging container 332 to clamp against a lower portion of the purging container 332 to sealingly engage the spray nozzle 320. The cleaner interface 722 may then send a signal to control or otherwise cause a motor and/or a pump (not shown) to pump a cleaning solution or solvent through the mixing assembly 326, through the spray nozzle 320, and to a waste collection bin. The spray nozzle 320 purges a quantity of adhesive and solvent mixture remaining in the mixing assembly 326 during a cleaning cycle. The cleaner interface 722 may be configured to cause a vacuum or pump to operate to remove the waste or purged material from the purging container 332. When the cleaning or purging cycle is complete, the cleaner interface 722 causes the purging container 332 to open to release the spray nozzle 320 and sends a signal to the drive adjustor 714 that the cleaning cycle is complete.
While an example manner of implementing the adhesive application system 102 of
As mentioned above, the example process 800 of
For purposes of discussion, the example method 800 of
Turning in detail to
After the frame adjustor 304 adjusts of the position of the spray nozzles 320 relative to the spray areas 116 and 120, the flow rate adjustor 706 delivers the adhesive components 204a and 204b to the mixing assembly 326 (block 804). For example, the flow rate adjustor 706 provides an adhesive flow rate based on the production line speed value to deliver a first quantity of adhesive or adhesive application rate to the spray areas 116 and 120.
As the adhesive 322 moves toward the nozzle outlet 506 of the spray nozzle 320, the spray atomizer interface 716 provides the pressurized air flow 504 adjacent the nozzle outlet 506 (block 806). For example, the spray atomizer interface 716 provides the pressurized air flow 504 (e.g. pressurized air) to the nozzle outlet 506, where the air flow 504 atomizes with the mixed adhesive 322 to form the spray pattern 502. For example, the spray atomizer interface 716 may change the pressure of the pressurized air flow 504 to achieve a desired flow rate or spray pattern 502 of the adhesive 322.
During operation, the reference speed detector 718 obtains or retrieves a speed value of the production line 104 (block 808). For example, the reference speed detector 718 sends a signal or value to the comparator 712.
The drive adjustor 714 then drives the spray assemblies 114 and 118 across the respective spray areas 116 and 120 of the panels 106a and 106b to evenly and consistently apply the adhesive 322 to the spray areas 116 and 120 (block 810). For example, the drive adjustor 714 receives the production line speed from the reference speed detector 718 and/or from the user interface 702 and drives the spray booms 318 across the spray areas 116 and 120 to apply a consistent quantity of the adhesive 322 based on the speed of the production line 104. Additionally, the drive adjustor 714 may receive spray area information from the user interface 702 and/or the storage interface 710. In some examples, the drive adjustor 714 can move the spray assembly 118 across the spray area 116 independently and/or at a different speed than the speed and/or position of the spray assembly 114 moving across the spray area 120.
The reference speed detector 718 then determines if a magnitude of a difference between the measured production line speed provided at block 808 and the target production line speed value provided by the user interface 702 at block 802 exceeds a threshold value (block 812). For example, the threshold value may be a percentage (e.g., 1%, 5%, 10%, etc.) of the target production line speed value provided by the user interface 702 at block 802. For example, the comparator 712 compares the measured speed value provided by the reference speed detector 718 at block 808 with the target production line speed value provided via the user interface 702 at block 802.
If the speed reference detector 718 determines that the magnitude of the difference between the production line speed and the target speed does not exceed the threshold value at block 812, the process system 800 proceeds to block 822 (block 812).
If the measured production line speed value measured by the reference speed detector 718 exceeds the target production line speed value provided by the user interface 702 at block 802 by the threshold value (e.g., 1%, 5%, 10%, etc.) (block 812), then the flow rate adjustor 706 determines the desired flow rate based on the measured production line speed (block 814).
For example, the desired flow rate is to deliver or apply the adhesive application rate or spread received by the user interface 702 at block 802 for the given measured speed of the production line obtained at block 808. For example, the fluid flow rate adjustor 706 may determine the desired flow rate value from the storage interface 710 (e.g., a look-up table) and send the desired flow rate value to the comparator 712.
The flow rate detector 708 then measures the flow rate of the adhesive 322 through the spray nozzles 320 (block 816). For example, the fluid rate detector 708 sends a signal or value representative of a measured volumetric flow rate provided by a volumetric flow meter of the adhesive application system 102 to the comparator 712.
The flow rate adjustor 706 then determines if the measured flow rate is within a threshold value (e.g., 1%, 5%, 15%, etc.) of the desired flow rate (block 818). For example, the comparator 712 compares the measured volumetric flow rate provided at block 816 and the desired flow rate based on the measured production line speed provided at block 814.
If the flow rate adjustor 706 determines that the measured flow rate is within the threshold value of the desired flow rate, then the process 800 proceeds to block 822 (block 818).
If the flow rate adjustor 706 determines that the measured flow rate exceeds the threshold value of the desired flow rate at block 818, then the flow rate adjustor 706 adjusts the flow rate of the adhesive 322 (block 820). For example, the flow rate adjustor 706 increases or decreases the flow rate of the adhesive 322 by increasing or decreasing the speeds of the motors 214 and 216 of the pumps 210 and 212 until the flow rate detector 706 determines that the measured flow rate is within the threshold of the desired flow rate based on the measured production line speed value provided at block 808.
If the measured production line speed does not exceed the threshold value at block 812, or if the measured flow rate is within the threshold of the desired flow rate based on the measured production line speed at block 818, or after the flow rate is adjusted at block 820, then the cleaner interface 722 determines if the production run is complete (block 822).
For example, the cleaner interface 722 and/or the comparator 712 receive the measured speed value from the reference speed detector 718. If, for example, the comparator 712 determines that measured speed value of the production line 104 measured by the reference speed detector 718 is greater than a zero value, then the cleaner interface 722 determines that the production run is not complete and returns to block 808. If, for example, the comparator 712 determines that the measured speed value provided by the reference speed detector 718 is equal to a zero value, then the cleaner interface 722 determines that the production run is complete or the production line 104 is stopped.
When the production run is complete or stopped, the cleaner interface 722 initiates a purging and cleaning cycle (block 824). For example, the cleaner interface 722 may cause the drive adjustor 714 to position the spray nozzles 320 of the spray assemblies 114 and 118 within their respective purging containers 332. Also, the fluid control interface 720 moves a fluid control device to a closed position to prevent flow of the adhesive components 204a and 204b to the fluid lines 414 and/or the mixing assembly 326. The cleaner interface 722 then flushes the mixing chamber 412, the static spiral mixing chamber 410 and the spray nozzle 320 with a solvent solution. Once the cleaning cycle is complete, the cleaner interface 720 may cause the purging containers 332 to move to an open position to release the spray nozzles 320.
The processor system 910 of
The processor 912 of
In general, The system memory 924 may include any desired type of volatile and/or non-volatile memory such as, for example, static random access memory (SRAM), dynamic random access memory (DRAM), flash memory, read-only memory (ROM), etc. The mass storage memory 925 may include any desired type of mass storage device including hard disk drives, optical drives, tape storage devices, etc. The machine readable instructions of
The I/O controller 922 performs functions that enable the processor 912 to communicate with peripheral input/output (I/O) devices 926 and 928 and a network interface 930 via an I/O bus 932. The I/O devices 926 and 928 may be any desired type of I/O device such as, for example, a keyboard, a video display or monitor, a mouse, etc. The network interface 930 may be, for example, an Ethernet device, an asynchronous transfer mode (ATM) device, an 802.11 device, a DSL modem, a cable modem, a cellular modem, etc. that enables the processor system 910 to communicate with another processor system. The example network interface 930 of
While the memory controller 920 and the I/O controller 922 are depicted in
Referring to
The spray nozzle assembly 1002 includes a nozzle arm 1014 that couples a spray nozzle 1016 to the first portion 1008 of the housing 1006. As shown, the nozzle arm 1014 is coupled to the first portion 1008 of the housing 1006 via a fastener 1018 (e.g., a locking nut). A ball valve 1020 and an elbow 1022 couple the spray nozzle 1016 to the nozzle arm 1014 (e.g., via threads). The spray nozzle assembly 1002 also includes a second fluid line 1024 (e.g., a pneumatic line) having a first end or inlet 1026 coupled to the first portion 1008 of the housing 1006 and a second end or outlet 1028 coupled to an end 1030 of the nozzle arm 1014 adjacent the ball valve 1020. In particular, the second fluid line 1024 is adjacent (e.g., below) the nozzle arm 1014 and is coupled to the housing 1006 via a connector 1032 (e.g., a pneumatic push in connector).
The manifold assembly 1004 includes a first manifold 1034 coupled to the second portion 1010 of the housing 1006 via a connector 1036 and a second manifold 1038 coupled to the second portion 1010 of the housing 1006 via a connector 1040. The first manifold 1034 includes a plurality of fluid flow paths 1042 to fluidly couple a first adhesive component (e.g., the adhesive 204a of
Additionally, the housing 1006 defines a fluid passageway 1110 to fluidly couple the first fluid line 1012 and the second fluid line 1024. The fluid passageway 1110 is disposed adjacent (e.g., between and/or below) the passageways 1104 and 1106. Additionally, each of the passageways 1104, 1106 and 1110 defined by the housing 1006 is fluidly isolated from the other one of the passageways 1104, 1106 and 1110. In the illustrated example, the passageways 1104, 1106 and 1110 of the housing 1006 may be formed via, for example, machining, molding, and/or any other suitable manufacturing process(es).
In this example, the plurality of fluid flow paths 1042 of the first manifold 1034 are fluidly coupled or converge adjacent the connector 1036, which fluidly couples the first manifold 1034 to the first fluid flow passageway 1104 of the housing 1006. Likewise, the plurality of fluid flow paths 1044 of the second manifold 1038 converge adjacent the connector 1040, which fluidly couples the second manifold 1038 to the second fluid flow passageway 1106 of the housing 1006. The first flow passageway 1104 fluidly couples the first manifold 1034 to the mixing chamber 1108 and the second fluid flow passageway 1106 fluidly couples the second manifold 1038 to the mixing chamber 1108. Thus, adhesive components (e.g., the adhesive components 204a and 204b of
The nozzle arm 1014 of the illustrated example defines a static mixer 1112 that is in fluid communication with the mixing chamber 1108 when the nozzle arm 1014 is coupled to the housing 1006. The nozzle arm 1014 is a tubular member that includes a flow path or a channel 1114 having an inlet or first end 1116 fluidly coupled to the mixing chamber 1108 and an outlet or second end 1118 fluidly coupled to an atomizing chamber 1120. In this example, the atomizing chamber 1120 is integrally formed with the nozzle arm 1014 and is adjacent the ball valve 1020. Further, the static mixer 1112 of the illustrated example includes a plurality of projections, tabs, and/or other mixing elements, patterns or profiles 1122 that mix the adhesive components into a resultant or mixed adhesive as the adhesive components flow through the channel 1114 of the nozzle arm 1014 and the static mixer 1112. For example, the projections 1122 may define a spiral shaped flow path, profile or pattern and/or any other suitable flow path or pattern to mix components of an adhesive or other fluid(s). After the adhesive components are mixed via the static mixer 1112, the resultant adhesive flows to the atomizing chamber 1120.
The atomizing chamber 1120 receives an atomizing fluid or gas (e.g., air) via the first and second fluid lines 1012 and 1024 and the passageway 1110 of the housing 1006. The atomized adhesive (e.g., the adhesive 322 of
Although certain methods, apparatus, and articles of manufacture have been described herein, the scope of coverage of this patent is not limited thereto. To the contrary, this patent covers all methods, apparatus, and articles of manufacture fairly falling within the scope of the appended claims either literally or under the doctrine of equivalents.
This patent claims the benefit of U.S. Provisional Patent Application Ser. No. 61/522,946, filed on Aug. 12, 2011, entitled “ADHESIVE APPLICATION APPARATUS AND METHODS,” which is hereby incorporated herein by reference in its entirety.
Number | Date | Country | |
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61522946 | Aug 2011 | US |