Patent Grant
10675653
This disclosure generally relates to a fluid dispensing apparatus, and more particularly relates to a robot-mounted motorized fluid dispensing apparatus configured to dispense fluid from a cartridge.
The dispensing of fluid material at a precise location in a controlled manner presents many challenges due to the viscosity of the material and the precise location of delivery and form on an object. Conventional robot-mounted fluid dispensers are limited by the parameters of the robot, and thus often have significant performance limitations. For instance, the response time of conventional systems is relatively slow and not very accurate. As a consequence, the ability of the system to control an amount of dispensed fluid is limited, especially during rapid changes in the relative speed between a dispenser nozzle and the application site.
Moreover, various conventional fluid dispensing devices require extensive handling by an operator to load the fluid, which increases the risk of contamination. Such conventional devices are not capable of dispensing both high and low viscosity material from a cartridge, and are also unreliable. Therefore, there is a need for a reliable robot-mounted fluid dispensing system that has the ability to dispense high or low viscosity material from a prefilled cartridge. Further, there is a need for a fluid dispensing system that can automatically open or close a space to receive a replaceable fluid cartridge in order to reduce extensive handling.
The foregoing needs are met, to a great extent, by implementations of the robot-mounted motorized fluid dispensing apparatus according to this disclosure. In accordance with one implementation, a fluid dispensing apparatus, or dispenser, is configured to dispense fluid from a fluid cartridge having an internal plunger movable between a proximal end of the cartridge and a distal end of the cartridge. The dispenser includes a housing frame configured to be releasably coupled to a robot, a cartridge holder defining a cartridge holding space configured to receive the fluid cartridge and contain the cartridge under pressure, and a cartridge actuator assembly including a linear actuator and a piston rod configured to urge the plunger from the proximal end of the fluid cartridge to the distal end of the fluid cartridge for discharging fluid from the distal end of the cartridge. The dispenser further includes a dispense section having a dispense valve assembly. An end effector assembly may be coupled to the dispense section and configured to dispense the fluid to an application site in a precise and controlled manner.
In some implementations, the dispenser may further include a fluid mating member configured to releasably couple the end effector to the dispense section. The cartridge holder may include a first clamshell member fixed to the housing and a second clamshell member pivotably connected to the first clamshell member such that the second clamshell member is pivotable between an open position for loading or unloading the cartridge and a closed position for securing the cartridge in place, as well as for supporting and containing the cartridge under pressure.
In some implementations, a locking member may be configured to secure the cartridge holder in the closed position by clamping the first and second clamshell members together. The locking member may be connected to a locking actuator fixed to the housing frame and configured to move in and out of locking engagement with the first and second clamshell members. The locking actuator includes a pneumatic driver and a reciprocating rod coupled to the locking member, or other types of devices.
In some implementations, the cartridge actuator assembly may further include a motor, a drive rod coupled to the motor, such as a servomotor, and arranged substantially parallel to the piston rod, and an actuator linkage member configured to couple the drive rod to the piston rod. The piston rod may include a piston head configured to correspondingly interface with a proximal surface of the plunger of the cartridge for urging the plunger through the fluid cartridge during a dispensing operation. Moreover, the piston rod may define an internal piston passageway and the piston head defines an internal piston head passageway, such that the piston passageway and the piston head passageway are in fluid communication with each other. Additionally, the piston head may further include a fluid outlet defining at least one vent hole in fluid communication with the piston head passageway for providing ventilation so as to prevent a vacuum between the piston head and the plunger in order to relieve pressure between the piston and the plunger during piston insertion into the cartridge, and also to relieve vacuum pressure between the piston and the plunger during piston withdrawal from the cartridge. Furthermore, air pressure may be conveyed through this passage to aid in separation of the piston from the plunger and the cartridge during piston withdrawal therefrom.
In some implementations, the housing frame may also include at least one robot mounting plate configured to connect to a robotic arm of the robot for precisely controlling the location of dispensing.
In some implementations, the dispense section may further include a discharge passage configured to receive fluid discharged from the cartridge during a dispensing operation. The dispense section may also include a discharge outlet in fluid communication with the discharge passage, and a dispense valve actuator configured to move the dispense valve assembly between an open position in which fluid flows through the discharge outlet and a closed position in which no fluid flows through the discharge outlet. The dispense valve assembly may include a valve rod and a snuff back mechanism, or other type of valve.
In some implementations, the snuff back mechanism may include a snuff back element provided within the snuff back passage in fluid communication with both the discharge passage and the discharge outlet. The snuff back element may be configured to reciprocate within the snuff back passage by moving forward and backward in response to the dispense valve actuator between a respective flow position and a snuff back position. The snuff back element may define a thick region and a directly adjacent thin region, such that the thick region sealingly abuts a resilient valve seal provided at the intersection of the snuff back passage and the discharge outlet when the dispense valve is in the closed position in order to block fluid flow between the discharge passage and the discharge outlet, and the thin region does not sealingly abut the valve seal for allowing fluid to flow past the snuff back element toward the discharge outlet when dispense valve is in the open position.
In some implementations, the end effector assembly may include a dispense nozzle. In other implementations, the end effector assembly may include an applicator brush.
In some implementations, a cartridge ejector may be configured to eject the cartridge from the holding space. The cartridge ejector may include a pneumatic actuator, or other type of mechanism, defining a cylindrical ejector housing and a pneumatic ejector piston mounted for reciprocation within the ejector housing, the ejector piston being coupled to an ejector element that is configured to engage and lift at least the distal end of the cartridge. In other implementations, other types of ejector devices and methods may be used.
According to another implementation of the disclosure, a fluid dispensing system for dispensing fluid from a cartridge may include a robot having a robotic arm, a housing frame mounted to the robotic arm of the robot, a cartridge holder secured to the housing frame and configured to receive the fluid cartridge, a cartridge actuator assembly comprising a piston rod and a linear actuator, such as a servomotor, configured to move the piston rod in a reciprocating manner to urge an internal plunger of the cartridge toward a dispensing end of the cartridge. In other implementations, the cartridge actuator assembly may comprise other types of linear actuators, including an air cylinder, a hydraulic cylinder, an electric cylinder, a force tube, a ball screw, and a mechanical screw drive, among others. A dispense section is in fluid communication with the dispensing end of the fluid cartridge and having a dispense valve assembly and a snuff back mechanism. An end effector assembly may be coupled to the dispense section by a quick change adapter.
In some implementations, the snuff back mechanism includes a snuff back element having a thick region and a directly adjacent thin region. The thick region sealingly abuts a resilient valve seal provided in the dispense section in order to block fluid flow from being dispensed to the end effector, and the thin region does not sealingly abut the valve seal when the dispense valve is in the open position for allowing fluid to flow past the snuff back element. The dispense valve assembly and the snuff back mechanism may be configured to be simultaneously actuated to a flow position during the dispensing operation. In other implementations, the dispense valve assembly may be configured to perform a snuff back operation.
Various advantages, features and functions of the present disclosure will become readily apparent and better understood in view of the following description and accompanying drawings. The following description is not intended to limit the scope of the present disclosure, but instead merely details exemplary aspects for ease of understanding.
The dispensing apparatus 10 also comprises a cartridge holder 30 including a first clamshell member 32 and a second clamshell member 34. The cartridge holder 30 is configured to receive the cartridge 12 in a cartridge holding space 36. At least one of the clamshell members 32, 34 is movable toward and away from the other of the clamshell members 32, 34 for allowing the cartridge 12 to be received in and removed from the holding space 36. The dispenser 10 may be sized to accommodate a variety of cartridge sizes, such as a 6 oz. capacity cartridge or a 12 oz. capacity cartridge.
The dispensing apparatus 10 further includes a dispense section 40 having a discharge passage 42 and a discharge outlet 44. A fluid mating member 200 may be coupled to the discharge outlet 44 for further directing the discharged fluid from the dispensing apparatus 10 to an end effector assembly 300, such as dispensing nozzle or an applicator brush. The fluid mating member 200 serves as an adapter to connect the end effector assembly 300 to the dispense section 40 in fluid communication. The discharge passage 42 communicates with a suitable fluid supply in the cartridge.
As shown in
Turning back to
The dispensing apparatus 10 further includes a locking member 130 configured to secure the cartridge holder 30 in the closed position by clamping the first and second clamshells together. The locking member 130 is provided proximate to the side of the cartridge holder 30 opposite the hinges 39a, 39b, and is movably connected to a locking actuator 132. The locking actuator 132 is fixed to a side of the housing frame 24 and is configured move the locking member 130 in and out of locking engagement with the first and second clamshells 32, 34. The locking actuator 132 may comprise a pneumatic driver and a reciprocating rod 134 that is coupled to the locking member 130.
As shown in
Referring to
The snuff back mechanism comprises a snuff back element 80 having an hourglass shape that is slidably mounted within a snuff back passage 82 located between the discharge passage 42 and the discharge outlet 44. More particularly, the snuff back passage 82 intersects with, and therefore, fluidly communicates with the discharge passage 42. Further, the snuff back passage 82 aligns with, and therefore, fluidly communicates with the discharge outlet 44. The snuff back element 80 is configured to reciprocate within the snuff back passage 82 by moving forward and backward in response to the dispense valve actuator 70, such that the snuff back element 80 is movable between a respective flow position and a snuff back position.
Referring again to
A first end 117 of the actuator linkage member 116 is secured to an end of the drive rod 112 by a rod fastener 114, such as a threaded nut. A second end 118 of the actuator linkage member 116 is attached to a first end of the piston rod 120. Accordingly, reciprocating movement of the drive rod 112 caused by the servomotor likewise results in reciprocating movement of the piston rod 120. The piston rod 120 extends from the actuator linkage member in a direction toward the cartridge holding space 36 of the cartridge holder 30, such that the piston rod 120 and the cartridge are coaxially aligned when the cartridge is placed within the cartridge holder 30. Moreover, the piston rod 120 and the drive rod are arranged substantially parallel to each other. At least one auxiliary piston rod 122 may also be connected to the actuator linkage member 116 and configured to move along with the piston rod 120 and the drive rod 112 for providing additional support and stability. Such an auxiliary piston rod 122 is also arranged substantially parallel to the piston rod 120 and the drive rod 112. Both the piston rod 120 and the auxiliary piston rod 122 may be rigidly fixed to the actuator linkage member 116, or removably attached via fasteners such as screws and bolts, among others. The piston rod 120 includes a piston head 140 configured to matingly engage the plunger 22 of the cartridge in order to move the plunger 22 through the fluid cartridge 12 during a dispense operation, as will later be described below.
Referring to
Still referring to
During a flow or dispensing condition when the dispense valve 62 is opened by the dispense valve actuator 70, the snuff back element 80 is simultaneously actuated to a flow position by moving toward the discharge outlet 44. The hour glass shape of the snuff back element 80 defines a thick, or wide, region 85 and a directly adjacent thin, or narrow, region 86. The thick region 85 sealingly abuts a resilient valve seal 84, such as an elastomeric O-ring, provided at the intersection of the snuff back passage 82 and the discharge outlet 44 when the dispense valve 62 is in the closed position. Thus, fluid communication between the discharge passage and the discharge outlet 44 is prevented when the dispense valve 62 is closed. Prior to opening the dispense valve 62, the dispense valve actuator 70 and the piston 72 may travel forward to create a pre-determined pre-pressure value within the material in order to assist in obtaining the desired flow rate at the beginning of a dispense cycle.
When the dispense valve actuator 70 moves the dispense valve to the open position, the thin region 86 of the snuff back element 80 is positioned concentrically within the valve seal 84 in the flow position. The thin region 86 of the snuff back element 80 does not sealingly abut the valve seal 84, and thus fluid is allowed to flow past the snuff back element 80 toward the discharge outlet 44 when dispense valve 62 is opened. Further, the thick region 85 of the snuff back element 80 moves into the discharge outlet 44 when the dispense valve is in the open position. The thick region 85 of the snuff back element 80 has a smaller diameter than the diameter of the discharge outlet 44, so that fluid flow through the discharge outlet 44 is not blocked or impeded by the thick region 85 of the snuff back element 80 when in the flow position.
In the dispense condition, the plunger 22 of the fluid cartridge 12 is moved from the proximal end 18 to the distal end 16 of the cartridge body 14 by a force applied by the piston rod 120 of the cartridge actuator assembly 100 against the proximal end 22a of the plunger 22. This forces the fluid in the fluid space 20 through the outlet passage 50 of the cartridge 12 and into the discharge passage 42, through the dispense valve assembly 60, past the snuff back element 80, and finally out of the discharge outlet 44.
As illustrated in
The piston rod 120 defines an internal piston passageway 124 that is in fluid communication with an internal piston head passageway 146. A proximal end 147 of the piston head 140 includes a vent outlet defining at least one vent hole 148 that is in fluid communication with the piston head passageway 146. The proximal end 147 of the piston head 140 is also configured to matingly interface with the proximal end 22a of the plunger 22 of the cartridge in order to maintain the integrity of the plunger 22 during dispensing by preventing it from rolling over or changing shape under pressure. Maintaining the integrity of the plunger 22 further helps prevent fluid leakage between the plunger 22 and the interior walls of the cartridge 12.
In some instances when the piston head 140 enters the cartridge 12 and moves the plunger 22 therethrough to push the fluid out of the cartridge 12, it may be difficult to then move the piston head 140 proximally back out of the cartridge 12. This difficulty may be caused by a vacuum formed between the piston head 140 and the plunger 22 as a result of moving the piston rod 120 distally without having any fluid return to the cartridge 12. The at least one vent hole 148 provides ventilation in order to prevent vacuum pressure when the piston head 140 pushes the plunger 22 during the dispense operation.
In the implementation shown in
Further, since the inner diameter and outer diameter of each cartridge may change depending on the temperature and other tolerances held during manufacturing, it is necessary to maintain the integrity of the cartridge during the dispensing operation when the pressure inside the cartridge is increased, in order to avoid breaking the cartridge and having fluid material flow uncontained throughout the dispenser. Furthermore, the cartridge is captured and retained in position so that it can be pressurized. Accordingly, when the piston head 140 matingly interfaces with the plunger 22, the air trapped therebetween flows through the at least one vent hole 148 and into the piston head passageway 146 for relieving vacuum pressure within the cartridge. As previously described, the piston head 140 may be threadedly attached to the piston rod 120 so that it can easily be removed and cleaned or replaced in the event of fluid leakage.
In one implementation, the cartridge 12 may contain a two-part curing material, such as a polysulfide two-component premixed and frozen material. The distal end of the piston head 140 may be configured to attach to an internal safety hose 125, such as a vinyl hose, extending through the piston rod passageway 124 of the piston rod 120. The distal end of the piston head 140 includes internal threads 141 for threadedly engaging a push fitting to connect to the hose 125. Thus, in the event that leaked fluid material enters into the piston head passageway 146 through the vent holes 148, the leaked fluid can be blown out before it cures. Moreover, the internal safety hose 125 prevents leaked fluid material from adhering to, gumming up, or otherwise clogging the interior passageway 124 of the piston rod 120. In one implementation, the internal hose 125 extends through the piston rod 120 and terminates in a pig tail end so that an operator can connect to the pig tail end and blow out material from the hose. Without the safety hose, any leaked fluid material that enters the piston head passageway and/or the piston rod passageway could harden and block airflow, thus rendering the components unusable for venting air.
When the plunger 22 has reached the end of its travel during a dispensing operation, or otherwise when a dispense cycle or operation is complete, the dispense valve 60 is moved by the dispense valve actuator 70 to the closed position as shown in
Once the plunger 22 is urged to the distal end 16 of the cartridge 12 by the piston head 140 at the end of the dispense cycle, the piston head 140 can be removed from the cartridge by operating the servomotor in the reverse direction to retract the piston rod 120. The dispensed cartridge 12 may then be removed from the cartridge holder 30, and a new cartridge may be placed in the dispensing apparatus 10. Turning again to
One implementation of the cartridge may include a flange 430 defining a flange stop surface 432 configured to retain the cartridge 12 within the dispenser 10. When the cartridge is placed within the cartridge holder, the flange stop surface 432 abuts against a distal stop surface 434 defined by the clam shell halves 32 to limit the travel of the cartridge 12 in a distal direction. The flange 430 is located in a flange groove 438 defined by the clam shell halves 32, 34. A proximal stop surface 436 defined by the clam shell halves 32 will engage the flange 430 to limit the axial travel of the cartridge in the proximate direction. As such, the flange groove 438 is defined in part by the distal stop surface 434 and the proximal stop surface 436.
The cartridge 12 connects with a cartridge mating member 440 having a projection 442. A projection receiver 444 located in the distal end 16 of the cartridge 12 fits over the projection 442 to attach the cartridge 12 to the cartridge mating member 440 in a sealed manner. The projection receiver 444 on the cartridge 12 can slip over the projection 442 when the cartridge 12 is pushed on to the cartridge mating member 440. The projection receiver 444 flexes to fit over the projection 442. The flexure of the projection receiver 444 may be limited by a retaining ring 446. A space 448 between the retaining ring 446 and the projection receiver 444 indicates the amount the projection receiver 444 may flex before it is stopped by the retaining ring 446. The projection 442 is used to connect the cartridge 12 to the dispenser 10 and provide fluid communication between the cartridge 12 and the discharge passage in a sealed manner.
As shown in
Referring to
Turning back to
As shown in
The fluid mating projection 204 of the fluid mating member 200 includes a tapered surface which is dimensioned to fit into the correspondingly dimensioned fluid mating receiver 330. The fluid or adhesive in the interior fluid passageway 202 is transmitted through the fluid mating projection 204 to the fluid mating receiver 330. The fluid mating projection 204 may include fluid mating member seals 206 that reside in fluid mating member seal grooves 208. These seals 206 are located in the seal grooves 208 to ensure that when the end effector assembly 300 is attached to the dispense section 40 of the dispenser 10, the fluid mating projection 204 is fluidly sealed to the fluid mating receiver 330 in order to prevent leakage. The seals 206 may be resilient seals, such as elastomeric O-rings.
The motor 327 includes a power output shaft 340 which connects to a power transmitting shaft 342 via a power transmission mechanism, such as a power coupler 344. The power from the motor 327 is in turn transmitted to the at least one dispensing brush.
The end effector assembly 300 includes an adjustable elongating mechanism 350 comprising a drive chain with drive gears, such as sprockets 350a, 350b, 350c, 350d, and 350e. In other implementations, the end effector may be driven by a drive belt or gears. At least one brush configured to rotate may be attached to the end of the adjustable mechanism 350. The adjustable mechanism 350 uses the drive chain and drive gears to transmit the rotating motion to the brush. In one implementation, the brush may be attached to the final sprocket 350e to allow the brush to rotate. The hose 328 transmits fluid to an axial opening of the brush via a hose connection 332 which is part of the brush mounting assembly 352, and which allows the brush to be connected to the sprocket 350e. The drive chain may be covered with a housing 354. A hose housing 356 may provide some protection for the hose 328. Further, a hose clip 329 may attach the hose 328 to the tube 326.
It should be appreciated that the tube 326 may have an octagonal, hexagonal, or other suitably shaped cross section to fit into a correspondingly shaped hole in the end effector mounting plate 324. Also, the brush may be oriented at different angular positions with respect to the end effector mounting plate 324. Further, the tube 326 may also be of different lengths as desired to provide the brush in a desired position.
The end effector assembly 300 is configured to quickly connect and disconnect to the dispense section 40 via an adapter such as the fluid mating member 200. The fluid mating member 200 may be equipped with pivotable attaching fingers 210 each having an oppositely disposed hook shape defining attaching surfaces. The attaching fingers 210 are configured to pivotably engage and secure together the motor mounting plate 322 and the end effector mounting plate 324.
As shown in
The motor mounting plate 322 includes a mounting structure configured to connect to the end effector assembly 300. The motor 327 has a power output shaft 340 that connects to a power coupler 344. The power coupler 344 has a large axial hole 345 in which the power output shaft 340 extends. The exterior of the power output shaft 340 and the interior of the large axial hole 345 may be hexagonally, octagonally, or some other suitably shaped cross section to allow the power output shaft 340 to grip the walls of the large axial hole 345 without spinning with respect to the power coupler 344.
The power coupler 344 also has a small axial hole 346 which also may be be hexagonally, octagonally, or some other suitably shaped cross section to allow the power coupler 344 to attach to the power transmitting shaft 342. It should be appreciated that the power transmitting shaft 342 also may have a corresponding hexagon, octagon, or other suitable shaped cross section in order to allow the power coupler 344 to rotate with and transmit torque from the motor 327 without slipping with respect to the power transmitting shaft 342. A biasing member, such as a spring 348, biases the power coupler 344 toward the power transmitting shaft 342. The power transmitting shaft 342 aids in transmitting rotational energy and torque from the motor 327 to the drive chain.
The end effector assembly 300 attaches to the rest of the dispense section of the dispenser 10 via attaching fingers. When the end effector mounting plate 324 moves toward the motor mounting plate 322, the attaching fingers will pivot over the end effector mounting plate 324 until the motor mounting plate 322 is moved close enough to allow the attaching fingers to snap back due to the urging of the a resilient member, such as a spring, and place the attaching surfaces of the attaching fingers in a locking position on a shoulder of the end effector mounting plate 324. To remove the end effector assembly 300, the attaching fingers are pivoted against the urging of the resilient member, thereby moving the attaching surfaces on the attaching fingers from the shoulder on the mounting plate 322. The end effector assembly 300 may then be separated from the rest of the dispenser 10.
In further implementations of the disclosure, operation of the dispenser 10 may be controlled by a controller or a plurality of controllers connected to various elements of the dispenser 10. Various types of controllers may be used, including local controllers and/or remote controllers. Further, the controllers may have wired or wireless connections.
While the present disclosure has been illustrated by the description of specific embodiments thereof, and while the embodiments have been described in considerable detail, it is not intended to restrict or in any way limit the scope of the appended claims to such detail. The various features discussed herein may be used alone or in any combination. Additional advantages and modifications will readily appear to those skilled in the art. The claims are therefore not limited to the specific details, representative apparatus and methods and illustrative examples shown and described.
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