Technical Field
This document discloses actuating systems and nozzles for liquid dispensers. More specifically, this document discloses actuating systems for a liquid dispenser that includes a stationary and circular array of nozzles. The disclosed actuating systems are capable of moving an actuator amongst or around the circular array of nozzles before the actuating system stops the actuator at a specific nozzle. The actuating systems then rotate the actuator to open the selected nozzle.
This document also discloses nozzles for multiple liquid dispensers that feature a slider that is movable between a fully closed position and a plurality of open positions, including a fully open position. The disclosed nozzles may be equipped with a sniff back function and a reverse sniff back function that keeps the nozzle full of liquid before, during and after the opening and closing of the nozzle.
Description of the Related Art
Systems for dispensing a plurality of different liquids into a container are known. For example, systems for dispensing paint base materials and colorants into a paint container are known. These paint dispensing systems may use twenty or more different colorants to formulate a paint mixture. Each colorant is contained in a separate canister or package and typically includes its own dispensing pump. In some systems, the colorants and the respective pumps may be disposed on a rotating turntable disposed above a stationary container. In other systems, the colorants may be disposed along one or more stationary horizontal rows disposed above a container disposed on moving platform. Also, in some systems, the colorants may be dispensed through a stationary dispense manifold into a stationary container, wherein the manifold includes a plurality of nozzles.
In a turntable system, the turntable rotates so that the liquid to be dispensed is moved to a position above a stationary container that is being filled. Turntable systems require at least one motor to rotate the turntable, another motor to open and close the nozzles associated with the liquids to be dispensed and separate motors to operate each liquid pump. Further, the motors operating each pump and the canisters containing the liquids are mounted for rotation with the turntable, resulting in a complex and somewhat cumbersome design.
In liquid dispensers using one or more stationary horizontal rows, the container moves laterally to the appropriate colorant/pump for the next dispense. A motor for opening and closing the nozzles associated with each liquid must travel with the container, which also makes for a cumbersome design.
In manifold designs, the container, liquid pumps, liquid canisters and nozzles remain stationary as the liquids are sequentially or simultaneously pumped though individual nozzles held closely together by a manifold block. However, as noted above, some liquid dispensers dispense more than 20 different liquids and it is difficult to design a manifold that can accommodate so many different nozzles in a space-efficient and compact manner. Further, nozzles disposed in manifolds are prone to clogging and dripping, both of which are problematic.
One way in which the precision of a liquid dispensing system is compromised is “dripping”. Specifically, a “leftover” drip may be hanging from a nozzle that was intended for a previous formulation and, with a new container in place under the nozzle, the drop of liquid intended for a previous formulation may be erroneously added to a new formulation. Thus, the previous container may not receive the desired amount of the liquid ingredient and the next container may receive too much.
To solve the drip problem, various scraper and wiper designs have been proposed to scrape any leftover material from an individual nozzle or an entire manifold block after a dispense operation is complete. However, these designs often require one or more different motors to operate the wiper element. Further, the use of a wiper or scraping function may not be practical in a multiple nozzle manifold design, as the liquids from the different nozzles will be cross-contaminated by the wiper or scraper, which would then also contribute to the lack of precision of subsequently produced formulations. Accordingly, improved nozzle designs that address the drip problem are needed.
Another problem associated with dispensing systems that make use of nozzles is clogging. Specifically, nozzle clogging may be experienced with the dispensing of relatively viscous liquids such as tints, colorants, base materials for paints and cosmetic products, certain pharmaceutical ingredients or other liquid materials having relatively high viscosities and/or volatile solvents. The viscous liquids have a tendency to dry and cake onto the end of the nozzles, thereby requiring frequent cleaning in order for the nozzles to operate effectively. For example, when a liquid or slurry material dries on a nozzle, the dispense stream may be misdirected causing the liquid or slurry to miss the container being filled. This problem is particularly prevalent in the dispensing of colorants or tints. While some mechanical wiping or scrapping devices are available, these devices are not practical for multiple nozzle manifold systems for the reasons set forth above and the scraper or wiper element must be manually cleaned anyway. Further, nozzles have also been known to clog entirely when exposed to air for an extended period, which renders wiping or scrapping devices ineffective.
Another problem associated with liquid dispensing systems is air entering the nozzle during the opening or closing of the nozzle. For example, when a nozzle is opened, air may be free to enter the nozzle outlet and consume some of the interior volume of the nozzle through which the liquid flows. Some dispensing systems may attempt to account for air in the nozzle during calibrations, but the results may be inconsistent. Other systems may require the nozzle to be primed with liquid before a dispense, which is time consuming and wasteful. Regardless, the presence of air in a nozzle compromises the accuracy of the dispense and improved nozzle designs are needed that address the air problem.
Nozzles for liquid dispensers of the type described above typically have two positions—open and closed. Because of the high degree of precision required by some applications, a nozzle design that can be opened fully or partly by a motorized mechanism would be very beneficial. Such a nozzle design would enable a fast dispense rate when in a fully open position and slower dispense rates when in partially open positions. Such an improved nozzle design would need to address the problem of air entering the nozzle between dispenses as well.
Accordingly, a need exists for improved multiple liquid dispensers and actuation systems that are less cumbersome and complex. A need also exists for improved nozzle designs that are not prone to clogging, that are not prone to allowing air into the nozzle between dispenses and that enable dispensing through the nozzle in not only a fully open position but through a plurality of partially open positions as well.
In one aspect, the document discloses a method for opening and closing a nozzle outlet of a nozzle of a liquid dispenser without dripping liquid or drawing air into the nozzle. The nozzle includes a body having an interior space in communication with the nozzle outlet. The interior space provides an available volume for accommodating liquid. The nozzle outlet provides an outlet volume for accommodating liquid. The method may include:
charging the nozzle outlet and the interior space with liquid;
providing a volume compensator in liquid communication with the nozzle outlet and the interior space, the volume compensator configured to increase the available volume of the interior space when the nozzle is closed and the volume compensator further configured to decrease the available volume of the interior space when the nozzle is opened;
opening the nozzle outlet and decreasing the available volume of the interior space by a first amount about equal to an increase in the outlet volume at the nozzle outlet created by opening the nozzle outlet; and
closing the nozzle outlet and increasing the available volume of the interior space by a second amount about equal to a decrease in the outlet volume at the nozzle outlet created by closing the nozzle outlet.
In another aspect, this document discloses a nozzle for liquid dispenser. The nozzle may include a hollow nozzle body including a nozzle body inlet and an outlet body with a slider passageway extending therebetween. The outlet body may terminate at a U-shaped nozzle outlet. The nozzle outlet may include a distal wall disposed between two side walls. The nozzle may further include a slider including a slider body coupled to a gate. The slider body may be slidably accommodated in the slider passageway. The gate may be slidably accommodated in the outlet body and nozzle outlet. The gate may engage the distal wall and the two side walls of the nozzle outlet when the slider shifts to a fully closed position. The nozzle outlet may be in communication with the passageway as the slider and gate moves from the fully closed position to an open position. Further, the nozzle may include a volume compensating element in communication with the passageway that decreases an available volume in the passageway for accommodating liquid as the gate is opened and that increases the available volume in the passageway for accommodating liquid as the gate is closed.
In another aspect, an actuation system for a liquid dispenser is disclosed. The disclosed actuation system may include an indexer motor coupled to an indexer drive mechanism. The indexer drive mechanism may couple to indexer wheel. The indexer wheel may carry a final wheel. The final wheel may couple to an actuator transfer wheel. The actuator transfer wheel may coaxially couple for rotation with an actuator wheel. The actuator wheel may enmesh with an actuator drive mechanism. The actuator drive mechanism may couple to an actuator motor. And, the final wheel may carry an actuator implement.
In another aspect, a disclosed actuation system may include an indexer motor coupled to an indexer drive gear. The indexer drive gear enmeshes with an indexer gear. The indexer gear carries a final gear. The final gear enmeshes with an actuator transfer gear. The actuator transfer gear coaxially couples for rotation with an actuator gear. The actuator gear enmeshes with an actuator drive gear. The actuator drive gear couples to an actuator motor. Further, the final gear may carry or otherwise be coupled to an actuator implement.
In another aspect, a disclosed liquid dispenser may include a circular array of nozzles disposed on a stationary table. Each nozzle may be in communication with its own pump and its own canister of liquid. Each nozzle may also include an actuator pin movable between a fully open position and fully closed position. The indexer motor couples to an indexer drive gear. The indexer drive gear enmeshes with an indexer gear. The indexer gear carries a final gear for imparting circular motion to the final gear above the valves. The final gear enmeshes with an actuator transfer gear. The actuator transfer gear coaxially couples to the actuator gear for rotation with an actuator gear. The actuator gear enmeshes with an actuator drive gear. The actuator drive gear couples to the actuator motor. Further, the final gear may carry or otherwise be coupled to an actuator implement.
In another aspect, a disclosed liquid dispenser may include a stationary and circular array of nozzles, wherein each nozzle may be in communication with its own pump and its own canister of liquid. The dispenser may further include an actuation system that includes an indexer motor coupled to an indexer drive gear. The indexer drive gear enmeshes with an indexer gear. The indexer gear carries a final gear. The final gear in enmeshed with an actuator transfer gear. The actuator transfer gear coaxially couples to an actuator gear for rotation with the actuator gear. The actuator gear enmeshes with an actuator drive gear. The actuator drive gear couples to an actuator motor. The final gear carries an actuator implement. Each nozzle includes a hollow nozzle body including a nozzle body inlet, an outlet body and a nozzle body sidewall that extends therebetween. Each nozzle further includes a slider that includes a slider body coupled to a gate. Each outlet body includes an outlet body that slidably accommodates the gate of its respective slider. Each outlet body terminates at a nozzle outlet. Each outlet body includes a distal wall. Each gate includes at least one distal seal that sealably engages the distal wall of its respective outlet body when its respective slider shifts to a fully closed position. Each slider body sealably and slidably engages its respective nozzle body as each slider moves from the fully close position towards a fully open position or any one of a plurality of open positions.
In another aspect, yet another nozzle for a liquid dispenser may include a nozzle body including an inlet and an outlet. The nozzle body further includes a slider passageway for slidably accommodating a slider. The slider may include a gate. The slider body includes a reduced diameter portion that is disposed between the inlet and outlet when the slider is in an open position. The outlet includes a wall that engages the gate when the nozzle is in a closed position. The slider passageway is in communication with the outlet. The slider passageway accommodates a distal end of the slider when the slider is in the open position. Said distal end of the slider at least partially withdraws from the passageway when the slider moves towards a closed position. As a result, the movement of the slider partially out of the passageway as the nozzle is closed creates available volume and/or a low-pressure region in the passageway for receiving liquid from the outlet as the gate approaches and engages the wall of the outlet. Conversely, as the gate moves away from the wall of the outlet as the nozzle opens, available volume in the nozzle outlet is created for receiving liquid from the passageway. As a result, the nozzle outlet fills with liquid and presents a liquid surface that is flush with the nozzle outlet as the gate proceeds from a closed position to any open position, including but not limited to a fully open position.
In another aspect, another nozzle for a liquid dispenser includes a nozzle body including an inlet, an outlet and a passageway extending therebetween. The passageway slidably accommodates a slider. The slider includes a slider body coupled to a gate. The outlet slidably accommodates the gate and the outlet further includes a wall. The gate sealably engages the wall of the outlet when the slider shifts to a closed position. The nozzle body includes a chamber that at least partially accommodates the slider body when the slider is in an open position. The chamber is in communication with the outlet when the slider is in the open position. The slider body at least partially departs the chamber when the slider moves from the open position to a closed position thereby, thereby creating volume in the chamber for receiving liquid from the outlet as the gate is closed. Conversely, as the gate opens, available volume is created in the nozzle outlet and the available volume in the chamber is reduced as the slider body reenters the chamber. As a result, liquid flows from the chamber into the nozzle outlet, filling the nozzle outlet with liquid so the liquid continuously presents a liquid surface that is flush with the nozzle outlet as the gate opens.
In any one or more of the embodiments described above, the indexer wheel is an indexer gear, the indexer drive mechanism is an indexer drive gear enmeshed with the indexer gear, the actuator wheel is an actuator gear, the actuator drive mechanism is an actuator drive gear enmeshed with the actuator gear, the final wheel is a final gear, and the actuator transfer wheel is an actuator transfer gear enmeshed with the final gear.
In any one or more of the embodiments described above, the indexer wheel is an indexer pulley, the indexer drive mechanism is an indexer drive pulley coupled to the indexer pulley by a first endless belt, the actuator wheel is an actuator pulley, the actuator drive mechanism is an actuator drive pulley coupled to the actuator pulley by a second endless belt, the final wheel is a final pulley, and the actuator transfer wheel is an actuator transfer pulley coupled to the final pulley by a third endless belt.
In any one or more of the embodiments described above, the indexer gear is disposed coaxially between the actuator gear and the actuator transfer gear.
In any one or more of the embodiments described above, the indexer motor and the actuator motor are linked to a controller.
In any one or more of the embodiments described above, the indexer motor and the actuator motor are stepper motors.
In any one or more of the embodiments described above, the indexer motor and the actuator motor are mounted on a platform disposed above the actuator gear and opposite the actuator gear from the indexer gear.
In any one or more of the embodiments described above, the actuator transfer gear and the final gear are disposed below the indexer gear and opposite the indexer gear from the actuator gear.
In any one or more of the embodiments described above, the actuator implement couples to an underside of the final gear and extends vertically downward therefrom.
In any one or more of the embodiments described above, the indexer gear includes indicia that are readable by an indexer gear sensor. The indicia indicate a position of the indexer gear with respect to a zero position. The indexer gear sensor links to the controller.
In any one or more of the embodiments described above, the nozzle body and outlet body are separate components and the nozzle body includes a nozzle body outlet and the outlet body includes a collar that is sealably and mateably received in the nozzle body outlet.
In any one or more of the embodiments described above, the slider body is hollow and includes a slider body inlet, a slider body outlet and a slider body sidewall extending therebetween. The slider body sidewall couples to the actuator pin.
In any one or more of the embodiments described above, the collar of the outlet body includes an inner surface that mateably, sealably and slidably receives the slider outlet. Further, the collar of the outlet body includes an outer surface that is mateably and sealably received in the nozzle body outlet.
In any one or more of the embodiments as described above, the gate includes at least one proximal seal that sealably and slidably engages the inner surface of the collar as the slider slides towards the fully closed position.
In any one or more of the embodiments as described above, the slot in the nozzle body sidewall is elongated to permit the actuator pin and the slider to be slid from a fully open position where communication is established between the nozzle body inlet and the nozzle outlet to a fully closed position where engagement of the gate against the distal wall of the outlet body blocks communication between the nozzle body inlet and the nozzle outlet.
In any one or more of the embodiments described above, the slider is slidable to a plurality of open positions between the fully open position and fully closed position while maintaining sealing engagement between the slider body outlet and the collar of the outlet body.
In any one or more of the embodiments described above, the slider couples to a slider cover that is disposed exterior of the nozzle body. The slider cover engages a compensating member. The compensating member extends through an opening in the nozzle body. The slider cover pulls the compensating member at least partially out of the nozzle body as the slider moves towards the fully closed position and the slider cover pushes the compensating member into the nozzle body as the slider moves towards the fully open position.
In any one or more of the embodiments described above, the slider cover couples to the slider by the actuator pin.
The above features, functions, and advantages are achievable independently in various embodiments or may be combined in yet other embodiments, further details of which can be seen with reference to the following description and drawings.
For a more complete understanding of the disclosed methods and apparatuses, reference should be made to the embodiments illustrated in greater detail on the accompanying drawings, wherein:
The drawings are not necessarily to scale and that the disclosed embodiments are sometimes illustrated diagrammatically and in partial views. In certain instances, details are omitted which are not necessary for an understanding of the disclosed methods and apparatuses or which render other details difficult to perceive. Further, this disclosure is not limited to the particular embodiments illustrated herein.
Turning first to
The actuator pins 35 are moved by the actuator system 20, which may be applied to any array of mechanical devices as discussed below. In short, the actuator system 20 is not limited to the opening and closing of nozzles 33, but may be used to actuate individual mechanical devices that are arranged in a circular array.
Returning to
The actuator gear 45 connects to an actuator transfer gear 46 that, as shown in
As shown schematically
Turning to
Referring to
It will be noted that the dispenser 30 features a design where both motors 39, 41, along with various motors driving the pumps 49 remain stationary thereby avoiding problems with mounting the motors 39, 41 on moving parts or platforms. Placing the motors 39, 41 on moving platforms presents problems associated with cabling and providing power to the motors 39, 41.
It will also be noted that the indexer gear 43, indexer drive gear 42, actuator gear 45, actuator drive gear 44, actuator transfer gear 46 and final gear 47 may be wholly or partly replaced by a belt drive transmission.
In
To close the nozzle 33, the actuator implement 48a engages the actuator pin 35 and shifts the actuator pin 35 to the left in
Still referring to
Specifically, as the nozzle 33 is opened by moving the gate 69 away from the distal wall 73, liquid disposed in the through passageway 71 is drawn towards the nozzle outlet 55 because the available volume at the nozzle outlet 55 increases and the available volume in the through passageway 71 decreases as the slider body 66 moves towards the inlet 34 and farther into the nozzle body 61. Further, the increase in available volume at the nozzle outlet 55 is equal to or about equal to the decrease in volume experienced in the through passageway 71 as the slider body 66 moves back into the nozzle body 61 and towards the inlet 34. By balancing these volumes, the reverse action that occurs when the nozzle 33 is opened prevents air from entering the nozzle outlet 55 as the gate 69 is opened. In addition, a fresh supply of liquid is disposed in the nozzle outlet 55 each time the gate 69 is opened. As a result, when the gate 69 is opened, a fresh supply of liquid is disposed inside the nozzle outlet 55 that presents a liquid surface that is flush or essentially flush with the nozzle outlet 55. Therefore, each time the gate 69 is opened before a dispense, the nozzle outlet 55 or outlet body 54 is charged with liquid and not air. This action enhances the accuracy of the dispenser 30 because the nozzle 33 is always full of liquid without substantial pockets of air, which would compromise the accuracy of a volumetric dispense. Further, the flush liquid surface presented at nozzle outlet 55 is predictable and repeatable.
Turning to
To move the slider 162 from the open position shown in
The nozzles 33, 33b, 133, 233, 333 include generally rectangular nozzle outlets 55, 55b, 155, 255, 355. The creation and maintenance of a “flush” liquid supply at a nozzle outlet 455 as a gate 469 moves towards or away from a closed position is illustrated schematically in
However, this disclosure is not limited to rectangular or 4-walled nozzle outlets. For example,
An actuation system for a liquid dispenser 30 is shown and described. The liquid dispenser 30 includes a stationary and circular array of nozzles 31 that may be individually actuated by upwardly protruding actuator pins 35. The actuator pins 35 may be actuated one at a time. Two stationary motors 39, 41 are used to rotate an actuator implement 48a around the circular array of nozzles 31 until a selected nozzle 33 is arrived at. Then, the actuator motor 41 is activated again which results in rotation of the actuator implement 48a which engages the actuator pin 35 of the selected nozzle 33 thereby partially or fully opening the nozzle 33 or fully closing the nozzle 33.
The two motors 39, 41 of the actuation system may be mounted on a stationary table or platform 38. Because the circular array of nozzles 31 is stationary, all motors used to drive the liquid dispenser 30 remain stationary, resulting in a simplified design with less moving parts and less problems associated with motors mounted on moving parts or platforms.
Improved nozzles 33, 133, 233, 333, 433, 533 are also disclosed in
Number | Name | Date | Kind |
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4466559 | Loader | Aug 1984 | A |
4966308 | Strazdins | Oct 1990 | A |
Number | Date | Country | |
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20150053719 A1 | Feb 2015 | US |
Number | Date | Country | |
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61868371 | Aug 2013 | US |