This disclosure relates to the coupling of a fluid dispenser to a fluid dispensing system.
There are many situations in which it is desirable to dispense small controlled amounts of fluid in a specific location. One example is the dispensing of an adhesive in an automated production line, such as dispensing a fraction of a milliliter of UV-cured adhesive at the base of the needle of a hypodermic assembly where the adhesive is cured so as to hold the needle in place in the plastic base. There are myriad other situations in which small controlled amounts of fluid need to be dispensed very exactly.
In a production environment it is desirable to have as few interruptions as possible to an automated assembly line. One interruption occurs when a fluid dispenser needs to be refilled or replaced; the line must be halted, the fluid dispenser removed, and a full dispenser placed properly into position. Many assembly lines use several fluid dispensers, each of which needs to hold fluid. This situation leads to the need to stop production fairly frequently so as to replace empty fluid dispensers. It is thus desirable to design the fluid dispensing system in a manner that allows the fluid dispensers to be replaced as quickly as possible.
In general, one aspect of the disclosure features a system for releasably coupling a fluid dispenser to a structure. There is a push to connect-pull to disconnect connector system that has first and second mating connectors. The fluid dispenser is mounted to a first connector. The second connector is mounted to the structure. The connector system accomplishes releasable mechanical interconnection between the dispenser and the structure, and in most but not all embodiments also accomplishes electrical interconnection between the dispenser and the structure.
Various implementations may include one or more of the following features. The structure may be a fluid dispensing system. The fluid dispenser may comprise a syringe with a dispensing plunger. The fluid dispenser may further comprise a stepper motor operably connected to the syringe and adapted to move the plunger, and wherein the connector system further accomplishes an electrical interconnection between the dispenser and the structure. The fluid dispenser may further comprise a dispenser housing in which the stepper motor is located. The first connector may be mounted to the dispenser housing by one or more straps. The dispenser housing may define an outer shape, and the first connector may define an outer shape that is essentially a mirror image of the outer shape of the dispenser housing, such that the first connector is mounted to the dispenser housing with little space between them.
The first connector may have a connector body that defines a connector face entirely circumscribed by a projecting rim, with the male portion of a male/female electrical connector projecting outward from the connector face and a plurality of post-receiving openings defined in the face on different sides of the projecting electrical connector. The second connector may have a connector body that defines a connector face entirely circumscribed by a plurality of projecting flexible fingers that project outward from the body, wherein the fingers each define a groove near their distal end such that the fingers are adapted to snap over the rim of the first connector and the rim is sized and shaped to be accepted into the grooves, to accomplish a positive locking of the two connectors. The second connector may further define a plurality of posts projecting outwardly from the face and located, sized and shaped to fit into the receiving openings of the first connector when the rim is received in the grooves. The second connector may further define a female portion of the male/female electrical connector, which is located sized and adapted to receive the male electrical connector portion.
In general, another aspect of the disclosure features a method for accomplishing simple and fast coupling and decoupling of a fluid dispenser to a dispensing system. There is a push to connect-pull to disconnect connector system comprising first and second mating connectors, with a first connector adapted to be mounted to the dispenser and a second connector adapted to be mounted to the dispensing system, wherein the connector system accomplishes both mechanical and electrical interconnection between the dispenser and the dispensing system. The dispenser and the dispensing system are mechanically and electrically coupled together by pushing a first connector into the second connector, and are mechanically and electrically decoupled by pulling the first connector away from the second connector.
Various implementations may include one or more of the following features. The fluid dispenser may comprise a syringe with a dispensing plunger, wherein the fluid dispenser further comprises a stepper motor operably connected to the syringe and adapted to move the plunger, and wherein the fluid dispenser further comprises a dispenser housing in which the stepper motor is located. The first connector may be mounted to the dispenser housing by one or more straps. The dispenser housing may define an outer shape and the first connector may define an outer shape that is essentially a mirror image of the outer shape of the dispenser housing such that the first connector is mounted to the dispenser housing with little space between them.
The first connector may have a connector body that defines a connector face entirely circumscribed by a projecting rim, with the male portion of a male/female electrical connector projecting outward from the connector face and a plurality of post-receiving openings defined in the face on different sides of the projecting electrical connector. The second connector may have a connector body that defines a connector face entirely circumscribed by a plurality of projecting flexible fingers that project outward from the body, wherein the fingers each define a groove near their distal end such that the fingers are adapted to snap over the rim of the first connector and the rim is sized and shaped to be accepted into the grooves, to accomplish a positive locking of the two connectors. The second connector may further define a plurality of posts projecting outwardly from the face and located, sized and shaped to fit into the receiving openings of the first connector when the rim is received in the grooves. The second connector may further define a female portion of the male/female electrical connector, which is located sized and adapted to receive the male electrical connector portion.
In general, another aspect of the disclosure features a connector system for accomplishing simple and fast coupling and decoupling of a fluid dispenser to a dispensing system, comprising a push to connect-pull to disconnect connector system comprising first and second mating connectors, with a first connector adapted to be mounted to the dispenser and a second connector adapted to be mounted to the dispensing system, wherein the connector system accomplishes both mechanical and electrical interconnection between the dispenser and the dispensing system. The first connector is mounted to the dispenser such that it lies against a portion of the dispenser, the mounting accomplished by one or more straps that are coupled to the first connector and encircle the dispenser.
Various implementations may include one or more of the following features. The fluid dispenser may comprise a syringe with a dispensing plunger, wherein the fluid dispenser further comprises a stepper motor operably connected to the syringe and adapted to move the plunger, and wherein the fluid dispenser further comprises a housing for the stepper motor. The dispenser housing may define an outer shape and the first connector may define an outer shape that is essentially a mirror image of the outer shape of the dispenser housing such that the first connector is mounted to the dispenser housing with little space between them. The first connector may have a connector body that defines a connector face entirely circumscribed by a projecting rim, with the male portion of a male/female electrical connector projecting outward from the connector face and a plurality of post-receiving openings defined in the face on different sides of the projecting electrical connector. The second connector may have a connector body that defines a connector face entirely circumscribed by a plurality of projecting flexible fingers that project outward from the body, wherein the fingers each define a groove near their distal end such that the fingers are adapted to snap over the rim of the first connector and the rim is sized and shaped to be accepted into the grooves, to accomplish a positive locking of the two connectors. The second connector may further define a plurality of posts projecting outwardly from the face and located, sized and shaped to fit into the receiving openings of the first connector when the rim is received in the grooves. The second connector may further define a female portion of the male/female electrical connector, which is located sized and adapted to receive the male electrical connector portion. The fluid may be a viscous adhesive.
The embodiments depicted in the drawings accomplish a system that releasably couples an automated dispenser for a liquid adhesive to another structure. As one example the dispenser can be coupled to an automation platform that is automatically moved (typically in two, three or six degrees of freedom) by a control system. The platform can be part of an adhesive dispensing system. The coupling system uses a two part push to connect-pull to disconnect connector structure or system that in most embodiments accomplishes both a mechanical and an electrical interconnection of the fluid dispenser to the dispensing system. The dispensing system carries one connector, and the other connector is coupled to the fluid dispenser. The connector system allows the dispenser to be removed from the dispensing system simply by pulling the dispenser off of the dispensing system. Since the electrical control signals and power to operate the dispenser are provided to the dispenser through the connector, there are no separate or additional control or power wires or cables connected to the fluid dispenser. Thus the dispenser with mounted connector can be removed from the system without the need to unplug or otherwise handle a separate cable running to the dispenser. The coupling disclosed herein can be used for dispensers for fluids other than adhesives. Typically but not necessarily the dispensers are used in automated manufacturing operations.
System 10 for releasably coupling a fluid dispenser to a structure is shown in
Controller 16 controls operation of fluid dispenser 12. Controller 16 can be programmed, for example using a programmable logic controller (PLC) or over a network (not shown). Fluid dispenser 12 operates to dispense the fluid; in one non-limiting embodiment the dispensing is accomplished with a stepper motor. Dispenser energizing signals are provided via connector 22 that is permanently or semi-permanently connected to dispenser 12. Connector 22 is releasably, and mechanically and electrically, coupled to connector 20. Connector 20 is permanently or semi-permanently coupled to dispensing system 18. Connectors 20 and 22 can be the two mating portions of a two-part mechanical and electrical push-pull type connector system 19.
Results of system 10 are that an empty fluid dispenser can be removed from the dispensing system simply by pulling the dispenser away from the dispensing system to dislodge connector 22 from connector 20. A replacement fluid dispenser filled with a pre-determined amount of fluid can then be added simply by pushing the connector 22 that is mounted to the filled fluid dispenser onto connector 20. This allows quick and simple replacement without the need to loosen any brackets or other hardware that is typically used to couple a fluid dispenser to a fluid dispensing system.
An example of a fluid dispenser 12a is shown in
In one non-limiting example, there are a series of three dispense guns that can each operate syringes such as that shown in
1 step with a 3 cc syringe barrel will yield 0.00023 cc of fluid dispensed.
1 step with a 5 cc syringe barrel will yield 0.00039 cc of fluid dispensed.
1 step with a 10 cc syringe barrel will yield 0.00065 cc of fluid dispensed.
1 step with a 30 cc syringe barrel will yield 0.00129 cc of fluid dispensed.
1 step with a 3 cc syringe barrel will yield 0.00045 cc of fluid dispensed.
1 step with a 5 cc syringe barrel will yield 0.00079 cc of fluid dispensed.
1 step with a 10 cc syringe barrel will yield 0.00131 cc of fluid dispensed.
1 step with a 30 cc syringe barrel will yield 0.00257 cc of fluid dispensed.
1 step with a 3 cc syringe barrel will yield 0.00090 cc of fluid dispensed.
1 step with a 5 cc syringe barrel will yield 0.00158 cc of fluid dispensed.
1 step with a 10 cc syringe barrel will yield 0.00261 cc of fluid dispensed.
1 step with a 30 cc syringe barrel will yield 0.00514 cc of fluid dispensed.
Additional examples of fluid dispensers are depicted in
Connector 130 further includes projecting flexible fingers 134 that project from body 133. Fingers 134 each define a groove 135 near the distal end. The fingers snap over rim 145 of connector 140 and rim 145 is accepted into grooves 135, to accomplish a positive locking of the two connectors. Fingers 134 circumscribe the entire connector body to define a receptacle for rim 145. Because fingers 134 are made of a plastic material that has some give, and because the fingers have free distal ends, the fingers are sufficiently flexible such that they release rim 145 when connector 140 is pulled away from connector 130. Posts 136 and 137 fit into receiving openings 146 and 147. Male electrical connector portion 141 fits into female electrical connector receiving portion 138, which has sloped sidewalls that guide portion 141 into portion 138. The posts and these guide features help to allow a blind connection of the two connector halves.
Connector system 120 thus accomplishes both mechanical and electrical connection between the dispenser and the dispensing system in a push on-pull off system that can be operated with one hand and without direct sight of the connection location on the dispense system.
The connector system herein could be used to couple fluid dispensers other than syringes. For example the dispenser could be a dispense gun or other device that is electrically operated to dispense a controlled amount of fluid. As another alternative, the fluid dispenser could be a dispense valve, in which case there may not need to be an electrical connection accomplished by the connector system. A further alternative to the fluid dispenser could be a dispense tip such as a needle or other orifice; the connector could be used to hold the tubing leading to the dispense tip and the tip itself, to allow rapid attachment and detachment of them for replacement.
A number of embodiments and options have been described herein. Modifications may be made without departing from the spirit and scope of the invention. For example, the
Accordingly, other embodiments are within the claims.
This application claims priority of Provisional Application Ser. No. 61/468,239, filed on Mar. 28, 2011, the disclosure of which is incorporated herein by reference.
Number | Date | Country | |
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61468239 | Mar 2011 | US |