Patent Grant
9108214
The present invention relates generally to a dispensing module for dispensing viscous liquids and, more particularly, to a dispensing module for dispensing an adhesive.
Dispensing modules are commonly used to dispense viscous liquids, such as hot melt adhesives, in a variety of dispensing applications employed in the manufacture of products and in product packaging. Conventional dispensing modules are provided with either electrically actuated or electro-pneumatically actuated valve assemblies that regulate the flow and discharge of adhesive from the dispensing module. Typically, the valve assembly incorporates a valve element that is movable to a valve seat between open and closed positions. In the closed position, the valve member seals against the valve seat with a continuous line of contact to discontinue a flow of the adhesive from an outlet of the dispensing module. Cyclical movement of the valve element between the open and closed positions intermittently interrupts the flow to generate a pattern of adhesive on a receiving surface of the product or product packaging.
In many instances, the pattern includes one or more “beads” of the adhesive. The term “bead” generally refers to a continuous discharge of the adhesive, or any other viscous liquid, on the receiving surface with a desirable length, height, width, or other dimension. While the dimensions may vary given the particular application, the ability to repeatedly, accurately, and precisely initiate and terminate the bead provides a manufacturer with the best opportunity to efficiently position each bead on the receiving surface without waste. For example, there are many applications in which it is desirable or necessary to sharply cut off flow of the adhesive from the dispensing module to quickly and precisely terminate the bead on the receiving surface.
Unfortunately, known dispensing modules require a tradeoff between repeatability discharging adhesive and sharply cutting off the flow of adhesive. On one hand, many known dispenser modules capable of sharply cutting off the flow of adhesive tend to be more prone to “clogging,” in which the adhesive blocks the outlet from the further discharge of adhesive. Clogged dispensing modules must be manually cleaned or replaced, resulting in equipment downtime and significant labor and replacement costs to the manufacturer. On the other hand, many known dispenser modules capable of physically displacing clogged adhesive tend to be more prone to a bead “tailing effect” or “stringing,” in which the flow of adhesive gradually reduces to terminate the bead. The “tailing effect” refers to the bead tapering to termination due to the more gradual flow reduction, whereas “stringing” refers to wasted adhesive that discharges from the dispensing module but fails to reach the bead. For this reason, manufacturers carefully consider these various tradeoffs when selecting a dispensing module for a particular application.
There is a need for a dispensing module and method for dispensing a viscous liquid that sharply cuts off the flow of viscous liquid and inhibits clogging while addressing issues such as those discussed above.
An exemplary embodiment of a dispensing module for dispensing adhesive comprises a dispenser body and a nozzle connected to the dispenser body. The dispenser body has a liquid supply passageway and a valve element. The valve element includes a first valve surface and a second valve surface and moves from a proximal position to a distal position. The nozzle comprises a nozzle member, a sealing zone, and a valve seat.
The nozzle member includes an inlet, an outlet, and a liquid passageway extending from the inlet to the outlet. The liquid passageway is fluidly connected to the liquid supply passage and includes a bore extending toward the outlet and a cylindrical surface extending toward the outlet. In addition, the liquid passageway includes a second converging surface tapering conically toward the outlet and a shoulder positioned between the second converging surface and the cylindrical surface.
The sealing zone is defined by the cylindrical surface and extends from an intersection between the cylindrical surface and the bore toward the shoulder. The sealing zone also has a seal diameter sized to engage the first valve surface of the valve element moving from the proximal position to the distal position. The sealing zone and valve element close a first volume of the liquid passageway from the inlet.
The valve seat is defined by an intersection between the shoulder and the bore as a circular line of contact. The circular line of contact is sized such that the valve seat engages the second valve surface of the valve element in the distal position. The valve seat and valve element close a second volume of the liquid passageway from the inlet. As such, the first volume of the passageway reduces to the second volume as the valve element moves distally along the sealing zone for discharging a volume of adhesive from the outlet.
Another exemplary embodiment of a nozzle for a dispensing module comprises a nozzle member, a sealing zone, and a valve seat. The nozzle member includes an inlet, an outlet, and a liquid passageway extending from the inlet to the outlet. The liquid passageway is fluidly connected to the liquid supply passage and includes a bore extending toward the outlet and a cylindrical surface extending toward the outlet. In addition, the liquid passageway includes a second converging surface tapering conically toward the outlet and a shoulder positioned between the second converging surface and the cylindrical surface. The sealing zone is defined by the cylindrical surface and extends from an intersection between the cylindrical surface and the bore toward the shoulder. The sealing zone also has a seal diameter sized for sealing against a valve element and closing a first volume of the liquid passageway from the inlet. Furthermore, the valve seat is defined by an intersection between the shoulder and the second converging surface as a circular line of contact. The circular line of contact is sized for sealing against the valve element and closing a second volume of the liquid passageway from the inlet. As such, the first volume of the passageway reduces to the second volume along the sealing zone for discharging a volume of adhesive from the outlet.
In use, an adhesive bead is dispensed from a dispensing module having a nozzle with an inlet, an outlet, and liquid passageway extending therebetween. A method of dispensing the adhesive bead includes forcing a pressurized adhesive from the outlet with a valve element in a proximal position to discharge a first portion of the adhesive bead. The method also includes moving the valve element from the proximal position to a sealing zone and closing a first volume of the liquid passageway from the inlet to cease discharging the first portion of the adhesive bead. Furthermore, the method includes moving the valve element distally along the sealing zone toward a distal position and reducing the first volume of the liquid passageway to force additional adhesive from the outlet and discharge a second portion of the adhesive bead. In addition, the method includes engaging the valve element against a valve seat in the distal position to close a second volume of the liquid passageway from the inlet to cease discharging the second portion of the adhesive bead. The method further includes inserting at least a portion of a needle tip into a discharge passageway that defines the outlet for inhibiting clogging of the adhesive within the nozzle.
Various additional objectives, advantages, and features of the invention will be appreciated from a review of the following detailed description of the illustrative embodiments taken in conjunction with the accompanying drawings.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with a general description of the invention given above, and the detailed description given below, serve to explain the invention.
With respect to
The needle 18 is in the proximal open position such that the inlet 42 openly communicates adhesive to the outlet 36. The dispenser body 12 further includes a nozzle adapter 32 inserted into the bore 16 to partially extend from the dispenser body 12. The nozzle adapter 32 is configured to mate with the nozzle body 22 for mechanically coupling or attaching the nozzle 14 with the dispenser body 12. An O-ring 34 provides a fluid seal between the nozzle adapter 32 and the nozzle body 22.
A liquid supply passage 38 extends through the dispenser body 12 along a length of the needle 18. The liquid supply passage 38 fluidly connects to an inlet 42 of a liquid passageway 44 within the nozzle 14. Accordingly, liquid adhesive flows through the liquid supply passage 38, the liquid passageway 44, and the discharge passageway 30, to be dispensed from the outlet 36 when the needle 18 is disengaged from valve seat 28. Accordingly, the nozzle 14 and the needle 18 collectively provide a dispensing valve for controlling the flow of adhesive from the outlet 36.
More particularly, as shown in
The valve seat 28 is centered or coaxial with, and radially symmetric relative to the longitudinally extending needle 18 within the liquid passageway 44. The second converging surface 56 extends to the discharge passageway 30 having the outlet 36, which is defined by a distal, second cylindrical surface 58. The bore 48, in the form of the first converging surface, and the second converging surface 56 taper conically toward the outlet 36 with a given taper angled relative to the longitudinally extending needle 18. In contrast, the first and second cylindrical surfaces 46, 58 extend toward the outlet 36 generally parallel to the longitudinally extending needle 18.
The needle 18 includes a cylindrical valve surface 59 extending to the needle tip 20. An intersection of the cylindrical valve surface 59 and the needle tip 20 define a valve leading edge 60, whereas an intersection of the sealing cylindrical surface 50 and the bore 48 define a nozzle leading edge 61. The sealing cylindrical surface 50 of the liquid passageway 44 defines a sealing diameter sized to provide a sealing engagement with the cylindrical valve surface 59. As such, the valve leading edge 60 contacts and aligns with the nozzle leading edge 61 to define a first volume 70 (see
Furthermore, the needle tip 20 includes a first frustoconical valve surface 62 and a second frustoconical valve surface 64. The first and second frustoconical valve surfaces 62, 64 form a compound angle and terminate at a blunt apex 66. A circumferential portion of the first frustoconical valve surface 62 contacts the valve seat 28 to create the thin circular line of contact, which provides a sealing engagement in the distal closed position that defines a second volume 72 (see
Furthermore, the first frustoconical valve surface 62 tapers conically toward the apex 66 with a first included angle, whereas the second frustoconical valve surface 64 tapers conically toward the apex 66 with a second included angle smaller than the first included angle. According to an exemplary embodiment, the second included angle is smaller than the first included angle. The taper angle of the second converging surface 56 of the liquid passageway 44 is greater than or equal to the second included angle of the second frustoconical valve surface 64 such that a volume of a cavity 68 defined therebetween is reduced to minimize residual adhesive within the cavity 68. Also, at least a portion of the second frustoconical valve surface 64 and the apex 66 extend into the discharge passageway 30, proximate to the outlet 36, to inhibit clogging of adhesive in the distal closed position.
With respect to
The valve leading edge 60 moves distally beyond the nozzle leading edge 61 along the sealing cylindrical surface 50 as the needle 18 moves from the medial closed position to the distal closed position. Accordingly, the distance along the sealing cylindrical surface 50 that the valve leading edge 60 travels and further defines the sealing zone 26 along at least a portion of the sealing cylindrical surface 50 with the seal diameter. As the valve leading edge 60 moves distally along the sealing zone 26, the first volume 70 gradually reduces to the second volume 72 and the needle 18 positively displaces a differential volume of adhesive from the liquid passageway 44. The differential volume of the adhesive equates to the difference between the first remaining volume of adhesive 70 and the second remaining volume of adhesive 72.
With respect to
As shown in
The liquid supply passage 38 fluidly connects to an inlet 142 of a liquid passageway 144 within the nozzle 114. Accordingly, liquid adhesive flows through the liquid supply passage 38, the liquid passageway 144, and a discharge passageway 130, to be dispensed from the outlet 136 when the needle 118 is disengaged from valve seat 128. The nozzle 114 and the needle 118 collectively provide a dispensing valve for controlling the flow of adhesive from the outlet 136.
More particularly, the liquid passageway 144 is defined by the nozzle insert 124 including a proximal bore 148 defining the inlet 142 that extends to a sealing cylindrical surface 150. According to an exemplary embodiment, the bore 148 is in the form of a first converging surface, such as a first frustoconical surface. In turn, the sealing cylindrical surface 150 extends to a shoulder 152 carrying the valve seat 128. The shoulder 152 has a raised annular projection 154 tapering proximally toward the inlet 142. The valve seat 128 is further defined by an intersection between the shoulder 152 and a distal, second converging surface 156. More particularly, the second converging surface 156 is in the form of a second frustoconical surface. Accordingly, the valve seat 128 provides a smooth circumferential surface that defines a circular surface of contact with the needle tip 120. As described above, it will be appreciated that the term “circular line of contact” may refer to a circular line of generally any width. According to an exemplary embodiment, the smooth circumferential edge defines a relatively thick circular line of contact.
The valve seat 128 is centered or coaxial with, and radially symmetric relative to the longitudinally extending needle 118 within the liquid passageway 144. The second converging surface 156 extends to the discharge passageway 130. In addition, the bore 148 and the second converging surface 156 and second cylindrical surface 158 taper and extend respectively similar to those discussed above.
The needle 118 includes the cylindrical valve surface 159 extending to the needle tip 120. An intersection of the cylindrical valve surface 159 and the needle tip 120 define a valve leading edge 160, whereas an intersection of the sealing cylindrical surface 150 and the bore 148 define a nozzle leading edge 161. The sealing cylindrical surface 150 of the liquid passageway 144 defines a sealing diameter sized to provide a sealing engagement with the cylindrical valve surface 159. As such, the valve leading edge 160 makes initial engagement with the nozzle leading edge 161 to define a first volume 170 (see
Furthermore, the needle tip 120 includes a first frustoconical valve surface 162 and a second frustoconical valve surface 164. The first frustoconical valve surface 162 tapers toward the inlet 142 to define an annular converging groove 163 about the needle tip 120. The annular converging groove 163 is configured for sealing against the circular surface of the raised annular projection 154. As such, a circumferential portion of the first frustoconical valve surface 162 contacts the valve seat 128 to create the circular surface of contact, which provides a sealing engagement in the distal closed position that defines a second volume 172 (see
The second frustoconical valve surface 164 tapers conically toward the apex 66 with a first included angle. The taper angle of the second converging surface 156 of the liquid passageway 144 is greater than or equal to the second included angle of the second frustoconical valve surface 164 such that a volume of a cavity 68 defined therebetween is reduced to minimize residual adhesive within the cavity 68. Also, at least a portion of the second frustoconical valve surface 164 and the apex 66 extend into the discharge passageway 130, proximate to the outlet 136, to inhibit clogging of adhesive in the distal closed position.
With respect to
The valve leading edge 160 moves distally beyond the nozzle leading edge 161 along the sealing cylindrical surface 150 as the needle 118 moves from the medial closed position to the distal closed position. Accordingly, the distance along the sealing cylindrical surface 150 that the valve leading edge 160 travels, defines the sealing zone 126 along generally an entirety of the sealing cylindrical surface 150 with the seal diameter. As the valve leading edge 160 moves distally along the sealing zone 126, the first volume 170 gradually reduces to the second volume 172 and the needle 118 positively displaces a differential volume of adhesive from the liquid passageway 144.
With reference to
From the medial closed position, the needle 18 continues moving distally along the sealing zone 26 toward the distal closed position. While moving along the sealing zone 26, the first volume 70 of the liquid passageway 44 gradually reduces to the second volume 72 of the liquid passageway 44 in the distal closed position. In turn, the needle 18 positively displaces the adhesive remaining in the liquid passageway 44 and discharges the differential volume of adhesive as a second bead portion 80.
Furthermore, as the needle 18 approaches the valve seat 28, at least a portion of the needle tip 20 inserts into the discharge passageway 30 to inhibit adhesive clogging proximate to the outlet 36. According to an exemplary embodiment, the discharge passageway 30 and needle tip 20 define the cavity 68 therebetween that contains a final remaining portion of adhesive. While the approaching needle tip 20 partially obstructs the discharge passageway 30, the positive displacement of the adhesive forces the adhesive around the needle tip 20 and through the outlet 36 with sufficient consistency to generate a desirable bead 82 of adhesive as shown in
While the above description refers to the dispensing module 10 for dispensing the adhesive, the dispensing module 110 shown in
With respect to
While the present invention has been illustrated by the description of one or more embodiments thereof, and while the embodiments have been described in considerable detail, they are not intended to restrict or in any way limit the scope of the appended claims to such detail. The various features shown and described herein may be used alone or in any combination. Additional advantages and modifications will readily appear to those skilled in the art. The invention in its broader aspects is therefore not limited to the specific details, representative apparatus and method and illustrative examples shown and described. Accordingly, departures may be from such details without departing from the scope of the general inventive concept.
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