ADHESIVE DISPENSER WITH SLOTTED NOZZLE ASSEMBLY

TECHNICAL FIELD

This disclosure generally relates to adhesive dispensers for applying an adhesive to a substrate and, more particularly to a pump and slotted nozzle assembly of an adhesive dispenser for applying a pattern of adhesive to a substrate.

BACKGROUND

In the garment manufacturing field, adhesive dispensers are commonly used to apply an adhesive, such as a polyurethane (PUR) glue, to a fabric or cloth for binding pieces of the fabric or cloth together. When bonding pieces of fabric together, an adhesive dispenser is required that has the ability to apply a small amount of a material with a high degree of accuracy and precision. For example, the width of the desired strip of material to be applied to a fabric can have requirements of less than 8 mm in width and less than 0.2 mm in height. In many currently existing adhesive dispensers, adhesive is sprayed with low levels of accuracy and precision, which can result in the spraying of excessive amounts of adhesive.

In addition to problems caused by excessive adhesive spray, in many conventional adhesive dispensers, material will continue to flow out of the adhesive dispenser for some time after the spraying operation has completed due to the effects of gravity. Due to the fact that during a conventional fabric bonding process an operator needs to repeatedly start and stop the adhesive dispenser, adhesive will constantly flow out of the adhesive dispenser, leading to big ends, silk drawing, and other defects. Additionally, many conventional adhesive dispensers have weights and sizes that prevent their implementation in an environment requiring compact and low-weight design, such as on a tabletop.

Therefore, there is a need for an adhesive dispenser that is compact, low-weight, and accurately applies adhesive and minimizes continued flowing of adhesive out of the adhesive dispenser during a nonoperational state due to gravity.

SUMMARY

An embodiment of the present disclosure is an adhesive dispenser that includes a pump. The pump comprises a pump body assembly including a nozzle body defining a recess that extends into the nozzle body, and a fluid channel that has an inlet configured to receive adhesive and an outlet, where the outlet is open to the recess. The pump also comprises a valve member movably disposed in the fluid channel and configured to selectively block the adhesive from flowing to the outlet of the fluid channel. The adhesive dispenser also includes a slotted nozzle assembly for dispensing the adhesive, where the slotted nozzle assembly comprises a baffle plate including a slot that extends through the baffle plate and a cover plate attached to the baffle plate. The slotted nozzle assembly is received in the recess of the nozzle body such that an input channel that extends from the outlet of the nozzle body to the slot is defined between the baffle plate and the nozzle body, and an output channel that extends from the slot to a dispensing outlet is defined between the baffle plate and the cover plate.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of an adhesive dispenser according to an embodiment of the present disclosure;

FIG. 2 is a perspective view of a lower portion of the adhesive dispenser shown in FIG. 1;

FIG. 3 is a cross-sectional view of the adhesive dispenser shown in FIG. 1, taken along line 3-3 shown in FIG. 1;

FIG. 4 is a cross-sectional view of the adhesive dispenser shown in FIG. 1, taken along line 4-4 shown in FIG. 1;

FIG. 5 is an enlarged cross-sectional view of the adhesive dispenser shown in FIG. 1, as noted by the encircled region in FIG. 4;

FIG. 6 is an exploded view of a nozzle body and a slotted nozzle assembly according to an embodiment of the present disclosure;

FIG. 7 is a perspective view of the a nozzle body of the adhesive dispenser shown in FIG. 1;

FIG. 8A is a rear perspective view of a cover plate of a slotted nozzle assembly according to a first embodiment of the present disclosure;

FIG. 8B is a rear perspective view of a baffle plate of the first embodiment of the slotted nozzle assembly;

FIG. 8C is a front perspective view of the baffle plate of the first embodiment of the slotted nozzle assembly;

FIG. 8D is a bottom perspective view of the first embodiment of the slotted nozzle assembly;

FIG. 8E is a cross-sectional view of the first embodiment of the slotted nozzle assembly attached to the nozzle body, as noted by the encircled region in FIG. 5;

FIG. 8F is a perspective view of a substrate with an adhesive pattern applied using the first embodiment of the slotted nozzle assembly;

FIG. 9A is a rear perspective view of a cover plate of a slotted nozzle assembly according to a second embodiment of the present disclosure;

FIG. 9B is a rear perspective view of a baffle plate of the second embodiment of the slotted nozzle assembly;

FIG. 9C is a front perspective view of the baffle plate of the second embodiment of the slotted nozzle assembly;

FIG. 9D is a bottom perspective view of the second embodiment of the slotted nozzle assembly;

FIG. 9E is a cross-sectional view of the second embodiment of the slotted nozzle assembly attached to the nozzle body;

FIG. 10A is a rear perspective view of a cover plate of a slotted nozzle assembly according to a third embodiment of the present disclosure;

FIG. 10B is a rear perspective view of a baffle plate of the third embodiment of the slotted nozzle assembly;

FIG. 10C is a front perspective view of the baffle plate of the third embodiment of the slotted nozzle assembly;

FIG. 10D is a bottom perspective view of the third embodiment of the slotted nozzle assembly;

FIG. 10E is a cross-sectional view of the third embodiment of the slotted nozzle assembly attached to the nozzle body;

FIG. 10F is a perspective view of a substrate with an adhesive pattern applied using the third embodiment of the slotted nozzle assembly;

FIG. 11A is a rear perspective view of a cover plate of a slotted nozzle assembly according to a fourth embodiment of the present disclosure;

FIG. 11B is a rear perspective view of a baffle plate of the fourth embodiment of the slotted nozzle assembly;

FIG. 11C is a front perspective view of the baffle plate of the fourth embodiment of the slotted nozzle assembly;

FIG. 11D is a bottom view of the baffle plate of the fourth embodiment of the slotted nozzle assembly;

FIG. 11E is a bottom perspective view of the fourth embodiment of the slotted nozzle assembly;

FIG. 11F is a cross-sectional view of the fourth embodiment of the slotted nozzle assembly attached to the nozzle body;

FIG. 11G is a perspective view of a substrate with an adhesive pattern applied using the fourth embodiment of the slotted nozzle assembly;

FIG. 12 is an isometric perspective view of an adhesive dispenser according to another embodiment of the present disclosure;

FIG. 13A is an isometric perspective view of a baffle plate according to another embodiment of the slotted nozzle assembly;

FIG. 13B is an isometric perspective view of a baffle plate according to yet another embodiment of the slotted nozzle assembly;

FIG. 13C is an isometric perspective view of a baffle plate according to yet another embodiment of the slotted nozzle assembly;

FIG. 13D is an isometric perspective view of a baffle plate according to yet another embodiment of the slotted nozzle assembly; and

FIG. 14 is an isometric perspective view of a nozzle body according to another aspect of the present disclosure.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

Described herein is an adhesive dispenser 10 that includes a material supply 12, a pump 16, and a slotted nozzle assembly 100a-100d for applying an adhesive to a substrate 80. Certain terminology is used to describe the adhesive dispenser 10 in the following description for convenience only and is not limiting. The words “right”, “left”, “lower,” and “upper” designate directions in the drawings to which reference is made. The words “inner” and “outer” refer to directions toward and away from, respectively, the geometric center of the description to describe the adhesive dispenser 10 and related parts thereof. The words “forward” and “rearward” refer to directions in a longitudinal direction 2 and a direction opposite the longitudinal direction 2 along the adhesive dispenser 10 and related parts thereof. The terminology includes the above-listed words, derivatives thereof and words of similar import.

Unless otherwise specified herein, the terms “longitudinal,” “lateral,” and “vertical” are used to describe the orthogonal directional components of various components of the adhesive dispenser 10, as designated by the longitudinal direction 2, lateral direction 4, and vertical direction 6. It should be appreciated that while the longitudinal and lateral directions 2, 4 are illustrated as extending along a horizontal plane, and the vertical direction 6 is illustrated as extending along a vertical plane, the planes that encompass the various directions may differ during use.

Referring to FIGS. 1-8, the adhesive dispenser 10 includes a material supply 12 for storing a supply of the adhesive. In the depicted embodiment, the material supply 12 defines a cavity 15 for receiving a prepackaged syringe 17 that contains a supply of the adhesive. However, other embodiments for supplying the material supply 12 with adhesive are contemplated, such as directly filling the material supply 12 with a volume of the adhesive or pumping adhesive to the material supply 12 from an external supply (not shown) that is spaced from the adhesive dispenser 10. In some embodiments, the adhesive may be a glue, such as polyurethane (PUR) glue, though other materials are contemplated. The material supply 12 can be configured to melt and/or maintain the adhesive at an elevated temperature while it remains within the material supply 12. In some embodiments, the material supply 12 can be designed to hold up to 300 milliliters (ml) of adhesive, though the material supply 12 can be larger or smaller as desired. For example, the material supply 12 can also be designed to hold 30 ml of adhesive. The material supply 12 can include a heating element (not shown) to provide heat to the adhesive within the material supply 12, or, alternatively, to maintain a desired temperature within the material supply 12. This prevents the adhesive from cooling when it is being dispensed, thus preserving the desired flow properties. In some embodiments, the adhesive dispenser 10 may include a second heating element (not shown) that is configured to maintain the adhesive at a different temperature than the heating element described above. Further, the material supply 12 can include a cap 13 for securing the syringe 17 within the cavity 15, where the cap 13 defines a passage 14 extending therethrough. The passage 14 can be connected to an external pressurized air source (not shown) that is configured to apply pressure to the adhesive within the cavity 15 for pumping the adhesive out of the material supply 12.

The material supply 12 further includes a fluid channel 21 that extends from the cavity 15 to a fluid outlet 22. The fluid outlet 22 is configured to provide the adhesive to the inlet 26a of the pump 16, as will be described below. A check valve 23 can be disposed in the fluid channel 21 between the cavity 15 and the fluid outlet 22 to prevent adhesive that has flowed past the check valve 23 from returning to the cavity 15. This prevents the contamination of new adhesive disposed in the cavity 15 after an old supply of adhesive has been replaced. Though a ball-type check valve 23 is shown, other conventional types of check valves can alternatively be incorporated.

The adhesive dispenser 10 also includes a pump 16 releasably attached to the material supply 12 and fluidly connected to the material supply 12. The pump 16 can include a pump body assembly 32 comprising a pump body 32b, a cap 32a attached to the upper end of the pump body 32b, and a nozzle body 32c attached to the lower end of the pump body 32b. It will be understood that the pump 16 can alternatively define a monolithic body or have any other number of components. The pump body 32b can define the portion of the pump body assembly 32 that directly connects to the material supply 12, though other arrangements are contemplated.

The pump body assembly 32 can define several hollow portions. For example, the pump body 32b and the nozzle body 32c of the pump body assembly 32 can collectively define a fluid channel 26 that extends from an inlet 26a to an outlet 26b. The fluid channel 26 is configured to receive adhesive from the material supply 12 through the inlet 26a and provide the adhesive to one of the nozzle assemblies 100a-100d through the outlet 26b, as will be described further below. Additionally, the pump body 32b and the nozzle body 32c can collectively define an upper chamber 36 and a lower chamber 38. Upper and lower seal packs 40a, 40b are positioned within the pump body assembly 32 to separate the upper and lower chambers 36, 38.

The pump 16 also includes a valve member 48 positioned within the pump body assembly 32. The valve member 48 defines an upper end 48a and a valve stem 48b that extends from the upper end 48a along the vertical direction 6. The upper end 48a is positioned within the upper chamber 36, while the valve stem 48b extends from the upper end 48a through the upper chamber 36, through the upper and lower seal packs 40a, 40b, and into the lower chamber 38, which can define a portion of the fluid channel 26. The valve member 48 is configured to be movably disposed within the upper and lower chambers 36, 38, and thus the fluid channel 26. The upper and lower seal packs 40a, 40b are configured to prevent adhesive migration from the lower chamber 38 to the upper chamber 36 and pressurized air migration from the upper chamber 36 to the lower chamber 38. A valve seat 54 is disposed at the lower end of the lower chamber 38 and is defined by the nozzle body 32c. In operation, the valve member 48 is configured to reciprocate within the pump body assembly 32 between a first, retracted position and a second, extended position. In the retracted position, the valve stem 48b is spaced in an entirety from the valve seat 54, allowing adhesive to flow past the valve stem 48b and the valve seat 54 and to the outlet 26b of the fluid channel 26. In the extended position, the valve stem 48b contacts the valve seat 54 and the adhesive is blocked from flowing to the outlet 26c of the fluid channel 26. As such, the valve member 48 is configured to selectively block the flow of adhesive through the fluid channel 26.

The translation of the valve member 48 can be caused by pressurized air that flows into the upper chamber 36 through first and second air paths 52a, 52b of connector 24. Each of first and second air paths 52a, 52b can receive pressurized air from a valve 20, which is connected to the pump 16 through the connector 24. The valve 20 can be a pneumatic valve, an electronic valve, or any other type of valve as desired. The valve 20 can be connected to and receive the pressurized air from a pressurized air source 25, such that the valve functions to control the flow of air from the pressurized air source 25 to the pump 16. The upper end 48a of the valve member 48 divides the upper chamber 36 into first and second portions 36a, 36b, where the first portion 36a can receive pressurized air from the first air path 52a, and the second portion 36b can receive pressurized air from the second air path 52b. Specifically, the first portion 36a can be defined between the cap 32a and the upper end 48a of the valve member 48, and the second portion 36b can be defined between the upper end 48a of the valve member 48 and the pump body 32b. When pressurized air flows through the first air path 52a and into the first portion 36a of the upper chamber 36, the valve member 48 is driven downwards along the vertical direction 6 into the extended position. In contrast, when pressurized air flows through the second air path 52b and into the second portion 36b of the upper chamber 36, the valve member 48 is driven upwards along the vertical direction 6 into the retracted position.

When the valve member 48 transitions from the retracted position to the extended position along the vertical direction 6, the valve member 48 travels a distance that can be referred to as the stroke length. The required stroke length can vary between dispensing operations, types of materials dispensed, wear of internal parts over time, etc. In one embodiment of the pump 16, the stroke length can be adjusted using a limiting rod (not shown) that extends through the cap 32a of the pump body assembly 32 and into the first portion 36a of the upper chamber 36. When the valve member 48 is in the retracted position, the upper end 48a can contact the lower end of the limiting rod, such that the limiting rod 44 controls the how far upwards the valve member 48 moves in the retracted position. The limiting rod can threadedly engage the cap 32a, such that rotation of the limiting rod relative to the cap 32a moves the limiting rod further into or out of the upper chamber 36, thus changing the maximum upward position of the valve member 48 in the retracted position, and likewise the stroke length. However, other methods for adjusting the stroke length are also contemplated.

Continuing with FIGS. 2 and 5-7, the nozzle body 32c of the pump body assembly 32 can define an outer surface that comprises a front surface 35a, a rear surface 35b opposite the front surface 35a along the lateral direction 4, a first side surface 35c, a second side surface 35d opposite the first side surface 35c along the longitudinal direction 2, a lower surface 35e, and a top surface 35f opposite the lower surface 35e along the vertical direction 6. In particular, the top surface 35f can directly contact the pump body 32b when the pump body assembly 32 is completely assembled, while the nozzle body 32c can define a recess 60 that extends into the nozzle body 32c from the front and lower surfaces 35a, 35e. The nozzle body 32c can have a plurality of surfaces that define the recess 60. In particular, the nozzle body 32c can have an upper recess surface 60a, a first side recess surface 60b, a second side recess surface 60c opposite the first side recess surface 60b along the longitudinal direction 2, and a rear recess surface 60d. Each of the surfaces 60a-60d can collectively define the recess 60, which is configured to receive a slotted nozzle assembly 100a-100d, as will be described further below.

In the depicted embodiment, the recess 60 is substantially rectangular, though other shapes are contemplated depending on the shape of the slotted nozzle assembly to be attached. The upper recess surface 60a can extend from the front surface 35a of the nozzle body 32c to the rear recess surface 60d, while the rear recess surface 60d can extend from the lower surface 35e of the nozzle body 32c to the upper recess surface 60a. The outlet 26b of the fluid channel 26 can be defined by the rear recess surface 60d, causing the outlet 26b to be open to the recess 60. In particular, the outlet 26b can comprise a plurality of outlets 28a-28e. Though five outlets 28a-28e are shown specifically, the outlet 26b can include more or less than six outlets, such as one, two, three, or more than six outlets. Further, each of the outlets 28a-28e can be differently configured. In the depicted embodiment, the third outlet 28c is depicted as a lateral slot, while the first, second, fourth, and fifth outlets 28a, 28b, 28d, 28e are depicted as circular holes. However, the outlets 28a-28e can be alternatively configured to include other combinations of the depicted shapes or other shapes not shown. Additionally, the outlets 28a-28e are shown as substantially aligned along the longitudinal direction 2. Despite this, in other embodiments the outlets 28a-28e can be alternatively spaced. The rear recess surface 60d can also define two bores 62a, 62b configured to receive respective fasteners 64 for releasably attaching one of the slotted nozzle assemblies 100a-100d to the pump 16. The slotted nozzle assemblies 100a-100d are each configured to dispense the adhesive onto the substrate in a particular pattern. Each of the slotted nozzle assemblies 100a-100d will be discussed below in turn. Referring to the exemplary aspect depicted in FIG. 14, for example, the outlet 26b may be a single rectangular slot.

Referring to FIGS. 8A-8E, a first embodiment of a slotted nozzle assembly 100a and its constituent components are depicted. The slotted nozzle assembly 100a can comprise a cover plate 102 and a baffle plate 120. The cover plate 102 can be a substantially rectangular shaped plastic or metallic component. The cover plate 102 can define a body 104 that has a front surface 104a, a rear surface 104b opposite the front surface 104a along the lateral direction 4, an upper surface 104c, a lower surface 104d opposite the upper surface 104c along the vertical direction 6, a first side surface 104e, and a second side surface 104f opposite the first side surface 104e along the longitudinal direction 2. The cover plate 102 can also include a lip 108 embodying a substantially rectangular protrusion that extends from the lower surface 104d along the vertical direction 6 and along the lower surface 104d in the longitudinal direction 2. Additionally, the cover plate 102 can define bores 112a, 112b that extend from the front surface 104a to the rear surface 104b along the lateral direction 4. Each of the bores 112a, 112b is configured to receive a respective fastener 64. Though the cover plate 102 is shown as including two bores 112a, 112b, the cover plate 102 can include more or less bores as desired. However, the number of bores included in the cover plate 102 will generally correspond to the number of bores defined by the rear recess surface 60d of the nozzle body 32c.

Similar to the cover plate 102, the baffle plate 120 can be a substantially rectangular shaped plastic or metallic component. The baffle plate 120 can define a body 124 that has a front surface 124a, a rear surface 124b opposite the front surface 124a along the lateral direction 4, an upper surface 124c, a lower surface 124d opposite the upper surface 124c along the vertical direction 6, a first side surface 124e, and a second side surface 124f opposite the first side surface 124e along the longitudinal direction 2. The baffle plate 120 can also include a lip 128 that substantially matches the lip 108 of the cover plate 102. As such, the lip 128 can embody a substantially rectangular protrusion that extends from the lower surface 124d along the vertical direction 6 and along the lower surface 124d in the longitudinal direction 2. Additionally, the baffle plate 120 can define bores 132a, 132b that extend from the front surface 124a to the rear surface 124b along the lateral direction 4. Each of the bores 132a, 132b is configured to receive a respective fastener 64. Though the baffle plate 120 is shown as including two bores 132a, 132b, the baffle plate 120 can include more or less bores as desired. However, like the cover plate 102, the number of bores included in the baffle plate 120 will generally correspond to the number of bores defined by the rear recess surface 60d of the nozzle body 32c.

The baffle plate 120 can also include the features of the slotted nozzle assembly 100a that allow the adhesive to flow through the slotted nozzle assembly 100a. The baffle plate 120 can define an input recess 136 that extends into the body 124 of the baffle plate 120 from the rear surface 124b along the lateral direction 4. The input recess 136 can be substantially rectangular shaped, though other shapes are contemplated. At the top of the input recess 136, the baffle plate 120 can have a slot 140 that extends through the baffle plate 120 from the rear surface 124b to the front surface 124a. The baffle plate 120 can include a plurality of inner surfaces that define the slot 140. Specifically, the baffle plate 120 can have first and second slot surface 144a, 144b that define the lower side of the slot 140, as well as a third slot surface 144c that is spaced from the first and second slot surface 144a, 144b along the vertical direction 6 and defines the upper side of the slot 140. The first and third slot surfaces 144a, 144c can each be substantially planar surfaces, while the second slot surface 144b can be a substantially curved, semicircular surface. Though one specific arrangement and design of slot surfaces 144a-144c are depicted, other embodiments and designs are contemplated. Notably, the slot 140 is depicted as spaced in an entirety from the upper surface 124c and the lower surface 124d. However, it is contemplated that the slot 140 could extend into the body 124 from the upper surface 124c. Opposite the input recess 136, the baffle plate 120 can define an output recess 148 that extends into the body 124 of the baffle plate 120 from the front surface 124a along the lateral direction 4. The output recess 148 can be substantially rectangular shaped, though other shapes are contemplated, and can extend from the slot 140 to the bottom of the lip 128 of the baffle plate 120. The output recess 148 can define a width W₁measured along the longitudinal direction 2, where the width W₁can be from about 4 mm to about 20 mm.

With specific reference to FIG. 8E, the slotted nozzle assembly 100a is shown fully assembled and connected to the pump 16. Specifically, the slotted nozzle assembly 100a is shaped and sized to be received in the recess 60 of the pump body assembly 32. To attach the slotted nozzle assembly 100a to the pump 16, the bores 112a, 112b of the cover plate are aligned with the bores 132a, 132b of the baffle plate 120 and the bores 62a, 62b of the nozzle body 32c. Then, a fastener 64 is disposed through bores 112a, 132a, 62a while another fastener 64 is disposed through bores 112b, 132b, 62b, and the fasteners 64 engage the nozzle body 32c to releasably couple the slotted nozzle assembly 100a to the pump 16. When attached to the pump 16, the upper surface 104c of the cover plate 102 and the upper surface 124c of the baffle plate 120 can engage the upper recess surface 60a, while the rear surface 124b of the baffle plate 120 can engage the rear recess surface 60d. Additionally, the first side surface 104e of the cover plate 102 and the first side surface 124e of the baffle plate 120 can engage the first side recess surface 60b, while the second side surface 104f of the cover plate 102 and the second side surface 124f of the baffle plate 120 can engage the second side recess surface 60c. The front surface 104a of the cover plate 102 can be substantially coplanar with the front surface 35a of the nozzle body 32c, while the lower surfaces 104d, 124d of the cover plate 102 and baffle plate 120, respectively, can be positioned below the lower surface 35e of the nozzle body 32c along the vertical 6.

Gaskets or other sealing components may be disposed throughout the adhesive dispenser 10. In some aspects, one or more sealing gaskets may be disposed between the valve seat 54 and the dispensing outlet 152 to prevent leakage of the adhesive. Referring, for example, to FIG. 12, a gasket 50 may be disposed between the nozzle body 32c and the slotted nozzle assembly 100a. It will be appreciated that any suitable sealing gasket may be used, such as flat washers or rounded or semi-rounded washers, and that they may vary in shape and size to form the proper seals between adjacent components.

FIG. 9E also shows the flow path of adhesive as it flows through the pump 16 and slotted nozzle assembly 100a, where the direction of fluid flow is indicated by solid arrows. When the cover plate 102 and baffle plate 120 are secured to the nozzle body 32c, an input channel 138 that receives adhesive from the outlet 26b of the fluid channel 26 is defined between the baffle plate 120 and the nozzle body 32c. Specifically, the input channel 138 is defined by the input recess 136 of the baffle plate 120 and the rear recess surface 60d of the nozzle body 32c. The input channel 138 extends from the outlet 26b of the fluid channel 26 to the slot 140, which, as noted above, extends through the entirety of the baffle plate 120. The slotted nozzle assembly 100a also defines an output channel 150 between the baffle plate 120 and the cover plate 102. Specifically, the output channel 150 is defined by the output recess 148 of the baffle plate 120 and the rear surface 104b of the cover plate 102. The output channel 150 extends from the slot 140 and terminates at the dispensing outlet 152, from which adhesive is applied to the substrate 80. As shown in FIGS. 9D-9E, the dispensing outlet 152 of the slotted nozzle assembly 100a takes the form of a single, elongate slot so as to produce an adhesive pattern that comprises a continuous adhesive strip 84 having a width W₁on the substrate 80. As such, when the valve member 48 of the pump 16 is in a retracted position, adhesive can flow past the valve seat 54, through the outlet 26b of the fluid channel 26, and into the input channel 138. From there, the adhesive flows vertically up through the input channel 138, laterally through the slot 140, downwardly through the output channel 150, and through the dispensing outlet 152 and onto the substrate 80.

Referring to FIGS. 9A-9E, a second embodiment of a slotted nozzle assembly 100b and its constituent components are depicted. Like the slotted nozzle assembly 100a, the slotted nozzle assembly 100b can comprise a cover plate 202 and a baffle plate 220. The cover plate 202 can be a substantially rectangular shaped plastic or metallic component. The cover plate 202 can define a body 204 that has a front surface 204a, a rear surface 204b opposite the front surface 204a along the lateral direction 4, an upper surface 204c, a lower surface 204d opposite the upper surface 204c along the vertical direction 6, a first side surface 204e, and a second side surface 204f opposite the first side surface 204e along the longitudinal direction 2. The cover plate 202 can also include a lip 208 embodying a substantially rectangular protrusion that extends from the lower surface 204d along the vertical direction 6 and along the lower surface 204d in the longitudinal direction 2. Additionally, the cover plate 202 can define bores 212a, 212b that extend from the front surface 204a to the rear surface 204b along the lateral direction 4. Each of the bores 212a, 212b is configured to receive a respective fastener 64. Though the cover plate 202 is shown as including two bores 212a, 212b, the cover plate 202 can include more or less bores as desired. However, the number of bores included in the cover plate 202 will generally correspond to the number of bores defined by the rear recess surface 60d of the nozzle body 32c. In some aspects, the cover plate 202 may be fastened via 2, 4, or another suitable number of fasteners 64. Referring to the exemplary aspect depicted in FIG. 12, for example, four fasteners 64 may be used.

Similar to the cover plate 202, the baffle plate 220 can be a substantially rectangular shaped plastic or metallic component. The baffle plate 220 can define a body 224 that has a front surface 224a, a rear surface 224b opposite the front surface 224a along the lateral direction 4, an upper surface 224c, a lower surface 224d opposite the upper surface 224c along the vertical direction 6, a first side surface 224e, and a second side surface 224f opposite the first side surface 224e along the longitudinal direction 2. The baffle plate 220 can also include a lip 228 that substantially matches the lip 208 of the cover plate 202. As such, the lip 228 can embody a substantially rectangular protrusion that extends from the lower surface 224d along the vertical direction 6 and along the lower surface 224d in the longitudinal direction 2. Additionally, the baffle plate 220 can define bores 232a, 232b that extend from the front surface 224a to the rear surface 224b along the lateral direction 4. Each of the bores 232a, 232b is configured to receive a respective fastener 64. Though the baffle plate 220 is shown as including two bores 232a, 232b, the baffle plate 220 can include more or less bores as desired. However, like the cover plate 202, the number of bores included in the baffle plate 220 will generally correspond to the number of bores defined by the rear recess surface 60d of the nozzle body 32c.

The baffle plate 220 can also include the features of the slotted nozzle assembly 100b that allow the adhesive to flow through the slotted nozzle assembly 100b. The baffle plate 220 can define an input recess 236 that extends into the body 224 of the baffle plate 220 from the rear surface 224b along the lateral direction 4. The input recess 236 can be substantially rectangular shaped, though other shapes are contemplated. At the top of the input recess 236, the baffle plate 220 can have a slot 240 that extends through the baffle plate 220 from the rear surface 224b to the front surface 224a. The baffle plate 220 can include a plurality of inner surfaces that define the slot 240. Specifically, the baffle plate 220 can have first and second slot surface 244a, 244b that define the lower side of the slot 240, as well as a third slot surface 244c that is spaced from the first and second slot surface 244a, 244b along the vertical direction 6 and defines the upper side of the slot 240. The first and third slot surfaces 244a, 244c can each be substantially planar surfaces, while the second slot surface 244b can be a substantially curved, semicircular surface. Though one specific arrangement and design of slot surfaces 244a-244c are depicted, other embodiments and designs are contemplated. Notably, the slot 240 is depicted as spaced in an entirety from the upper surface 224c and the lower surface 224d. However, it is contemplated that the slot 240 could extend into the body 224 from the upper surface 224c. Opposite the input recess 236, the baffle plate 220 can define a plurality of output recesses 248 that extend into the body 224 of the baffle plate 220 from the front surface 224a along the lateral direction 4. As depicted, the baffle plate 220 includes seven output recesses 248a-248g that extend generally parallel to each other and are spaced apart along the longitudinal direction 2. However, the baffle plate 220 can include anywhere from two to ten output recesses 248. The output recesses 248a-248g can be substantially rectangular shaped, though other shapes are contemplated, and can extend from the slot 240 to the bottom of the lip 228 of the baffle plate 220. The output recesses 248a-248g can define a width W₂measured along the longitudinal direction 2, where the width W₂can be from about 0.5 mm to about 1 mm. As shown, each of the plurality of output recesses 248 does not define the same width. Also, the plurality of output recesses are non-equidistantly spaced apart along the longitudinal 2.

With specific reference to FIG. 9E, the slotted nozzle assembly 100b is shown fully assembled and connected to the pump 16. Specifically, the slotted nozzle assembly 100b is shaped and sized to be received in the recess 60 of the pump body assembly 32. To attach the slotted nozzle assembly 100b to the pump 16, the bores 212a, 212b of the cover plate 202 are aligned with the bores 232a, 232b of the baffle plate 220 and the bores 62a, 62b of the nozzle body 32c. Then, a fastener 64 is disposed through bores 212a, 232a, 62a while another fastener 64 is disposed through bores 212b, 232b, 62b, and the fasteners 64 engage the nozzle body 32c to releasably couple the slotted nozzle assembly 100b to the pump 16. When attached to the pump 16, the upper surface 204c of the cover plate 202 and the upper surface 224c of the baffle plate 220 can engage the upper recess surface 60a, while the rear surface 224b of the baffle plate 220 can engage the rear recess surface 60d. Additionally, the first side surface 204e of the cover plate 202 and the first side surface 224e of the baffle plate 220 can engage the first side recess surface 60b, while the second side surface 204f of the cover plate 202 and the second side surface 224f of the baffle plate 220 can engage the second side recess surface 60c. The front surface 104a of the cover plate 202 can be substantially coplanar with the front surface 35a of the nozzle body 32c, while the lower surfaces 204d, 224d of the cover plate 202 and baffle plate 220, respectively, can be positioned below the lower surface 35e of the nozzle body 32c along the vertical direction 6.

FIG. 9E also shows the flow path of adhesive as it flows through the pump 16 and slotted nozzle assembly 100b, where the direction of fluid flow is indicated by solid arrows. When the cover plate 202 and baffle plate 220 are secured to the nozzle body 32c, an input channel 238 that receives adhesive from the outlet 26b of the fluid channel 26 is defined between the baffle plate 220 and the nozzle body 32c. Specifically, the input channel 238 is defined by the input recess 236 of the baffle plate 220 and the rear recess surface 60d of the nozzle body 32c. The input channel 238 extends from the outlet 26b of the fluid channel 26 to the slot 240, which, as noted above, extends through the entirety of the baffle plate 220. The slotted nozzle assembly 100b also defines a plurality of output channels 250a-250g between the baffle plate 220 and the cover plate 202. Specifically, the plurality of output channels 250a-250g are each defined by a respective one of the output recesses 248a-248g of the baffle plate 220 and the rear surface 204b of the cover plate 202. The plurality of output channels 250a-250g each extend from the slot 240 and terminate at a respective dispensing outlet 252a-252g, from which adhesive is applied to the substrate 80. Because the baffle plate 220 can have between two and ten output recesses 248, the nozzle assembly 100b can similarly have between two and ten output channels 250 and between two and ten dispensing outlets 252. As shown in FIG. 9D, the dispensing outlets 252a-252g of the slotted nozzle assembly 100b take the form of longitudinally spaced apart slots so as to produce an adhesive pattern that comprises an array of adhesive dots. Thus, when the valve member 48 of the pump 16 is in a retracted position, adhesive can flow past the valve seat 54, through the outlet 26b of the fluid channel 26, and into the input channel 238. From there, the adhesive flows vertically up through the input channel 238, laterally through the slot 240, downwardly through the output channels 250a-250g, and through the dispensing outlets 252a-252g and onto the substrate 80. Because the output recesses 248a-248g, and thus the dispensing outlets 252a-252g have varying widths and are not equidistantly spaced apart, the resulting array of dispensed adhesive dots will similarly have such spacing and size differences.

Referring to FIGS. 10A-10F, a third embodiment of a slotted nozzle assembly 100c and its constituent components are depicted. Like the slotted nozzle assemblies 100a, 100b, the slotted nozzle assembly 100c can comprise a cover plate 302 and a baffle plate 320. The cover plate 302 can be a substantially rectangular shaped plastic or metallic component. The cover plate 302 can define a body 304 that has a front surface 304a, a rear surface 304b opposite the front surface 304a along the lateral direction 4, an upper surface 304c, a lower surface 304d opposite the upper surface 304c along the vertical direction 6, a first side surface 304e, and a second side surface 304f opposite the first side surface 304e along the longitudinal direction 2. The cover plate 302 can also include a lip 308 embodying a substantially rectangular protrusion that extends from the lower surface 304d along the vertical direction 6 and along the lower surface 304d in the longitudinal direction 2. Additionally, the cover plate 302 can define bores 312a, 312b that extend from the front surface 304a to the rear surface 304b along the lateral direction 4. Each of the bores 312a, 312b is configured to receive a respective fastener 64. Though the cover plate 302 is shown as including two bores 312a, 312b, the cover plate 302 can include more or less bores as desired. However, the number of bores included in the cover plate 302 will generally correspond to the number of bores defined by the rear recess surface 60d of the nozzle body 32c.

Similar to the cover plate 302, the baffle plate 320 can be a substantially rectangular shaped plastic or metallic component. The baffle plate 320 can define a body 324 that has a front surface 324a, a rear surface 324b opposite the front surface 324a along the lateral direction 4, an upper surface 324c, a lower surface 324d opposite the upper surface 324c along the vertical direction 6, a first side surface 324e, and a second side surface 324f opposite the first side surface 324e along the longitudinal direction 2. The baffle plate 320 can also include a lip 328 that substantially matches the lip 308 of the cover plate 302. As such, the lip 328 can embody a substantially rectangular protrusion that extends from the lower surface 324d along the vertical direction 6 and along the lower surface 324d in the longitudinal direction 2. Additionally, the baffle plate 320 can define bores 332a, 332b that extend from the front surface 324a to the rear surface 324b along the lateral direction 4. Each of the bores 332a, 332b is configured to receive a respective fastener 64. Though the baffle plate 320 is shown as including two bores 332a, 332b, the baffle plate 320 can include more or less bores as desired. However, like the cover plate 302, the number of bores included in the baffle plate 320 will generally correspond to the number of bores defined by the rear recess surface 60d of the nozzle body 32c.

The baffle plate 320 can also include the features of the slotted nozzle assembly 100c that allow the adhesive to flow through the slotted nozzle assembly 100c. The baffle plate 320 can define an input recess 336 that extends into the body 324 of the baffle plate 320 from the rear surface 324b along the lateral direction 4. The input recess 336 can be substantially rectangular shaped, though other shapes are contemplated. At the top of the input recess 336, the baffle plate 320 can have a slot 340 that extends through the baffle plate 320 from the rear surface 324b to the front surface 324a. The baffle plate 320 can include a plurality of inner surfaces that define the slot 340. Specifically, the baffle plate 320 can have first and second slot surfaces 344a, 344b that define the lower side of the slot 340, as well as a third slot surface 344c that is spaced from the first and second slot surfaces 344a, 344b along the vertical direction 6 and defines the upper side of the slot 340. The first and third slot surfaces 344a, 344c can each be substantially planar surfaces, while the second slot surface 344b can be a substantially curved, semicircular surface. Though one specific arrangement and design of slot surfaces 344a-344c are depicted, other embodiments and designs are contemplated. Notably, the slot 340 is depicted as spaced in an entirety from the upper surface 324c and the lower surface 324d. However, it is contemplated that the slot 340 could extend into the body 324 from the upper surface 324c. Opposite the input recess 336, the baffle plate 320 can define a plurality of output recesses 348 that extend into the body 324 of the baffle plate 320 from the front surface 324a along the lateral direction 4. As depicted, the baffle plate 320 includes six output recesses 348a-348f that extend generally parallel to each other and are spaced apart along the longitudinal direction 2. However, the baffle plate 320 can include anywhere from two to ten output recesses 348. The output recesses 348a-348f can be substantially rectangular shaped, though other shapes are contemplated, and can extend from the slot 340 to the bottom of the lip 328 of the baffle plate 320. The output recesses 348a-348f can each define a width W₃measured along the longitudinal direction 2, where the width W₃can be from about 0.5 mm to about 1 mm. As shown, each of the output recesses 348a-348f defines the same width. Also, the output recesses 348a-348f are equidistantly spaced apart along the longitudinal direction 2.

With specific reference to FIG. 10E, the slotted nozzle assembly 100c is shown fully assembled and connected to the pump 16. Specifically, the slotted nozzle assembly 100c is shaped and sized to be received in the recess 60 of the pump body assembly 32. To attach the slotted nozzle assembly 100c to the pump 16, the bores 312a, 312b of the cover plate 302 are aligned with the bores 332a, 332b of the baffle plate 320 and the bores 62a, 62b of the nozzle body 32c. Then, a fastener 64 is disposed through bores 312a, 332a, 62a while another fastener 64 is disposed through bores 312b, 332b, 62b, and the fasteners are coupled to the nozzle body 32c to releasably couple the slotted nozzle assembly 100c to the pump 16. When attached to the pump 16, the upper surface 304c of the cover plate 302 and the upper surface 324c of the baffle plate 320 can engage the upper recess surface 60a, while the rear surface 324b of the baffle plate 320 can engage the rear recess surface 60d. Additionally, the first side surface 304e of the cover plate 302 and the first side surface 324e of the baffle plate 320 can engage the first side recess surface 60b, while the second side surface 304f of the cover plate 302 and the second side surface 324f of the baffle plate 320 can engage the second side recess surface 60c. The front surface 304a of the cover plate 302 can be substantially coplanar with the front surface 35a of the nozzle body 32c, while the lower surfaces 304d, 324d of the cover plate 302 and baffle plate 320, respectively, can be positioned below the lower surface 35e of the nozzle body 32c along the vertical direction 6.

FIG. 10E also shows the flow path of adhesive as it flows through the pump 16 and slotted nozzle assembly 100c, where the direction of fluid flow is indicated by solid arrows. When the cover plate 302 and baffle plate 320 are secured to the nozzle body 32c, an input channel 338 that receives adhesive from the outlet 26b of the fluid channel 26 is defined between the baffle plate 320 and the nozzle body 32c. Specifically, the input channel 338 is defined by the input recess 336 of the baffle plate 320 and the rear recess surface 60d of the nozzle body 32c. The input channel 338 extends from the outlet 26b of the fluid channel 26 to the slot 340, which, as noted above, extends through the entirety of the baffle plate 320. The slotted nozzle assembly 100c also defines a plurality of output channels 350a-350f between the baffle plate 320 and the cover plate 302. Specifically, the output channels 350a-350f are each defined by a respective one of the output recesses 348a-348f of the baffle plate 320 and the rear surface 304b of the cover plate 302. The output channels 350a-350f each extend from the slot 340 and terminate at a respective dispensing outlet 352a-352f, from which adhesive is applied to the substrate 80. Because the baffle plate 320 can have between two and ten output recesses 348, the nozzle assembly 100c can similarly have between two and ten output channels 350 and between two and ten dispensing outlets 352. As shown in FIG. 10D-10E, the dispensing outlets 352a-352f of the slotted nozzle assembly 100c take the form of longitudinally spaced apart slots so as to produce an adhesive pattern 184 on the substrate 80 that comprises an array of adhesive dots 188. Thus, when the valve member 48 of the pump 16 is in a retracted position, adhesive can flow past the valve seat 54, through the outlet 26b of the fluid channel 26, and into the input channel 338. From there, the adhesive flows vertically up through the input channel 338, laterally through the slot 340, downwardly through the output channels 350a-350f, and through the dispensing outlets 352a-352f and onto the substrate 80. Because the output recesses 348a-348f, and thus the dispensing outlets 352a-352g have equal widths and are equidistantly spaced apart, the resulting adhesive pattern 184 will comprise equidistantly spaced and uniform adhesive dots 188. In contrast, the slotted nozzle assembly 100b described above will produce a similar adhesive pattern to the adhesive pattern 184, but with adhesive dots of varying sizes that are unequally spaced apart.

Referring to FIGS. 11A-11F, a fourth embodiment of a slotted nozzle assembly 100d and its constituent components are depicted. Like the slotted nozzle assemblies 100a-100c, the slotted nozzle assembly 100d can comprise a cover plate 402 and a baffle plate 420. The cover plate 402 can be a substantially rectangular shaped plastic or metallic component. The cover plate 402 can define a body 404 that has a front surface 404a, a rear surface 404b opposite the front surface 404a along the lateral direction 4, an upper surface 404c, a lower surface 404d opposite the upper surface 404c along the vertical direction 6, a first side surface 404e, and a second side surface 404f opposite the first side surface 404e along the longitudinal direction 2. The cover plate 402 can also include a lip 408 embodying a substantially rectangular protrusion that extends from the lower surface 404d along the vertical direction 6 and along the lower surface 404d in the longitudinal direction 2. Additionally, the cover plate 402 can define bores 412a, 412b that extend from the front surface 404a to the rear surface 404b along the lateral direction 4. Each of the bores 412a, 412b is configured to receive a respective fastener 64. Though the cover plate 402 is shown as including two bores 412a, 412b, the cover plate 402 can include more or less bores as desired. However, the number of bores included in the cover plate 402 will generally correspond to the number of bores defined by the rear recess surface 60d of the nozzle body 32c.

Similar to the cover plate 402, the baffle plate 420 can be a substantially rectangular shaped plastic or metallic component. The baffle plate 420 can define a body 424 that has a front surface 424a, a rear surface 424b opposite the front surface 424a along the lateral direction 4, an upper surface 424c, a lower surface 424d opposite the upper surface 424c along the vertical direction 6, a first side surface 424e, and a second side surface 424f opposite the first side surface 424e along the longitudinal direction 2. The baffle plate 420 can also include a lip 428 that substantially matches the lip 408 of the cover plate 402. As such, the lip 428 can embody a substantially rectangular protrusion that extends from the lower surface 424d along the vertical direction 6 and along the lower surface 424d in the longitudinal direction 2. Additionally, the baffle plate 420 can define bores 432a, 432b that extend from the front surface 424a to the rear surface 424b along the lateral direction 4. Each of the bores 432a, 432b is configured to receive a respective fastener 64. Though the baffle plate 420 is shown as including two bores 432a, 432b, the baffle plate 420 can include more or less bores as desired. However, like the cover plate 402, the number of bores included in the baffle plate 420 will generally correspond to the number of bores defined by the rear recess surface 60d of the nozzle body 32c.

The baffle plate 420 can also include the features of the slotted nozzle assembly 100d that allow the adhesive to flow through the slotted nozzle assembly 100d. The baffle plate 420 can define an input recess 436 that extends into the body 424 of the baffle plate 420 from the rear surface 424b along the lateral direction 4. The input recess 436 can be substantially rectangular shaped, though other shapes are contemplated. At the top of the input recess 436, the baffle plate 420 can have a slot 440 that extends through the baffle plate 420 from the rear surface 424b to the front surface 424a. The baffle plate 420 can include a plurality of inner surfaces that define the slot 440. Specifically, the baffle plate 420 can have first and second slot surface 444a, 444b that define the lower side of the slot 440, as well as a third slot surface 444c that is spaced from the first and second slot surface 444a, 444b along the vertical direction 6 and defines the upper side of the slot 440. The first and third slot surfaces 444a, 444c can each be substantially planar surfaces, while the second slot surface 444b can be a substantially curved, semicircular surface. Though one specific arrangement and design of slot surfaces 444a-444c are depicted, other embodiments and designs are contemplated. Notably, the slot 440 is depicted as spaced in an entirety from the upper surface 424c and the lower surface 424d. However, it is contemplated that the slot 440 could extend into the body 424 from the upper surface 424c. Opposite the input recess 436, the baffle plate 320 can define a plurality of output recesses 448 that extend into the body 424 of the baffle plate 420 from the front surface 424a along the lateral direction 4. As depicted, the baffle plate 420 includes five output recesses 448a-448e that extend generally parallel to each other and are spaced apart along the longitudinal direction 2. However, the baffle plate 420 can include anywhere from two to ten output recesses 448.

The output recesses 448a-448e can be substantially rectangular shaped, though other shapes are contemplated, and can extend from the slot 440 to the bottom of the lip 428 of the baffle plate 420. Four of the output recesses can define a width W4 measured along the longitudinal direction 2, where the width W₄can be from about 0.5 mm to about 1 mm, while one of the output recesses 448e can define a width W₅measured along the longitudinal direction, where the width W₅can be from about 2 mm to about 6 mm. Though the output recess 448e having the greater width W₅is shown as the rightmost recess, the output recesses 448a-448e can be arranged in any order. Also, as shown in FIG. 12D, the output recesses 448a-448d can define a first depth D₁measured along the lateral direction 4, while the output recess 448e can define a second depth D₂measured along the lateral direction 4 that is greater than the first depth D₁. The purpose of these differing depths will be discussed further below.

With specific reference to FIG. 11F, the slotted nozzle assembly 100d is shown fully assembled and connected to the pump 16. Specifically, the slotted nozzle assembly 100d is shaped and sized to be received in the recess 60 of the pump body assembly 32. To attach the slotted nozzle assembly 100d to the pump 16, the bores 412a, 412b of the cover plate 402 are aligned with the bores 432a, 432b of the baffle plate 420 and the bores 62a, 62b of the nozzle body 32c. Then, a fastener 64 is disposed through bores 412a, 432a, 62a while another fastener 64 is disposed through bores 412b, 432b, 62b, and the fasteners 64 are coupled to the nozzle body 32c to releasably couple the slotted nozzle assembly 100d to the pump 16. When attached to the pump 16, the upper surface 404c of the cover plate 402 and the upper surface 424c of the baffle plate 420 can engage the upper recess surface 60a, while the rear surface 424b of the baffle plate 420 can engage the rear recess surface 60d. Additionally, the first side surface 404e of the cover plate 402 and the first side surface 424e of the baffle plate 420 can engage the first side recess surface 60b, while the second side surface 404f of the cover plate 402 and the second side surface 424f of the baffle plate 420 can engage the second side recess surface 60c. The front surface 404a of the cover plate 402 can be substantially coplanar with the front surface 35a of the nozzle body 32c, while the lower surfaces 404d, 424d of the cover plate 402 and baffle plate 420, respectively, can be positioned below the lower surface 35e of the nozzle body 32c along the vertical 6.

FIG. 11F also shows the flow path of adhesive as it flows through the pump 16 and slotted nozzle assembly 100d, where the direction of fluid flow is indicated by solid arrows. When the cover plate 402 and baffle plate 420 are secured to the nozzle body 32c, an input channel 438 that receives adhesive from the outlet 26b of the fluid channel 26 is defined between the baffle plate 420 and the nozzle body 32c. Specifically, the input channel 438 is defined by the input recess 436 of the baffle plate 420 and the rear recess surface 60d of the nozzle body 32c. The input channel 438 extends from the outlet 26b of the fluid channel 26 to the slot 440, which, as noted above, extends through the entirety of the baffle plate 420. The slotted nozzle assembly 100d also defines a plurality of output channels 450a-450e between the baffle plate 320 and the cover plate 302. Specifically, the output channels 450a-450e are each defined by a respective one of the output recesses 448a-448e of the baffle plate 420 and the rear surface 404b of the cover plate 402. The output channels 450a-450e each extend from the slot 440 and terminate at a respective dispensing outlet 452a-452g, from which adhesive is applied to the substrate 80. Because the baffle plate 420 can have between two and ten output recesses 448, the nozzle assembly 100d can similarly have between two and ten output channels 450 and between two and ten dispensing outlets 452. As shown in FIG. 11E, the dispensing outlets 452a-452e of the slotted nozzle assembly 100d take the form of longitudinally spaced apart slots so as to produce an adhesive pattern 284 that comprises an array of adhesive dots 288 and a continuous adhesive strip 290. Thus, when the valve member 48 of the pump 16 is in a retracted position, adhesive can flow past the valve seat 54, through the outlet 26b of the fluid channel 26, and into the input channel 438. From there, the adhesive flows vertically up through the input channel 438, laterally through the slot 440, downwardly through the output channels 450a-450e, and through the dispensing outlets 452a-452e and onto the substrate 80. However, due to the increased depth D₂of the output recess 448e relative to the depth D₁of the output recesses 448a-448d, when the valve member 48 is in the extended position and adhesive is blocked from flowing past the valve seat 54, no adhesive will flow through output channels 450a-450d, while adhesive will continue to flow through output channel 450e, producing the adhesive pattern shown in FIG. 11G.

FIGS. 13A-13D depict alternative aspects of slotted nozzle assemblies. Referring to FIG. 13A, an aspect of a baffle plate 520 is shown having four output channels 550a-550d. FIG. 13B depicts another aspect of a baffle plate 620 showing five output channels 650a-650e. FIG. 13C depicts another aspect of a baffle plate 720 showing six output channels 750a-750f. FIG. 13C depicts yet another aspect of a baffle plate 820 showing six output channels 850a-850f.

The design of the disclosed adhesive dispenser 10, and particularly the slotted nozzle assemblies 100a-100d, provides for many benefits when performing an adhesive dispensing operation. Conventional adhesive dispensers frequently spill excessive material during a dispensing process due to gravity, which can lead to big ends, silk drawing, and other dispensing defects on the surface of the substrate during a dispensing process, as well as at the end of a dispensing process due to the continued undesired flow of adhesive. In contrast, the slotted nozzle assemblies 100a-100d can prevent such a consequence. The placement of the outlet 26b of the fluid channel 26 of the pump 16 between the slot 140, 240, 340, 440 of the baffle plate 120, 220, 320, 420 and the dispensing outlets 152, 252, 352, 452 of the slotted nozzle assemblies 100a-100d along the vertical direction helps prevent material from continuing to flow to the dispensing outlets 152, 252, 352, 452 when the valve member 48 engages the valve seat 54 and blocks the flow of adhesive through the fluid channel 26. This is because the adhesive must first flow upwards in a first flow direction through the respective input channel 138, 238, 338, 438 of each of the slotted nozzle assemblies 100a-100d before flowing through the slot 140, 240, 340, 440 and then downwards in a second flow direction that is opposite the first flow direction and out of the respective dispensing outlets 152, 252, 352, 452. When the valve member 48 engages the valve seat 54, the upward position of the slot 140, 240, 340, 440 in comparison to the outlet 26b of the fluid channel 26 will prevent overflow of adhesive through the slot 140, 240, 340, 440, and likewise prevent adhesive flow out of the slotted nozzle assemblies 100a-100d. Further, the disclosed adhesive dispenser 10 embodies a low weight, low profile dispenser. The ability to receive a slotted nozzle assembly 100a-100d within the recess 60 of the pump 16 causes the inclusion of the slotted nozzle assembly 100a-100d to not significantly increase the overall profile of the adhesive dispenser 10, while still providing the ability to change between any of the slotted nozzle assemblies 100a-100d.

While various inventive aspects, concepts and features of the inventions may be described and illustrated herein as embodied in combination in the exemplary embodiments, these various aspects, concepts and features may be used in many alternative embodiments, either individually or in various combinations and sub-combinations thereof. Unless expressly excluded herein all such combinations and sub-combinations are intended to be within the scope of the present inventions. Still further, while various alternative embodiments as to the various aspects, concepts, and features of the inventions—such as alternative materials, structures, configurations, methods, circuits, devices and components, software, hardware, control logic, alternatives as to form, fit and function, and so on—may be described herein, such descriptions are not intended to be a complete or exhaustive list of available alternative embodiments, whether presently known or later developed. Those skilled in the art may readily adopt one or more of the inventive aspects, concepts or features into additional embodiments and uses within the scope of the present inventions even if such embodiments are not expressly disclosed herein. Additionally, even though some features, concepts or aspects of the inventions may be described herein as being a preferred arrangement or method, such description is not intended to suggest that such feature is required or necessary unless expressly so stated. Still further, exemplary or representative values and ranges may be included to assist in understanding the present disclosure; however, such values and ranges are not to be construed in a limiting sense and are intended to be critical values or ranges only if so expressly stated. Moreover, while various aspects, features, and concepts may be expressly identified herein as being inventive or forming part of an invention, such identification is not intended to be exclusive, but rather there may be inventive aspects, concepts, and features that are fully described herein without being expressly identified as such or as part of a specific invention, the scope of the inventions instead being set forth in the appended claims or the claims of related or continuing applications. Descriptions of exemplary methods or processes are not limited to inclusion of all steps as being required in all cases, nor is the order that the steps are presented to be construed as required or necessary unless expressly so stated.

While the invention is described herein using a limited number of embodiments, these specific embodiments are not intended to limit the scope of the invention as otherwise described and claimed herein. The precise arrangement of various elements and order of the steps of articles and methods described herein are not to be considered limiting. For instance, although the steps of the methods are described with reference to sequential series of reference signs and progression of the blocks in the figures, the method can be implemented in a particular order as desired.

ADHESIVE DISPENSER WITH SLOTTED NOZZLE ASSEMBLY

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CPC

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