Patent Description:
Various techniques for spraying an adhesive on a moving web are well known to those skilled in the art. Many conventional techniques have relied upon pressure to deliver the adhesive to a plurality of nozzles and spray the adhesive from the nozzles onto a moving web. In such conventional techniques, the amount and pattern of the spray of adhesive is directly dependent upon the pressure at each nozzle.

For example, one conventional technique which relies upon pressure for spraying the adhesive involves an apparatus having a plurality of nozzles which are connected to a manifold. Adhesive is supplied to the manifold and nozzles by a single large, central tank of molten adhesive. The tank of adhesive is pressurized to deliver the adhesive from the tank to the manifold and to the individual nozzles. The individual nozzles are then independently turned on and off to spray the adhesive. The amount of adhesive which is dispensed from the nozzles is dependent upon the pressure at the tank of adhesive, the length of the supply lines, the number of nozzles which are being operated at a given point in time and whether the nozzles are operating efficiently.

Various problems, however, exist is spraying an adhesive on a moving web. For instance, it is very difficult to control the placement of the adhesive on the web and to control the amount of adhesive applied to the web. Collateral spray of adhesive, for instance, can land on portions of the moving web where adhesive is not desired and/or on the processing equipment. In addition, some spray adhesives lack adhesive strength, especially when applying elastic components to a web that are later to be stretched.

In addition to spraying adhesives onto a moving web, hot melt adhesives are also applied by being extruded onto a web using a slot coater or similar device. In these processes, the moving web contacts the adhesive head and the adhesive is periodically applied to the web. At faster web speeds, however, the application of a hot melt adhesive through extrusion can be the rate limiting step in the process. For instance, due to the speed of the web, even short pulses of adhesive form relatively long lengths of adhesive streaks. For instance, during conventional processes, the moving web is in constant contact with the adhesive head. A single bead of adhesive extruded from the adhesive head contacts the moving web and is smeared over the web as the web is moving past the adhesive head. These adhesive streaks typically must be covered by a material joined to the web. Thus, long adhesive streaks require longer pieces of material, which may represent excess material and waste in the final product. In order to create shorter streaks of adhesive, the process speeds, i.e. the speed of the moving web, must be decreased. Consequently, the adhesive application step of the process can be a rate limiting step and can adversely affect the overall throughput of the process.

In addition to problems experienced in applying adhesives at fast speeds, adhesive applicators as described above also have experienced problems with maintaining uniform flow through the adhesive head due to clogging and other issues. For instance, over time, adhesive heads can generate significant amounts of dust and lint. In addition, adhesive build up on the head can occur over time. Thus, adhesive applicators are typically periodically cleaned which can require downtime of the process.

In view of the above, a need exists for an improved method and system for applying an adhesive, such as a hot melt adhesive, to a moving web. More particularly, a need exists for an adhesive applicator system and method capable of controlling the amount of adhesive being applied to a web while the web is moving at very fast speeds. <CIT> discloses fluid adhesive and similar applicator systems and methods. <CIT> discloses an adhesive agent applying apparatus. <CIT> discloses an apparatus and method for uniting layers of material. <CIT> discloses a process for applying glue, in particular glue of the hot-melt type. <CIT> discloses a method of applying a liquid to a flexible substrate.

In general, the present disclosure is directed to a system and process for applying an adhesive to a moving web of material. The system and process of the present disclosure are capable of dramatically reducing the adhesive application length when the web of material is running at high speeds in comparison to conventional systems. In addition, the system and process of the present disclosure is also capable of providing better control of application of the adhesive. In addition, the system and process of the present disclosure can apply adhesives to moving webs in unique patterns that can result in improved bonding between two materials during the process.

The present disclosure is directed to a system for applying an adhesive to a moving web of material in accordance with claim <NUM>. For instance, the adhesive control device can be configured to enable and disable flow of adhesive through the nozzle prior to the nozzle contacting a moving web of material. Alternatively, the adhesive control device can be configured to enable flow of adhesive through the nozzle prior to contact with the moving web and then to disable flow of an adhesive through the nozzle while the nozzle is in contact with the moving web of material. In this manner, lesser of amounts of adhesive can be applied to the web even at extremely fast speeds. In addition, the length of adhesive applied to the moving web can be minimized in relation to the amount of time the moving web is in contact with the nozzle.

In one embodiment, the nozzle can include a plurality of spaced apart exit ports for depositing a plurality of parallel and vertical adhesive streaks onto the moving web of material. For instance, the nozzle can include from about <NUM> to about <NUM> exit ports.

The web deflecting device can cause the moving web of material to contact the nozzle by moving the web and/or by moving the nozzle. In one embodiment, for instance, the web deflecting device comprises a deflecting cam that moves the moving web of material periodically into contact with the nozzle. For instance, the deflecting cam can be attached to a rotating roll positioned adjacent to the moving web of material. The deflecting cam can project from the surface of the rotating roll. As the roll rotates, the deflecting cam contacts the web and pushes the web into contact with the nozzle. In one embodiment, the rotating roll can be configured to rotate at a speed such that a web contacting surface on the deflecting cam moves at a speed that is faster than the speed at which the web of material is moving.

In one embodiment, the action of the web contacting the nozzle not only removes adhesive from the nozzle but also wipes the nozzle head in a manner that prevents the buildup of adhesive and prevents the buildup of lint and dust.

The deflecting device causes the moving web of material to contact the nozzle in a manner such that the web forms a maximum exit angle with the nozzle. The maximum exit angle is from about <NUM>° to about <NUM>° in relation to a horizontal plane that is perpendicular to an exit port on the nozzle. During the process, the exit angle can constantly change from a minimum exit angle to a maximum exit angle as the deflecting device deflects the web.

The deflecting device can be positioned downstream from the nozzle or can be positioned upstream from the nozzle. In one embodiment, the deflecting device contacts the moving web of material in a manner that causes the web of material to increase in tension during contact with the nozzle. Increasing the tension of the web can further improve application of the adhesive to the web. In one embodiment, the web conveying device moves the web of material at a speed of at least <NUM>/min, such as at least about <NUM>/min, such as at least about <NUM>/min, such as at least about <NUM>/min, such as even greater than about <NUM>/min.

The present disclosure is also directed to a process for applying an adhesive to a moving web of material in accordance with claim <NUM>. In this manner, the nozzle applies at least one vertical streak of an adhesive to the web. The flow of adhesive through the nozzle, for instance, can be intermittent. For example, in one embodiment, the process includes the step of starting and stopping the flow of adhesive through the nozzle prior to contacting the nozzle with the moving web. In an alternative process, flow of adhesive through the nozzle is started prior to contact with the moving web of material and is stopped during contact with the moving web.

The adhesive can comprise a pressure sensitive hot melt adhesive. In one embodiment, the nozzle can include a plurality of exit ports for forming a plurality of parallel and vertical adhesive streaks on the moving web of material. In one embodiment, the web of material is moving at a speed of at least <NUM>/min and each vertical streak of adhesive has a length of less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>. In one embodiment, the process includes the steps of incorporating the moving web of material into a product, such as an absorbent article or into a packaging product.

A full and enabling disclosure of the present disclosure is set forth more particularly in the remainder of the specification, including reference to the accompanying figures, in which:.

Repeat use of reference characters in the present specification and drawings is intended to represent the same or analogous features or elements of the disclosure.

It is to be understood by one of ordinary skill in the art that the present discussion is a description of exemplary embodiments only, and is not intended as limiting the broader aspects of the present disclosure.

In general, the present disclosure is directed to a system and method for accurately applying an adhesive onto a continuously moving web in a desired pattern. The apparatus and method are particularly useful for applying viscous adhesives, such as hot melt adhesives, to bond together different components of various different products, such as a disposable absorbent article. The system and method of the present disclosure, for instance, can be used to bond elastic panels, side panels, fastener panels, leg elastics, and the like to other materials during the production of an absorbent article, such as a diaper, an adult incontinence product, a training pant, a swim pant, a feminine hygiene product, or the like. It should be understood, however, that the system and process can also be used in numerous and various other applications and is not in any way limited to the production of absorbent articles.

The system of the present disclosure generally includes a web conveying device that conveys the web adjacent to an adhesive applicator. The system further includes a web deflecting device that periodically causes the moving web to contact a nozzle of the adhesive applicator. Adhesive, in one embodiment, intermittently exits the nozzle of the adhesive applicator for application to the web. The adhesive flows from the nozzle prior to contact with the web. In this manner, during contact with the web, the adhesive is smeared onto the web in a controlled manner. The system and process of the present disclosure provide numerous benefits and advantages in processing webs of material. For instance, the amount of adhesive and the length of adhesive that extends in the machine direction (i.e. moving direction or longitudinal direction) can be minimized at extremely fast web speeds. In addition, controlling the timing of supply of adhesive to the nozzle allows for extremely accurate control over the desired amount of adhesive to be applied to the web. In this manner, less materials are needed in constructing the product, such as the absorbent article. In addition, line speeds can be increased in comparison to the use of conventional adhesive applicators.

Referring to <FIG>, one embodiment of an adhesive applicator system made in accordance with the present disclosure is illustrated. As shown, the system includes an adhesive applicator <NUM> that includes a nozzle <NUM>. The nozzle <NUM>, for instance, may comprise a slot coating device. In one embodiment, the nozzle <NUM> can include a single adhesive orifice or slot. The orifice may be designed to apply adhesive to a particular location on a web of material or can be designed to apply adhesive over the entire width of the material.

Alternatively, the nozzle <NUM> may include a plurality of spaced apart exit ports or slots for depositing a plurality of parallel treated discrete areas of adhesive onto a moving web. The nozzle <NUM> can receive adhesive from an adhesive supply. For instance, as shown in the figures, the adhesive applicator <NUM> can include an adhesive supply line <NUM> in fluid communication with the nozzle <NUM>.

The adhesive applicator <NUM> further includes an adhesive flow control device <NUM>. The adhesive flow control device <NUM> controls the flow of adhesive from the supply line <NUM> to the one or more exit ports on the nozzle <NUM>. The flow control device <NUM> can comprise, for instance, any suitable valve or similar device. In one embodiment, for instance, the adhesive flow control device <NUM> may comprise a solenoid valve. In one embodiment, the adhesive flow control device <NUM> can be in communication with a controller, such as one or more microprocessors. The controller can be configured to control the adhesive flow control device <NUM> for enabling and disabling flow of an adhesive through the nozzle <NUM> at desired times, such as during periodic intervals. For example, the adhesive flow control device <NUM> may open the valve to allow the adhesive to flow through the nozzle <NUM> and may close the valve to cease the flow of adhesive through the nozzle <NUM>.

The adhesive applicator <NUM> can include a single adhesive control device <NUM> or can include multiple devices. Additionally, the adhesive applicator <NUM> can include a single valve or multiple valves. For instance, if the nozzle <NUM> includes a plurality of exit ports, the adhesive applicator <NUM> can include a corresponding plurality of control devices <NUM> and/or valves for controlling each of the individual exit ports. Alternatively, a single control device <NUM>, along with either a single valve or multiple valves, can control flow through all of the exit ports simultaneously.

The system of the present disclosure further includes a web conveying device for conveying a web of material. As shown in <FIG>, the web conveying device can include guide rolls <NUM> and <NUM> for supporting a web of material <NUM>. As shown in <FIG>, the guide rolls <NUM> and <NUM> are positioned to convey the web of material <NUM> in close proximity to the nozzle <NUM> without contacting the nozzle. The web conveying device can be designed to convey the web <NUM> at very fast speeds. For instance, the web <NUM> during processing can be moving at a speed of at least about <NUM>/min, such as at least about <NUM>/min, such as at least about <NUM>/min, such as at least about <NUM>/min, such as at least about <NUM>/min, such as at least about <NUM>/min, such as at least about <NUM>/min, such as at least about <NUM>/min. The speed of the web of material <NUM> is generally less than about <NUM>,<NUM>/min, such as less than about <NUM>/min.

In accordance with the present disclosure, the system further includes a web deflecting device <NUM> that is designed to periodically cause contact between the nozzle <NUM> and the web of material <NUM>. In the embodiment illustrated in <FIG>, the web deflecting device contacts the web <NUM> moving the web into contact with the nozzle <NUM>. In other embodiments, however, the web deflecting device may move the nozzle into contact with the web. In general, the web deflecting device can be any suitable device or apparatus capable of causing contact between the nozzle <NUM> and the moving web of material <NUM>.

In the embodiment illustrated in <FIG>, the web deflecting device includes a rotating roll <NUM> attached to a deflecting cam <NUM>. The deflecting cam <NUM> extends radially outward from the roll <NUM> and includes a web contacting surface <NUM>. The web contacting surface <NUM> can have a width that can correspond with the width of the moving web <NUM>. In general, the width of the web contacting surface <NUM> is at least as wide as the one or more exit ports located on the nozzle <NUM>.

In order to apply adhesive from the nozzle <NUM> of the adhesive applicator <NUM> to the moving web <NUM>, the web deflecting device <NUM> is rotated, which causes the web contacting surface <NUM> of the deflecting cam <NUM> to contact the web <NUM> as shown in <FIG> and <FIG>. For at least a portion of the rotation of the web deflecting device <NUM> where the deflecting cam <NUM> is in contact with the web <NUM>, the web <NUM> comes into contact with the nozzle <NUM>. During contact between the web of material <NUM> and the nozzle <NUM>, adhesive is transferred to the web. The web deflecting device <NUM> continues to rotate causing the deflecting cam <NUM> to rotate out of the path of travel of the web of material <NUM> causing the web to once again move away from the nozzle <NUM> and to continue to move downstream in a noncontacting relationship with the adhesive applicator <NUM>.

In order to apply adhesive to the web of material <NUM>, the adhesive control device <NUM> can be used to control the flow of adhesive from the nozzle <NUM> in a manner that forms the desired pattern of adhesive onto the web. For example, enabling flow of adhesive and disabling flow of adhesive from the nozzle in conjunction with the timing of contact between the nozzle and the moving web can be varied and adjusted in order to obtain an optimum result for the particular application.

In one embodiment, for instance, flow of adhesive through the nozzle <NUM> is started and stopped prior to any contact of the nozzle <NUM> with the web <NUM>. For example, the flow control device <NUM> may cause the one or more valves to open for a period of time, allowing adhesive to flow to the nozzle <NUM>, and then close the one or more valves, causing the adhesive to cease flowing to the nozzle <NUM>, all during a time period where the web <NUM> is not in contact with the nozzle <NUM>. In this embodiment, for instance, a bead of adhesive is discharged from the exit port of the nozzle <NUM>. Due to the fluid properties of the adhesive, the adhesive remains adhered to the nozzle head. The web of material <NUM> is then brought into contact with the bottom surface of the nozzle <NUM> by the web deflecting device <NUM>. The bead of adhesive is then removed from the surface of the nozzle <NUM> due to contact with the moving web. Due to the manner in which the adhesive is wiped off the nozzle <NUM>, a streak of adhesive is then deposited onto the web <NUM> in the longitudinal direction or the machine direction of the moving web.

In an alternative embodiment, flow of adhesive through the nozzle <NUM> is enabled by the adhesive control device <NUM> prior to contact with the moving web. For example, the flow control device <NUM> may cause the one or more valves to open allowing adhesive to flow to the nozzle <NUM>. In this embodiment, however, the one or more valves remain open as the web <NUM> contacts the nozzle <NUM>. Accordingly, flow of adhesive through the nozzle <NUM> continues for at least a portion of the time period during which the nozzle <NUM> is in contact with the web <NUM>. The adhesive control device <NUM> can disable flow of adhesive at any point during contact with the web <NUM>, for instance by closing the one or more valves. For example, flow of adhesive can be discontinued just as the web <NUM> contacts the nozzle <NUM> for applying lesser amounts of adhesive or can discontinue the flow of adhesive generally at the same time the web <NUM> separates from the nozzle <NUM> for applying greater amounts of adhesive. In still further embodiments, the flow of adhesive may be stopped after contact between the web <NUM> and the nozzle <NUM> has ceased.

Thus, the system and process of the present disclosure provides a significant amount of variability in the amount of adhesive that is applied to the web depending upon the application. The length of adhesive in the longitudinal direction can be controlled by controlling the amount of adhesive that flows through the nozzle <NUM>, the duration of flow of adhesive, and/or the timing of the flow of adhesive in relation to contact with the moving web.

In accordance with the present disclosure, the amount of time that the web <NUM> contacts the surface of the nozzle <NUM> can also be controlled depending upon various factors. The amount of time the web <NUM> remains in contact with the nozzle <NUM>, for instance, depends upon the speed of the web and the construction of the web deflecting device <NUM>, including the shape of the deflecting cam <NUM>. The contact time, for instance, can depend upon the amount the web <NUM> is deflected towards the adhesive applicator <NUM> and can also depend upon the length of the web contacting surface <NUM> in the longitudinal direction. In one embodiment, for instance, the system of the present disclosure can be configured such that the web of material <NUM> contacts the nozzle <NUM> for at least about <NUM> milliseconds, such as at least about <NUM> milliseconds, such as at least about <NUM> milliseconds, such as at least about <NUM> milliseconds, such as at least about <NUM> milliseconds. The contact time is generally less than about <NUM> second, such as less than about <NUM> milliseconds, such as less than about <NUM> milliseconds, such as less than about <NUM> milliseconds, such as less than about <NUM> milliseconds, such as less than about <NUM> milliseconds, such as less than about <NUM> milliseconds, such as less than about <NUM> milliseconds, such as less than about <NUM> milliseconds.

During the process, the adhesive is deposited onto the moving web of material <NUM> so as to form treated discrete areas on the web. For instance, when the nozzle <NUM> includes a plurality of spaced apart exit ports, a pattern of treated discrete areas can be formed on one surface of the moving web <NUM>. The treated discrete areas are generally parallel to each other and extend in a longitudinal direction or the machine direction of the web <NUM>. Due to the speed of the moving web and continuous contact between the web and the adhesive nozzle, conventional adhesive applicators tended to apply relatively long streaks of adhesive to the web and provided little to no control over the adhesive pattern. The system of the present disclosure, however can apply relatively short streaks of adhesive to a web of material <NUM> moving at very rapid speeds. For example, for a web of material <NUM> moving at a speed of greater than about <NUM>/min, such as greater than about <NUM>/min, such as even greater than about <NUM>/min, the streaks of adhesive can have a length in the longitudinal direction of generally less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as even less than about <NUM>. The adhesive lengths are generally greater than about <NUM>, such as greater than about <NUM>, such as greater than about <NUM>.

In addition to being capable of controlling the amount of adhesive applied to the moving web <NUM> and being able to reduce the adhesive application length when running at high speeds, the process and system of the present disclosure also provides for a self-cleaning mechanism of the nozzle. For example, by periodically contacting the nozzle <NUM> as shown is <FIG>, the web of material <NUM> wipes the surface of the nozzle <NUM> clean during application of the adhesive to the web <NUM>. Thus, during application of the adhesive to the moving web <NUM>, the web <NUM> wipes away the adhesive residing on the nozzle <NUM> and simultaneously wipes away any lint on the nozzle head.

In one embodiment the deflecting cam <NUM> of the web deflecting device <NUM> contacts the moving web <NUM> and pushes the web above the exit ports on the nozzle <NUM>. In this manner, the web <NUM> forms an exit angle with the nozzle <NUM>.

Referring to <FIG>, for instance, the exit ports on the nozzle <NUM> are perpendicular to a horizontal plane <NUM>. When the web of material <NUM> is deflected, the web of material <NUM> forms an exit angle <NUM> in relation to the horizontal plane <NUM>. During contact with the nozzle <NUM>, the exit angle <NUM> of the web of material <NUM> with the exit ports on the nozzle changes from a minimum exit angle to a maximum exit angle. The maximum exit angle during the process is greater than about <NUM>°, such as greater than about <NUM>°, such as greater than about <NUM>°, such as greater than about <NUM>°, such as greater than about <NUM>°, such as greater than about <NUM>°, such as greater than
about <NUM>°, such as greater than about <NUM>°, such as greater than about <NUM>°. The maximum exit angle is less than <NUM>°, such as less than about <NUM>°, such as less than about <NUM>°. As the exit angle <NUM> of the web of material <NUM> changes with respect to the nozzle <NUM>, the wiping motion of the web <NUM> against the nozzle <NUM> changes further facilitating cleaning of the nozzle <NUM> during the process. Changing the exit angle <NUM> during the process also facilitates application of adhesive to the web <NUM> and provides greater uniformity and control.

In addition to forming and changing the exit angle of the web <NUM> with the nozzle <NUM>, the tension of the web <NUM> as it contacts the nozzle <NUM> can also be varied in order to facilitate application of the adhesive to the web <NUM> and/or further clean the surface of the nozzle <NUM> during contact. For example, in one embodiment, the rotating roll <NUM> of the web deflecting device <NUM> can be rotated so that the web contacting surface <NUM> of the deflecting cam <NUM> contacts the web <NUM> at a speed that is faster than the speed the web <NUM> is moving. In this manner, tension in the web <NUM> can be increased during contact with the nozzle <NUM>. For example, the web contacting surface <NUM> can be moving at a speed that is at least about <NUM>% greater, such as at least about <NUM>% greater, such as at least about <NUM>% greater, such as at least about <NUM>% greater, such as at least about <NUM>% greater than the speed at which the web <NUM> is moving during contact with the web <NUM>. The speed of the web contacting surface <NUM> is generally moving at a speed that is no more than about <NUM>% greater than the speed of the web <NUM>, such as no more than about <NUM>% greater than the speed of the web <NUM>, such as no more than about <NUM>% greater than the speed of the web <NUM>.

In the embodiment illustrated in <FIG>, the web deflecting device <NUM> is positioned in the system such that the web contacting surface <NUM> contacts the web <NUM> downstream from the nozzle <NUM>. For instance, the web contacting surface <NUM> can contact the web of material <NUM> a distance downstream from the one or more exit ports from the nozzle <NUM> a distance of greater than about <NUM>, such as greater than about <NUM>, such as greater than about <NUM>, such as greater than about <NUM>, such as greater than about <NUM>. The distance downstream can generally be less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>.

In an alternative embodiment, instead of contacting the web <NUM> downstream from the nozzle12, the web deflecting device <NUM> can also be positioned to contact the web <NUM> upstream from the nozzle <NUM>. When contacting the web <NUM> upstream from the nozzle <NUM>, an entrance angle will be formed between the web <NUM> and a horizontal plane that is perpendicular to the exit port on the nozzle <NUM>. The entrance angle can have the same dimensions as the exit angle <NUM> described above.

It should also be understood that the web deflecting device <NUM> as shown in <FIG> represents one embodiment of the web deflecting device <NUM> and that various other web deflecting devices may be utilized. For instance, in an alternative embodiment, the web deflecting device <NUM> may be configured to move the deflecting cam <NUM> up and down instead of in a rotating motion.

The adhesive that is emitted or extruded from the nozzle <NUM> in accordance with the present disclosure can vary depending upon various factors including the type of material <NUM> being processed, the type of product being formed, and the type of opposing material that is later attached to the web of material <NUM>. In one embodiment, for instance, the adhesive applied to the web <NUM> may comprise a hot melt adhesive, such as a hot melt, pressure-sensitive adhesive. For example, in one embodiment, an adhesive composition is applied to the web of material <NUM> containing a thermoplastic polymer which may comprise an elastomeric polymer. The polymer may be combined with one or more tackifying resins and/or one or more plasticizers. Optionally, the adhesive composition may also contain an oil, a wax, and/or a stabilizer.

In one embodiment, the polymer contained in the adhesive composition is a polyolefin polymer. The polyolefin polymer may comprise a polypropylene, a polyethylene, copolymers thereof, homopolymers thereof, and the like. In an alternative embodiment, the polymer contained in the polymer composition contains a block copolymer, such as a styrene block copolymer. The block copolymer, for instance, may comprise, a polystyrene-polybutadiene-polystyrene polymer, a polystyrene-polyisoprene-polystyrene polymer, a polystyrene-polyisoprene-polybutadiene-polystyrene polymer, a polystyrene-poly(ethylenebutylene)-polystyrene polymer, a polystyrene-poly(ethylenepropylene)-polystyrene polymer, or mixtures thereof. One or more of the block copolymers can also be combined with a polyolefin as described above.

In general, the adhesive composition can contain one or more polymers in an amount greater than about <NUM>% by weight, such as in an amount greater than about <NUM>% by weight, such as in an amount greater than about <NUM>% by weight, such as in an amount greater than about <NUM>% by weight, such as in an amount greater than about <NUM>% by weight, such as in an amount greater than about <NUM>% by weight, such as in an amount greater than about <NUM>% by weight. One or more polymers may be contained in the adhesive composition in an amount less than about <NUM>% by weight, such as in an amount less than about <NUM>% by weight, such as in an amount less than about <NUM>% by weight, such as in an amount less than about <NUM>% by weight, such as in an amount less than about <NUM>% by weight.

Tackifying resins that may be combined with the polymer include, for instance, colophony rosins, terpene resins, copolymers based on natural terpenes, or resins that have been hydrogenated, polymerized or copolymerized with an aromatic hydrocarbon.

The use of a tackifying resin in an adhesive composition is optional. When present the tackifying resin can be included in the composition generally in an amount greater than about <NUM>% by weight, such as in an amount greater than about <NUM>% by weight, such as in an amount greater than about <NUM>% by weight. Tackifying resins are generally present in an amount less than about <NUM>% by weight, such as in an amount less than about <NUM>% by weight, such as in an amount less than about <NUM>% by weight.

Use of plasticizers in the adhesive composition is also optional. When present, a plasticizer can be included in the composition in an amount greater than about <NUM>% by weight, such as in an amount greater than about <NUM>% by weight, such as in an amount greater than about <NUM>% by weight, and generally less than about <NUM>% by weight, such as in an amount less than about <NUM>% by weight, such as in an amount less than about <NUM>% by weight. Suitable plasticizers that may be included in the adhesive composition include mineral oil, vegetable oils, animal oils, and derivatives thereof. Petroleum derived oils may also be used as plasticizers.

As described above, beginning a flow of the adhesive composition through the nozzle <NUM> can occur prior to contact of the nozzle <NUM> with the moving web <NUM>. Thus, the adhesive composition used in the present disclosure, in one embodiment, has sufficient cohesive properties such that the adhesive will not drip from the surface of the novel during flow. For example, in one embodiment, the adhesive composition has sufficient viscosity and cohesiveness to remain adhered to the surface of the nozzle <NUM> until contact with the moving web <NUM>.

For instance, the adhesive composition can have a viscosity at <NUM>°F (<NUM>) of generally greater than about 500cps (<NUM> Pa-s) such as greater than about <NUM> cps (<NUM>,<NUM> Pa-s) such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps, such as greater than about <NUM> cps (<NUM> Pa-s) ( <NUM> cps = <NUM>,<NUM> Pa-s) The viscosity of the adhesive composition is generally less than about <NUM>,<NUM> cps at <NUM>°F (<NUM>), such as less than about <NUM>,<NUM> cps, such as less than about <NUM>,<NUM> cps, such as less than about <NUM>,<NUM> cps, such as less than about <NUM>,<NUM> cps, such as less than about <NUM>,<NUM> cps, such as less than about <NUM>,<NUM> cps, such as less than about <NUM>,<NUM> cps, such as less than about <NUM>,<NUM> cps, such as less than about <NUM> cps, such as less than about <NUM> cps, such as less than about <NUM> cps (3Pa-s; <NUM> cps = <NUM>,<NUM> Pa-s).

The Viscosity Test is conducted in accordance with ASTM Test Method D3236-<NUM>, entitled "Standard Test Method for Apparent Viscosity of Hot Melt Adhesives and Coating Materials," The viscometer used is that made by Brookfield Engineering Laboratories of Middleboro, Mass. , as model RVDV III. The spindle number to use in conducting the ASTM Test Method is SC4-<NUM>. The sample size should be about <NUM> grams of adhesive. The spindle speed (rpm) is set to a value that results in a torque reading in the range of <NUM> percent to <NUM> percent. A reading should be taken every few minutes for about <NUM> minutes, or until the viscosity values stabilize, after which the final viscosity reading (in centipoises) is recorded.

The system and process of the present disclosure is capable of producing a unique adhesive pattern applied to the moving web <NUM>. For instance, through the process of the present disclosure, an adhesive pattern of treated discrete areas can be formed onto the moving web <NUM>. These treated discrete areas can have many beneficial properties for attaching the moving web <NUM> to an adjoining surface, such as to another piece of material. For example, in one embodiment, the adhesive pattern made according to the present disclosure can be applied to the web <NUM> at high speeds while minimizing the amount of materials needed to construct a product. In addition, the adhesive pattern may include treated discrete areas having a unique adhesive profile that facilitates attachment to another material and provides for a strong bond.

For example, in one embodiment, the nozzle <NUM> of the adhesive applicator <NUM> includes a plurality of exit ports. For instance, the nozzle <NUM> can include greater than about <NUM> exit ports, such as greater than about <NUM> exit ports, such as greater than about <NUM> exit ports, such as greater than about <NUM> exit ports, such as greater than about <NUM> exit ports and generally less than about <NUM> exit ports, such as less than about <NUM> exit ports, such as less than about <NUM> exit ports that extend along the width of the web of material <NUM>. The plurality of exit ports can be used to form a pattern of treated discrete areas on the top surface of the moving web <NUM>. The treated discrete areas form streaks on the surface of the web <NUM> and generally extend in the longitudinal direction of the web <NUM> or the machine direction.

For instance, one example of a pattern of treated discrete areas of an adhesive composition is shown in <FIG>. Referring to <FIG>, for example, a plurality of vertically extending treated discrete areas <NUM> are shown applied to the web <NUM>. The treated discrete areas <NUM> are generally parallel to each other in the length direction of the web <NUM>. In <FIG>, six parallel discrete areas are shown. It should be understood, however, that a greater number or lesser number of treated discrete areas may be formed on the web <NUM>. For example, in one embodiment, from about <NUM> to about <NUM> treated discrete areas, such as from about <NUM> to about <NUM> treated discrete areas can be formed on the web of material <NUM>.

As shown in <FIG>, in one embodiment, each treated discrete area can include a head portion <NUM> integral with a tail portion <NUM>. The head portion <NUM> is formed when the web of material <NUM> first contacts the nozzle <NUM> during the process. The tail <NUM>, on the other hand, is formed as the web of material <NUM> moves across the head of the nozzle <NUM>. A cross section of one of the treated discrete areas <NUM> showing the head portion <NUM> and the tail portion <NUM> is illustrated in <FIG>.

Referring to <FIG>, one of the treated discrete areas <NUM> is shown in greater detail. The treated discrete area <NUM> includes a head portion <NUM> and a tail portion <NUM>. In <FIG>, a broken line <NUM> is used to illustrate where the head portion <NUM> ends and the tail portion <NUM> begins. For most applications, the head portion <NUM> is visually distinct from the tail portion <NUM>. For example, in one embodiment, the head portion <NUM> will appear more as a bead or glob of adhesive composition, while the tail portion <NUM> appears more like a smear or streak of the adhesive composition. As shown in <FIG>, the tail portion <NUM> typically has a more uniform width than the head portion <NUM>. The width of the tail portion <NUM> generally corresponds to the width of the exit orifice on the nozzle <NUM>. As used herein, the head portion is defined as the area above the tail portion wherein the tail portion is the part of the treated discrete area <NUM> where a relatively uniform width is achieved as shown in <FIG>. The head portion, on the other hand, can have various irregular shapes and can generally have a width that is wider than the width of the tail portion <NUM>. As shown in <FIG>, the position of the line of demarcation <NUM> is where the head portion <NUM> tapers inward and joins the tail portion <NUM>.

As shown in <FIG>, in one embodiment, the head portion <NUM> can have a maximum width that is wider than the maximum width of the corresponding tail portion <NUM>. The tail portion <NUM>, on the other hand, can be substantially longer than a corresponding head portion <NUM>. For example, the ratio of the length of the head portion <NUM> to the length of the tail portion <NUM> is generally greater than about <NUM>:<NUM>, such as greater than about <NUM>:<NUM>, such as greater than about <NUM>:<NUM>, such as greater than about <NUM>:<NUM>. The ratio of the length of the head portion <NUM> to the length of the tail portion <NUM> is generally less than about <NUM>:<NUM>, such as less than about <NUM>:<NUM>, such as less than about <NUM>:<NUM>, such as less than about <NUM>:<NUM>. As described above, the length of the treated discrete area <NUM> can vary depending upon the particular application but can be less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as less than about <NUM>, such as even less than about <NUM>. These short lengths can be achieved even when the web of material <NUM> is being conveyed at extremely fast speeds, such as greater than about <NUM>/min.

The amount of adhesive composition contained in each head portion <NUM> in relation to the amount of adhesive composition contained in a corresponding tail portion <NUM> can vary by controlling the web speed, the web deflecting device <NUM> and the adhesive flow rates. For instance, in general, the amount of adhesive composition contained in each head portion <NUM> in comparison to the amount of adhesive composition contained in each tail portion <NUM> can be from about <NUM>:<NUM> to about <NUM>:<NUM>. In one embodiment, however, a greater amount of adhesive composition may be contained in head portion <NUM> in relation to the amount of adhesive composition as contained in the tail portion <NUM>. For example, a bead of the adhesive composition first contacts the web of material <NUM> during the process forming the head portion <NUM> followed by formation of the tail portion <NUM> through a smearing process. In these embodiments, for instance, the amount of adhesive composition contained in each head portion <NUM> in comparison to the amount of adhesive composition contained in each tail portion <NUM> can be from about <NUM>:<NUM> to about <NUM>:<NUM>.

As shown in <FIG>, for instance, the adhesive composition can have a basis weight (i.e. amount of adhesive composition per area on the web) in the head portion <NUM> that is greater than the basis weight of the adhesive composition in the tail portion <NUM>. For example, the basis weight of the adhesive composition in the head portion <NUM> can be at least about <NUM>%, such as at least about <NUM>%, such as at least about <NUM>%, such as least about <NUM>%, such as least about <NUM>%, such as least about <NUM>%, such as least about <NUM>%, such as least about <NUM>%, such as even at least about <NUM>% greater than the basis weight of the adhesive composition in the tail portion <NUM>.

As used herein, the basis weight of the adhesive composition refers to an average basis weight over the particular area taken up by the adhesive composition on the web <NUM>. For instance, the basis weight of the adhesive composition in the head portion <NUM> would be the average basis weight of the adhesive composition over the area occupied by the head portion <NUM>. Similarly, the basis weight of the adhesive composition in the tail portion <NUM> would be the average basis weight of the adhesive composition over the area occupied by the tail portion <NUM>.

In one embodiment, the amount of adhesive in the head portion <NUM> and the amount of adhesive in the tail portion <NUM> can be measured on a grams per linear meter basis. When measuring the amount of adhesive composition in the different portions based on a grams per linear meter basis, the total weight of the adhesive composition in grams in a particular portion can be divided by the length of the particular portion in the machine direction or in the length direction. For instance, as shown in <FIG>, the amount of adhesive composition in the head portion <NUM> can first be measured. In one embodiment, for instance, the head portion <NUM> can be removed from the web of material <NUM> and weighed in grams. An untreated portion of the web material can also be weighed having the exact same dimensions. The mass of the untreated material can then be subtracted from the mass of the head portion <NUM> in order to arrive at the mass of the adhesive composition itself. The mass of the adhesive composition can then be divided by the length L as shown in <FIG> in order to calculate the amount of adhesive composition in grams per linear meter. A similar analysis can be conducted in order to determine the amount of adhesive composition present in the tail portion <NUM> in grams per linear meter.

In general, the adhesive composition in the head portion <NUM> in grams per linear meter can be at least about <NUM>%, such as at least about <NUM>%, such as at least about <NUM>%, such as at least about <NUM>%, such as at least about <NUM>%, such as at least about <NUM>%, such as at least about <NUM>%, such as at least about <NUM>%, such as even at least about <NUM>% greater than the amount of adhesive composition in grams per linear meter contained within the tail portion <NUM>. For example, the adhesive composition in grams per linear meter in the head portion <NUM> can be greater than about <NUM>%, such as greater than about <NUM>% than the amount of adhesive composition in grams per linear meter contained in the tail portion <NUM>. In general, the ratio of the amount of adhesive composition in grams per linear meter in the head portion <NUM> in comparison to the amount of adhesive composition in grams per linear meter in the tail portion <NUM> is less than about <NUM>:<NUM>, such as less than about <NUM>:<NUM>, such as less than about <NUM>:<NUM>.

As shown in <FIG>, the tail portion <NUM> can include a middle section <NUM> and an end section <NUM>. The end section <NUM> can be located opposite the head portion <NUM>. In one embodiment, the middle section <NUM> can have a substantially uniform basis weight while the end section <NUM> can have a gradually decreasing basis weight. For example, the basis weight of the middle section <NUM> can vary by no more than about <NUM>%, such as by no more than about <NUM>%, such as by no more than about <NUM>% over the length of the middle section. The end section <NUM>, on the other hand, can gradually decrease from the average basis weight of the middle section <NUM> to zero.

In general, the web of material <NUM> can comprise any suitable substrate for receiving the adhesive composition. The web of material <NUM>, for instance, can comprise a single layer of material or can comprise a laminate. In one embodiment, the web of material <NUM> comprises a nonwoven web. For instance, the web of material <NUM> may comprise a spunbond web, a meltblown web, a coform web, a hydroentagled web, or the like. In one embodiment the web of material <NUM> can contain pulp fibers and may comprise a paper or tissue web. In another embodiment, the web of material <NUM> comprises a woven fabric or a knitted fabric. In still another alternative embodiment of the present disclosure, the web of material <NUM> can comprise a film. The film can be a single layer film or a multi-layer film.

In one embodiment, the web of material <NUM> may comprise a laminate comprised of multiple layers. In one embodiment, for instance, the web of material <NUM> may comprise a spunbond/meltblown/spunbond web.

The web of material <NUM> can be used to construct many different types of products. In one embodiment, for instance, the web of material <NUM> can be incorporated into an absorbent article. The adhesive composition is applied to the web during the process in order to attach a separate piece of material to the web for constructing a particular portion of the product. The absorbent article, for instance, may comprise a diaper, a training pant, a swim pant, an adult incontinence product, a feminine hygiene product, or the like. In one embodiment the adhesive composition may be applied to the web of material <NUM> in order to attach side panels to an absorbent article, such as elastic side panels. In an alternative embodiment, the adhesive composition may be used to attach fastener panels, such as hook and loop fasteners, to the material that serve as attachment devices for attaching the diaper to the wearer. In still another embodiment, the adhesive composition can be used to form a pocket within the absorbent article.

In another embodiment, the web of material <NUM> may be used to produce various other products in addition to absorbent articles. For instance, in one embodiment, the web of material <NUM> may be used to form packaging.

Claim 1:
A system for applying an adhesive to a moving web of material (<NUM>) comprising:
a nozzle (<NUM>) in fluid communication with an adhesive supply;
a web conveying device for conveying a web of material, the web conveying device being configured to convey the web of material adjacent to the nozzle without contacting the nozzle;
a web deflecting device (<NUM>) that periodically causes a moving web of material being conveyed by the web conveying device to contact the nozzle for a length of time;
an adhesive control device (<NUM>) in communication with the nozzle, characterised in that the adhesive control device is configured to control a flow of adhesive through the nozzle in relation to contact of a moving web with the nozzle caused by the deflecting device such that flow of adhesive from the nozzle occurs prior to contact with the moving web of material;
characterized in that the deflecting device is configured to cause a moving web of material to contact the nozzle in a manner such that the web forms a maximum exit angle (<NUM>) with the nozzle, the maximum exit angle being from <NUM>° to <NUM>° in relation to a horizontal plane that is perpendicular to an exit port on the nozzle, wherein the deflecting device is further configured such that the exit angle changes from a minimum exit angle to the maximum exit angle while the web of material is in contact with the nozzle.