Nozzle and applicator system for fabric bonding

What is claimed is: 1. A method of bonding fabrics with an adhesive, the method comprising: receiving the adhesive from an adhesive supply into a chamber of a body of a nozzle assembly, the nozzle assembly having a valve seat disposed in the body at a lower end of the chamber, a valve stem configured to slidably move within the chamber towards and away from the valve seat, and a plurality of outlet channels, each of the plurality of outlet channels disposed in the body of the nozzle assembly directly adjacent to the valve seat and being configured to receive a discrete portion of the adhesive directly from the chamber; jetting the adhesive from the plurality of outlet channels onto a first fabric by moving the valve stem towards the valve seat and impacting the valve stem onto the valve seat directly adjacent the plurality of outlet channels, such that a fluid seal is created directly between the chamber and each of the plurality of outlet channels, each discrete portion of the adhesive is provided directly from the chamber to one of the plurality of outlet channels, and a discrete volume of the adhesive is forcefully ejected directly from the chamber through the plurality of outlet channels due to the momentum of the impact between the valve stem and the valve seat; and applying a second fabric to the first fabric to adhere the first and second fabrics to each other. 2. The method of claim 1 , wherein jetting the adhesive includes jetting a substantially equal portion of the adhesive through each of the plurality of outlet channels. 3. The method of claim 1 , wherein the first fabric and the second fabric are both part of a single integrated piece of fabric, and applying the second fabric to the first fabric includes folding the single integrated piece of fabric. 4. The method of claim 1 , wherein the first fabric is separate from the second fabric. 5. The method of claim 1 , wherein jetting the adhesive includes jetting the adhesive through three outlet channels onto the first fabric. 6. The method of claim 1 , wherein jetting the adhesive includes jetting the adhesive through two outlet channels onto the first fabric. 7. The method of claim 1 , further comprising: orienting the nozzle assembly in a first configuration and jetting the adhesive from the plurality of outlet channels onto the first fabric, such that the jetted adhesive on the first fabric forms a first pattern; and orienting the nozzle assembly in a second configuration different from the first configuration and jetting the adhesive from the plurality of outlet channels onto the first fabric, such that the jetted adhesive on the first fabric forms a second pattern different from the first pattern. 8. The method of claim 1 , wherein the plurality of outlet channels are uniformly distributed in an arc end part of the body of the nozzle assembly adjacent to the valve seat and each outlet channel of the plurality of outlet channels has a centerline directed toward a center of the arc end part of the body of the nozzle assembly. 9. A nozzle assembly for jetting an adhesive to bond fabrics, the nozzle assembly comprising: a body defining a chamber therein between an inlet and an outlet, the chamber being configured to receive the adhesive through the inlet and to allow the adhesive to exit through the outlet; a valve seat disposed in the body of the nozzle assembly at a lower end of the chamber adjacent to the outlet; a valve stem configured to slidably move within the chamber towards and away from the valve seat and to contact the valve seat; and a plurality of outlet channels in fluid communication with the outlet of the chamber, each of the plurality of outlet channels disposed in the body of the nozzle assembly directly adjacent to the valve seat and being configured to receive a discrete portion of the adhesive directly from the chamber, wherein the valve stem is configured to impact the valve seat directly adjacent the plurality of outlet channels, such that a fluid seal is created directly between the chamber and each of the plurality of outlet channels, each discrete portion of the adhesive is provided directly from the chamber to one of the plurality of outlet channels, and a discrete volume of the adhesive is forcefully ejected directly from the chamber through the plurality of outlet channels onto a first fabric due to the momentum of the impact between the valve stem and the valve seat. 10. The nozzle assembly of claim 9 , wherein when the valve stem is moved toward the valve seat, the adhesive in the chamber is moved towards and through the outlet. 11. The nozzle assembly of claim 9 , wherein each of the plurality of outlet channels is configured to receive a substantially equal portion of the adhesive from the chamber. 12. The nozzle assembly of claim 9 , further comprising a fluid-tight seal between the valve stem and the valve seat when the valve stem is in contact with the valve seat to prevent the adhesive from moving out of the chamber through the outlet. 13. The nozzle assembly of claim 9 , wherein the plurality of outlet channels are splayed relative to each other, such that at least some of the plurality of outlet channels face different directions. 14. The nozzle assembly of claim 9 , wherein the plurality of outlet channels includes three outlet channels. 15. The nozzle assembly of claim 9 , wherein the plurality of outlet channels includes two outlet channels. 16. The nozzle assembly of claim 9 , wherein the plurality of outlet channels are uniformly distributed in an arc end part of the body of the nozzle assembly adjacent to the valve seat and each outlet channel of the plurality of outlet channels has a centerline directed toward a center of the arc end part of the body of the nozzle assembly. 17. An applicator system for jetting an adhesive onto a fabric, the applicator system comprising: a material supply for storing the adhesive; and a nozzle assembly configured to receive the adhesive from the material supply and to jet the adhesive onto the fabric, the nozzle assembly comprising: a body defining a chamber therein between an inlet and an outlet, the chamber being configured to receive the adhesive through the inlet and to allow the adhesive to exit through the outlet; a valve seat disposed in the body of the nozzle assembly at a lower end of the chamber adjacent to the outlet; a valve stem configured to slidably move within the chamber towards and away from the valve seat and to contact the valve seat; and a plurality of outlet channels in fluid communication with the outlet of the chamber, each of the plurality of outlet channels disposed in the body of the nozzle assembly directly adjacent to the valve seat and being configured to receive a discrete portion of the adhesive directly from the chamber, wherein the valve stem is configured to impact the valve seat directly adjacent the plurality of outlet channels, such that a fluid seal is created directly between the chamber and each of the plurality of outlet channels, each discrete portion of the adhesive is provided directly from the chamber to one of the plurality of outlet channels, and a discrete volume of the adhesive is forcefully ejected directly from the chamber through the plurality of outlet channels onto the fabric due to the momentum of the impact between the valve stem and the valve seat. 18. The applicator system of claim 17 , wherein the material supply further includes a heating element configured to heat the adhesive in the material supply. 19. The applicator system of