High viscosity fluid dispensing system

What is claimed is: 1. A method for depositing a fluid over an interface, the method comprising: moving, by a dispensing device, the fluid within a chamber in a housing towards an exit of the chamber such that the fluid is dispensed through the exit of the chamber, wherein the chamber is configured to increase a tendency of the fluid to flow within the chamber; receiving the fluid from the exit of the chamber at an input of a nozzle located at a first end of a body of the nozzle; moving the fluid from the input through an arrangement of a plurality of channels located within the body such that the fluid exits the plurality of channels at an output of the nozzle located at a second end of the body, including: moving the fluid through a center channel located along a center axis that extends through the first end and the second end of the body of the nozzle, wherein the cross-sectional diameter of the center channel varies along a length that extends along the center axis; and moving the fluid through outer channels located away from the center axis around the center channel, wherein the cross-sectional diameter of each of the outer channels remains substantially constant along the center axis; controlling a flow of the fluid through the plurality of channels by a configuration of the plurality of channels, wherein the configuration comprises a diameter profile that includes the cross-sectional diameter for each of the plurality of channels; and depositing the fluid that exits the output of the nozzle over the interface to form a deposition having a desired shape. 2. The method of claim 1 , wherein controlling the flow of the fluid through the plurality of channels by the configuration of the plurality of channels comprises: controlling the flow of the fluid through the plurality of channels by the configuration of the plurality of channels such that the fluid exits the output of the nozzle with a desired velocity profile and a desired pressure profile to form the deposition having the desired shape. 3. The method of claim 1 , wherein moving the fluid from the input through the plurality of channels comprises: moving the fluid from the input of the nozzle into a cavity in a first section of the body; and moving the fluid from the cavity in the first section of the body to the plurality of channels in a second section of the body of the nozzle. 4. The method of claim 1 further comprising: positioning the second end of the body relative to the interface, wherein the second end of the body has a selected shape that allows the second end to be positioned within a desired distance from the interface. 5. The method of claim 1 further comprising: depositing the fluid that exits the output of the nozzle over the interface to form the deposition, wherein the interface is selected from one of a seam interface, a cross-seam interface, a fastener interface, a corner interface, and a step interface. 6. A method for depositing a fluid over an interface using a nozzle, the method comprising: positioning the nozzle relative to the interface in which the nozzle comprises a body having a first end and a second end in which the second end of the body has a selected shape that allows the second end to be positioned within a desired distance from the interface; moving, by a dispensing device, the fluid within a chamber in a housing of a fluid dispensing system towards an exit of the chamber such that the fluid is dispensed through the exit of the chamber, wherein the chamber is configured to increase a tendency of the fluid to flow within the chamber; receiving the fluid within a cavity in a first section of the body from the exit of the chamber through an input of the nozzle; moving the fluid from the cavity in the first section through an arrangement of a plurality of channels in a second section of the body such that the fluid exits the plurality of channels at an output of the nozzle located at the second end of the body, including: moving the fluid through a center channel located along a center axis that extends through the first end and the second end of the body of the nozzle, wherein the cross-sectional diameter of the center channel varies along a length that extends along the center axis; and moving the fluid through outer channels located away from the center axis around the center channel, wherein the cross-sectional diameter of each of the outer channels remains substantially constant along the center axis; controlling a flow of the fluid through the plurality of channels by a configuration of the plurality of channels, wherein the configuration comprises a diameter profile that includes the cross-sectional diameter for each of the plurality of channels; and depositing the fluid that exits the output of the nozzle over the interface to form a deposition in which the interface is selected from one of a seam interface, a cross-seam interface, a fastener interface, a corner interface, and a step interface.