Customizable apparatus and method for transporting and depositing fluids

What is claimed: 1. A method of depositing a fluid onto a substrate, the method comprising the steps of: providing a substrate; providing a fluid; providing an additively manufactured cylindrical rotating roll comprising a central longitudinal axis and an exterior surface wherein the rotating roll rotates about the central longitudinal axis and the exterior surface defines an interior region and substantially surrounds the central longitudinal axis; providing a vascular network to supply the fluid from the interior region to the exterior surface of the cylindrical rotating roll in a predetermined path wherein the vascular network comprises: a main artery, a first capillary and a plurality of fluid exits on the exterior surface wherein: the main artery comprises an inlet and is substantially parallel to the central longitudinal axis of the rotating roll wherein the fluid enters the vascular network at the inlet; and wherein the first capillary is associated with the main artery and is in fluid communication with the main artery and at least two fluid exits on the exterior surface of the cylindrical rotating roll through substantially radial fluid paths in a first tree expanding both axially and circumferentially in a radial direction from the main artery to the exterior surface; transporting the fluid to the vascular network; controlling the flow of the fluid by at least one of the group consisting of pressure, volume, viscosity, surface tension, diameter of one or more channels, length of one or more channels, relative length of at least two channels, relative diameter of at least two channels, roll diameter, temperature and combinations thereof to move the fluid at a predetermined flow rate to at least one of the at least two fluid exits; and contacting the substrate with the fluid. 2. The method of claim 1 wherein the step of contacting the substrate with the fluid further comprises contacting the substrate with the exterior of the roll at at least one of the fluid exits. 3. The method of claim 1 further comprising the steps of providing a backing surface and contacting the substrate with the backing surface. 4. The method of claim 3 further comprising the steps of: creating a nip between the backing surface and the rotating roll, and contacting the substrate with the fluid at the nip. 5. The method of claim 1 wherein at least one fluid exit comprises a micro-reservoir and the step of contacting the substrate with the fluid further comprising contacting the substrate with the fluid at the micro-reservoir. 6. The method of claim 1 further comprising providing a rotary union wherein the fluid is supplied from the rotary union to the rotating roll. 7. The method of claim 1 further comprising moving the substrate. 8. The method of claim 1 wherein the vascular network further comprises a second capillary in fluid communication with the main artery and at least two fluid exits through substantially radial paths. 9. The method of claim 1 further comprising providing a control mechanism capable of controlling one of the group consisting of: fluid application level, application rate, roll surface speed, fluid flow rate, pressure, temperature, substrate speed, degree of circumferential roll contact by the substrate, distance between the exterior surface a backing surface, pressure between the rotating roll and the backing surface and combinations thereof. 10. The method of claim 1 wherein the step of contacting the substrate with the fluid further comprises registering the fluid with a product feature. 11. A method of depositing a plurality of fluids onto a substrate, the method comprising: providing a substrate; providing a fluid; providing a rotating roll comprising a central longitudinal axis and an exterior surface wherein the rotating roll rotates about the central longitudinal axis and the exterior surface defines an interior region and substantially surrounds the central longitudinal axis; providing a vascular network to supply the fluid from the interior region to the exterior surface of the rotating roll in a predetermined path wherein the vascular network comprises: a plurality of main arteries, a plurality of first capillaries and a plurality of fluid exits on the exterior surface wherein: each of the main arteries comprise an inlet and is substantially parallel to the central longitudinal axis of the rotating roll and wherein the fluid enters the vascular network at the inlet; and wherein each of the first capillaries is associated with one of the main arteries and is in fluid communication with the one of the main arteries and at least two fluid exits through substantially radial fluid paths in a tree expanding both axially and circumferentially in a radial direction from the main artery to the exterior surface, the tree designed using the following formula: Diameter Level =Diameter Start *BR^(−Level/(2+epsilon)) Where: Diameter Start is the average diameter of the first capillary; Diameter Level is the average diameter of at least one channel on the first tree disposed on a tree level other than Level 0 BR is a branching ratio of the first tree; Level is an integer representing the tree level; and Epsilon is a real number that is not equal to −2 transporting the fluid to the vascular network; controlling the flow of the fluid by at least one of the group consisting of pressure, volume, viscosity, surface tension, diameter of one or more channels, length of one or more channels, relative length of at least two channels, relative diameter of at least two channels, roll diameter, temperature and combinations thereof to move the fluid at a predetermined flow rate to at least one of the at least two fluid exits; and contacting the substrate with the fluid. 12. The method of claim 11 further comprising providing a control mechanism capable of separately controlling each of the main arteries with respect to one of the group consisting of: fluid application level, fluid application rate, fluid flow rate, pressure, temperature and combinations thereof.