Chemical deposition reactor assembly configured for formation of coatings on surfaces of fluid-permeable materials, such as porous materials, by chemical deposition is provided, the reactor assembly includes a reaction chamber configured to receive, at least in part, a fluid-permeable substrate with a target surface to be coated; at least one reactive fluid intake line configured to mediate a flow of reactive fluid into the reaction chamber, and an inert fluid delivery arrangement with at least one enclosed section configured to mediate a flow of inert fluid through the substrate towards its' target surface such, that at the surface the flow of inert fluid encounters the flow of reactive fluid, whereby a coating is formed at the target surface of the fluid-permeable substrate.

Chemical deposition reactor assembly configured for formation of coatings on surfaces of fluid-permeable materials, such as porous materials, by chemical deposition is provided, the reactor assembly includes a reaction chamber configured to receive, at least in part, a fluid-permeable substrate with a target surface to be coated; at least one reactive fluid intake line configured to mediate a flow of reactive fluid into the reaction chamber, and an inert fluid delivery arrangement with at least one enclosed section configured to mediate a flow of inert fluid through the substrate towards its' target surface such, that at the surface the flow of inert fluid encounters the flow of reactive fluid, whereby a coating is formed at the target surface of the fluid-permeable substrate.

A method for coating the lumen of a tube comprises the steps of inserting the distal opening of a tube into a first coating solution, drawing the first coating solution into the lumen of the tube, draining the first coating solution from the lumen leaving a film of the first coating solution on the lumen of the tube, and curing the first coating solution. This leaves a first coating on the lumen of the tube. A coating apparatus comprises a pallet, and one or more dip funnels. The pallet comprises a manifold and is configured to fluidically connect the manifold to one or more tubes. The one or more dip funnels are configured to hold a coating solution and are located below the pallet so that when the pallet is moved vertically, the one or more tubes are inserted into the dip funnels.

A method for coating the lumen of a tube comprises the steps of inserting the distal opening of a tube into a first coating solution, drawing the first coating solution into the lumen of the tube, draining the first coating solution from the lumen leaving a film of the first coating solution on the lumen of the tube, and curing the first coating solution. This leaves a first coating on the lumen of the tube. A coating apparatus comprises a pallet, and one or more dip funnels. The pallet comprises a manifold and is configured to fluidically connect the manifold to one or more tubes. The one or more dip funnels are configured to hold a coating solution and are located below the pallet so that when the pallet is moved vertically, the one or more tubes are inserted into the dip funnels.

In an embodiment, the invention comprises a method of coating a three-dimensional article comprising depositing a quantity of a liquid coating material onto a surface of a form factor, contacting a surface of the three-dimensional article with the form factor surface, wherein the form factor surface is configured to nest with the three-dimensional article. The method further comprises coalescing the liquid coating material on the surface of the three-dimensional article for uniform coverage.

In an embodiment, the invention comprises a method of coating a three-dimensional article comprising depositing a quantity of a liquid coating material onto a surface of a form factor, contacting a surface of the three-dimensional article with the form factor surface, wherein the form factor surface is configured to nest with the three-dimensional article. The method further comprises coalescing the liquid coating material on the surface of the three-dimensional article for uniform coverage.

To increase the strength and water resistance of a joint between two slabs of building materials, an interface for inserting bonding material between the joins of two interlocking members is used. The interface has two interlocking slabs, a tongue ridge, a groove slot, a fill channel, and a quantity of adhesive. The two interlocking slabs are the pieces of building material that are joined by the interface. To accomplish this, the tongue ridge connects to the first interlocking slabs, and the groove slot traverses into the second interlocking slab. The tongue ridge engages the groove slot to form an interlocking connection. The fill channel traverses through the tongue ridge along the length of the tongue ridge so that the quantity of adhesive can be deposited into the interlocking connection between the tongue ridge and the groove slot.

To increase the strength and water resistance of a joint between two slabs of building materials, an interface for inserting bonding material between the joins of two interlocking members is used. The interface has two interlocking slabs, a tongue ridge, a groove slot, a fill channel, and a quantity of adhesive. The two interlocking slabs are the pieces of building material that are joined by the interface. To accomplish this, the tongue ridge connects to the first interlocking slabs, and the groove slot traverses into the second interlocking slab. The tongue ridge engages the groove slot to form an interlocking connection. The fill channel traverses through the tongue ridge along the length of the tongue ridge so that the quantity of adhesive can be deposited into the interlocking connection between the tongue ridge and the groove slot.

Described herein is a coating system configured for providing a washcoat onto a substrate. The coating system can be configured to pump a coating solution, particularly a low viscosity solution, into a coating vessel have the substrate positioned therein. The coating system further includes elements configured for removal of a non-coating portion of the coating solution from the substrate and recycling of the non-coating portion. Also described herein are methods for applying a washcoat to a substrate as well as multi-station coater systems.

Described herein is a coating system configured for providing a washcoat onto a substrate. The coating system can be configured to pump a coating solution, particularly a low viscosity solution, into a coating vessel have the substrate positioned therein. The coating system further includes elements configured for removal of a non-coating portion of the coating solution from the substrate and recycling of the non-coating portion. Also described herein are methods for applying a washcoat to a substrate as well as multi-station coater systems.