A method for screen printing of a material on a substrate is provided. The method includes moving a process head assembly having at least one deposition device from a first position to a second position to perform a stroke, wherein the stroke includes at least a first phase for material processing of a material on a screen device using the at least one deposition device and a second phase for a material transfer from the screen device to the substrate. The at least one deposition device moves in a first direction in the first phase. At least one device moves in a second direction perpendicular to the first direction in the first phase. The at least one deposition device and the at least one device simultaneously move during at least a part of the first phase. The at least one device is selected from the group including the at least one deposition device, a material processing device, the screen device, and a substrate support.

In an embodiment of the present invention, a squeegee blade holder is provided. The holder includes a first side member, a second side member, and a pivot portion between the first and second side members. The holder also includes a separator between the first and second side members for maintaining compression of the side members against the squeegee blade.

A screen printer including a squeegee device to spread from above solder paste on a stencil; a clamp device to grip a board conveyed to a position below the stencil by a board conveyance member that is flat and provided with a board holding portion in a central opening portion, the clamp device gripping the board via the board conveyance member; a board supporting device to support the board from below and move the board in a vertical direction inside the clamp device; and a raising and lowering device to move the board supported inside the clamp device in the vertical direction and position the board at a printing position, and the clamp device is provided with a board printing guide member to be removably attached to an upper end of a pair of clamp members to sandwich the board conveyance member in a widthwise direction.

A screen printer including a squeegee device to spread from above solder paste on a stencil; a clamp device to grip a board conveyed to a position below the stencil by a board conveyance member that is flat and provided with a board holding portion in a central opening portion, the clamp device gripping the board via the board conveyance member; a board supporting device to support the board from below and move the board in a vertical direction inside the clamp device; and a raising and lowering device to move the board supported inside the clamp device in the vertical direction and position the board at a printing position, and the clamp device is provided with a board printing guide member to be removably attached to an upper end of a pair of clamp members to sandwich the board conveyance member in a widthwise direction.

In an embodiment of the present invention, a squeegee blade holder has a first side member, a second side member, and a pivot portion between the first and second side members. The holder also includes a separator between the first and second side members for maintaining compression of the side members against the squeegee blade.

In an embodiment of the present invention, a squeegee blade holder has a first side member, a second side member, and a pivot portion between the first and second side members. The holder also includes a separator between the first and second side members for maintaining compression of the side members against the squeegee blade.

A method for producing a heating system on a 3D plastic window, such as a car window. The heating system having an electric heat conductor structure with at least two bus bars and a grid line pattern with a plurality of grid lines. The method having: a step in which the two bus bars, made of a first electrically conductive paste are screen-printed onto the window by a displaceable squeegee; a step in which the grid line pattern is applied onto the window such that it respectively overlaps the two bus bars with at least one second electrically conductive paste which has a greater electrical resistance than the first electrically conductive paste, and a final step in which the two bus bars and the grid lines overlapping these bus bars are at the respective overlapping points electrically connected into the electric heat conductor structure by means of electrical connectors.

Screen printer 10 is for screen printing solder paste 13 loaded on an upper surface of stencil 12 onto board S using one of first and second squeegees 71 and 72. Screen printer 10 is provided with a stencil frame holding rail that holds stencil frame 12a of stencil 12, pair of board holding members 36 and 38 that hold board S, raising and lowering table 16 that raises and lowers board holding members 36 and 38, and pair of stencil supporting members 50 and 52 that support stencil 12 from below at a portion outside a printing region of stencil 12 used for screen printing. Stencil supporting members 50 and 52 are provided independently from raising and lowering table 16. Therefore, the load applied to raising and lowering table 16 is reduced. Also, there is increased design freedom with respect to members and the like loaded on raising and lowering table 16.

The application relates to a printing device for printing onto substrates, in particular solar cells, wafers or printed circuit boards, including a squeegee means and including at least one printing table, wherein the squeegee means is arranged above the printing table, and including at least one conveying means, by means of which a substrate can be transported away in each case to a printing nest below the squeegee direction and away out of the printing nest after the printing process has taken place. It is provided that the printing table has several conveying means, which are arranged side by side and aligned parallel to one another and which each have at least one printing nest, and that the squeegee means has at least one squeegee, which can be moved over each printing nest in order to print successively onto the substrates, which are arranged in the printing nests.

The application relates to a printing device for printing onto substrates, in particular solar cells, wafers or printed circuit boards, including a squeegee means and including at least one printing table, wherein the squeegee means is arranged above the printing table, and including at least one conveying means, by means of which a substrate can be transported away in each case to a printing nest below the squeegee direction and away out of the printing nest after the printing process has taken place. It is provided that the printing table has several conveying means, which are arranged side by side and aligned parallel to one another and which each have at least one printing nest, and that the squeegee means has at least one squeegee, which can be moved over each printing nest in order to print successively onto the substrates, which are arranged in the printing nests.