A method of dispensing paste for a printer using a paste dispensing apparatus is provided. The paste dispensing apparatus includes a reservoir for storing a paste for a printer. The reservoir includes a stirrer for stirring the paste. The paste dispensing apparatus includes a receptacle for receiving paste from the reservoir. The paste dispensing apparatus includes a closable passage from the reservoir to the receptacle. The closable passage is changeable between an open state and a closed state. In the open state, the receptacle is fluidly coupled to the reservoir so that paste can pass from the reservoir to the receptacle. In the closed state, the receptacle is fluidly decoupled from the reservoir so that the paste is prevented from passing from the reservoir to the receptacle. The paste dispensing apparatus includes a pusher for pushing paste out of the receptacle. The method includes transferring a first volume of paste from the reservoir to the receptacle while the closable passage is in the open state. The method includes, after the transferring, changing the closable passage from the open state to the closed state. The method includes, after the changing, performing a first discharging operation by the pusher to discharge a first amount of paste from the receptacle while the closable passage is in the closed state.

A method of manufacturing a Glow in the Dark Blanket on Premium GSM is glow-in-the-dark blanket that combines premium quality, exceptional durability, vibrant visual representation, and safety features. With a high GSM of 360 and large, colorful glow-in-the-dark images, this blanket delivers a captivating and enchanting experience for users. It addresses the limitations of conventional glow-in-the-dark blankets, ensuring longevity, visual appeal, and flame retardancy.

A method of screen printing positionally synchronizes a plurality of pallet assemblies on a first screen printing machine with a plurality of pallet assemblies on a second screen printing machine. A screen printed garment having a properly aligned first image received from the first screen printing machine is transferred on a portion of one of the pallet assemblies on the first screen printing machine to one of the plurality of pallet assemblies on the second printing machine. The properly aligned first image on the garment is in proper positional alignment with a screen printing head on the second screen printing machine such that a second image complimentary to the first image is printed on the garment in proper position on the garment relative to the first image without user intervention to positionally locate the first image relative to the screen printing head on the second machine.

A stencil printer includes a frame, a stencil, a support assembly, and a print head, and a print head assembly supported by the print head gantry in such a manner that the print head assembly is configured to traverse the stencil during print strokes. The support assembly supports the electronic substrate in a print position beneath the stencil. The print head assembly includes a print head a squeegee blade assembly configured to roll solder paste along the stencil. The stencil printer further includes a cover coupled to the frame to enclose operating components of the stencil printer, including the stencil, the support assembly, the print head gantry and the print head assembly. The cover includes an elongate opening formed therein and a movable door configured to selectively close the elongate opening. The elongate opening is sized to enable the stencil and/or a tooling tray to pass through.

A printing form for producing a structure of an electronic component, in particular a photovoltaic solar cell, having a screen frame and a screen, which is in the form of a sheet-like textile and has a multiplicity of elongate screen elements. The screen is arranged in the screen frame and the screen has at least one printing region which a printing paste can permeate and at least one barrier region which the printing paste cannot permeate. The elongate screen elements are made from glass fiber, carbon fiber and/or carbon nanotubes.

A screen printing device includes a substrate support unit, a squeegee member above the substrate support unit, a screen mask unit disposed between the substrate support unit and the squeegee member, the screen mask unit defining a printing opening for forming a printed pattern, and at least one tension adjusting member disposed on a first surface of the screen mask unit facing the substrate support unit and adjacent to the printing opening.

A control system for a printing apparatus for printing in particular flat substrates, with a rack, on which a receptacle for a printing template, in particular printing screen or printing stencil, is arranged, with a camera device, which is assigned to the receptacle, and with a user interface for inputting and/or obtaining information. What is provided is an evaluation device, which is connected to the camera device, in order to receive at least one image of the printing template detected by the camera device, wherein the evaluation device is formed to classify the printing template as being reusable or as being non-reusable as a function of the received image.

A cover of a stencil printer is hingedly mounted to a frame, and movable between a closed and open positions. The cover includes an elongate opening formed therein and a movable door configured to selectively close the elongate opening. The elongate opening is sized to enable the stencil and/or a tooling tray to pass through. A controller is configured to control movement of the movable door between a closed position and an open position. A sensor assembly is proximate the elongate opening. The sensor assembly is coupled to the controller and configured to detect an object within the elongate opening when moving the movable door to the closed position. The sensor is configured to generate a signal to the controller when detecting an object within the elongate opening. The controller, upon receiving the signal from the sensor, is configured to move the movable door to the open position.

The present invention relates to a batch alignment device for screen printers and a batch alignment method using the same, and can simultaneously, collectively, and quickly align multiple printed circuit boards in multiple alignment holes formed in one alignment jig to enable components to be simplified, the weight of a device to be reduced, production process and time to be shortened, and productivity to be improved and, accordingly, enable mass production, and can quickly implement high-quality printing, which corresponds to the alignment jig and a printing pattern of the mask, on the multiple printed circuit boards, simultaneously with completion of the alignment of the multiple printed circuit boards by aligning only the X-axes and Y-axes on the planes of the printed circuit boards in the alignment jig in a state where a mask and the alignment jig are aligned.

The present invention discloses a four-position full-cell solar silicon wafer printer, including a base, an infeed guide rail, a detection camera assembly, a turntable assembly, a lifting module, a UVW correction alignment mechanism, and an outfeed guide rail. The UVW mechanism comprises two Y-axis modules, one X-axis module, a printing platform, a steel mesh frame, and a printing squeegee kit. The Y/X-axis modules are under the platform, their drive ends connected to the steel mesh frame. The squeegee kit moves left-right on the platform. It uses the Y/X-axis modules and detection camera to realize X, Y, three-axis motion, ensuring steel mesh-silicon wafer alignment and optimizing printing directions.