A squeegee assembly for a screen printing machine has a squeegee support body having a side configured to be fastened to the screen printing machine, a front portion provided with a front element and a rear portion provided with a rear element, respectively having a front element printing end and a rear element printing end for screen printing by ink. The front element printing end is spaced apart with respect to the rear element printing end in a translation direction so that an ink collection space is formed therebetween. In the front portion, one or more ink passage openings are formed for allowing passage of ink from a region in front of the front element towards the ink collection space during translation of the squeegee assembly during screen printing. Ink in the ink collection space is draggable by the rear element during translation of the squeegee assembly.

A squeegee assembly for a screen printing machine has a squeegee support body having a side configured to be fastened to the screen printing machine, a front portion provided with a front element and a rear portion provided with a rear element, respectively having a front element printing end and a rear element printing end for screen printing by ink. The front element printing end is spaced apart with respect to the rear element printing end in a translation direction so that an ink collection space is formed therebetween. In the front portion, one or more ink passage openings are formed for allowing passage of ink from a region in front of the front element towards the ink collection space during translation of the squeegee assembly during screen printing. Ink in the ink collection space is draggable by the rear element during translation of the squeegee assembly.

A solder printing machine, which is configured to print paste-state solder on a board by use of a mask and a squeegee configured to move on an upper surface of the mask, includes a bed, a mask frame fixedly provided on the bed and configured to hold the mask, and a squeegee frame fixedly provided on the bed, formed separately from the mask frame, and configured to support a driving mechanism configured to drive the squeegee.

A squeegee for spreading a conductive paste across a stencil during a stencil printing process is provided. The stencil covers an underlying base such that the conductive paste is spread across the stencil and into openings in the stencil to contact the underlying base. The squeegee has a leading surface at the front of the squeegee, a trailing surface at the rear of the squeegee, and a bottom surface. The bottom surface is oriented at an oblique angle relative to the leading surface and the trailing surface. In some embodiments, a rear corner or edge of the squeegee is the contact point between the squeegee and the stencil. Some of the paste can be collected beneath the bottom surface and scraped along with the squeegee.

A squeegee for spreading a conductive paste across a stencil during a stencil printing process is provided. The stencil covers an underlying base such that the conductive paste is spread across the stencil and into openings in the stencil to contact the underlying base. The squeegee has a leading surface at the front of the squeegee, a trailing surface at the rear of the squeegee, and a bottom surface. The bottom surface is oriented at an oblique angle relative to the leading surface and the trailing surface. In some embodiments, a rear corner or edge of the squeegee is the contact point between the squeegee and the stencil. Some of the paste can be collected beneath the bottom surface and scraped along with the squeegee.

Deflector units for use with a printing blade in printing a print medium through a printing screen, which are self-adjustable in a vertical direction for controlling production of rolls of print medium.

Deflector units for use with a printing blade in printing a print medium through a printing screen, which are self-adjustable in a vertical direction for controlling production of rolls of print medium.

Disclosed herein are squeegee apparatuses and methods and systems for screen printing on a surface of a substrate comprising the disclosed squeegee apparatus and a framed screen. Also disclosed herein are methods for screen printing a 3D substrate comprising creating a 2D test framed screen. Methods for predicting the distortion of an image printed on a 3D substrate are also disclosed herein.

Disclosed herein are squeegee apparatuses and methods and systems for screen printing on a surface of a substrate comprising the disclosed squeegee apparatus and a framed screen. Also disclosed herein are methods for screen printing a 3D substrate comprising creating a 2D test framed screen. Methods for predicting the distortion of an image printed on a 3D substrate are also disclosed herein.

The supply unit is used in a printing device including a printing head configured to perform printing process of a viscous fluid on a printing target using a screen mask, a collection section having a collection member configured to contact the screen mask to collect and move the viscous fluid and a collecting and moving section configured to move the collection member in a predetermined printing direction. The supply unit includes a supply section having a mounting section capable of mounting and dismounting a cartridge accommodating the viscous fluid, a driving section configured to move the supply section in the supply operation direction, a detection member, and a supply section detecting section configured to detect whether the supply section is positioned in a passage space where the collection section and the supply section do not contact each other by the position of the detection member.