The present disclosure discloses a device for detaching a textile from a printing plate, in particular in the case of direct printing and/or screen printing using a plurality of colours, comprising a lifting device which comprises a gripper for gripping a first end of the textile, and a first movement axis for lifting the gripper; and a detachment slider, which can be inserted, via a second movement axis, between the printing plate and the first end of the textile, lifted by the lifting device, in order to detach the textile from the printing plate.

A rotary screen printing press includes: a screen plate; a squeegee; squeegee supporting means for supporting the squeegee; and a worm and a worm wheel. The squeegee supporting means includes: a supporting plate swingably supported and supporting the worm and the worm wheel; an eccentric sleeve configured to adjust the position of the center of swinging movement of the supporting plate; and a contact surface and a screw configured to limit the direction of the movement of the supporting plate. The eccentric sleeve and the contact surface and screw cooperate with each other to move the tip of the squeegee along the tangent line of an impression cylinder at a position at which the screen plate and the squeegee contact each other.

The present invention relates to the technical field of conductivity measurement electrode preparation, and specifically discloses a method for manufacturing a high-precision marine conductivity measurement electrode based on screen printing. The method of the present invention can realize the preparation of a conductivity measurement electrode with high precision, short preparation time and less drop-out of the electrode, thereby meeting the requirements of the current marine observation network for the high-volume and high-precision application of the conductivity sensor.

The present invention relates to the technical field of conductivity measurement electrode preparation, and specifically discloses a method for manufacturing a high-precision marine conductivity measurement electrode based on screen printing. The method of the present invention can realize the preparation of a conductivity measurement electrode with high precision, short preparation time and less drop-out of the electrode, thereby meeting the requirements of the current marine observation network for the high-volume and high-precision application of the conductivity sensor.

The present disclosure relates to a control unit for a vehicle interior. In particular, the control unit can comprise an information region with symbols, wherein some symbols are always visible and some symbols are only visible when they are back lit. The application also relates to a method for producing a corresponding control unit. The control unit can be part of a vehicle interior trim part, for example part of an instrument panel, door trim or center console.

The present disclosure relates to a control unit for a vehicle interior. In particular, the control unit can comprise an information region with symbols, wherein some symbols are always visible and some symbols are only visible when they are back lit. The application also relates to a method for producing a corresponding control unit. The control unit can be part of a vehicle interior trim part, for example part of an instrument panel, door trim or center console.

A laser alignment tool is a device that facilitates the efficient and accurate alignment of a product for different manufacturing processes such as Direct-to-Film, screen printing, embroidery, etc. The device includes a tool base, at least one laser module, a controller, and a portable power source. The tool base corresponds to the portion of the device that supports the operation of the at least one laser module. The tool base also facilitates the attachment of the device to a surface adjacent to the product that needs to be aligned. The at least one laser module emits one or more light beams on the adjacent surface that can be used to align the desired product. The controller enables the user to selective control the operation of the at least one laser module. The portable power source provides the electrical power necessary for the operation of the at least one laser module.

A printing result prediction device is configured to predict a volume of solder paste printed by a printer onto a substrate. The printer is configured to print the solder paste by filling the solder paste into a stencil aperture of a stencil disposed on the substrate. The printing result prediction device includes a calculation part. The calculation part is configured to input a printing condition to a prediction model trained by machine learning, and predict a volume of solder paste printed by the stencil aperture of the stencil in a next printing using the input printing condition. The printing condition includes stencil information related to the stencil used to print, solder paste information related to the solder paste used to print, substrate information including unevenness information related to a protrusion on the substrate used to print, and a printing parameter of an operation of the printer when printing.

A printing result prediction device is configured to predict a volume of solder paste printed by a printer onto a substrate. The printer is configured to print the solder paste by filling the solder paste into a stencil aperture of a stencil disposed on the substrate. The printing result prediction device includes a calculation part. The calculation part is configured to input a printing condition to a prediction model trained by machine learning, and predict a volume of solder paste printed by the stencil aperture of the stencil in a next printing using the input printing condition. The printing condition includes stencil information related to the stencil used to print, solder paste information related to the solder paste used to print, substrate information including unevenness information related to a protrusion on the substrate used to print, and a printing parameter of an operation of the printer when printing.

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.