According to a manufacturing method of an electrolytic capacitor according to an embodiment, a fiber film, which serves as a separator, is formed on a surface of a substrate, which serves as an electrode, by ejecting a material liquid against the substrate. When the fiber film is formed, thicker fiber is formed at end parts of the substrate in a width direction, compared to a center part of the substrate in the width direction.

A nozzle for dispensing adhesive between a first part and a second part comprises a nozzle body. The nozzle body comprises a first-part engagement surface. The nozzle body also comprises a second-part engagement surface, contiguous with the first-part engagement surface and defining an engagement-surface angle, greater than 0° and less than 180°, with a virtual plane, coincident with the first-part engagement surface. The nozzle body further comprises a nozzle-body outlet port, formed in the second-part engagement surface. The nozzle body additionally comprises a nozzle-body inlet port, formed in the first-part engagement surface. The nozzle also comprises a separator plate, coupled with and extending from the nozzle body.

An adhesive applicator head, having a heated block (1) to which an adhesive feed (2) is connected; linked to the heated block (1) is a nozzle (4) determining an outlet for the laminar projection of the adhesive to be applied from the heated block (1), where the nozzle (4) has a body (6) and a cover (7) between which there is a space (8) leading to an adhesive outlet groove (9); with regard to the space (8), and externally, there being a plate (10) covering the groove (9), the plate (10) being displaceable between different attachment positions of the plate (10) to the nozzle (4) determining variable lengths of laminar adhesive outlet through the groove (9).

A method to fill the flowable material into the semiconductor assembly module gap regions is described. In an embodiment, multiple semiconductor units are formed on the substrate to create an array module; the array module is attached to a backplane having circuitry to form the semiconductor assembly module in which multiple gap regions are formed inside the semiconductor assembly module and edge gap regions are formed surround an edge of the assembly module; The flowable material is forced inside the gap regions by performing the high acting pressure environment and then cured to be a stable solid to form a robustness structure. A semiconductor convert module is formed by removing the substrate utilizing a substrate removal process. A semiconductor driving module is formed by utilizing a connecting layer on the semiconductor convert module. In one embodiment, a vertical light emitting diode semiconductor driving module is formed to light up the vertical LED array. In another one embodiment, multiple color emissive light emitting diodes semiconductor driving module is formed to display color images. In another embodiment, multiple patterns of semiconductor units having multiple functions semiconductor driving module is formed to provide multiple functions for desire application.

A method for coating a tile element includes providing a tile element made of a compressed fibre material having a porosity in the range of 0.92-0.99 and applying a water-based coating material to a side edge surface of the tile element extending between two opposite major surfaces of the tile element. The applying is performed by an applicator head of a continuous vacuum coating apparatus that applies the water-based coating material to the side edge surface of the tile element and removes excess through a vacuum. The water-based coating material is applied at a feeding rate of the tile element relative the applicator head in the range of 25-150 m/min. The water-based coating material forms a coating layer including an outer coating layer and an inner coating layer penetrating the side edge surface. The inner coating layer has penetration depth of at least 100 μm.

The disclosure relates to a spreading unit having a shaper for spreading viscous material, in particular sealing material, on a component, wherein the shaper has a first shaping contour for shaping the viscous material in the process of the spreading, wherein at least a second shaping contour of the shaper for shaping the viscous material can be brought by means of an actuator, in a direction of spreading, into superimposition with the first shaping contour, so that a shape of the shaper is adjustable during an application process.

The disclosure relates to a coating device for edge-coating a panel with a coating medium, the device comprising at least one medium line, for guiding a coating medium, which comprises an inlet and an outlet, wherein the medium line comprises a recess for introducing a panel into a coating-medium stream, and wherein the medium line and the recess are designed such that the coating medium can be applied to the edge of the panel by means of suction in the flow direction of the medium. The present disclosure also relates to a coating system for edge-coating a panel with a coating medium.

The present application discloses a coating method including: detecting a shape of an object over a coating zone which extends from a start point position to an end point position to generate first detection data before application of coating agent to the object; moving a bracket for holding a nozzle for discharging the coating agent with bringing the bracket into contact with the object to apply the coating agent to the object over the coating zone; detecting a shape of the object after application of the coating agent over the coating zone, to generate second detection data; extracting first extraction data and second extraction data in correspondence to detection positions intermittently set in the coating zone from the first detection data and the second detection data; and comparing the first extraction data with the second extraction data to detect a coating state of the coating agent.

A nozzle (100) for applying a bead (103) of a glutinous substance (101) to a surface (102) of an object (104) comprises a body (110), a first guide (116), a gate (130), a second guide (132), and a biasing member (150). The body (110) comprises an inlet opening (112) and an outlet opening (114), joined by a channel (115). The first guide (116) is coupled to the body (110). The gate (130) is translatably coupled to the body (110). Movement of the gate (130) relative to the body (110) controls flow of the glutinous substance (101) through the outlet opening (114), and width of the bead (103). The second guide (132) is coupled to the gate (130). The biasing member (150) is coupled to the body (110) and to the gate (130). The biasing member (150) urges the gate (130) toward the first guide (116).

A fluid dispensing apparatus is disclosed. Systems include an in-line or linear bladder apparatus configured to expand to collect a charge of fluid, and contract to assist with fluid delivery and dispensing. During a dispense-off period process fluid can collect in this bladder after the process fluid is pushed through a fine filter (micro filter). A given filtration rate can be less than a dispense rate and thus the system herein compensates for filter-lag that often accompanies fluid filtering for microfabrication, while providing a generally linear configuration that reduces chances for defect creation.