A method of manufacturing a lithium-ion secondary battery electrode sheet disclosed herein includes the step of preparing powder 220 of granulated particles. In this step, the powder (220) of granulated particles (240) including active material particles (241) and a binder (242) is prepared. The powder (220) is deposited on a strip-shaped collector foil (201) that is being conveyed. Then, the powder (220) is removed from widthwise center portions (202) and (203) of the collector foil (201), and a squeegee (106) is brought into contact with the powder (220) remaining on the opposite sides of the center portions (202) and (203) of the collector foil (201), thus adjusting the thickness of the powder (220). Subsequently, the powder (220) remaining on the opposite sides of the center portions (202) and (203) of the collector foil (201) is pressed.

An adhesive dispensing system for applying liquid adhesive to a substrate using different nozzles with the same manifold is disclosed. The adhesive dispensing system includes a manifold having a body, a first clamp configured to engage the body of the manifold, a second clamp configured to engage the body of the manifold, and a nozzle. The first and second clamps secure the nozzle to the body of the manifold. The body of the manifold has a first contact surface that engages the first clamp and a second contact surface that engages the second clamp and the nozzle, where the second contact surface is angularly offset from the first contact surface.

An applicator for dispensing adhesive is disclosed. The applicator includes a manifold, at least one dispensing module coupled to the manifold, a supply channel configured to contain at least a portion of the adhesive, a recirculation channel configured to contain at least a portion of the adhesive, and a recirculation pump assembly connected to the manifold. The recirculation pump assembly includes an inlet in fluid communication with the recirculation channel, an outlet in fluid communication with the supply channel, a gear assembly, and a drive motor coupled to the gear assembly and operable to pump the adhesive, where the drive motor is configured to operate at an adjustable number of revolutions per minute (RPM). The recirculation pump assembly can be configured to move at least a portion of the adhesive from the recirculation channel to the supply channel, such that a first pressure of the adhesive in the recirculation channel is substantially equal to a second pressure of the adhesive in the supply channel.

An applicator for dispensing adhesive and a method of diverting flow in an applicator are disclosed. The applicator includes a plurality of pump assemblies each having an inlet and an outlet, a plurality of dispensing modules each having an inlet, and a flow diverter plate in fluid communication with the plurality of pump assemblies. The flow diverter plate defines a body having a first surface in fluid communication with the plurality of pump assemblies, a second surface opposite the first surface in fluid communication with the plurality of dispensing modules, and a plurality of diverter passages extending from the first surface to the second surface. Each of the plurality of diverter passages has a first opening on the first surface and a second opening on the second surface, and the first opening is in fluid communication with the outlet of one of the plurality of pump assemblies, and the second opening is in fluid communication with the inlet of at least one of the plurality of dispensing modules.

A method for controlling a recirculation pump assembly is disclosed. The method includes receiving a process-dependent characteristic and determining a recirculation flow rate of adhesive that flows to the recirculation pump assembly based on the process-dependent characteristic. The method further includes determining a recirculation pump speed of the recirculation pump assembly for pumping the adhesive to a supply channel using the recirculation flow rate, and adjusting an operating speed of the recirculation pump assembly to match the recirculation pump speed. A system and storage device for performing the above method are also disclosed.

An embodiment of the present disclosure is an applicator for dispensing adhesive onto a substrate. The applicator includes a manifold and at least one dispensing module coupled to the manifold. The applicator may include a least one pump assembly removably mounted the manifold. Each pump assembly having an outlet in flow communication with the manifold, and an inlet in flow communication with the adhesive. The pump assembly includes a gear assembly for pumping adhesive from said inlet to said outlet and a drive motor with a drive shaft connected to the gear assembly. The drive motor has a shaft with an axis that intersects said front surface of the pump assembly. In another example, the shaft has an axis that does not intersect both of a first side and a second side of said manifold.

A method and an arrangement are disclosed for producing an electrically conductive pattern on a surface. Electrically conductive solid particles are transferred onto an area of predetermined form on a surface of a substrate. The electrically conductive solid particles are heated to a temperature that is higher than a characteristic melting point of the electrically conductive solid particles, thus creating a melt. The melt is pressed against the substrate in a nip, wherein a surface temperature of a portion of the nip that comes against the melt is lower than said characteristic melting point.

The disclosure relates to a coating apparatus for applying a monolayer layer of particles to a receiving surface. The apparatus comprises a pressurized air source, an application chamber partially bounded by the receiving surface into which an air stream is delivered by the air source, an air return path for returning air from the application chamber to an intake of the air source to form an air circulation loop, and a dosing device for introducing particles to be coated onto the receiving surface into the air circulation loop, a particle deflector being positioned in the path of the air stream to break up agglomerated particles carried by the air stream prior to coating the receiving surface with the particles. A method of applying a layer of particles is also provided, as well as printing systems benefiting from the present coating apparatus.

A facility for depositing a film of ordered particles onto a moving substrate, the facility configured to allow deposition, onto the substrate, of a film of ordered particles escaping from a particle outlet of a transfer zone having a first width. The facility further includes an accessory device in a form of a deposit head, provided to seal the particle outlet and configured to allow the deposition, onto the substrate, of a film of ordered particles escaping from an end of a particle transfer channel of the deposit head, the end having a second width strictly lower than the first width.

A coater includes a chuck, a source of a coating material, a dispensing head, an exhaust system, and a liner. The chuck is configured to support a wafer. The dispensing head is configured to dispense the coating material onto the wafer. The exhaust system is configured to exhaust the excess coating material. The liner is present at least partially on an inner surface of the exhaust system. The liner has a stick resistance to the coating material, and the stick resistance of the liner is greater than a stick resistance of the inner surface of the exhaust system.