The disclosure relates to a method of manufacturing a fibre reinforced composite, wherein the surface of the fibre reinforced composite modified by using a laser radiation. In particular, the pre-treatment is performed before a bonding process. Time-consuming and dust generating grinding of the surface can be avoided.

A processing system is a processing system that is configured to process an object by using an energy beam, and includes: an irradiation optical system that includes a condensing optical system and that is configured to condense the energy beam entering a pupil plane of the condensing optical system to irradiate the object with it; and a detection apparatus that is configured to detect, through the condensing optical system, an object light including a light from the object, at least a part of a path of the object light in the condensing optical system is different from at least a part of a path of the energy beam in the condensing optical system.

A substrate manufacturing method of manufacturing a substrate from a workpiece is disclosed. A laser beam is first split and condensed to form a plurality of focal points aligned side by side along a first direction, and with the focal points positioned inside the workpiece, the focal points and the workpiece are moved relative to each other along a second direction orthogonal to the first direction such that a separation layer is formed. A region of the focal points and the workpiece are then moved relative to each other along the first direction. These relative movements are alternately and repeatedly performed. The splitting and condensation of the laser beam are performed such that a volume expansion of the workpiece associated with the formation of the modified regions is relatively small in the vicinity of at least one focal point formed on a center side.

The present invention discloses that a multi-laser cutting method and system, which is applied to a substrate to form a primary substrate having a pattern of rounded corners and a line, the throughput could be improved because CO.sub.2 laser cannot cut the round corner at the high speed, but the substrate strength could be kept due to the high cutting quality of the lines by CO.sub.2 laser. The poor quality of the cutting edges of the round corners will not affect on the substrate strength but the round corner cutting by the second laser unit will speed up the cutting process. The present invention applies the method by the 2 different laser machines to balance the throughput. Because at the same speed, for example 150 mm/sec, the cycle time per 1 substrate will be different due to the different length of the cutting lines.

The invention refers to a deflection module comprising a first deflection unit (10a) comprising a first scanning device (12a) for scanning a first working beam (50a) over a first working field and (40a) and a second deflection unit (10b) comprising a second scanning device (12b) for scanning a second working beam (50b) over a second working field (40b). At least a movable mirror (12a-2) of the first scanning device (12a) and at least a movable mirror (12b-2) of the second scanning device (12b) are arranged mirror-symmetrically with respect to each other. The first working field (40a) and the second working field (40b) overlap in a common overlap area (42).

The present disclosure provides methods and systems for composite-to-metal hybrid bonded structures compromising the laser surface treatment on titanium alloys to promote adhesive bond performance. For example, a computer may be programmed to set a laser path corresponding to a predetermined geometric pattern. A laser may be coupled to the computer and apply a pulsed laser beam to a contact surface of the titanium alloy along the predefined geometric pattern. The laser may generate an open pore oxide layer on the contact surface of the substrate with a thickness of 100 and 500 nm. The open pore oxide layer may have a topography corresponding to the predefined geometric pattern. The topography may contain high degree of open pore structure and promote adhesive bond performance. Adhesive, primer or composite resin matrix may fully infiltrate into the open pore structures. Adhesive and composite laminate may co-cure to form composite-to-titanium hybrid bonded structures.

An apparatus and a method for producing strip wound tube products are disclosed. The apparatus includes a winding machine for winding a strip to a strip wound tube and a finishing machine for cutting off pieces of desired length from the strip wound tube and for connecting strip layers in the end sections of the strip wound tube product by way of an joining operation, the finishing machine having a mobile operating head and/or a force decoupling unit.

A welding or cladding apparatus in which one or more energy beam emitters are used to generate a wide beam spot transverse to a welding or cladding path, and one or more wide feeders feed wire to the spot to create a wide welding or cladding puddle.

A laser head apparatus that enables the use of smaller parallel converging laser beams that create multiple smaller holes in a material followed by a larger parallel diverging laser beams that remove additional material. The laser head apparatus includes laser optics and purging nozzles. A process for removing material using the laser head apparatus includes moving the laser head apparatus to a position to generate parallel converging laser beams at a target location in the material and moving the laser head apparatus to a position to generate parallel diverging laser beams at the target location from the converging laser beams.

The invention provides a method for laser modification of a sample to form a modified region at a target location within the sample. The method comprises positioning a sample in a laser system for modification by a laser; measuring tilt of a surface of the sample through which the laser focusses; using at least the measured tilt to determine a correction to be applied to an active optical element of the laser system; applying the correction to the active optical element to modify wavefront properties of the laser to counteract an effect of coma on laser focus; and laser modifying the sample at the target location using the laser with the corrected wavefront properties to produce the modified region.