A simultaneous laser welding apparatus of a vehicle light comprising a placement support for a container body and a lenticular body of a vehicle light to be welded together at reciprocal perimeter profiles associated at a welding interface, a plurality of laser sources suitable for emitting light beams, a plurality of optical fibres associated with the laser sources at input ends and suitable for transmitting said light beams, a fibre-holder support device for the optical fibres, suitable for blocking output ends of said optical fibres in predetermined positions, spaced apart by a pitch, a light guide provided with at least one seat which extends from a light input wall, which receives the light beams coming from the output ends of the optical fibres, to a light output wall which sends the light beams towards the welding interface. Advantageously, a single optical fibre is associated at its input end with each laser source so as to receive, channel and transmit towards the welding interface, the light beam produced by said corresponding laser source.

Plastic parts are welded in a laser welding system. An infrared laser source in a laser chamber is controlled by a controller using closed-loop feedback control with a corrected feedback signal that is compensated for background infrared radiation in the laser chamber. Prior to the infrared laser source being turned on, the controller senses with the optical sensor an intensity of background infrared radiation in the laser chamber. Once the laser is on, the controller senses with the optical sensor an intensity of infrared laser radiation in the laser chamber. The controller calculates the corrected feedback signal by subtracting the intensity of the background infrared radiation sensed when the infrared laser source was off from the intensity of the infrared laser radiation sensed when the infrared laser source is on.

A light source module includes a light source; an optical fiber configured to guide light output from the light source; a pair of holding members configured to hold both ends of a first portion of the optical fiber such that the first portion extends linearly; a first vibrator configured to vibrate the first portion along a first direction intersecting an extending direction of the first portion; and a second vibrator configured to vibrate the first portion along a second direction intersecting the extending direction and differing from the first direction.

The present invention relates to a method and to a device for assembling together two tubes (1, 2) comprising a tubular junction sleeve and an internal pipe liner tube made of thermoplastic materials by laser welding two contact surfaces of revolution (1-1, 2-1) pressed one against the other at the ends of the tubular sleeve of said liner tube overlapping coaxially.

A seam production machine for joining at least two planar flexible components is provided, wherein at least one of the components includes thermoplastic synthetic material. Included is a machine housing, which is designed with a work surface and a work arm, wherein a retaining bar mounted movably in the longitudinal axis including a seam production tool and a likewise mounted support bar including a component presser element are provided on the work arm, and a support plate for the components, including at least one oscillatingly drivable component feeder is disposed in the work surface, wherein the component presser element is lowerable and acted upon by a force and, when lowered, cooperates with the at least one component feeder. At least one seam pressing ram, serving as the seam production tool, is disposed at the bottom of the retaining bar, wherein a laser beam is directed at the support plate and forms a laser light spot there for plasticizing the synthetic material of at least one of the components.

A welding apparatus for making an automotive light including light guides having an inlet which receives the fibers the laser beam produced by the laser emitting device and an outlet which propagates/transmits the laser beam collimated by said guides. The light guide has respective free ends mechanically separated from each other, wherein the light guides are configured so as to direct collimated light beams on adjacent and locally continuous portions of welding interface so as to obtain a homogeneous and uniform distribution of the light beams along the welding interface.

In an apparatus for successively making plastic bags, a laser beam irradiator irradiates laser beam onto webs of panel material and a body of zipper material to heat and melt the webs of panel material and the body of zipper material with the laser beam. The webs of panel material and the body of zipper material are fed intermittently at a speed predetermined to be changed by time. The irradiator is controlled on a feedforward control basis for the laser beam to be regulated in amount, the amount being calculated from the speed predetermined, to obtain a calculated value of amount. The laser beam is regulated in accordance with the calculated value to heat and melt the webs of panel material and the body of zipper material uniformly irrespective of the speed being changed.

A reinforcement and/or lining method is provided, wherein a thermoplastic reinforcement and/or lining element is subject to mechanical energy impact and mechanical pressure by a tool so that reinforcement and/or lining material of the reinforcement and/or lining element is liquefied and pressed into porous material to reinforce the porous material. In at least one axial depth, the reinforcement and/or lining element is segmented as a function of the circumferential angle so that at this axial depth the circumferential wall of the initial opening in first regions is in contact with the reinforcement and/or lining element and in second regions is not in contact with the reinforcement and/or lining element.

The present disclosure relates more to processes for making a filter element that includes a filter membrane having a strip of thermoplastic polymer material laminated thereto, for example, as a strip along an edge of the filter membrane. For example, one such process includes providing a sheet of filter membrane having a first surface and an opposed second surface; providing a strip of thermoplastic polymer material having a first surface and an opposed second surface; contacting the first surface of the strip of thermoplastic polymer material with the first surface of the filter membrane; and softening the strip of thermoplastic polymer material at at least its first surface by irradiation with laser radiation; such that the softened polymer material of the first surface of the strip of thermoplastic polymer material bonds to the first surface of the filter membrane upon hardening.

The present invention relates to a process for laminating a first substrate, which comprises a thermoplastic polymer material surface, and wherein the first substrate preferably is a thermoplastic polymer film, to a second substrate, wherein the second substrate preferably is a non-woven or woven fabric, wherein the thermoplastic polymer material surface is activated by irradiation with a laser beam prior to laminating the two substrates to each other as well as a device for carrying out such a process.