A molded article for laser welding is disclosed which has excellent visible light transmittance and laser transmittance and in which variation in laser transmittance is suppressed, and an agent for suppressing variation in laser transmittance of a molded article for laser welding. The molded article for laser welding includes a polybutylene terephthalate resin composition containing 100 parts by mass of (A) a polybutylene terephthalate resin, (B) a polycarbonate resin in which the melt viscosity at 300 C. and a shear rate of 1000 sec.sup.1 is 0.20 kPa.Math.s or greater, and 1 part by mass or greater and 10 parts by mass or less of (C) an epoxy-based compound, the molded article having a thickness at a welded part of 1.3 mm or greater, and an agent for suppressing variation in laser transmittance of a molded article for laser welding, the agent containing an epoxy-based compound.

A multilayered article for laser marking can comprise: a first layer having a visible transmission of greater than or equal to 80%; a second layer having a visible transmission of greater than or equal to 80%, and wherein the second layer comprises an active component that will form a laser mark with an L* of less than or equal to 40, when exposed to a laser light of a wavelength of greater than 800 nm; a third layer reflective to laser light having a wavelength greater than 800 nm, wherein the third layer has a visible transmission of greater than or equal to 80%; and optionally a substrate; wherein the article comprises a laser mark having an L* of less than or equal to 40 as measured according to CIELAB 1976 (specular included).

Device and method for needle penetrating and filling a chamber with a predetermined substance, and hermetically resealing a resulting needle hole in the device by applying radiation thereto. The needle penetrable and resealable portion defines a predetermined wall thickness in an axial direction thereof, and may include a thermoplastic that substantially prevents the formation of particles released into the chamber from the needle penetrable and resealable portion during penetration by and withdrawal of the needle. Such thermoplastic may include a predetermined amount of pigment that allows the thermoplastic to substantially absorb laser radiation at a predetermined wavelength, substantially prevent the passage of radiation through the predetermined wall thickness thereof, and hermetically seal a needle aperture formed in the needle penetration region thereof in a predetermined time period.

A method of sealing a container and a lid by melt adhesion by laser. Either the container or the lid has a thermoplastic resin that permits the laser beam to transmit through and the other one has a resin composition of the thermoplastic resin containing a heat-generating substance. Further, the laser beam applies a rectangular beam having a uniform intensity distribution. The upper-limit of temperature is not lower than a melting point of the thermoplastic resin but lower than a thermal decomposition start temperature thereof in the melt adhesion interface between the container and the lid, and the temperature reaches the upper-limit in a heating time t (msec) represented by the following formula (1),
t (msec)=L/S(1)
where L is the length (mm) of the rectangular beam in the scanning direction, and S is the rate of laser scanning (mm/msec) of not higher than 1.65 mm/msec.

This invention provides a process and device for simultaneous laser welding; after using the moving lower die and the fixing upper die to make the base and the lens attached, by using the light pipe, for example, transparent substances or other cheap materials, to make the laser, which is emitted from the laser source, emit through the lens to a welding region of the base after being processed, to operate rapid and average heating to the welding region; meanwhile, using the welding cylinder to press the base and the lens together, to make base and the lens pressed and welded together in molten state, and when welding, it does not generate powder or other defects, and, at the same time, it can make the height H and the width w of the generated waste selvage between [0, 0.4] mm, which can improve the performance of welding object more efficiently.

Method for manufacturing a composite work piece for a drug delivery device, comprising the steps: Providing a first work piece part 1 and a second work piece part 2, arranging both work piece parts 1, 2 with respect to each other in such a way that both work piece parts 1, 2 are in mechanical contact with one another in a contact area 3, irradiating a surface of the first work piece part 1 with electromagnetic radiation, thereby softening the first work piece part 1 and/or the second work piece part 2 in a region adjacent to the contact area 3, and joining the first work piece part 1 to the second work piece part 2 in the contact area 3 for the composite work piece. Furthermore, a composite work piece for a drug delivery device is provided.

[Object] To provide a sensor module and a method for producing the sensor module, the sensor module making it possible to improve a degree of freedom in design, to facilitate the operation, and to reduce costs by reducing the number of components. [Solving Means] A sensor module according to an embodiment of the present technology includes a first member, a second member, a third member, and a sensor element. The first member is made of a synthetic resin material that has absorptive properties with respect to first laser light. The second member is made of a synthetic resin material that has transmissive properties with respect to second laser light of a wavelength that is different from a wavelength of the first laser light. The third member is made of a synthetic resin material that has transmissive properties with respect to the first laser light and has absorptive properties with respect to the second laser light, the third member including a first surface and a second surface, the first surface including a first welding portion that is welded to the first member, the second surface including a second welding portion that is welded to the second member.

A multilayer structure selected from a reservoir, a pipe or a tube, for transporting, distributing or storing hydrogen, including, from the inside to the outside, at least one sealing layer and at least one composite reinforcing layer, the innermost composite reinforcing layer being welded to the outermost adjacent sealing layer, the sealing layers including at least one semi-crystalline thermoplastic polymer, the Tm of which is less than 280 C., wherein the at least one thermoplastic polymer of each sealing layer may be the same or different, and at least one of the composite reinforcing layers being of a fibrous material in the form of continuous fibers impregnated with a composition of at least one thermoplastic polymer P2j, the thermoplastic polymer P2j having a Tg greater than the maximum temperature of use of said structure (Tu), with TgTu+20 C., Tu being greater than 50 C.

A fluidic device including an inorganic solid support attached to an organic solid support by a bonding layer, wherein the inorganic solid support has a rigid structure and wherein the bonding layer includes a material that absorbs radiation at a wavelength that is transmitted by the inorganic solid support or the organic solid support; and a channel formed by the inorganic solid support and the organic solid support, wherein the bonding layer that attaches the inorganic solid support to the organic solid support provides a seal against liquid flow. Methods for making fluidic devices, such as this, are also provided.

A method includes arranging at least one laser-weldable conduit along a contact interface with a laser-weldable polymer film layer of a seat inflatable bladder carrier, directing a laser beam at the laser-weldable polymer film layer, and moving the laser beam along a welding path that intersects the contact interface. The laser beam penetrates through the laser-weldable polymer film layer and impinges the at least one laser-weldable conduit. The laser beam causes localized heating and welding along the weld path at the contact interface, to fuse the laser-weldable polymer film layer and the conduit together.