A first resin member including a first contact surface and formed of laser beam-transmissive resin and a second resin member including a second contact surface, which contacts the first contact surface, and formed of laser beam-absorbing resin are arranged one upon the other. A laser welding apparatus includes a clamping unit abutting the second resin member and applying clamping force to the second resin member, a laser emitter emitting laser beam, a laser controller controlling output of the laser beam, a displacement sensor measuring displacement of the second contact surface in stacking direction of the resin members, and a control unit controlling the clamping unit to adjust the clamping force corresponding to displacement amount of the second contact surface continuously or intermittently obtained from the displacement sensor.

A method for producing a component from two or more sub-components includes the steps of: producing each of the sub-components using an additive manufacturing process in which a resin, which is radiant-energy-curable, is partially cured using a selective application of radiant energy, wherein each sub-component includes a joint surface in which the resin is partially cured which is cured to a lesser degree than the remainder of the respective sub-component, so as to leave the joint surfaces in a condition suitable for bonding; assembling the sub-components with their respective joint surfaces in mutual contact; and performing a secondary cure of the partially-cured resin at the joint surfaces using an application of radiant energy, so as to further cure the partially-cured resin and bond the sub-components to each other, thereby forming the component.

The present invention relates to an apparatus and method for joining a longitudinal seam in a tube, to an apparatus and method of joining a longitudinal seam in a tube in a borehole, to an apparatus and method of repairing a tube and to a pig. In an aspect an apparatus is provided for joining a longitudinal seam in a tube. The apparatus (200) includes a spool (202) for progressively unwinding a coiled member (10) into an extended form (12). The member (10) transitions from a flat form when coiled (11) to a slit tube form when extended (12), in which form the member is resiliently biased. A joining device (214) is positioned downstream of the spool arranged to provide energy to a portion of the member in its extended form to cause heating so as to progressively join together the longitudinal edges of the slit tube as the member passes the joining device. A longitudinal seam (20) is thereby formed in the tube.

A method of making a flowcell includes bonding a first surface of an organic solid support to a surface of a first inorganic solid support via a first bonding layer, wherein the organic solid support includes a plurality of elongated cutouts. The method further includes bonding a surface of a second inorganic solid support to a second surface of the organic solid support via a second bonding layer, so as to form the flowcell. The formed flowcell includes a plurality of channels defined by the surface of the first inorganic solid support, the surface of the second inorganic solid support, and walls of the elongated cutouts.

A connection element for adhering to a component surface of a first component, such that a second component can be secured to the first component by the connection element, including a base element having an adhesive side with an adhesive surface, and a mounting structure. The base element consists of a thermoplastic with a temperature of continued use of at least 130° C., which can be poorly irradiated or cannot be irradiated with light, and has at least one irradiation region. The base element can be irradiated with light in this region in such a way that light energy penetrates the base element. The irradiation region, in cross-section, has a smaller thickness and a transmittance at least 20% with a light wavelength between 320 and 500 nm. Alternatively, the irradiation region is formed by a through-opening.

[Problem] To bond an electronic component on a substrate via an adhesive material satisfactorily. [Solution] A bonding device 10 for thermally bonding an electronic component 100 to a substrate 110 or to another electronic component via an adhesive material 112, the bonding device being provided with: a bonding tool 40 comprising a bonding distal-end portion 42 which includes a bonding surface 44 and tapered side surfaces 46 formed in a tapering shape becoming narrower toward the bonding surface 44, the bonding surface 44 having a first suction hole 50 for suction-attaching the electronic component 100 via an individual piece of a porous sheet 130, the tapered side surfaces 46 having second suction holes 52, 54 for suction-attaching the porous sheet 130; and a bonding control unit 30 which controls the first suction hole 50 and the second suction holes 52, 54 independently from each other.

[Problem] To bond an electronic component on a substrate via an adhesive material satisfactorily.

[Solution] A bonding device 10 for thermally bonding an electronic component 100 to a substrate 110 or to another electronic component via an adhesive material 112, the bonding device being provided with: a bonding tool 40 comprising a bonding distal-end portion 42 which includes a bonding surface 44 and tapered side surfaces 46 formed in a tapering shape becoming narrower toward the bonding surface 44, the bonding surface 44 having a first suction hole 50 for suction-attaching the electronic component 100 via an individual piece of a porous sheet 130, the tapered side surfaces 46 having second suction holes 52, 54 for suction-attaching the porous sheet 130; and a bonding control unit 30 which controls the first suction hole 50 and the second suction holes 52, 54 independently from each other.

The fluid connecting system comprises a connecting piece (16) that consists of a single injection-molded part of plastic material, said part accommodating a coaxial first fluid conveying arrangement (15), as well as an also coaxial second fluid conveying arrangement (17) and providing several adhesive reservoirs that allow a pressure-resistant gluing of the two fluid conveying arrangements (15, 17) to each other by a reliable safe process.

A welding method heats a surface to be welded of a continuous strip member with a laser beam. The welding method pressurizes the strip member and a continuous film to weld the surface to the film, when or after heating the surface with the laser beam. The welding method preheats the surface before heating the surface with the laser beam. A welding device includes a heat device having an infrared light source disposed to extend along a feed path for the strip member. The heat device is configured to irradiate the surface with infrared light to heat the surface with infrared light. The welding device includes a pressure device configured to pressurize the strip member and the film to weld the surface to the film.

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.