The invention relates to a device (1) for use in the production of a tube bundle (3) of a wound heat exchanger (100), wherein tubes (30) are wound in a plurality of tube layers (4) onto a core tube (300) running in an axial direction (z), webs (10) which run in the axial direction (z) being arranged between the tube layers (4). The invention further relates to a method for producing a tube bundle using said device (1).

The invention relates to a device (1) for use in the production of a tube bundle (3) of a wound heat exchanger (100), wherein tubes (30) are wound in a plurality of tube layers (4) onto a core tube (300) running in an axial direction (z), webs (10) which run in the axial direction (z) being arranged between the tube layers (4). The invention further relates to a method for producing a tube bundle using said device (1).

A counterflow heat transfer system comprises a heat exchanger and a flow controller arranged to convey a first fluid through the heat exchanger in a first flow direction and a second fluid through the heat exchanger in a second counterflow direction. The heat exchanger comprises at least one first thermally conductive tube conveying the first fluid and at least one second thermally conductive tube conveying the second fluid. The first and second tubes are wound around one another and in contact with one another in an entwined tubular arrangement.

A counterflow heat transfer system comprises a heat exchanger and a flow controller arranged to convey a first fluid through the heat exchanger in a first flow direction and a second fluid through the heat exchanger in a second counterflow direction. The heat exchanger comprises at least one first thermally conductive tube conveying the first fluid and at least one second thermally conductive tube conveying the second fluid. The first and second tubes are wound around one another and in contact with one another in an entwined tubular arrangement.

Method for manufacturing a finned tube, in which a tube base body is finned on its outside, in particular helically, by a band, to which end the band is taken to the tube base body using a guide element and is attached to the base body, in particular by means of a laser beam, characterized in that the guide element is adjusted in particular in respect of its orientation relative to the tube base body during the attachment process.

A control method for a winding wire manufacturing device that includes a base, a clamp, a bending top and a controller, includes a first process of detecting a bending torque applied to the bending top at the time of edgewise bending, a second process of determining whether or not a maximum value obtained by removing a torque value in starting the bending top from the bending torque is equal to or smaller than a predetermined value set in advance, and a third process of reducing a clamp load applied to a rectangular wire by the clamp when the maximum value of the bending torque is larger than the predetermined value.

A manufacturing method for a pipe structure includes a pipe bending step for implementing for a plurality of times a bending process of bending a part of a straight pipe by wrapping the part around a peripheral surface of a rolling block to form a plurality of bend portions in intermediate locations along a longitudinal direction of the pipe. When a final bending process is implemented during the pipe bending step, a position of a rear end portion of the pipe is determined, and relative positions of the pipe and the rolling block in a predetermined y direction are controlled on the basis of the position of the rear end portion so that after the bending process, a y-direction position of the rear end portion is aligned with a y-direction position of the front end portion. According to this configuration, complicated operations such as cutting the respective end portions of the pipe after bending the pipe can be eliminated, and a pipe structure such as a meandering pipe body in which the positions of the respective end portions are aligned can be manufactured appropriately and with favorable productivity.

Device for the production of selectively configured roll assemblies of expanded aluminium mesh (17) adapted to efficiently fill fuel containers and provide suppression of ignition and combustion of the fuel contained therein, comprising a roll (1) of in expanded aluminium mesh at an inlet of the device, a mechanism (5) for providing tensioning of a mesh web (15) flowing from the inlet to the outlet of the device, a mechanism (6) for forwardly moving mesh web (15), a mechanism (7) for transversely cutting a predetermined portion of mesh web (15), a mechanism (8) that securely folds the edge of the transversely cut end of mesh web (15) and a mechanism (10) wherein a mesh roll assembly (16) is set up onto a disc (12c) that rotates to wind a predetermined number of turns of mesh web (15) around mesh roll assembly (16) and provide an end product of roll assembly of expanded aluminium mesh (17).

Device for the production of selectively configured roll assemblies of expanded aluminium mesh (17) adapted to efficiently fill fuel containers and provide suppression of ignition and combustion of the fuel contained therein, comprising a roll (1) of in expanded aluminium mesh at an inlet of the device, a mechanism (5) for providing tensioning of a mesh web (15) flowing from the inlet to the outlet of the device, a mechanism (6) for forwardly moving mesh web (15), a mechanism (7) for transversely cutting a predetermined portion of mesh web (15), a mechanism (8) that securely folds the edge of the transversely cut end of mesh web (15) and a mechanism (10) wherein a mesh roll assembly (16) is set up onto a disc (12c) that rotates to wind a predetermined number of turns of mesh web (15) around mesh roll assembly (16) and provide an end product of roll assembly of expanded aluminium mesh (17).

A helicoidal blade system is presented having an armature to facilitate bending of metal stock to form helicoidal blades. In one or more embodiments, the armature has an exterior surface that is generally conical in shape and includes a guide structure and an engagement track. The helicoidal blade system also includes drive coupler and motor that are operably coupled together. The drive coupler is configured to engage the engagement track of the conical armature and rotate the conical armature when the motor is operated. A blade metal feed apparatus is configured to feed the metal stock into the helical shaped guide structure as the conical armature is rotated. As the conical armature is rotated, the metal stock is bent around the armature within the helical shaped guide structure to form one or more helicoidal blades.