A method of at least partially filling an opening in a workpiece made of metal, the opening being at least partially defined by one or more opening walls having one or more opening wall surfaces. The method includes providing an insert bondable with the workpiece, the insert having one or more insert engagement surfaces formed for engagement with the opening wall surface. The opening wall surface and the insert engagement surface are heated to a hot working temperature. The insert is subjected to an engagement motion, to move the insert engagement surface relative to the opening wall surface. While the insert is subjected to the engagement motion, the insert is also subjected to a translocation motion to move the insert at least partially into the opening, for engaging the insert engagement surface with the opening wall surface, for at least partially creating a metallic bond between the insert and the workpiece.

A method of at least partially filling an opening in a workpiece made of metal, the opening being at least partially defined by one or more opening walls having one or more opening wall surfaces. The method includes providing an insert bondable with the workpiece, the insert having one or more insert engagement surfaces formed for engagement with the opening wall surface. The opening wall surface and the insert engagement surface are heated to a hot working temperature. The insert is subjected to an engagement motion, to move the insert engagement surface relative to the opening wall surface. While the insert is subjected to the engagement motion, the insert is also subjected to a translocation motion to move the insert at least partially into the opening, for engaging the insert engagement surface with the opening wall surface, for at least partially creating a metallic bond between the insert and the workpiece.

In order to reduce the adverse effect from a thermal medium splashing as a result of a vapor chamber bursting, this protective structure is provided with a perforation member comprising an end section that: comprises an upper surface and a lower surface; either comes into contact with a first surface, which is either the upper surface or the lower surface, or is located near the first surface, before a flat vapor chamber in contact with an electronic component is overheated by heat from the electronic component; and breaks an outer member of the vapor chamber and penetrates into the interior when the vapor chamber is overheated by the heat.

In order to reduce the adverse effect from a thermal medium splashing as a result of a vapor chamber bursting, this protective structure is provided with a perforation member comprising an end section that: comprises an upper surface and a lower surface; either comes into contact with a first surface, which is either the upper surface or the lower surface, or is located near the first surface, before a flat vapor chamber in contact with an electronic component is overheated by heat from the electronic component; and breaks an outer member of the vapor chamber and penetrates into the interior when the vapor chamber is overheated by the heat.

A process for joining steel plate includes providing a steel plate and joining the steel plate to another material. The steel plate includes at least one surface having an Al—Si coating. The step of joining the steel plate to another material is performed while the steel plate is in an as- coated condition. Joining is performed using a forging process.

A system for securing first and second metal workpieces to a central metal workpiece located therebetween. The system includes clamps to secure the first and second metal workpieces in coaxial alignment with the central metal workpiece, which is rotatable about its axis. Heating elements heat opposed ends of the first metal workpiece and the central metal workpiece, and opposed ends of the second metal workpiece and the central metal workpiece, to a hot working temperature. While the opposed ends are at the hot working temperature, the heating elements are removed. The opposed end of the first metal workpiece is urged against the end opposed thereto of the rotating central metal workpiece, while the central metal workpiece rotates. At the same time, the rotating central metal workpiece is pulled against the second metal workpiece to engage the opposed ends thereof with each other. The workpieces are then allowed to cool.

A method of manufacturing a heat exchanger is provided. The method includes forming a first substrate by additively manufacturing a body defining a first outer surface and a second outer surface opposite the first outer surface, a first partial fluid flow channel formed within the first outer surface, a second partial fluid flow channel formed within the second outer surface, and at least one internal fluid flow channel completely formed within the body, and coupling the first substrate to a second substrate including a partial fluid flow channel formed within a surface of the second substrate such that the first partial fluid flow channel of the first substrate and the partial fluid flow channel of the second substrate combine to form a combined fluid flow channel.

A method of manufacturing a heat exchanger is provided. The method includes forming a first substrate by additively manufacturing a body defining a first outer surface and a second outer surface opposite the first outer surface, a first partial fluid flow channel formed within the first outer surface, a second partial fluid flow channel formed within the second outer surface, and at least one internal fluid flow channel completely formed within the body, and coupling the first substrate to a second substrate including a partial fluid flow channel formed within a surface of the second substrate such that the first partial fluid flow channel of the first substrate and the partial fluid flow channel of the second substrate combine to form a combined fluid flow channel.

A method for forming a metal flow module includes stacking together a first metal plate having opposing first and second major surfaces and one or more flow channels defined at least in part in the first major surface with a second metal plate having opposing first and second major surfaces, the plates stacked together with their respective first major surfaces facing each other and with a layer of flux positioned in between contacting portions of the respective first major surfaces defined as those portions of the respective first and second major surfaces which would be in contact absent the flux; then heating the plates together in a non-oxidizing atmosphere to thermally bond the contacting portions of the respective first major surfaces of the first and second metal plates. Resulting modules are also disclosed.

A method for forming a metal flow module includes stacking together a first metal plate having opposing first and second major surfaces and one or more flow channels defined at least in part in the first major surface with a second metal plate having opposing first and second major surfaces, the plates stacked together with their respective first major surfaces facing each other and with a layer of flux positioned in between contacting portions of the respective first major surfaces defined as those portions of the respective first and second major surfaces which would be in contact absent the flux; then heating the plates together in a non-oxidizing atmosphere to thermally bond the contacting portions of the respective first major surfaces of the first and second metal plates. Resulting modules are also disclosed.