Various embodiments of thermal compression bonding transient cooling solutions are described. Those embodiments include a an array of vertically separated micro channels coupled to a heater surface, wherein every outlet micro channel comprises two adjacent inlet micro channel, and wherein an inlet and outlet manifold are coupled to the array of micro channels, and wherein the heater surface and the micro channels are coupled within the same block.

A brazing system according to an embodiment of the present invention, which is for brazing an object to be bonded to a base material, comprises: a turntable provided with a reception part for receiving the base material and rotatable clockwise or counterclockwise; a base material supply device for supplying the base material to the reception part; a brazing filler metal supply device for supplying a brazing filler metal to an upper side of the base material; a first heating device for bonding the brazing filler metal to the base material; a bonding object supply device for supplying the object to be bonded to an upper side of the brazing filler metal bonded to the base material; a second heating device which is in contact with opposite sides of the base material to fix the base material and is provided with electrodes for supplying electric current to the base material so as to bond the object to be bonded to the base material; and a cooling device which comes into contact with the object to be bonded to cool the object to be bonded.

A cooling module, according to an embodiment of the present disclosure, for cooling an object to be brazed comprises: a body part having a contact part in contact with the object to be brazed, and cooling the object to be brazed; a first nipple connected to one side of the body part, and having a first supply flow path for receiving fluid from the outside; and a second nipple connected to the other side of the body part, and having a first discharge flow path for discharging the fluid to the outside, wherein the body part includes: a second supply flow path formed inside the body part so as to be connected to the first supply flow path; a second discharge flow path formed inside the body part so as to be connected to the first discharge flow path; and a connection flow path positioned to be adjacent to the contact part of the body part, and connecting the second supply flow path and the second discharge flow path.

Method for cooling soldered printed circuit board modules in a cooling zone of a soldering system, wherein at least one cooling gas comprising inert gas is introduced into the cooling zone, wherein the printed circuit boards are conveyed continuously from a soldering zone of the soldering system into the cooling zone, wherein the cooling gas is generated using liquid cooling gas. The method according to the invention and the device (1) according to the invention advantageously permit highly efficient cooling of printed circuit board modules after the soldering process. The cooling gas may advantageously be used for inerting the soldering system (2) after extraction from the cooling zone (15).

A heat-bonding apparatus and method of manufacturing a heat-bonded product not allowing the temperature of the object to be heat-bonded to overshoot greatly from a specified target temperature, and setting the temperature of the object to the target temperature in a shorter time and with higher efficiency and accuracy than the conventional when heat-bonding in vacuum. A heat-bonding apparatus having a vacuum chamber for housing an object to be heat-bonded and a buffer part, a heater for the buffer part in contact with the object in the chamber, a cooler for the buffer part, a sensor for detecting temperature of the object heated through the buffer part and a controller for controlling the temperature of the object to be the target temperature by adjusting heat discharge from the buffer part with the cooler based on the detected temperature of the object.

An atomization mechanism for cooling a bond head comprises an atomization module and a conduit. In use, the atomization module receives gas and liquid from a gas supply and a liquid supply respectively to form an atomized spray and the conduit conveys the atomized spray from the atomization module to a spray inlet located at the bond head to receive the atomized spray into the bond head for cooling the bond head.

The apparatus serves for inhomogeneous cooling of a flat object with a first main face and a second main face opposite the first main face. The flat object is cooled by a cooling device from the direction of the first main face. On the second main face, a heating device locally acts upon a first partial face in such a way that the flat object is subjected to heat at said first partial face relative to a second partial face adjoining said first partial face in such a way that said first partial face is cooled more slowly in comparison with the second partial face and, during the cooling process, the second main face of the flat object therefore has an inhomogeneous temperature distribution at least in a partial time period of the cooling.

A solder reflow apparatus includes a vapor generating chamber configured to accommodate a heat transfer fluid and to be filled with saturated vapor generated when the heat transfer fluid is heated; a heater configured to heat the heat transfer fluid to generate saturated vapor; a substrate stage configured to be moved up and down within the vapor generating chamber and configured to support a substrate on which an electronic component is mounted via solder; a cleaning portion installed in an upper portion of the vapor generating chamber, wherein the cleaning portion is configured to spray a cleaning fluid onto the substrate on the substrate stage, wherein the cleaning fluid includes a material the same as the heat transfer fluid; and a guide structure configured to collect the cleaning fluid sprayed onto the substrate on the substrate stage and to direct the cleaning fluid to a reservoir that contains the heat transfer fluid.

An electronic apparatus includes a first electronic part with a first terminal, a second electronic part with a second terminal opposite the first terminal, and a joining portion which joins the first terminal and the second terminal. The joining portion contains a pole-like compound extending in a direction in which the first terminal and the second terminal are opposite to each other. The joining portion contains the pole-like compound, so the strength of the joining portion is improved. When the first terminal and the second terminal are joined, the temperature of one of the first electronic part and the second electronic part is made higher than that of the other. A joining material is cooled and solidified in this state. By doing so, the pole-like compound is formed.

An electronic apparatus includes a first electronic part with a first terminal, a second electronic part with a second terminal opposite the first terminal, and a joining portion which joins the first terminal and the second terminal. The joining portion contains a pole-like compound extending in a direction in which the first terminal and the second terminal are opposite to each other. The joining portion contains the pole-like compound, so the strength of the joining portion is improved. When the first terminal and the second terminal are joined, the temperature of one of the first electronic part and the second electronic part is made higher than that of the other. A joining material is cooled and solidified in this state. By doing so, the pole-like compound is formed.