An integrated liquid-cooling radiator includes a first reservoir, a second reservoir and a plurality of radiating pipes. The first reservoir is made of a heat-dissipating metal material. A first partition is provided in the first reservoir to divide an inside of the first reservoir into a first liquid inlet chamber and a first liquid outlet chamber. A bottom of the first reservoir is provided with a thermally conductive copper sheet. By arranging the thermally conductive copper sheet on the first reservoir to form an integrated structure, the product has a compact structure.

A technique to additively print onto a dissimilar material, especially ceramics and glasses (e.g., semiconductors, graphite, diamond, other metals) is disclosed herein. The technique enables manufacture of heat removal devices and other deposited structures, especially on heat sensitive substrates. It also enables novel composites through additive manufacturing. The process enables rapid bonding, orders-of-magnitude faster than conventional techniques.

A technique to additively print onto a dissimilar material, especially ceramics and glasses (e.g., semiconductors, graphite, diamond, other metals) is disclosed herein. The technique enables manufacture of heat removal devices and other deposited structures, especially on heat sensitive substrates. It also enables novel composites through additive manufacturing. The process enables rapid bonding, orders-of-magnitude faster than conventional techniques.

A heat exchanger has an outer shell enclosing an inner chamber and extending between a first inlet and a first outlet. The chamber receives a separating wall. The shell extends between axial ends, and generally along a helix. The helix is defined with the wall moving in a continuous manner along a first axial direction and with a circumferential component between the first inlet and the first outlet. A plurality of tubes extend through openings in the separating wall and generally along a helix. The plurality of tubes extend from a second inlet and a second outlet, and with the helix defined along the first axial direction and with a component in a circumferential direction. A method and a temperature control system are also disclosed.

A heat exchanger has an outer shell enclosing an inner chamber and extending between a first inlet and a first outlet. The chamber receives a separating wall. The shell extends between axial ends, and generally along a helix. The helix is defined with the wall moving in a continuous manner along a first axial direction and with a circumferential component between the first inlet and the first outlet. A plurality of tubes extend through openings in the separating wall and generally along a helix. The plurality of tubes extend from a second inlet and a second outlet, and with the helix defined along the first axial direction and with a component in a circumferential direction. A method and a temperature control system are also disclosed.

A dual loop type temperature control module and an electronic device testing apparatus having the same are provided. The temperature control module comprises a first loop through which a first working fluid of a first temperature flows, a second loop through which a second working fluid of a second temperature flows, a controller for controlling a first switching valve such that the first or second working fluid flows through a temperature regulating device, and a second switching valve such that the working fluid flowing through the temperature regulating device returns to the first or second loop. The temperature regulating device adjusts a thermoelectric cooling device to reach two different reference temperatures based on the rise/fall of its temperature dependent on the working fluid. The thermoelectric cooling device regulates the temperature of the tested object under a wide range of temperature difference and with accuracy based on the reference temperatures to facilitate the detection of high/low temperature.

A dual loop type temperature control module and an electronic device testing apparatus having the same are provided. The temperature control module comprises a first loop through which a first working fluid of a first temperature flows, a second loop through which a second working fluid of a second temperature flows, a controller for controlling a first switching valve such that the first or second working fluid flows through a temperature regulating device, and a second switching valve such that the working fluid flowing through the temperature regulating device returns to the first or second loop. The temperature regulating device adjusts a thermoelectric cooling device to reach two different reference temperatures based on the rise/fall of its temperature dependent on the working fluid. The thermoelectric cooling device regulates the temperature of the tested object under a wide range of temperature difference and with accuracy based on the reference temperatures to facilitate the detection of high/low temperature.

A chilled beam system may incorporate a terminal unit to provide additional heating and cooling capacity including latent cooling. In a system, terminal units may be distributed and connected to cooperate with a primary air stream from a central air handling unit. The chilled beam and/or terminal units may employ features for enhancing heating mode operation. Control embodiments take advantage of the additional capabilities described.

A shroud that includes a body, a cavity, a curved outlet, and at least one non-linear channel. The body can have a top end and a bottom surface, as well as a first end and a second end located opposite the first end. The cavity can be located under the top end of the body and disposed toward the first end. The curved outlet can be disposed toward the second end of the body and have a banana-shaped vent that traverses at least two sides of the body. Each linear channel can include a bent passage, a third end, and a fourth end, where the third end adjoins the cavity, and where the fourth end adjoins a portion of the banana-shaped vent of the curved outlet. The curved outlet and the at least one non-linear channel can prevent substantially all liquids and solids outside the body from entering the cavity.

A shroud that includes a body, a cavity, a curved outlet, and at least one non-linear channel. The body can have a top end and a bottom surface, as well as a first end and a second end located opposite the first end. The cavity can be located under the top end of the body and disposed toward the first end. The curved outlet can be disposed toward the second end of the body and have a banana-shaped vent that traverses at least two sides of the body. Each linear channel can include a bent passage, a third end, and a fourth end, where the third end adjoins the cavity, and where the fourth end adjoins a portion of the banana-shaped vent of the curved outlet. The curved outlet and the at least one non-linear channel can prevent substantially all liquids and solids outside the body from entering the cavity.