The present invention discloses a method for preparing an evaporator for reducing water condensing capacity and an evaporator. The preparation method comprises steps of: step A: selecting fins; step B: stacking; step C: arranging tubes; and, step D: expanding tubes. In accordance with the present invention, the existing fins and devices can be used to produce an evaporator in which the distance between two adjacent fins satisfies the requirements of the freezing operation, ensuring the normal operation of an air conditioner when the refrigeration temperature is below 0° C.

A multi-thermal characteristic heat sink fin, comprising a first heat spreading plate, a second heat spreading plate, and a primary heat spreading plate is provided. A plurality of multi-thermal characteristic heat sink fins is assembled together to form a heat sink, further having at least a heat pipe assembled therethrough, and a base plate, assembled to the at least a heat pipe and in contact with a heat source. The primary heat spreading plate is sandwiched and enclosed within the first and second heat spreading plates, hindering debris, contaminants, and moisture from entering the surface interfaces therebetween. The material of the heat pipes and primary heat spreading plate is different from that of the first and second heat spreading plates. No heat treatment process of two or more different materials is required for assembly of the multi-thermal characteristic heat sink fin and at least a heat pipe assembled thereto.

The disclosure provides a heat exchanger connecting device and a heat exchanger. The heat exchanger connecting device includes a first sheet body and a second sheet body, wherein a plurality of protrusions are provided in a length direction of the first sheet body and the second sheet body, each of a plurality protrusions is provided with a through hole cooperating with a heat exchange tube, and the first sheet body and the second sheet body are buckled and fixed together. The connecting device in the disclosure can reduce the manufacturing cost and meet the requirements of mass production, is economical, allows the size of a flat tube micro-channel heat exchanger to be increased, and is not limited by the size of a stamping forming process, thereby economically solving the problem of the size of a heat exchanger, and increasing the application range of a product.

Disclosed are a heat exchange tube, a processing method for same, and a heat exchanger having same. The heat exchange tube (10a, 10b, 10c, 10d, 10e) includes a body portion (11a, 11b, 11c, 11d, 11e) provided with a plurality of flow channels (111a, 111b, 111c, 111d, 111e) arranged in parallel and spaced apart with each other, the length direction of the flow channel (111a, 111b, 111c, 111d, 111e) being parallel to the length direction of the body portion (11a, 11b, 11c, 11d, 11e); at least one side of the body portion (11a, 11b, 11c, 11d, 11e) is provided with an extension portion (12a, 12b, 12c, 12d, 12e) along the width direction of the body portion (11a, 11b, 11c, 11d, 11e); and the extension portion (12a, 12b, 12c, 12d, 12e) and at least part of the body portion (11a, 11b, 11c, 11d, 11e) are formed by folding the same plate material.

The present invention discloses a method for preparing an evaporator for reducing water condensing capacity and an evaporator. The preparation method comprises steps of: step A: selecting fins; step B: stacking; step C: arranging tubes; and, step D: expanding tubes. In accordance with the present invention, the existing fins and devices can be used to produce an evaporator in which the distance between two adjacent fins satisfies the requirements of the freezing operation, ensuring the normal operation of an air conditioner when the refrigeration temperature is below 0° C.

An electronic device includes an outer case, a heat generating component and a heat dissipating module. The heat generating component is disposed inside the outer case. The heat dissipating module is located between the outer case and the heat generating component and includes a heat conducting assembly including a first heat conducting portion fixed on the outer case and connected to the outer case and a second heat conducting portion connected to the first heat conducting portion and for abutting against the heat generating component. The second heat conducting portion is movable relative to the outer case for moving toward or away from the outer case. The heat conducting assembly is resiliently deformed to apply a force on the heat generating component in a contacting manner when the heat generating component pushes the second heat conducting portion of the heat conducting assembly to move toward the outer case.

A heat exchanger includes: a heat exchange core portion; and a tank portion connected to the heat exchange core portion. The heat exchange core portion has a connection plate that surrounds a part of the tank portion from an outer peripheral side. The connection plate has slit-shaped openings arranged along an edge of the connection plate in a first direction. A part of the connection plate between each of the openings and the edge is deformable into a concave shape toward the tank portion. A part of the openings has a widened portion at both ends in the first direction. A width dimension of the widened portion in a second direction from the opening to the edge is larger than that of the other portion of the opening.

A heat exchanger has a collecting pipe, a separator and a number of heat exchange tubes. The collecting pipe has a pipe wall and an inner cavity. The separator is provided in the inner cavity. The separator extends along a lengthwise direction of the collecting pipe. The separator divides the collecting pipe into a first cavity and a second cavity. The heat exchange tubes are arranged along the lengthwise direction. Each heat exchange tube has a first end and an inner cavity. The first end of the heat exchange tube sequentially passes through the pipe wall of the collecting pipe, the first cavity and the separator to be inserted into the second cavity. The inner cavity of the heat exchange tube is communicated with the second cavity. As a result, uniformity of refrigerant distribution in the heat exchanger is improved.

A heat exchanger has a turbulating insert arranged between a pair of plates. The turbulating insert is permeable to fluid flow in both a high-pressure-drop direction and a low-pressure drop direction. One portion of the turbulating insert has the high-pressure-drop direction oriented at a non-zero angle to the high-pressure-drop direction of another portion. A method of making the heat exchanger includes forming a turbulating insert, removing a portion of the turbulating insert to create a cavity within the turbulating insert, placing the remaining turbulating insert into a stamped first plate, and placing the removed portion of the turbulating insert into the cavity at a non-zero angle of rotation relative to the remaining turbulating insert.

An electronic device includes an outer case, a heat generating component and a heat dissipating module. The heat generating component is disposed inside the outer case. The heat dissipating module is located between the outer case and the heat generating component and includes a heat conducting assembly including a first heat conducting portion fixed on the outer case and connected to the outer case and a second heat conducting portion connected to the first heat conducting portion and for abutting against the heat generating component. The second heat conducting portion is movable relative to the outer case for moving toward or away from the outer case. The heat conducting assembly is resiliently deformed to apply a force on the heat generating component in a contacting manner when the heat generating component pushes the second heat conducting portion of the heat conducting assembly to move toward the outer case.