"heat sink extrusion"
Found 59 製品
アルミニウム合金押出ヒートシンク ユニバーサル工業用粉体塗装
Aluminum Alloy Extruded Universal Industrial High-Efficiency Heat Sink 1. High temperature precision extrusion process: core forming, laying the foundation for heat dissipation Integrated extrusion molding: After heating and softening the 6063/6061 aluminum rod, the integrated structure of the substrate and fins is extruded in one go through a 10000 ton extruder and customized mold. No splicing or welding, eliminating contact thermal resistance from the root, and improving
PCB冷却アルミニウム押出ヒートシンク 青アルマイト ストレートフィン
Anodized Blue Aluminum Extrusion Heat Sink with Straight Fins for PCB Cooling This Anodized Blue Aluminum Extrusion Heat Sink with Straight Fins is specifically engineered for PCB thermal management, delivering efficient passive heat dissipation to maintain optimal operating temperatures for printed circuit boards and their mounted electronic components. Crafted from high-thermal-conductivity aluminum alloy via precision extrusion, its uniform straight fin array maximizes
調整可能な寸法 効率的な熱消耗とパワー半導体のための黒色アノイド表面のアルミニウムヒートシンク
Aluminum Heat Sink Power Semiconductors For New Energy Inverter Advanced aluminum heat sink solutions designed specifically for power semiconductors in new energy inverters, featuring precision manufacturing processes and optimized thermal performance. 1. Integrated Extrusion Molding Process Utilizes precise extrusion molding with specialized molds to create radiator fins integrated with the base without splicing. This eliminates faults and gaps in heat conduction, significan
工業用電源装置のための高硬度アルミニウム排出式熱槽
High Rigidity Extruded Aluminum Heat Sink For Industrial Power Unit 1. Integrated extrusion molding process Adopting precise extrusion molding with molds, the radiator fins are integrated with the base without splicing, and there are no faults or gaps in heat conduction, greatly improving heat transfer efficiency; Multiple structures such as dense teeth, wide surfaces, and irregular shapes can be formed at once. The fin pitch is uniform and the thickness is consistent,
カスタマイズ可能な寸法 効率的な熱放散と新エネルギーインバータ用の黒色陽極酸化表面を備えたアルミニウム製ヒートシンク
Aluminum Heat Sink Material For New Energy Inverter Integrated Extrusion Molding Process Adopting precise extrusion molding with molds, the radiator fins are integrated with the base without splicing, eliminating faults or gaps in heat conduction to greatly improve heat transfer efficiency. Multiple structures including dense teeth, wide surfaces, and irregular shapes can be formed at once with uniform fin pitch and consistent thickness, maximizing heat dissipation area
産業用電源用ハイパワー 6063 アルミニウム押出ヒートシンク
High Power 6063 Aluminum Extrusion Heat Sink for Industrial Power Supplies Engineered for high-performance thermal management, this high-power heat sink is precision-extruded from 6063-T5 aluminum alloy, offering excellent thermal conductivity and structural integrity for demanding industrial power supply applications. The high-density fin design maximizes surface area, enabling efficient heat dissipation and stable operating temperatures under continuous high-load conditions
カスタマイズ可能な寸法 効率的な熱放散と新エネルギーインバータ用の黒色陽極酸化表面を備えたアルミニウム製ヒートシンク
Aluminum Die Casting Heat Sink For New Energy Inverter Advanced Manufacturing Processes 1. Integrated Extrusion Molding Process Utilizing precise extrusion molding with specialized molds, the radiator fins are integrated with the base without splicing, eliminating faults or gaps in heat conduction to significantly improve heat transfer efficiency. Multiple structural configurations including dense teeth, wide surfaces, and irregular shapes can be formed in a single operation.
新エネルギーインバーター向けの効率的な放熱と黒色陽極酸化表面を備えたカスタマイズ可能なアルミニウム ヒートシンク
Aluminum Heat Sink Suppliers For New Energy Inverter Integrated Extrusion Molding Process Adopting precise extrusion molding with molds, the radiator fins are integrated with the base without splicing, eliminating faults or gaps in heat conduction to greatly improve heat transfer efficiency. Multiple structures including dense teeth, wide surfaces, and irregular shapes can be formed at once with uniform fin pitch and consistent thickness, maximizing heat dissipation area
産業用キャビネットのための大きな熱消耗高性能熱シンク
Large Heat Dissipation High Power Heat Sink For Industrial Cabinet 1.Integrated extrusion dense tooth process Adopting aviation grade aluminum alloy integrated extrusion forming dense tooth structure, with uniform tooth pitch and maximum heat dissipation area, without splicing faults for smoother heat conduction, and directly improving heat dissipation efficiency by more than 30%. Suitable for industrial cabinets, photovoltaic inverters, general high-power industrial control
データセンター機器用 高適応性 高出力ヒートシンク 1000W
High Adaptability High Power Heat Sink For Data Center Equipment 1.Integrated extrusion dense tooth process Adopting aviation grade aluminum alloy integrated extrusion forming dense tooth structure, with uniform tooth pitch and maximum heat dissipation area, without splicing faults for smoother heat conduction, and directly improving heat dissipation efficiency by more than 30%. Suitable for industrial cabinets, photovoltaic inverters, general high-power industrial control
電源装置冷却用押出ユニバーサル高効率ヒートシンク
Extruded Universal High-Efficiency Heat Sink For Power Supply Equipment Cooling Engineered for peak thermal performance in power supply units (PSUs), chargers, and industrial power converters, this extruded universal heat sink delivers exceptional heat dissipation to safeguard critical electronic components. Crafted from high-purity aluminum alloy via precision extrusion technology, it features a dense array of optimized fins that maximize surface area for rapid heat transfer
工業機械用空冷アルミニウム熱管熱槽
Heat Pipe Air Cooled Aluminum Heat Sink For Industrial Machinery 1. Vacuum sintering process for heat pipes The heat pipe is vacuum sintered into a capillary structure, combined with a high thermal conductivity working fluid, to achieve lossless and ultra fast heat conduction, with a thermal conductivity efficiency far exceeding that of pure metals. It can instantly absorb the concentrated heat source of the equipment and quickly transfer it to the heat dissipation end.