 |
VC004
| Quantity: | |
|---|---|
Ultra-High-Density Heat Dissipation Array: Employs 0.2mm ultra-thin aluminum sheets in an interlocking zipper arrangement, achieving an effective heat dissipation area exceeding 4500 cm² within an 89.5mm height, improving airflow efficiency by over 40% compared to traditional fins.
Optimized Aerodynamics: Fin orientation precisely matches the front-to-back airflow path of switches, reducing airflow resistance by 30% and allowing the use of lower-speed, longer-life fans.
Enhanced Structural Stability: Innovative interlocking structure ensures the high-density fin array remains stable during transportation, vibration, and long-term operation, preventing fatigue damage from resonance.
Extreme Utilization of Vertical Space: Six Ø6mm high-performance heat pipes employ a C-shaped three-dimensional bend design, extending from the vapor chamber base in the vertical direction, fully utilizing the Z-axis space of the 3U chassis.
Optimized Multi-Directional Heat Conduction: Heat pipes are arranged in central symmetry, ensuring rapid and uniform heat transfer from the chip center to the top fin array, improving heat conduction efficiency by 35%.
Omni-Directional Mounting Adaptability: Internal wick structure is optimized for different mounting orientations, ensuring stable performance whether installed horizontally, vertically, or at any angle.
Full-Coverage Heat Spreading: The 300×112mm large-area vapor chamber base fully covers the Tomahawk 4 chip and surrounding high-power components, eliminating local hotspots.
High-Strength Support Structure: Employs a matrix-style support pillar design, ensuring baseplate deformation is controlled within 0.1mm under the extreme 530W load.
Transient Thermal Shock Buffering: Specially calculated working fluid capacity effectively absorbs instantaneous power peaks during chip startup and load transients, providing stable thermal buffering capability.
Scenario Characteristics: Port density in next-gen data center switches continues to increase, single-chip power exceeds 500W, traditional cooling solutions can no longer meet the space constraints of 3U chassis.
VC004 Value: Three-dimensional cooling design provides over 50% more cooling capacity than traditional solutions in the same space, supporting stable operation of the Tomahawk 4 chip at its full 530W configuration, ensuring all 400G ports operate at full line rate simultaneously.
Scenario Characteristics: Enterprise environments are sensitive to equipment noise and have limited maintenance resources, requiring low-noise, maintenance-free, highly reliable cooling solutions.
VC004 Value: Optimized airflow design and low resistance characteristics enable the use of low-speed quiet fans, reducing system noise by 5-8 dBA; fully welded structure and nickel-plated surface ensure long-term maintenance-free operation, significantly reducing TCO.
Scenario Characteristics: Edge server rooms have limited space and variable environmental conditions; equipment needs to adapt to harsh conditions like high temperature and humidity.
VC004 Value: Compact 89.5mm height fits various edge cabinets; corrosion resistance of nickel plating adapts to temperature and humidity changes in edge environments; high-efficiency cooling capability ensures stable equipment performance even in 45°C high-temperature environments.
Breaks Space Limitations: Provides a ready-made solution to solve the 530W thermal challenge within a standard 3U chassis, allowing hardware engineers to focus on core functionality development.
Simplifies Thermal Design Verification: Pre-validated thermal solution significantly shortens thermal simulation and testing cycles, accelerating time-to-market.
Increases Design Flexibility: The heatsink's integrated design frees up PCB layout space, allowing more flexible signal routing and component placement.
Reduces R&D Risk: Adopts a mature, market-validated thermal solution, avoiding product delays or recall risks due to thermal issues.
Optimizes Material Cost: Although the VC004 unit cost is higher, it can replace an entire traditional cooling system (baseplate + heat pipes + fins + brackets), reducing overall BOM cost by 15-20%.
Accelerates Certification Process: Provides complete NEBS Level 3, ETSI, GR-63 certification test reports, helping products quickly pass operator and data center certifications.
Reduces Operational Costs: High-efficiency cooling reduces fan power consumption, saving approximately $150-200 per device annually, with significant benefits at large-scale deployment.
Improves Equipment Reliability: MTBF exceeding 200,000 hours extends equipment uptime, achieving 99.999% carrier-grade network availability standards.
Protects Investment Value: Ample thermal headroom supports future performance upgrades via software updates or minor hardware modifications, extending equipment lifecycle.
Q:Do you have your own brand? A:Yes. Our brand name is GREATMINDS. |
Q:Are you a manufacture or trading company? A:We design and produce thermal products by ourselves. |
Q:Where is your plant? A:We have two plants. One is at Suzhou in eastern China, and the other is at Dongguan in southern China. |
Q:What thermal products do you supply? A:We have heatsink, fan, heapipe, vapor chamber, liquid cooling solution, and so on. |
Q:Which types of heatsinks do you supply? A:Our products cover many processes, extrusion, die casting, skived fin, zipper fin, soldering,friction stir welding, vaccum brazing, and so on. |
Q:What is the leadtime for prototype? A:It depends on different type of products. Usually it takes 2-3 weeks. |
Q:Do you have a NPI process in your company? A:Yes. Tooling samples and trial run will be strictly implemented before mass production. |
Q:What capabilities do you have in your plant? A:We have stamping, machining, and soldering production in house. |
Ultra-High-Density Heat Dissipation Array: Employs 0.2mm ultra-thin aluminum sheets in an interlocking zipper arrangement, achieving an effective heat dissipation area exceeding 4500 cm² within an 89.5mm height, improving airflow efficiency by over 40% compared to traditional fins.
Optimized Aerodynamics: Fin orientation precisely matches the front-to-back airflow path of switches, reducing airflow resistance by 30% and allowing the use of lower-speed, longer-life fans.
Enhanced Structural Stability: Innovative interlocking structure ensures the high-density fin array remains stable during transportation, vibration, and long-term operation, preventing fatigue damage from resonance.
Extreme Utilization of Vertical Space: Six Ø6mm high-performance heat pipes employ a C-shaped three-dimensional bend design, extending from the vapor chamber base in the vertical direction, fully utilizing the Z-axis space of the 3U chassis.
Optimized Multi-Directional Heat Conduction: Heat pipes are arranged in central symmetry, ensuring rapid and uniform heat transfer from the chip center to the top fin array, improving heat conduction efficiency by 35%.
Omni-Directional Mounting Adaptability: Internal wick structure is optimized for different mounting orientations, ensuring stable performance whether installed horizontally, vertically, or at any angle.
Full-Coverage Heat Spreading: The 300×112mm large-area vapor chamber base fully covers the Tomahawk 4 chip and surrounding high-power components, eliminating local hotspots.
High-Strength Support Structure: Employs a matrix-style support pillar design, ensuring baseplate deformation is controlled within 0.1mm under the extreme 530W load.
Transient Thermal Shock Buffering: Specially calculated working fluid capacity effectively absorbs instantaneous power peaks during chip startup and load transients, providing stable thermal buffering capability.
Scenario Characteristics: Port density in next-gen data center switches continues to increase, single-chip power exceeds 500W, traditional cooling solutions can no longer meet the space constraints of 3U chassis.
VC004 Value: Three-dimensional cooling design provides over 50% more cooling capacity than traditional solutions in the same space, supporting stable operation of the Tomahawk 4 chip at its full 530W configuration, ensuring all 400G ports operate at full line rate simultaneously.
Scenario Characteristics: Enterprise environments are sensitive to equipment noise and have limited maintenance resources, requiring low-noise, maintenance-free, highly reliable cooling solutions.
VC004 Value: Optimized airflow design and low resistance characteristics enable the use of low-speed quiet fans, reducing system noise by 5-8 dBA; fully welded structure and nickel-plated surface ensure long-term maintenance-free operation, significantly reducing TCO.
Scenario Characteristics: Edge server rooms have limited space and variable environmental conditions; equipment needs to adapt to harsh conditions like high temperature and humidity.
VC004 Value: Compact 89.5mm height fits various edge cabinets; corrosion resistance of nickel plating adapts to temperature and humidity changes in edge environments; high-efficiency cooling capability ensures stable equipment performance even in 45°C high-temperature environments.
Breaks Space Limitations: Provides a ready-made solution to solve the 530W thermal challenge within a standard 3U chassis, allowing hardware engineers to focus on core functionality development.
Simplifies Thermal Design Verification: Pre-validated thermal solution significantly shortens thermal simulation and testing cycles, accelerating time-to-market.
Increases Design Flexibility: The heatsink's integrated design frees up PCB layout space, allowing more flexible signal routing and component placement.
Reduces R&D Risk: Adopts a mature, market-validated thermal solution, avoiding product delays or recall risks due to thermal issues.
Optimizes Material Cost: Although the VC004 unit cost is higher, it can replace an entire traditional cooling system (baseplate + heat pipes + fins + brackets), reducing overall BOM cost by 15-20%.
Accelerates Certification Process: Provides complete NEBS Level 3, ETSI, GR-63 certification test reports, helping products quickly pass operator and data center certifications.
Reduces Operational Costs: High-efficiency cooling reduces fan power consumption, saving approximately $150-200 per device annually, with significant benefits at large-scale deployment.
Improves Equipment Reliability: MTBF exceeding 200,000 hours extends equipment uptime, achieving 99.999% carrier-grade network availability standards.
Protects Investment Value: Ample thermal headroom supports future performance upgrades via software updates or minor hardware modifications, extending equipment lifecycle.
Q:Do you have your own brand? A:Yes. Our brand name is GREATMINDS. |
Q:Are you a manufacture or trading company? A:We design and produce thermal products by ourselves. |
Q:Where is your plant? A:We have two plants. One is at Suzhou in eastern China, and the other is at Dongguan in southern China. |
Q:What thermal products do you supply? A:We have heatsink, fan, heapipe, vapor chamber, liquid cooling solution, and so on. |
Q:Which types of heatsinks do you supply? A:Our products cover many processes, extrusion, die casting, skived fin, zipper fin, soldering,friction stir welding, vaccum brazing, and so on. |
Q:What is the leadtime for prototype? A:It depends on different type of products. Usually it takes 2-3 weeks. |
Q:Do you have a NPI process in your company? A:Yes. Tooling samples and trial run will be strictly implemented before mass production. |
Q:What capabilities do you have in your plant? A:We have stamping, machining, and soldering production in house. |
