Stamped Aluminum Liquid Cooling Plate with Continuous Brazing for Energy Storage, EV Battery & IGBT
|
|
Product Overview Trumony provides stamped aluminum liquid cooling plates manufactured with continuous brazing for high-volume battery and power electronics cooling. Our factory delivers fully custom designs — from channel pattern to surface finish — backed by one-stop service from prototyping to mass production. - Cause High-power battery packs and IGBT modules generate concentrated heat that passive cooling cannot handle. Without effective liquid cooling, cells degrade rapidly, charging slows, and power electronics risk thermal failure. - Solution Our precision stamping process forms consistent, optimized flow channels at low cost and high speed. Continuous brazing creates a uniform, leak-proof metallurgical bond across every plate. The result: dependable thermal performance at any production scale. --- Parameter Details
1. Electric Vehicle Traction Battery Packs 2. Commercial & Utility-Scale Energy Storage (BESS) 3. IGBT & SiC Power Module Cooling 4. Automotive Ancillary Electronics How It Works Stamped aluminum liquid cooling plates operate on a closed-loop liquid circulation principle. Coolant enters through an inlet fitting, flows through the stamped channel network beneath the heat-generating components, absorbs waste heat, and exits through an outlet to an external heat exchanger. The stamping process forms the intricate channel geometry directly into the aluminum sheet — creating raised features like dimples or chevrons that disturb the fluid boundary layer and enhance convective heat transfer. The cover plate is then joined via continuous brazing, where the assembly passes through a furnace with precisely controlled temperature and inert atmosphere. The brazing filler metal (typically a clad layer on the sheet) melts and forms a metallurgical bond along every contact point, creating a single, leak-proof structure. Because every plate undergoes identical automated processing, thermal performance is exceptionally consistent from the first unit to the millionth. How To Choose Your Stamped Cooling Plate 1. Heat Load & Flow Rate: Determine total watts to dissipate
and available coolant flow (L/min). Our engineers use this to
calculate required channel cross-section and plate size. 3. Channel Pattern Selection: Serpentine for simple, low-cost designs; multi-parallel for low pressure drop; dimpled or pin-fin for maximum turbulence and heat transfer. We recommend the pattern based on your thermal simulation inputs. 4. Surface Protection: Choose based on your coolant chemistry and environment. E-coat provides excellent corrosion resistance for water-glycol systems; hard anodizing adds electrical insulation for direct cell contact. 5. Project Timeline & Volume: Share your expected annual quantities and target SOP date. Our stamping die development lead-time is typically 4-6 weeks, with samples following shortly after. We manage everything in-house to keep your program on track. Simply reach out with your requirements. We return a comprehensive proposal including die design feasibility, CFD thermal report, and transparent cost breakdown for prototype, pilot, and mass production phases. FAQ Q1: I don’t have a finalized design. Can you help from the concept
stage? Absolutely. That is the core of our one-stop service. Share your heat load, space envelope, and target thermal performance. Our engineers will propose an initial flow channel design, run CFD simulations for your approval, and then move to prototype. We guide you from idea to serial production. Q2: What is the minimum order quantity (MOQ) for custom liquid
cooling plates? We have no fixed MOQ for the prototype and NPI (New Product Introduction) stage. For mass production, we work flexibly with your volumes. As a factory serving global clients, we comfortably handle everything from small pilot runs to millions of pieces annually. Q3: How do you ensure zero leaks in a water-cooled battery pack? Quality is built in from the start. We use vacuum brazing for high-integrity joints and 100% test every single plate with a helium mass spectrometer, achieving leak rates tighter than 1×10⁻⁹ Pa·m³/s. Additionally, we conduct pressure cycling and thermal shock tests on pre-production samples validated according to customer durability requirements. Q4: Do you hold certifications for the North American and Asian
markets? Yes. Our manufacturing is certified to ISO 9001 and IATF 16949. Our materials and components comply with RoHS, REACH, and UL standards as required by your product. We are also experienced in supporting customers through final system-level UL 9540A or UN 38.3 certification by providing detailed design and material documentation. Q5: What kind of warranty and after-sales support do you offer for
your cooling plates? We stand behind our workmanship. Our standard product warranty is 5 years when properly operated within specified parameters. In the rare event of an issue, our engineering team provides root cause analysis and works to resolve it immediately. For ongoing production, we maintain complete traceability records tied to each batch. |
||||||||||||||||||||||||
| Product Tags: stamped aluminum liquid cooling plate liquid cold plate for EV battery continuous brazing cooling plate |
|
Anti-Leak Liquid Cold Plate – Uniform Cooling for Thermal Runaway Prevention |
|
High Precision Stamping CAB Brazing Liquid Cooling Tray With PU Foam Insulation Helium Leak Test Battery Thermal Management Cold Plate |
|
Custom High-Efficiency Liquid Cold Plate Aluminum Continuous Brazed Water Cooling Plate for EV Battery & Data Center |
|
Custom Engineered Stamped Aluminum Liquid Cold Plate for Utility & Commercial BESS |
|
Advanced Continuous Brazed Cold Plate Technology Precision Liquid Cooling for High-Power Electronics |
|
Custom Vacuum Brazed Aluminum Liquid Cooling Plate 3003 6061 Alloy IP67 Insulated Battery Cold Plate For ESS EV Energy Storage |