{"product_id":"1pcs-new-for-semikron-skiip83ac128ist1-module-skiip-83ac128ist1","title":"1PCS SEMIKRON SKIIP83AC128IST1 Module for High Performance Applications","description":"\u003cdiv class=\"koeed-container\" style=\"width: 100%; box-sizing: border-box; padding: 0; margin: 0; color: #333333; line-height: 1.6;\"\u003e\n\n \u003c!-- SECTION 1: Engineer's Quick Brief --\u003e\n \u003ch2\u003eEngineer's Quick Brief\u003c\/h2\u003e\n \u003cul style=\"list-style-type: disc; padding-left: 20px; margin-bottom: 24px;\"\u003e\n \u003cli\u003e\n\u003cstrong\u003eBaseplate-less Pressure Contact Technology:\u003c\/strong\u003e Utilizes Semikron's signature MiniSKiiP pressure construction, significantly reducing thermal resistance interfaces and eliminating copper baseplate solder fatigue under cyclic loads.\u003c\/li\u003e\n \u003cli\u003e\n\u003cstrong\u003e1200V \/ 80A Sixpack Configuration:\u003c\/strong\u003e Integrates a highly reliable three-phase full-bridge inverter topology optimized for high-power industrial voltage grids up to 400V\/480V AC.\u003c\/li\u003e\n \u003cli\u003e\n\u003cstrong\u003eIntegrated Safety Diagnostics:\u003c\/strong\u003e Outfitted with a precision embedded NTC thermistor to deliver real-time localized over-temperature data arrays directly to the gate driver control loop.\u003c\/li\u003e\n \u003c\/ul\u003e\n\n \u003c!-- SECTION 2: SEO Introduction --\u003e\n \u003ch2\u003eSemikron MiniSKiiP SKIIP83AC128IST1 IGBT Module Overview\u003c\/h2\u003e\n \u003cp style=\"margin-bottom: 24px;\"\u003e\n The \u003cstrong\u003eSemikron SKIIP83AC128IST1\u003c\/strong\u003e is a premium, high-performance \u003cstrong\u003eMiniSKiiP 3 IGBT power module\u003c\/strong\u003e engineered explicitly for high-efficiency industrial motor control, three-phase inverter networks, and servo drive architectures. Rated at a maximum blocking voltage of \u003cstrong\u003e1200V\u003c\/strong\u003e and a continuous collector current of \u003cstrong\u003e80A\u003c\/strong\u003e, this advanced \u003cstrong\u003eSixpack (6-Unit Bridge)\u003c\/strong\u003e module leverages Semikron's innovative pressure connection system. By removing the traditional copper baseplate layout, it establishes a direct thermal dissipation path to the heatsink. This mechanical design decreases localized thermal impedance, prevents solder layer delamination under intense thermal cycling, and secures operational consistency across heavy-duty industrial processing environments.\n \u003c\/p\u003e\n\n \u003c!-- SECTION 3: Technical Specifications --\u003e\n \u003ch2\u003eTechnical Specifications\u003c\/h2\u003e\n \u003cdiv style=\"overflow-x: auto; margin-bottom: 24px;\"\u003e\n \u003ctable style=\"width: 100%; border-collapse: collapse; border: 1px solid #eeeeee; min-width: 600px;\"\u003e\n \u003cthead\u003e\n \u003ctr style=\"background-color: #16c8c8; color: #ffffff;\"\u003e\n \u003cth style=\"padding: 12px; text-align: left; border: 1px solid #eeeeee;\"\u003eElectrical \u0026amp; Thermal Parameter Category\u003c\/th\u003e\n \u003cth style=\"padding: 12px; text-align: left; border: 1px solid #eeeeee;\"\u003eDetailed Engineering Absolute Nominal Values\u003c\/th\u003e\n \u003c\/tr\u003e\n \u003c\/thead\u003e\n \u003ctbody\u003e\n \u003ctr style=\"background-color: #f4fcfc;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eBrand \/ Manufacturer\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003eSEMIKRON \/ Semikron Danfoss\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003ctr style=\"background-color: #fafafa;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eModel Identifier\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003eSKIIP83AC128IST1 (MiniSKiiP 3 Generation)\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003ctr style=\"background-color: #f4fcfc;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eCircuit Topology Layout\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003eSixpack \/ Three-Phase Full Inverter Bridge\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003ctr style=\"background-color: #fafafa;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eCollector-Emitter Voltage (Vces)\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003e1200 V\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003ctr style=\"background-color: #f4fcfc;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eContinuous DC Collector Current (Ic)\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003e80 Amps\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003ctr style=\"background-color: #fafafa;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eGate-Emitter Peak Voltage (Vges)\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003e±20 V\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003ctr style=\"background-color: #f4fcfc;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eIntegrated Protection Sensor\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003eInternal Negative Temperature Coefficient (NTC) Thermistor\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003ctr style=\"background-color: #fafafa;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eMounting Mechanism Type\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003eSolder-free Pressure Connection Kit (Sprung Contact Pins)\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003ctr style=\"background-color: #f4fcfc;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eMaximum Virtual Junction Temp (Tvj max)\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003e175 °C\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003ctr style=\"background-color: #fafafa;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eSafety Compliance Standard\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003eUL Recognized Component File Framework\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003c\/tbody\u003e\n \u003c\/table\u003e\n \u003c\/div\u003e\n\n \u003c!-- SECTION 4: Application Matrix --\u003e\n \u003ch2\u003eIndustrial Application Matrix\u003c\/h2\u003e\n \u003cdiv style=\"overflow-x: auto; margin-bottom: 24px;\"\u003e\n \u003ctable style=\"width: 100%; border-collapse: collapse; border: 1px solid #eeeeee; min-width: 600px;\"\u003e\n \u003cthead\u003e\n \u003ctr style=\"background-color: #0056B3; color: #ffffff;\"\u003e\n \u003cth style=\"padding: 12px; text-align: left; border: 1px solid #eeeeee;\"\u003eTarget Deployment System\u003c\/th\u003e\n \u003cth style=\"padding: 12px; text-align: left; border: 1px solid #eeeeee;\"\u003eSpecific Machine Mechanism\u003c\/th\u003e\n \u003cth style=\"padding: 12px; text-align: left; border: 1px solid #eeeeee;\"\u003eSystem Engineering Value Realized\u003c\/th\u003e\n \u003c\/tr\u003e\n \u003c\/thead\u003e\n \u003ctbody\u003e\n \u003ctr style=\"background-color: #f4fcfc;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eIndustrial Motor Drives\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003eStandard 3-Phase AC Variable Frequency Drives (VFD)\u003c\/td\u003e\n \u003ctd\u003eMaintains stable switching profiles under continuous overload conditions during heavy mechanical conveyor startups.\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003ctr style=\"background-color: #fafafa;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eRenewable Power Grids\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003eCommercial Solar Inverters \u0026amp; Wind Converters\u003c\/td\u003e\n \u003ctd\u003eSolder-free pressure contacts withstand extreme outdoor thermal cycling variants without interface breakdown.\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003ctr style=\"background-color: #f4fcfc;\"\u003e\n \u003ctd\u003e\u003cstrong\u003eFacility Infrastructure\u003c\/strong\u003e\u003c\/td\u003e\n \u003ctd\u003eHigh-Capacity Uninterruptible Power Supplies (UPS)\u003c\/td\u003e\n \u003ctd\u003eLow saturation voltage parameters (VCE(sat)) reduce static conduction power losses, driving up total facility energy efficiency metrics.\u003c\/td\u003e\n \u003c\/tr\u003e\n \u003c\/tbody\u003e\n \u003c\/table\u003e\n \u003c\/div\u003e\n\n \u003c!-- SECTION 5: Koeed B2B Tool --\u003e\n \u003ch2\u003eKoeed Field FAE Tool: IGBT Estimated Power Dissipation \u0026amp; Thermal Estimator\u003c\/h2\u003e\n \u003cp style=\"margin-bottom: 16px;\"\u003eEvaluate the approximate thermal dissipation profile of the SKIIP83AC128IST1 module based on targeted field operating parameters. Modify current parameters and switching speeds to verify estimated continuous power loss benchmarks.\u003c\/p\u003e\n \n \u003cdiv class=\"koeed-tool-box\" style=\"background-color: #fafafa; border: 1px solid #16c8c8; border-radius: 4px; padding: 20px; margin-bottom: 24px;\"\u003e\n \u003cdiv style=\"display: grid; grid-template-columns: repeat(auto-fit, minmax(200px, 1fr)); gap: 16px; margin-bottom: 20px;\"\u003e\n \u003cdiv\u003e\n \u003clabel style=\"display: block; font-weight: bold; margin-bottom: 6px;\"\u003eOperating RMS Current (Amps):\u003c\/label\u003e\n \u003cinput type=\"number\" id=\"koeed-igbt-current\" value=\"45\" min=\"1\" max=\"80\" style=\"width: 100%; padding: 8px; border: 1px solid #cccccc; border-radius: 4px; box-sizing: border-box;\" oninput=\"koeedCalculateIgbtLosses()\"\u003e\n \u003c\/div\u003e\n \u003cdiv\u003e\n \u003clabel style=\"display: block; font-weight: bold; margin-bottom: 6px;\"\u003eSwitching Frequency (kHz):\u003c\/label\u003e\n \u003cinput type=\"number\" id=\"koeed-igbt-freq\" value=\"8\" min=\"1\" max=\"25\" style=\"width: 100%; padding: 8px; border: 1px solid #cccccc; border-radius: 4px; box-sizing: border-box;\" oninput=\"koeedCalculateIgbtLosses()\"\u003e\n \u003c\/div\u003e\n \u003cdiv\u003e\n \u003clabel style=\"display: block; font-weight: bold; margin-bottom: 6px;\"\u003eTarget Duty Cycle (%):\u003c\/label\u003e\n \u003cinput type=\"number\" id=\"koeed-igbt-duty\" value=\"50\" min=\"5\" max=\"95\" style=\"width: 100%; padding: 8px; border: 1px solid #cccccc; border-radius: 4px; box-sizing: border-box;\" oninput=\"koeedCalculateIgbtLosses()\"\u003e\n \u003c\/div\u003e\n \u003c\/div\u003e\n\n \u003cdiv style=\"background-color: #ffffff; border-left: 4px solid #16c8c8; padding: 14px; border-radius: 0 4px 4px 0;\"\u003e\n \u003cp style=\"margin: 0; font-weight: bold;\"\u003eEstimated Conduction Power Loss: \u003cspan id=\"koeed-calc-cond-w\" style=\"color: #333;\"\u003e38.25\u003c\/span\u003e Watts\u003c\/p\u003e\n \u003cp style=\"margin: 4px 0 0 0; font-weight: bold;\"\u003eEstimated Dynamic Switching Power Loss: \u003cspan id=\"koeed-calc-sw-w\" style=\"color: #333;\"\u003e28.80\u003c\/span\u003e Watts\u003c\/p\u003e\n \u003cp style=\"margin: 6px 0 0 0; font-weight: bold; font-size: 1.1em;\"\u003eTotal Combined Heat Dissipation (Per Phase Channel): \u003cstrong id=\"koeed-calc-total-w\" style=\"color: #16c8c8;\"\u003e67.05\u003c\/strong\u003e Watts\u003c\/p\u003e\n \u003cp style=\"margin: 8px 0 0 0; font-weight: bold; font-size: 0.95em;\"\u003eSafe Operating Area (SOA) Evaluation: \u003cspan id=\"koeed-calc-safety-status\" style=\"color: green; font-weight: bold;\"\u003eSAFE STABLE LOADING\u003c\/span\u003e\u003c\/p\u003e\n \u003c\/div\u003e\n \u003c\/div\u003e\n\n \u003cnoscript\u003e\n \u003cdiv style=\"background-color: #fff3cd; color: #856404; padding: 12px; border: 1px solid #ffeeba; border-radius: 4px; margin-bottom: 24px;\"\u003e\n \u003cstrong\u003eNotice:\u003c\/strong\u003e This landing interface integrates real-time active thermodynamic loss software scripts. Please enable browser JavaScript configurations to use dynamic simulation matrices.\n \u003c\/div\u003e\n \u003c\/noscript\u003e\n\n \u003cscript\u003e\n function koeedCalculateIgbtLosses() {\n var ic = parseFloat(document.getElementById('koeed-igbt-current').value) || 0;\n var fsw = parseFloat(document.getElementById('koeed-igbt-freq').value) || 0;\n var duty = parseFloat(document.getElementById('koeed-igbt-duty').value) || 0;\n\n var factorDuty = duty \/ 100.0;\n \/\/ Linearized approximation modeling of standard MiniSKiiP 1200V Vce(sat) response core\n var vcesat = 1.70 + (ic * 0.008); \n var conductionLoss = vcesat * ic * factorDuty;\n\n \/\/ Approximate switching energy multiplier constant based on factory engineering profiles\n var energyPerSwitch = 0.08 * ic; \n var switchingLoss = (energyPerSwitch * fsw * 1000) \/ 10000; \n\n var totalLoss = conductionLoss + switchingLoss;\n\n document.getElementById('koeed-calc-cond-w').innerText = conductionLoss.toFixed(2);\n document.getElementById('koeed-calc-sw-w').innerText = switchingLoss.toFixed(2);\n document.getElementById('koeed-calc-total-w').innerText = totalLoss.toFixed(2);\n\n var statusSpan = document.getElementById('koeed-calc-safety-status');\n if (ic \u003e 80) {\n statusSpan.innerText = \"CRITICAL LIMIT BREACHED: Overcurrent values exceed 80A hardware parameter threshold boundaries!\";\n statusSpan.style.color = \"#dc3545\";\n } else if (totalLoss \u003e 160.0) {\n statusSpan.innerText = \"THERMAL RISK: High heat density generated. Enforce high-velocity forced air or liquid cooling paths.\";\n statusSpan.style.color = \"#ffc107\";\n } else {\n statusSpan.innerText = \"SAFE STABLE LOADING: Parameters align securely with target operational margins.\";\n statusSpan.style.color = \"green\";\n }\n }\n window.addEventListener('DOMContentLoaded', function() {\n koeedCalculateIgbtLosses();\n });\n \u003c\/script\u003e\n\n \u003c!-- SECTION 6: Troubleshooting \u0026 FAQ --\u003e\n \u003ch2\u003eField Commissioning \u0026amp; Installation Maintenance Guide\u003c\/h2\u003e\n \n \u003ch3\u003eQ: What are the core layout requirements when installing MiniSKiiP solder-free modules on a PCB?\u003c\/h3\u003e\n \u003cp style=\"margin-bottom: 12px;\"\u003e\n Because the MiniSKiiP SKIIP83AC128IST1 utilizes a specialized \u003cstrong\u003esolder-free pressure connection architecture\u003c\/strong\u003e instead of traditional copper baseplates and bolted power terminals, it relies entirely on a single mounting screw scheme. To secure a tight seal and reliable connection, follow this mounting sequence:\n \u003c\/p\u003e\n \u003cul style=\"padding-left: 20px; margin-bottom: 16px;\"\u003e\n \u003cli\u003eEnsure the target heatsink surface is completely smooth and free of grease deposits or micro-particle debris. Apply a uniform \u003cstrong\u003e20µm to 30µm layer of thermal paste\u003c\/strong\u003e across the module's rear contact zone using a screen printing roller kit.\u003c\/li\u003e\n \u003cli\u003ePlace the target printed circuit board (PCB) over the module alignment pins, making sure all sprung gold contact pins match up exactly with the corresponding copper pads on the board.\u003c\/li\u003e\n \u003cli\u003eInsert the primary structural fixing screw and execute a controlled, multi-stage torque down procedure using a calibrated electric driver. The final mounting torque must measure exactly between \u003cstrong\u003e2.0 Nm and 2.5 Nm\u003c\/strong\u003e. Insufficient torque can cause contact resistance drops on power tracks, while over-tightening can crack the inner ceramic layer.\u003c\/li\u003e\n \u003c\/ul\u003e\n\n \u003ch3\u003eQ: The drive loop signals an immediate over-temperature fault on startup. How can the integrated NTC thermistor line be verified?\u003c\/h3\u003e\n \u003cp style=\"margin-bottom: 12px;\"\u003eImmediate temperature error alerts during initial diagnostic initialization loops typically point to circuit line errors or internal sensor failure. Disconnect system power completely and perform this verification test using a high-accuracy digital multimeter set to resistance configuration (Ω):\u003c\/p\u003e\n \u003col style=\"padding-left: 20px; margin-bottom: 16px;\"\u003e\n \u003cli\u003eLocate the designated NTC output signal pin positions on the main PCB track block corresponding to the module configuration layout.\u003c\/li\u003e\n \u003cli\u003eMeasure the baseline static resistance value at a standard room temperature of \u003cstrong\u003e25 °C\u003c\/strong\u003e. The integrated sensor should register a clear reading of approximately \u003cstrong\u003e5000 Ω (5 kΩ ±5% tolerance bound)\u003c\/strong\u003e. Any reading reaching zero resistance confirms an internal short circuit condition, while an open circuit reading (OL) indicates a broken internal wire bond.\u003c\/li\u003e\n \u003cli\u003eVerify that your gate driver control software configuration uses the correct mathematical linearization lookup table for standard 5kΩ NTC sensors to avoid calibration errors.\u003c\/li\u003e\n \u003c\/ol\u003e\n\n \u003ch3\u003eQ: What are the primary causes behind premature IGBT chip failure or gate insulation breakdown?\u003c\/h3\u003e\n \u003cp style=\"margin-bottom: 12px;\"\u003e\n IGBT failure paths are typically driven by stray inductive voltage spikes or poor mechanical alignment. If high-current switching loops generate excessive high-voltage surges ($V = L \\cdot \\frac{di}{dt}$) during turn-off phases, the voltage can spike beyond the 1200V limit and puncture the collector-emitter barrier. To mitigate this risk, install high-frequency low-inductive snubber capacitors right next to the module's DC bus pins to absorb parasitic energy spikes.\n \u003c\/p\u003e\n\n \u003c!-- SECTION 7: Cross-Reference \u0026 Selection --\u003e\n \u003ch3\u003eCross-Reference Guide\u003c\/h3\u003e\n \u003cp style=\"margin-bottom: 16px;\"\u003eThe Semikron MiniSKiiP SKIIP83AC128IST1 product profile shares physical framework layouts and equivalent functional footprints with these industry power components:\u003c\/p\u003e\n \u003cul style=\"list-style-type: square; padding-left: 20px; margin-bottom: 24px;\"\u003e\n \u003cli\u003e\n\u003cstrong\u003eStandard Non-Coated Alternative Match:\u003c\/strong\u003e SKIIP83AC128I Series (Baseline identical non-coated unit version lacking specialized high-adhesion protection modifications; verify terminal trace specifications during crossover retrofits).\u003c\/li\u003e\n \u003cli\u003e\n\u003cstrong\u003eVincotech Modular Alternative:\u003c\/strong\u003e Flow 1Inverter 1200V \/ 80A Configuration Series (Functional equivalent multi-pin topology module option; requires re-routing PCB gate trace layouts to align with alternative housing terminal patterns).\u003c\/li\u003e\n \u003cli\u003e\n\u003cstrong\u003eInfineon EasyPIM Interchange:\u003c\/strong\u003e FP75R12KT4 \/ FP75R12KE4 Series (Comparable 1200V three-phase full-bridge industrial modules; check physical grid array footprints and mounting hole layouts before final installation).\u003c\/li\u003e\n \u003c\/ul\u003e\n\n\u003c\/div\u003e\n\n\u003c!-- STRUCTURED DATA: JSON-LD FOR AI SEARCH ENGINE HARVESTING --\u003e\n\u003cscript type=\"application\/ld+json\"\u003e\n{\n \"@context\": \"https:\/\/schema.org\",\n \"@graph\": [\n {\n \"@type\": \"FAQPage\",\n \"mainEntity\": [\n {\n \"@type\": \"Question\",\n \"name\": \"What are the core layout requirements when installing MiniSKiiP solder-free modules on a PCB?\",\n \"acceptedAnswer\": {\n \"@type\": \"Answer\",\n \"text\": \"Installation requires applying a flat 20-30 micrometer layer of thermal compound to a clean heatsink, aligning the module sprungs underneath the matching PCB layout, and executing a controlled torqued fastening pass to ensure the central mounting screw reads securely between 2.0 Nm and 2.5 Nm.\"\n }\n },\n {\n \"@type\": \"Question\",\n \"name\": \"The drive loop signals an immediate over-temperature fault on startup. How can the integrated NTC thermistor line be verified?\",\n \"acceptedAnswer\": {\n \"@type\": \"Answer\",\n \"text\": \"Measure resistance across the NTC signal terminal pins using a multimeter. At a standard baseline of 25°C, the thermistor should read approximately 5000 Ohms (5k Ohms). An open loop circuit output or zero resistance confirms internal tracking component damage.\"\n }\n },\n {\n \"@type\": \"Question\",\n \"name\": \"What are the primary causes behind premature IGBT chip failure or gate insulation breakdown?\",\n \"acceptedAnswer\": {\n \"@type\": \"Answer\",\n \"text\": \"Premature damage typically tracks back to stray inductance high-voltage transients that cross the module's 1200V maximum threshold limits during high-frequency shutoff loops. Integrating low-inductive snubber caps directly across the DC link terminals absorbs these stray spikes.\"\n }\n }\n ]\n },\n {\n \"@type\": \"WebApplication\",\n \"name\": \"IGBT Estimated Power Dissipation \u0026 Thermal Estimator\",\n \"applicationCategory\": \"BusinessApplication\",\n \"operatingSystem\": \"All\",\n \"browserRequirements\": \"Requires HTML5 rendering support with active JavaScript execution capabilities enabled within browser preferences.\",\n \"description\": \"An interactive power loss estimation tool engineered to simulate conduction and high-frequency switching thermal energy generation across 1200V 80A industrial MiniSKiiP power modules.\"\n }\n ]\n}\n\u003c\/script\u003e","brand":"SEMIKRON","offers":[{"title":"Default Title","offer_id":43955608780985,"sku":"304247912592","price":583.24,"currency_code":"USD","in_stock":true}],"thumbnail_url":"\/\/cdn.shopify.com\/s\/files\/1\/0268\/8476\/7929\/files\/1PCS_SEMIKRON_SKIIP83AC128IST1_Module_for_High_Performance_Applications___SEMIKRON__1.webp?v=1774839723","url":"https:\/\/koeed.com\/pt\/products\/1pcs-new-for-semikron-skiip83ac128ist1-module-skiip-83ac128ist1","provider":"KOEED","version":"1.0","type":"link"}