# VS1 Vacuum Circuit Breaker Technical Specifications > Source: https://voltgrids.com/blog/vs1-vacuum-circuit-breaker-technical-specifications/ > Published: 2026-04-21T03:57:13+00:00 > Modified: 2026-05-11T02:03:22+00:00 > Agent JSON: https://voltgrids.com/blog/vs1-vacuum-circuit-breaker-technical-specifications/agent.json > Agent Markdown: https://voltgrids.com/blog/vs1-vacuum-circuit-breaker-technical-specifications/agent.md ## Summary This comprehensive guide explores the technical specifications of the VS1 vacuum circuit breaker, covering its 12kV and 24kV ratings, core structural materials, and IEC compliance. Learn how to select the right VCB for medium voltage distribution and avoid common installation errors to ensure power system reliability. ## Media - YouTube: https://youtu.be/hg1nXzKSXYU - SoundCloud: https://soundcloud.com/bepto-247719800/vs1-vacuum-circuit-breaker/s-USW0skK5pxK?si=f4bb2f300b424b38911554b9462e2882&utm_source=clipboard&utm_medium=text&utm_campaign=social_sharing ## Article ![12kV Indoor Vacuum Circuit Breaker MV VCB 1250A - High Voltage Solid-Sealed Poles E2-M2 Life Frequent Operation](https://voltgrids.com/wp-content/uploads/2025/12/12kV-Indoor-Vacuum-Circuit-Breaker-MV-VCB-1250A-High-Voltage-Solid-Sealed-Poles-E2-M2-Life-Frequent-Operation-2.jpg) [Indoor VCB](https://voltgrids.com/product-category/switching-devices/vacuum-circuit-breaker-vcb/indoor-vcb/) ## Introduction When a fault current strikes a medium voltage distribution network, the difference between a controlled interruption and a catastrophic failure often comes down to one component: the vacuum circuit breaker. For electrical engineers specifying protection devices, and for procurement managers sourcing reliable switchgear, the VS1 Indoor Vacuum Circuit Breaker has become one of the most widely deployed VCB platforms across industrial and grid applications globally. **The VS1 VCB is a spring-operated, fixed or withdrawable indoor vacuum circuit breaker rated for medium voltage systems, designed to interrupt fault currents reliably across thousands of operating cycles without insulation degradation.** Yet despite its widespread use, many engineers still encounter specification mismatches — selecting the wrong rated voltage, underestimating the required breaking capacity, or overlooking creepage distance requirements for their environment. This guide breaks down the complete technical specifications of the VS1 VCB, explains its core operating mechanisms, provides a practical selection framework, and covers installation best practices — so your next switchgear project is built on solid engineering ground. ## Table of Contents - [What Is the VS1 Vacuum Circuit Breaker and How Is It Classified?](#what-is-the-vs1-vacuum-circuit-breaker-and-how-is-it-classified) - [What Are the Core Technical Specifications and Performance Parameters of the VS1 VCB?](#what-are-the-core-technical-specifications-and-performance-parameters-of-the-vs1-vcb) - [How Do You Select the Right VS1 VCB for Your Power Distribution Application?](#how-do-you-select-the-right-vs1-vcb-for-your-power-distribution-application) - [What Are the Key Installation, Maintenance, and Common Specification Errors for VS1 VCBs?](#what-are-the-key-installation-maintenance-and-common-specification-errors-for-vs1-vcbs) ## What Is the VS1 Vacuum Circuit Breaker and How Is It Classified? ![ZN63A-12 VS1 Vacuum Circuit Breaker 12kV-24kV 4000A - Indoor High Voltage VCB Embedded Poles KYN28A Switchgear](https://voltgrids.com/wp-content/uploads/2025/12/ZN63A-12-VS1-Vacuum-Circuit-Breaker-12kV-24kV-4000A-Indoor-High-Voltage-VCB-Embedded-Poles-KYN28A-Switchgear-4.jpg) [ZN63A-12 VS1 Vacuum Circuit Breaker 12kV/24kV 4000A – Indoor High Voltage VCB Embedded Poles KYN28A Switchgear](https://voltgrids.com/product/zn63a-12-vs1-vacuum-circuit-breaker-12kv-24kv-4000a-indoor-high-voltage-vcb-embedded-poles-kyn28a-switchgear/) The VS1 is a **fixed or withdrawable indoor medium voltage vacuum circuit breaker**, designed for installation within metal-enclosed switchgear panels. It operates on the principle of vacuum arc interruption — when contacts separate inside a sealed [vacuum interrupter](https://voltgrids.com/blog/vacuum-interrupters-explained-how-switchgear-uses-vacuum-to-extinguish-arcs-in-mv-systems/), [the arc extinguishes rapidly at the first current zero crossing](https://ieeexplore.ieee.org/document/8765432)[1](#fn-1) due to the near-absence of ionizable medium. ### Core Classification Parameters - **Voltage Class:** 12 kV (standard) / 24 kV (extended range variants) - **Insulation Medium:** Vacuum (10⁻³ Pa or lower internal pressure) - **Operating Mechanism:** Spring-charged manual or motor-driven - **Installation Type:** Indoor, fixed-mounted or withdrawable (plug-in) - **Applicable Standard:** [IEC 62271-100](https://webstore.iec.ch/publication/60702)[2](#fn-2), IEC 62271-200 ### Key Structural Materials - **Vacuum Interrupter:** Copper-chromium (CuCr) alloy contacts for superior arc erosion resistance - **Insulating Cylinder:** Epoxy resin molded housing with high dielectric strength - **Operating Rod:** Stainless steel with PTFE-coated guide bushings - **Frame:** Galvanized steel chassis rated for indoor IP4X environments ### Electrical Performance Highlights - Dielectric strength of vacuum interrupter: **≥ 42 kV (1-minute power frequency)** - creepage distance (phase-to-earth): **≥ 125 mm at 12 kV** - Mechanical endurance: **[10,000 CO operations (standard class M1)](https://webstore.iec.ch/publication/60702)[3](#fn-3)** - Electrical endurance: **30–50 breaking operations at rated short-circuit current** The VS1 platform is fully compatible with KYN28, XGN, and similar metal-clad switchgear enclosures, making it the default VCB choice for industrial power distribution and substation feeder protection. ## What Are the Core Technical Specifications and Performance Parameters of the VS1 VCB? ![A modern, clean graphical dashboard interface with a prominent Bepto logo, replacing realistic product photos. The image is a complex technical data visualization with structured tables, graphs, and status indicators. A primary table displays parameters like 'Power Frequency Withstand Voltage (1 min) | 42 kV | PASSED' and 'Short-Circuit Breaking Current (Isc) | 31.5 kA | VERIFIED'. Smaller graphical sections show 'Vacuum Integrity (18 mos in SE Asia Substation) | 0 Failure | ACHIEVED', a green 'TEST CERTIFIED' seal graphic, a dialectic strength waveform graph, and a material composition report icon. All text is sharp and correct, and the style is purely informational graphics with a deep blue, gold, and white color scheme.](https://voltgrids.com/wp-content/uploads/2026/04/Bepto-VS1-VCB-Performance-Reliability-Dashboard-a-graphical-summary-of-key-testing-results-and-project-case-success-1024x559.jpg) Bepto VS1 VCB Performance & Reliability Dashboard, a graphical summary of key testing results and project case success. Understanding the rated parameters of the VS1 is essential for correct application in any medium voltage power distribution system. Below is a structured breakdown of the primary electrical and mechanical ratings. ### VS1 Standard Technical Specification Table | Parameter | 12 kV Standard | 24 kV Variant | | Rated Voltage (Ur) | 12 kV | 24 kV | | Rated Current (Ir) | 630 / 1250 / 1600 / 2000 / 2500 A | 630 / 1250 / 1600 A | | Rated Short-Circuit Breaking Current (Isc) | 20 / 25 / 31.5 kA | 16 / 20 / 25 kA | | Rated Short-Time Withstand Current (Ik) | 20 / 25 / 31.5 kA (3s) | 16 / 20 / 25 kA (3s) | | Rated Lightning Impulse Withstand Voltage | 75 kV (peak) | 125 kV (peak) | | Power Frequency Withstand Voltage (1 min) | 42 kV | 65 kV | | Closing Time | ≤ 60 ms | ≤ 60 ms | | Opening Time | ≤ 33 ms | ≤ 33 ms | | Arcing Time | ≤ 16 ms | ≤ 16 ms | ### Reliability in Practice: A Real Project Case One of our clients — a procurement manager sourcing equipment for a 110/10 kV urban distribution substation expansion in Southeast Asia — had previously experienced repeated VCB failures from a low-cost supplier. The vacuum interrupters lost dielectric integrity within 18 months due to substandard CuCr contact material, causing two unplanned outages and significant project penalties. After switching to Bepto’s VS1 platform, the project team conducted incoming dielectric withstand tests on all units. Every breaker passed the 42 kV / 1-minute power frequency test. Eighteen months into operation, zero vacuum integrity failures have been recorded across 48 installed units. **The key differentiator:** certified vacuum interrupters with traceable material composition reports — not just a CE mark on a datasheet. ### Reliability-Defining Design Features - **Anti-rebound mechanism** prevents contact bounce during closing, eliminating pre-strike arc damage - **Position indicator** provides clear OPEN / CLOSE / EARTH visual status - **Secondary circuit plug** enables safe withdrawable operation without live circuit exposure - **Auxiliary contacts:** 4NO + 4NC standard, expandable to 8NO + 8NC ## How Do You Select the Right VS1 VCB for Your Power Distribution Application? ![A professional photograph of a Bepto VS1 vacuum circuit breaker on a display stand, next to an interactive graphical panel outlining the three key steps of selecting the right VCB: Electrical Requirements, Environmental Conditions, and Standards & Certifications.](https://voltgrids.com/wp-content/uploads/2026/04/A-graphical-guide-to-selecting-the-right-Bepto-VS1-VCB-for-power-distribution-1024x687.jpg) A graphical guide to selecting the right Bepto VS1 VCB for power distribution Selecting a VS1 VCB is not simply a matter of matching voltage class. A structured selection process prevents undersizing, ensures environmental compatibility, and guarantees regulatory compliance across different power distribution scenarios. ### Step 1: Define Electrical Requirements - **System Voltage:** Confirm nominal voltage and select Ur = 12 kV or 24 kV accordingly - **Continuous Current:** Select rated current Ir≥1.25× maximum continuous load currentI_r \geq 1.25 \times \text{maximum continuous load current} - **Fault Level:** Obtain prospective short-circuit current from system study; select Isc≥ system fault levelI_{sc} \geq \text{system fault level} - **Duty Cycle:** High-frequency switching applications (capacitor banks, motors) require Class E2 electrical endurance rating ### Step 2: Consider Environmental Conditions - **Ambient Temperature:** Standard rating –5°C to +40°C; request low-temperature variant for –25°C environments - **Altitude:** [Derate dielectric performance above 1000 m ASL per IEC 62271-1 correction factors](https://webstore.iec.ch/publication/60699)[4](#fn-4) - **Humidity & Pollution:** Indoor IP4X standard; for coastal or high-humidity installations, specify anti-condensation heaters - **Seismic Zone:** Specify seismic qualification testing (IEC 60068-3-3) for installations in earthquake-prone regions ### Step 3: Match Standards and Certifications - **IEC 62271-100:** Type test for AC circuit breakers — mandatory baseline - **IEC 62271-200:** Metal-enclosed switchgear compatibility - **CCC (China Compulsory Certification):** Required for projects within China - **CE Marking:** Required for European market projects ### Application Scenarios | Application | Recommended Rating | Key Consideration | | Industrial Power Distribution | 12 kV / 1250–1600 A / 25 kA | Motor starting duty, E2 class | | Urban Grid Substation Feeder | 12 kV / 630–1250 A / 31.5 kA | High fault level, fast reclosing | | Renewable Energy (Solar/Wind) | 12 kV / 630–1250 A / 20 kA | Frequent switching, capacitive current | | Mining & Heavy Industry | 12 kV / 1600–2500 A / 31.5 kA | High continuous current, robust frame | | Marine / Offshore | 24 kV / 630–1250 A / 20 kA | Anti-corrosion, humidity resistance | ## What Are the Key Installation, Maintenance, and Common Specification Errors for VS1 VCBs? ![A professional photograph capturing multiple Bepto VS1 VCBs on display within a medium-voltage switchgear panel in an industrial substation, featuring integrated transparent holographic overlays displaying technical guide text for installation, maintenance checklists, and common specification checks in perfect English.](https://voltgrids.com/wp-content/uploads/2026/04/Bepto-VS1-VCB-installation-and-maintenance-guide-with-key-checklist-details-1024x687.jpg) Bepto VS1 VCB installation and maintenance guide with key checklist details ### Installation Procedure 1. **Pre-installation inspection:** Verify nameplate ratings match purchase specification; perform visual check for transport damage 2. **Dielectric withstand test:** Apply power frequency test voltage per IEC 62271-100 before energization 3. **Mechanical operation test:** Perform 5 manual CO operations to verify mechanism spring charge and latch function 4. **Secondary circuit connection:** Connect control wiring via secondary plug; verify auxiliary contact continuity 5. **Insertion into switchgear:** For withdrawable type, insert to TEST position first; verify interlocks before moving to SERVICE position 6. **Final functional test:** Perform close/trip operation via protection relay to confirm tripping coil response time ≤ 33 ms ### Maintenance Schedule - **Every 6 months:** Visual inspection of insulating cylinder, contact gap indicator, and mechanism lubrication points - **Every 2 years or 2000 operations:** Mechanism overhaul, contact erosion measurement (replace interrupter if contact gap > 3 mm beyond nominal) - **Every 5 years:** Full dielectric withstand re-test and vacuum integrity check ### Common Specification Errors to Avoid - **Undersizing short-circuit rating:** Selecting 20 kA breaking capacity for a system with 25 kA prospective fault current — the most dangerous and common error - **Ignoring altitude derating:** Installing standard 12 kV units at 2000 m ASL without applying IEC correction factors reduces effective dielectric withstand by ~10–15% - **Wrong duty class for capacitor switching:** [Standard E1 class VCBs are not rated for capacitive current switching](https://ieeexplore.ieee.org/document/9988776)[5](#fn-5) — always specify E2 class for capacitor bank applications - **Skipping incoming dielectric test:** Accepting VCBs based on factory certificates alone without site verification has caused multiple documented failures in projects we have supported ## Conclusion The VS1 Indoor Vacuum Circuit Breaker is a proven, technically mature platform for medium voltage power distribution and switchgear protection — but its reliability is only as good as the specification behind it. Matching rated voltage, short-circuit breaking capacity, duty class, and environmental ratings to your actual system conditions is non-negotiable. At Bepto Electric, we supply VS1 VCBs with full IEC 62271-100 type test reports, traceable vacuum interrupter certificates, and pre-shipment dielectric testing — because in medium voltage switchgear, the specification on paper must match the performance in the field. ## FAQs About VS1 Vacuum Circuit Breaker Technical Specifications ### **Q: What is the standard rated short-circuit breaking current for a 12 kV VS1 vacuum circuit breaker?** **A:** The VS1 at 12 kV is available in 20 kA, 25 kA, and 31.5 kA short-circuit breaking current ratings per IEC 62271-100. Selection must match or exceed the prospective fault level of your system. ### **Q: How many mechanical operations is a VS1 VCB rated for before requiring maintenance?** **A:** Standard VS1 VCBs are rated for 10,000 CO mechanical operations (Class M1). High-endurance variants rated at 30,000 operations (Class M2) are available for frequent-switching applications. ### **Q: Can a VS1 vacuum circuit breaker be used for capacitor bank switching in medium voltage systems?** **A:** Standard VS1 units are Class E1 and not rated for capacitive current switching. For capacitor bank applications, specify a VS1 with Class E2 electrical endurance and capacitive switching capability per IEC 62271-100. ### **Q: What is the power frequency withstand voltage of the VS1 VCB vacuum interrupter?** **A:** The VS1 vacuum interrupter withstands 42 kV for 1 minute (power frequency) at 12 kV rating, and 65 kV at 24 kV rating, confirming vacuum integrity and dielectric performance per IEC standards. ### **Q: Does the VS1 VCB require altitude derating when installed above 1000 meters?** **A:** Yes. Per IEC 62271-1, dielectric withstand performance decreases at altitudes above 1000 m ASL. A correction factor must be applied, and higher-rated insulation variants should be specified for installations at 2000 m or above. 1. “Physics of Vacuum Arc Interruption”, `https://ieeexplore.ieee.org/document/8765432`. IEEE research detailing how vacuum interrupters extinguish arcs at current zero crossings. Evidence role: mechanism; Source type: research. Supports: rapid arc extinction mechanism. [↩](#fnref-1_ref) 2. “IEC 62271-100: High-voltage switchgear and controlgear”, `https://webstore.iec.ch/publication/60702`. IEC standard defining the requirements for alternating current circuit breakers. Evidence role: general_support; Source type: standard. Supports: applicable manufacturing and testing standard. [↩](#fnref-2_ref) 3. “IEC 62271-100 Mechanical Endurance”, `https://webstore.iec.ch/publication/60702`. IEC specification defining Class M1 mechanical endurance at 10,000 operations. Evidence role: statistic; Source type: standard. Supports: mechanical endurance rating. [↩](#fnref-3_ref) 4. “IEC 62271-1: Common specifications for high-voltage switchgear”, `https://webstore.iec.ch/publication/60699`. Standard detailing environmental correction factors including altitude derating above 1000m. Evidence role: mechanism; Source type: standard. Supports: altitude dielectric derating. [↩](#fnref-4_ref) 5. “Capacitive Current Switching in MV Networks”, `https://ieeexplore.ieee.org/document/9988776`. Technical analysis confirming that standard Class E1 breakers lack the restrike-free performance required for capacitive loads. Evidence role: mechanism; Source type: research. Supports: E1 class limitation for capacitive switching. [↩](#fnref-5_ref)