Liquid-cooled charging cable

Glossary • SoC: battery state of charge, shown as a percentage.• Charge curve: how power rises, peaks, then tapers as SoC increases.• Preconditioning: the car warms or cools the battery before a fast charge so it’s at the right temperature.• Peak power: the maximum kW your car can draw, usually only for a short burst.• Power sharing: a site splits power between stalls when many cars plug in.• BMS: the car’s battery management system that keeps the pack safe and sets charging limits.     Why is the same car fast today and slow tomorrowThree scenes explain most slow sessions. 1. Cold morning. You may arrive with the cabin toasty but the battery still cold, and the car will reduce charging power to protect the cells.   2. Hot afternoon. Cable and electronics run hot. The system reduces power to hold safe temperature.   3. Busy site. Two or more stalls pull from the same cabinet. Each car gets a slice, so your power drops.     The charge curve explained Fast at low SoC, slower near full. Most cars charge quickest below roughly 50–60 percent, then taper as they pass 70–80 percent. The last 10–20 percent is the slowest part. If you need to save time, plan for short stops in the fast zone instead of one long session to near 100 percent.       What drivers can control in minutes• Navigate to the fast charger in your car’s system before you set off. This triggers battery preconditioning on many models.• Arrive low, leave smart. Reach the site around 10–30 percent, charge to the range you need, often 70–80 percent, then go.• Pick the right stall. If cabinets are labeled A–B or 1–2, choose a stall that is not paired or not in use.• Check the handle and cable. Avoid damaged connectors, tight kinks, or hot-to-the-touch cables.• Avoid back-to-back heat. If your car or the cable feels hot after a long drive, a five-minute cool-off with the car in Park can help the next ramp.     What site owners can control• Available power. Size cabinets and grid feed for peak times, not only averages.• Power allocation. Use dynamic sharing so a single active stall gets the full output.• Thermal design. Keep inlets, filters, and cable routing clear; add shade or airflow in hot climates.• Firmware and logs. Keep charger and CSMS software up to date; watch for stalls that derate early.• Maintenance. Inspect pins, seals, strain relief, and contact resistance; swap worn parts before they cause drop-offs.     Quick diagnostic path when charge is slower than expectedStep 1 — Check the car:• SoC above 80 percent → taper is normal; stop early if time matters.• Battery too cold or too hot warning → start preconditioning, move the car into shade or out of wind, retry. Step 2 — Check the stall:• Paired stall light is active or neighbor is charging → move to an unpaired or idle stall.• Cable or handle feels very hot, or visible damage → switch to another stall and report it. Step 3 — Check the site:• Many cars waiting, site at capacity → accept a reduced rate or route to the next hub on your path.     Action plan scorecard Situation Quick move Why it helps Typical result Arrive with high SoC Stop sooner; plan two short stops Stays in the fast zone of the curve More kWh per minute overall Cold battery in winter Precondition via car navigation Brings cells into the optimal window Higher initial kW Hot cable or stall Change to a shaded or idle stall Lowers thermal stress on hardware Less thermal derate Paired stalls are busy Pick an unpaired cabinet output Avoids power sharing More stable power Unknown slow-down cause Unplug, replug after 60 seconds Resets session and handshake Recover lost ramp     Cold and hot weather tipsWinter: Start preconditioning 15–30 minutes before arrival. Park out of strong wind while waiting. If you do short hops between chargers, the pack may never warm up; plan one longer drive before your fast stop.Summer: Shade matters. Canopies reduce heat on chargers and cables. If you tow or climb hills before charging, give the car a short cool-off with HVAC on but drive unit at rest.     How connectors and cables affect your speed windowThe charger cabinet sets the ceiling, and your car sets the rules, but the connector and cable decide how long you can stay near peak power. Lower contact resistance, clear heat paths, and good strain relief help the system hold current without early derating. In high-traffic sites, liquid-cooled DC cables widen the usable high-power window, while naturally cooled assemblies work well at moderate currents with simpler upkeep. Workersbee focus: Workersbee liquid-cooled CCS2 connector uses a tightly managed thermal path and accessible sensor layout to help sites hold higher current longer, with field-serviceable seals and defined torque steps for quick swaps.     Operations playbook for site owners• Design for the dwell you promise. If you market 10–80 percent in under 25–30 minutes for typical cars, size your cabinets and cooling for warm days and shared use. • Map cabinet-to-stall pairing in your signage. Drivers should know which stalls share a module. • Add human factors. Cable length, reach angles, and parking geometry change how easily drivers plug and route the cable. Shorter, slimmer cables reduce mishandling and damage. • Build a five-minute inspection. Look for pitted pins, loose latches, torn boots, and hot spots on thermal cameras during peak hours. Log any stall that tapers too early. • Keep spares ready. Stock handles, seals, and strain relief kits so a tech can restore full speed in one visit.     Common myths, clarifiedMyth: A 350 kW charger is always faster than a 150 kW unit.Reality: It depends on your car’s max accept rate and where you are on the charge curve. Many cars never draw 350 kW except for a short spike.   Myth: If power drops after 80 percent, the charger is faulty.Reality: Taper near full is normal and protects the battery. Stop early if you are in a hurry.   Myth: Cold weather always means slow charging.Reality: Cold plus no preconditioning is slow. With preconditioning and a longer drive before your stop, many cars can still charge briskly.     Driver checklist•  Set the fast charger as your destination in the car’s navigation so preconditioning starts automatically.• Arrive low, leave around 70–80 percent if time is key.• Choose an idle, non-paired stall.• Avoid damaged or overheated cables.• If speed is poor, unplug and retry on another stall.     Light maintenance cues for attendants• Clean and check the connector’s pins and seals every day.• Keep cables off the ground and avoid tight bends along the run.• Note stalls that show early derate or frequent retries; schedule a deeper check.• Review logs weekly for temperature alarms and handshake errors.     What this means for fleets and high-use sitesFleets live on predictable turn-times. Standardize driver behavior, keep the fastest stalls clearly signed, and protect thermal performance with shade and airflow. If you operate mixed hardware, tag which stalls hold current longest during summer peaks and route queuing there first. Workersbee can help by matching connector and cable sets to your cabinet ratings and climate. Workersbee naturally cooled and liquid-cooled assemblies are built for repeatable handling and quick field service, which supports consistent dwell times during busy hours.     Key takeaways• Charging speed follows a curve, not a single fixed number. Use the fast zone and avoid the slow tail.• Temperature and sharing are the two biggest hidden factors.• Small habits make big differences: precondition, arrive low, pick the right stall.• For sites, thermal design and upkeep keep high current alive longer.

What MCS isMCS is a high-power DC charging system for heavy-duty EVs such as long-haul trucks and coaches. Current industry targets reference a voltage window up to ~1,250 V and current up to ~3,000 A, enabling multi-megawatt peak power. Early pilots have already shown 1 MW sessions on prototype long-haul trucks.     Why the industry needs it nowDriver-hours rules create natural charging windows: in the EU, a 45-minute break is required after 4.5 hours of driving; in the U.S., a 30-minute break is required after 8 hours of driving. The practical goal for MCS is to turn those mandated stops into meaningful refueling events without breaking route plans or depot schedules.     How it works Power math. Power = Voltage × Current. At 1 MW, 30 minutes of charging delivers about 500 kWh (gross). Battery window. A long-haul pack in market today is often ~540–600+ kWh installed. A 20–80% top-up on a 600 kWh usable pack equals ~360 kWh—well within what a 1 MW stop can deliver in half an hour when thermal limits and charge curves allow. Real-world energy use. Heavy-duty e-trucks publicly tested at ~1.1 kWh/km (~1.77 kWh/mi). If ~460 kWh actually reaches the battery (illustrative ~92% DC-to-pack efficiency), a stop can recover roughly ~420 km (~260 mi) of range under favorable conditions. Hardware & thermal. High current requires liquid-cooled cables and embedded temperature sensing (e.g., PT1000-class RTDs in the cable/contacts) so the handle stays safe and manageable for repeated manual use. Communication. High-level vehicle–charger messaging authenticates the session, negotiates power, and carries metering and status data over higher-bandwidth links suited to fleet operations.     Standards and interoperabilityStandards programs for the system (requirements), EVSE, connector & inlet, vehicle behavior, and communications are moving in step so trucks and chargers from different brands work together at scale. System-level guidance and connector definitions now align with public pilots and lab testing; additional revisions are expected as field data grows.     Milestones and progress 1 MW pilot charging publicly demonstrated on a prototype long-haul e-truck (2024). Heavy-duty models publicly list MCS-class charge windows such as 20–80% in ~30 minutes as a design target for near-term rollouts. Connector/inlet test programs instrument couplers with multi-point thermocouples to validate temperature rise and duty cycles at very high current.     Where MCS lands first Freight corridors where a 30–45-minute stop must add hundreds of kilometers of range Intercity coach hubs with tight turnarounds Ports/logistics terminals with high daily energy throughput Mines/construction and other duty cycles that cycle large packs continuously     What makes MCS different from car fast charging Scale & duty cycle. Daily high-energy operations vs. occasional road-trip stops. Connector & cooling. Couplers for very high currents employ liquid cooling and ergonomics that support frequent, safe hand connects and disconnects.. Ergonomics. Inlet position and handle design account for large-vehicle geometry and future automation.     Planning the site and the grid (worked examples)   Capacity & topology Example A (four bays): If you plan 4×1 MW dispensers but expect ~0.6 simultaneity and 30-minute average dwell, diversified peak ~2.4 MW and nameplate peak 4 MW. Choose a transformer in the ~5 MVA class to leave headroom for auxiliaries and growth. Ramp rates at megawatt levels are steep; DC bus or modular cabinet architectures help route power where it’s needed without oversizing every bay.   Storage & load management A 1 MWh on-site battery can shave ~1 MW for one hour. In the four-bay example, storage can trim the grid tie from ~4 MW toward ~2.5–3 MW during overlapping 30-minute peaks, depending on control strategy. Smart power management smooths current ramps, pre-conditions packs, and prioritizes imminent departures.   Civil, thermal, environmental Shield coolant hoses and cable pathways, and reserve clear maintenance access around pumps and heat exchangers. Specify ingress protection for dust, moisture, and road grime; plan ventilation for enclosures. Use quick-swap subassemblies (handles, cable sections, seals, sensors) to keep uptime high.   Operations & uptime Track both charger-side and vehicle-side fault codes; align spares & SLAs with route commitments. Make interoperability tests part of commissioning; early fixes are months of uptime gained.     Safety & compliance highlights Lockout, leakage/insulation monitoring, emergency-stop chains, and short-circuit energy handling are part of the spec family. Thermal limits and temperature sensing in cables/connectors keep surface temperatures and contact temperatures within safe bounds for repeated use. Ergonomic placement and handle geometry keep manual coupling practical at scale.     Procurement & rollout checklist Vehicle compatibility: inlet location, voltage window, current limits, communication profiles supported now and via firmware Power strategy: dispensers now, maximum per site later, and how cabinets/power blocks can be reconfigured Cooling & service: coolant type, service intervals, field-replaceable modules Cyber & billing: authentication methods, tariff options, secure update paths, metering class     Commissioning & QA: interop with target trucks, thermal & current-ramp tests, baseline KPIs (utilization, session efficiency, station availability)     FAQHow fast is it in practicePublic pilots at ~1 MW have shown ~20–80% in about 30 minutes on long-haul prototypes, with actual time governed by pack size, temperature, and the vehicle’s charge curve. Will passenger cars use MCSNo. MCS is tailored to heavy vehicles; cars continue with connectors and power levels optimized for smaller packs. Is liquid cooling requiredFor hand-held cables at very high current, liquid cooling is the practical way to keep temperature and weight within safe limits. What about the standards timelineSystem, EVSE, coupler, vehicle-side, and communications documents are being published/updated in coordination with field experience and interop events; further revisions are expected as deployments grow.     Workersbee and MCSWorkersbee is a connector-focused R&D and manufacturing partner. We have initiated development of a reliable MCS connector engineered for high-current, liquid-cooled operation, ergonomic handling, and maintainability. Prototyping and validation are underway, with a targeted market launch in 2026.