mababang porsyentong on-line UPS power supply (3-phase input 1-phase output)
Mga pangunahing katangian
| Brand | Switchgear parts |
| Numero ng Modelo | mababang porsyentong on-line UPS power supply (3-phase input 1-phase output) |
| Narirating na pagsasalungat | 50/60Hz |
| Lalabas na voltaje | 405VDC/220VDC |
| Paggalang ng Input | 380V |
| Kapasidad | 10kVA |
| Serye | HBD |
Mga paglalarawan ng produkto mula sa supplier
Mga Katangian ng Produkto
Teknolohiya ng matalinong digital na kontrol
Ginagamit ang mataas na bilis na microcontroller at programmable logic devices ng Intel upang makamit ang kontrol sa circuit, pagtakda ng mga parameter, pamamahala sa operasyon, advanced self-test at self-detection functions. Ito ay maaaring gumawa ng self-test at fault analysis sa lahat ng independiyenteng koneksyon ng circuit sa circuit board. Maaari kang mabigyan ng buong tiwala sa digital na naging sine wave voltage at bagong solusyon para sa perpektong operasyon upang matugunan ang iyong aktwal na pangangailangan.
Epektibong teknolohiya ng IGBT (Insulated Gate Bipolar Transistor) inverter
Ang IGBT ay may kahanga-hangang katangian sa mabilis na switching; Mayroong katangian ng mataas na voltaje at mataas na current; Ginagamit ang voltage type drive, kung saan ang maliit na kontrol na lakas lamang ang kinakailangan. Ang ika-anim na henerasyon ng IGBT ay may mas mababang saturation voltage drop, mas mataas na inverter efficiency, at mas mataas na reliabilidad.
Pinakamahusay na katangian ng load
Buong pagtugon sa transisyon mula sa 0 hanggang 100% load nang walang paglipat sa bypass, at protektahan ang maayos at mapagkakatiwalaang output.
Mapagkalingang malaking LCD display sa Chinese at English
Ang malaking screen ay nagpapakita ng menu sa Chinese at English, na may malinaw na flow chart na nagpapakita ng status ng operasyon, na nagbibigay-daan sa flexible na pagpapatupad ng mga function ng tao-makinang diyalogo. Intuwitibong LED status indication, workflow style status indication, malinaw sa isang tingin.
Mataas na performance na dynamic characteristics
Ang maraming feedback controls tulad ng instantaneous control at effective value ay ginagamit upang makamit ang mataas na dynamic regulation at bawasan ang distortion ng output voltage.
Kompletong function ng proteksyon
Ang maraming sistema ng proteksyon at alarm functions, kasama ang input/output overvoltage protection, input surge protection, phase sequence protection, battery low voltage protection, output overvoltage protection, at high temperature protection.
Intelligent battery management
Intelligent battery charging: Automatic adjustment ng mga charging parameters ng battery ayon sa configuration ng battery ng user, at paggawa ng equalization at float charging conversion, temperature compensation charging at discharging management sa battery ayon sa power supply environment. Palawigin ang lifespan ng battery at bawasan ang burden sa mga administrator.
Paggamit ng 6-pulse (optional 12 pulse) rectifier charger habang idinadagdag ang input harmonic filter
Epektibong pagsupil sa input harmonic pollution, pag-improve ng input power factor ng UPS power supply, at pagbawas ng input harmonic current.
intelligent monitoring
Ang RS232 at RS485 communication ports ay tunay na nagbibigay-daan sa multi-purpose communication at remote monitoring. Optional na SNMP card para sa remote monitoring at network management; Optional na dry contact interface, gamit ang passive contacts upang monitorin ang status ng UPS.
Larangan ng Application
Sapat para sa mga industriya tulad ng finance, telecommunications, securities, taxation, transportation, insurance, government, building lighting, road traffic lighting, electricity, at industrial at mining enterprises.
Mga Teknikal na Specification
| Model | HBD-6KS | HBD-10KS | HBD-15KS | HBD-20KS | HBD-30KS | HBD-40KS | HBD-50KS | HBD-60KS | HBD-80KS |
|---|---|---|---|---|---|---|---|---|---|
| Nominal Capacity | 6KVA | 10KVA | 15KVA | 20KVA | 30KVA | 40KVA | 50KVA | 60KVA | 80KVA |
| Working Mode and Principle | Online Power Supply, Static Bypass Switch (No-break Switching), Double Conversion Technology | Online Power Supply, Static Bypass Switch (No-break Switching), Double Conversion Technology | Online Power Supply, Static Bypass Switch (No-break Switching), Double Conversion Technology | Online Power Supply, Static Bypass Switch (No-break Switching), Double Conversion Technology | Online Power Supply, Static Bypass Switch (No-break Switching), Double Conversion Technology | Online Power Supply, Static Bypass Switch (No-break Switching), Double Conversion Technology | Online Power Supply, Static Bypass Switch (No-break Switching), Double Conversion Technology | Online Power Supply, Static Bypass Switch (No-break Switching), Double Conversion Technology | Online Power Supply, Static Bypass Switch (No-break Switching), Double Conversion Technology |
| AC Input | |||||||||
| Phase Number | Three Phase (A, B, C+N+G) | Three Phase (A, B, C+N+G) | Three Phase (A, B, C+N+G) | Three Phase (A, B, C+N+G) | Three Phase (A, B, C+N+G) | Three Phase (A, B, C+N+G) | Three Phase (A, B, C+N+G) | Three Phase (A, B, C+N+G) | Three Phase (A, B, C+N+G) |
| Input Nominal Voltage | 380 VAC | 380 VAC | 380 VAC | 380 VAC | 380 VAC | 380 VAC | 380 VAC | 380 VAC | 380 VAC |
| Input Voltage Range | ± 25% | ± 25% | ± 25% | ± 25% | ± 25% | ± 25% | ± 25% | ± 25% | ± 25% |
| Nominal Frequency | 50Hz ± 10%, 60Hz ± 10% | 50Hz ± 10%, 60Hz ± 10% | 50Hz ± 10%, 60Hz ± 10% | 50Hz ± 10%, 60Hz ± 10% | 50Hz ± 10%, 60Hz ± 10% | 50Hz ± 10%, 60Hz ± 10% | 50Hz ± 10%, 60Hz ± 10% | 50Hz ± 10%, 60Hz ± 10% | 50Hz ± 10%, 60Hz ± 10% |
| Voltage Harmonic Distortion | <5% | <5% | <5% | <5% | <5% | <5% | <5% | <5% | <5% |
| Soft Start | 0~100% 5sec | 0~100% 5sec | 0~100% 5sec | 0~100% 5sec | 0~100% 5sec | 0~100% 5sec | 0~100% 5sec | 0~100% 5sec | 0~100% 5sec |
| Battery (Maintenance-free Lead-acid Battery) | |||||||||
| Nominal Voltage | 360VDC/192VDC | 360VDC/192VDC | 360VDC/192VDC | 360VDC/192VDC | 360VDC/192VDC | 360VDC/192VDC | 360VDC/192VDC | 360VDC/192VDC | 360VDC/192VDC |
| Quantity Unit | 30 cells/12V in series (16 cells/12V in series) | 30 cells/12V in series (16 cells/12V in series) | 30 cells/12V in series (16 cells/12V in series) | 30 cells/12V in series (16 cells/12V in series) | 30 cells/12V in series (16 cells/12V in series) | 30 cells/12V in series (16 cells/12V in series) | 30 cells/12V in series (16 cells/12V in series) | 30 cells/12V in series (16 cells/12V in series) | 30 cells/12V in series (16 cells/12V in series) |
| Charging | |||||||||
| Maximum Output Voltage | 405VDC/220VDC | 405VDC/220VDC | 405VDC/220VDC | 405VDC/220VDC | 405VDC/220VDC | 405VDC/220VDC | 405VDC/220VDC | 405VDC/220VDC | 405VDC/220VDC |
| Float Voltage | 405VDC/220VDC (Automatic Battery Equalization Once Every 3 Months, Charging Voltage 435VDC/232VDC) | 405VDC/220VDC (Automatic Battery Equalization Once Every 3 Months, Charging Voltage 435VDC/232VDC) | 405VDC/220VDC (Automatic Battery Equalization Once Every 3 Months, Charging Voltage 435VDC/232VDC) | 405VDC/220VDC (Automatic Battery Equalization Once Every 3 Months, Charging Voltage 435VDC/232VDC) | 405VDC/220VDC (Automatic Battery Equalization Once Every 3 Months, Charging Voltage 435VDC/232VDC) | 405VDC/220VDC (Automatic Battery Equalization Once Every 3 Months, Charging Voltage 435VDC/232VDC) | 405VDC/220VDC (Automatic Battery Equalization Once Every 3 Months, Charging Voltage 435VDC/232VDC) | 405VDC/220VDC (Automatic Battery Equalization Once Every 3 Months, Charging Voltage 435VDC/232VDC) | 405VDC/220VDC (Automatic Battery Equalization Once Every 3 Months, Charging Voltage 435VDC/232VDC) |
| Microcomputer-set Charging Current | 1A~50A (Automatically Adjusted to 0.1C According to Battery Capacity) | 1A~50A (Automatically Adjusted to 0.1C According to Battery Capacity) | 1A~50A (Automatically Adjusted to 0.1C According to Battery Capacity) | 1A~50A (Automatically Adjusted to 0.1C According to Battery Capacity) | 1A~50A (Automatically Adjusted to 0.1C According to Battery Capacity) | 1A~50A (Automatically Adjusted to 0.1C According to Battery Capacity) | 1A~50A (Automatically Adjusted to 0.1C According to Battery Capacity) | 1A~50A (Automatically Adjusted to 0.1C According to Battery Capacity) | 1A~50A (Automatically Adjusted to 0.1C According to Battery Capacity) |
| AC Output | |||||||||
| Rated Power (KW COSφ=0.8) | Nominal Power × 0.8 | Nominal Power × 0.8 | Nominal Power × 0.8 | Nominal Power × 0.8 | Nominal Power × 0.8 | Nominal Power × 0.8 | Nominal Power × 0.8 | Nominal Power × 0.8 | Nominal Power × 0.8 |
| Phase Number | Single Phase (L+N+G) | Single Phase (L+N+G) | Single Phase (L+N+G) | Single Phase (L+N+G) | Single Phase (L+N+G) | Single Phase (L+N+G) | Single Phase (L+N+G) | Single Phase (L+N+G) | Single Phase (L+N+G) |
| Nominal Phase Voltage | 220VAC ± 1% (Stable Load), 220VAC ± 5% (Load Fluctuation) | 220VAC ± 1% (Stable Load), 220VAC ± 5% (Load Fluctuation) | 220VAC ± 1% (Stable Load), 220VAC ± 5% (Load Fluctuation) | 220VAC ± 1% (Stable Load), 220VAC ± 5% (Load Fluctuation) | 220VAC ± 1% (Stable Load), 220VAC ± 5% (Load Fluctuation) | 220VAC ± 1% (Stable Load), 220VAC ± 5% (Load Fluctuation) | 220VAC ± 1% (Stable Load), 220VAC ± 5% (Load Fluctuation) | 220VAC ± 1% (Stable Load), 220VAC ± 5% (Load Fluctuation) | 220VAC ± 1% (Stable Load), 220VAC ± 5% (Load Fluctuation) |
| Nominal Frequency | 50Hz ± 0.1% (Battery Power Supply) | 50Hz ± 0.1% (Battery Power Supply) | 50Hz ± 0.1% (Battery Power Supply) | 50Hz ± 0.1% (Battery Power Supply) | 50Hz ± 0.1% (Battery Power Supply) | 50Hz ± 0.1% (Battery Power Supply) | 50Hz ± 0.1% (Battery Power Supply) | 50Hz ± 0.1% (Battery Power Supply) | 50Hz ± 0.1% (Battery Power Supply) |
| Frequency Stability: Asynchronous | < ± 0.1% | < ± 0.1% | < ± 0.1% | < ± 0.1% | < ± 0.1% | < ± 0.1% | < ± 0.1% | < ± 0.1% | < ± 0.1% |
| Frequency Stability: Synchronous | < ± 5% | < ± 5% | < ± 5% | < ± 5% | < ± 5% | < ± 5% | < ± 5% | < ± 5% | < ± 5% |
| Crest Factor | 3: 1 | 3: 1 | 3: 1 | 3: 1 | 3: 1 | 3: 1 | 3: 1 | 3: 1 | 3: 1 |
| Output Waveform | Sine Wave | Sine Wave | Sine Wave | Sine Wave | Sine Wave | Sine Wave | Sine Wave | Sine Wave | Sine Wave |
| Total Harmonic Distortion | Linear Load < 3%; Non-linear Load < 5% | Linear Load < 3%; Non-linear Load < 5% | Linear Load < 3%; Non-linear Load < 5% | Linear Load < 3%; Non-linear Load < 5% | Linear Load < 3%; Non-linear Load < 5% | Linear Load < 3%; Non-linear Load < 5% | Linear Load < 3%; Non-linear Load < 5% | Linear Load < 3%; Non-linear Load < 5% | Linear Load < 3%; Non-linear Load < 5% |
| Operating Temperature | 0~40℃ | 0~40℃ | 0~40℃ | 0~40℃ | 0~40℃ | 0~40℃ | 0~40℃ | 0~40℃ | 0~40℃ |
| Relative Humidity | 30%~90% (No Condensation) | 30%~90% (No Condensation) | 30%~90% (No Condensation) | 30%~90% (No Condensation) | 30%~90% (No Condensation) | 30%~90% (No Condensation) | 30%~90% (No Condensation) | 30%~90% (No Condensation) | 30%~90% (No Condensation) |
| Operating Altitude | < 1000 meters (Power Drops by 1% for Every 100 Meters Increase, Maximum 3000 Meters) | < 1000 meters (Power Drops by 1% for Every 100 Meters Increase, Maximum 3000 Meters) | < 1000 meters (Power Drops by 1% for Every 100 Meters Increase, Maximum 3000 Meters) | < 1000 meters (Power Drops by 1% for Every 100 Meters Increase, Maximum 3000 Meters) | < 1000 meters (Power Drops by 1% for Every 100 Meters Increase, Maximum 3000 Meters) | < 1000 meters (Power Drops by 1% for Every 100 Meters Increase, Maximum 3000 Meters) | < 1000 meters (Power Drops by 1% for Every 100 Meters Increase, Maximum 3000 Meters) | < 1000 meters (Power Drops by 1% for Every 100 Meters Increase, Maximum 3000 Meters) | < 1000 meters (Power Drops by 1% for Every 100 Meters Increase, Maximum 3000 Meters) |
| Options | RS485 Network Adapter (SNMP) / Cabinet Size Can Be Designed According to Requirements | RS485 Network Adapter (SNMP) / Cabinet Size Can Be Designed According to Requirements | RS485 Network Adapter (SNMP) / Cabinet Size Can Be Designed According to Requirements | RS485 Network Adapter (SNMP) / Cabinet Size Can Be Designed According to Requirements | RS485 Network Adapter (SNMP) / Cabinet Size Can Be Designed According to Requirements | RS485 Network Adapter (SNMP) / Cabinet Size Can Be Designed According to Requirements | RS485 Network Adapter (SNMP) / Cabinet Size Can Be Designed According to Requirements | RS485 Network Adapter (SNMP) / Cabinet Size Can Be Designed According to Requirements | RS485 Network Adapter (SNMP) / Cabinet Size Can Be Designed According to Requirements |
| Dimensions (W×D×H) mm | 390×659×860 | 430×760×1350 | 710×720×1450 | 710×850×1500 | - | - | - | 1100×860×1680 | - |
| Main Unit Weight | 150 | 199 | 220 | 305 | 380 | 480 | 566 | 590 | 986 |
Tandaan: Ang modelo na may built-in na baterya at espesyal na mga pangangailangan sa voltaje ay maaaring i-customize ayon sa aktwal na sitwasyon ng user, at isusumite ang hiwalay na quotation.
① Overload alarm: Unplug non-essential single-phase loads, or replace with a larger capacity UPS; ② Phase loss alarm: Check 3-phase input wiring, repair loose or disconnected cables; ③ Battery low alarm: Charge continuously for 12 hours, replace aging batteries if the alarm persists; ④ Output voltage abnormal: Check output wiring, reset UPS (disconnect power and restart after 5 minutes); ⑤ Transformer overheating: Stop using immediately, check ventilation and load, contact after-sales for maintenance.
① Alarma ng overload: I-unplug ang mga hindi mahalagang single-phase na load, o palitan ito ng mas malaking kapasidad na UPS; ② Alarma ng phase loss: Suriin ang 3-phase input wiring, ayusin ang mga loose o disconnected na kable; ③ Alarma ng mababang battery: I-charge nang walang tigil sa 12 oras, palitan ang mga nag-aaging battery kung patuloy pa ang alarma; ④ Abnormal na output voltage: Suriin ang output wiring, i-reset ang UPS (i-disconnect ang power at i-restart pagkatapos ng 5 minuto); ⑤ Overheating ng transformer: I-stop ang paggamit agad, suriin ang ventilation at load, makipag-ugnayan sa after-sales para sa maintenance.
Ang pangunahing punsiyon nito ay ang pag-convert ng 3-phase mains power sa stable 1-phase power, nagbibigay ng walang pagkaputol, malinis na kuryente para sa single-phase critical loads habang sinusolve ang mga problema sa mains tulad ng voltage fluctuation, harmonic interference at power outage. Prinsipyo ng paggana: Ang double conversion (AC-DC-AC) + low-frequency transformer design. Kapag normal ang mains, ang 3-phase AC ay ina-convert sa DC upang mag-charge ng battery, pagkatapos ay ina-convert ang DC sa 1-phase pure sine wave AC para sa load supply; kapag nabigo ang mains, ito ay lumilipat sa battery power na may 0ms transfer time,
Mga Produkto na May Kaugnayan
-
Mataas na porsyentong online UPS power supply (Single phase/220V)
-
Mataas na porsyentong on-ine UPs power supply (3Phase Input1Phase output)
-
Mataas na pagsasanay sa frequency on-line (rack type) uPs power supply
-
Mataas na peryodyong on-line UPS (3phase in at 3phase out)
-
mababang patak na on-line UPS power supply (single phase 220V)
-
Mababang porsyentong on-line UPS na suplay ng kuryente (3-phase in at 3-phase out)
-
Modular na UPS na walang pagkakatigil ng supply ng kuryente
Mga Kaugnay na Kaalaman
-
Pagsasalamin ng DC Bias sa mga Transformer sa mga Renewable Energy Station Malapit sa UHVDC Grounding ElectrodesPagsasalamin ng DC Bias sa mga Transformer sa mga Renewable Energy Station Malapit sa UHVDC Grounding ElectrodesKapag ang grounding electrode ng isang Ultra-High-Voltage Direct Current (UHVDC) transmission system ay nasa malapit sa isang renewable energy power station, ang nagbabalik na current na umuusbong sa lupa ay maaaring magdulot ng pagtaas ng ground potential sa paligid ng lugar ng electrode. Ang pagtaas ng ground potential na ito ay nagdudulot ng paglipat ng neutral-point potential ng mg01/15/2026 -
HECI GCB para sa Mga Generator – Mabilis na SF₆ Circuit Breaker1. Paglalarawan at Pamamagitan1.1 Tungkulin ng Generator Circuit BreakerAng Generator Circuit Breaker (GCB) ay isang kontroladong punto ng paghihiwalay na matatagpuan sa pagitan ng generator at step-up transformer, na nagbibigay-daan bilang interface sa pagitan ng generator at power grid. Ang pangunahing tungkulin nito kasama ang paghihiwalay ng mga fault sa gilid ng generator at pagbibigay ng operasyonal na kontrol sa panahon ng pagsasama-sama ng generator at koneksyon sa grid. Ang prinsipyong01/06/2026 -
Pagsusuri Pagsisiyasat at Pagsasauli ng mga Kagamitan sa Distribusyon ng Transformer1. Pagsugpo at Inspeksyon sa Transformer Buksan ang low-voltage (LV) circuit breaker ng transformer na sinusubok, alisin ang control power fuse, at ilagay ang babala na “Huwag Isara” sa hawakan ng switch. Buksan ang high-voltage (HV) circuit breaker ng transformer na sinusubok, isara ang grounding switch, ganap na i-discharge ang transformer, i-lock ang HV switchgear, at ilagay ang babala na “Huwag Isara” sa hawakan ng switch. Para sa pagsugpo sa dry-type transformer: una, linisin ang porcelain12/25/2025 -
Paano Subukan ang Resistance ng Insulation ng mga Distribution TransformersSa praktikal na gawain, karaniwang sinusukat ang resistance ng insulation ng mga distribution transformers nang dalawang beses: ang resistance ng insulation sa pagitan ng high-voltage (HV) winding at low-voltage (LV) winding kasama ang tangki ng transformer, at ang resistance ng insulation sa pagitan ng LV winding at HV winding kasama ang tangki ng transformer.Kung parehong sukat ay nagbibigay ng tanggap na halaga, ito ay nagpapahiwatig na ang insulation sa pagitan ng HV winding, LV winding, at12/25/2025 -
Pangunahing Patakaran para sa mga Pole-Mounted Distribution TransformersPrinsipyo ng disenyo para sa mga pole-mounted na distribution transformers(1) Prinsipyo ng Lokasyon at LayoutAng platform ng pole-mounted transformer ay dapat ilagay malapit sa sentro ng load o malapit sa mga kritikal na loads, sumusunod sa prinsipyo ng "maliit na kapasidad, maraming lokasyon" upang mapadali ang pagpapalit at pag-aayos ng mga aparato. Para sa suplay ng kuryente sa mga tirahan, maaaring ilagay ang mga three-phase transformers malapit batay sa kasalukuyang pangangailangan at mga p12/25/2025 -
Mga Solusyon sa Pagkontrol ng Ingay ng Transformer para sa Iba't Ibang Pagsasakatawan1. Pagpapababa ng Ingay para sa Mga Silid na Transformer sa Ibabaw ng LupaStratehiya sa Pagpapababa ng Ingay:Una, gawin ang inspeksyon at pagmamanntento ng transformer nang walang kuryente, kasama ang pagsasalitla ng lumang langis na pang-insulate, pagsusuri at pagtigil ng lahat ng mga panakip, at paglilinis ng abo mula sa yunit.Pangalawa, palakihin ang pundasyon ng transformer o mag-install ng mga disenyo ng vibration isolation—tulad ng rubber pads o spring isolators—na pinili batay sa kabuuang12/25/2025
