maumizi ya umeme ya chini ya maelezo yenye mtandao (ingizo la tatu fasi mwisho wa moja fasi)
Sifa muhimu
| Chapa | Switchgear parts |
| Namba ya Modeli | maumizi ya umeme ya chini ya maelezo yenye mtandao (ingizo la tatu fasi mwisho wa moja fasi) |
| mfumo wa mafano | 50/60Hz |
| voltage ya chukua | 405VDC/220VDC |
| Ingizo la umeme | 380V |
| uwezo | 15kVA |
| Siri | HBD |
Maelezo ya bidhaa kutoka kwa mchambishi
Mipango ya Matumizi
Tecnologia ya kawaida ya utumiaji wa namba
Kutumia mikakamati yasiyofaa za Intel na vifaa vilivyotengenezwa vya muktadha kutumika katika kudhibiti mwendo, kupanga miundombinu, udhibiti wa uendeshaji, tasnia nyingi zisizo na mtazamo na kujitathmini, inaweza kufanya kujitathmini na kuanaliza hitilafu kwenye vitambulisho vyote muonekano vya mkataba. Unaweza kuaminika sana na sinusoidi iliyo transformika kwa njia ya namba na suluhisho jipya cha kazi nzuri kutoa haja zako halisi.
Tecnologia ya kusambaza IGBT (Insulated Gate Bipolar Transistor) yenye ufanisi
IGBT ana umuhimu mzuri wa kusambaza haraka; Ina umuhimu wa kazi wa nguvu ya juu na kima la kasi; Kutumia kudhibiti aina ya nguvu, hutahitaji nguvu ndogo tu ya kudhibiti. IGBT wa kizazi chenye tano ana ongezeko la chini la kusambaza, ufanisi wa kusambaza wa juu, na uhakika wa juu.
Umuhimu wa kiwango cha juu wa ukaribu
Inakidhi tamani kabisa ya kutumia kutoka 0 hadi 100% bila kubadilisha kwenye njia tofauti, na kuhifadhi matumizi yanayoweza kuzingatia na kutosha.
Chora kubwa cha LCD chenye kielelezo cha Kiingereza na Kichina
Chora kubwa kinachoelezea menyu cha Kiingereza na Kichina, na mchoro wa mzunguko wa kazi unaoonyesha hali ya kazi, kunaweza kutekeleza maslahi ya majadiliano ya binadamu na mashine kwa urahisi. Ishara ya LED yenye umuhimu wa kutosha, ishara ya hali ya mtaani, yenye umebaini.
Sifa zenye ufanisi wa kutosha
Imetumia usimamizi wa makosa mengi kama vile kudhibiti moja kwa moja na thamani yenye umuhimu wa kutosha kuboresha usimamizi wa kutosha na kupunguza upindelezi wa nguvu ya kutoa.
Funga rasilmali kamili
Vifaa vingineo vya kuhifadhi na kutoa taarifa, ikiwa ni kama kuhifadhi kwa nguvu ya juu ya kuingiza/kutoa, kuhifadhi kwa mapinduzi ya kuingiza, kuhifadhi kwa mfumo wa viwango, kuhifadhi kwa nguvu ya chini ya batili, kuhifadhi kwa nguvu ya juu ya kutoa, na kuhifadhi kwa joto la juu.
Udhibiti wa batili wenye hekima
Kuchanjo kwa batili kwa njia ya kihesabu: Kurekebisha parameta za kuchanjo kwa batili kulingana na mbinu ya batili ya mtumiaji, na kutekeleza mabadiliko ya kuchanjo sawa na kuchanjo la kivuli, chanjo la majira na kudhibiti kwa kutosha batili kulingana na mazingira ya umeme. Kuongeza muda wa maisha wa batili na kupunguza changamoto za wawekezaji.
Kutumia kucha kwenye kuchanjo cha 6-pulse (chaguo la 12 pulse) na kuongeza filtri ya harmoniki ya kuingiza
Kupunguza uzalishaji wa harmoniki za kuingiza, kuboresha sehemu ya nguvu ya kuingiza ya UPS, na kupunguza nguvu ya harmoniki ya kuingiza.
kujitambua kwa hekima
Mifumo ya mawasiliano ya RS232 na RS485 yanayoweza kutekeleza mawasiliano mengi na kujitambua mbali. Kadi ya SNMP chaguo la kujitambua mbali na kudhibiti mtandao; Mfululizo wa chaguo wa kushiriki, kutumia mashambulizi ya pasiva kutambua hali ya UPS.
Maeneo ya kutumia
Inaweza kutumiwa na sekta kama vile fedha, mawasiliano, hisa, kodi, nyanja, bima, serikali, mwanga wa nyumba, mwanga wa barabara, umeme, na mashirika ya kiuchumi na kichekundu.
Speki za teknolojia
| 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 |
Kumbuka: Mfumo unaoungwa na mizigo ya ndani na maagizo ya umeme vya kipekee yanaweza kutengenezwa kulingana na hali yake ya mtumiaji, na utaratibu wa pepe watafanyika.
Chanzo changuku lake ni kubadilisha umeme wa maingizo ya 3-phase kuwa umeme wa 1-phase yenye ustawi, kukusanya, na upweke wa umeme wa aina muhimu moja-kata huku kutatua matatizo ya maingizo kama vile mvuto wa volaji, ushirikiano wa harmoniki, na mafanikio ya umeme. Mbinu ya kufanya kazi: Chagua ubadilishaji wa mara mbili (AC-DC-AC) + ukuta wa transformer wa namba ndogo. Wakati maingizo yanaonekana sahihi, AC ya 3-phase inabadilishwa kuwa DC ili kumpa nguvu batte, basi DC inabadilishwa tena kuwa AC safi ya mwanga wa sine wa 1-phase kwa ajili ya kutumia; wakati maingizo huenda kushindwa, inabadilika kwa nguvu ya batte bila muda wa sekunde 0,
Bidhaa Zinazohusiana
-
Mfuko wa umeme wa awali wa kiwango kikuu (Fasi moja/220V)
-
Usumavu wa umeme wa kiwango cha juu wa IEE-Business (Ingizo ya vipimo vitatu tofauti na matumizi ya vipimo moja)
-
Mwendo wa ujenzi wa nguvu wa ukuaji wa muda (aibu ya rack) uPs
-
Ujenzi wa muktadha wa awali wa kiwango cha juu (mfululizo 3 na tofauti 3)
-
umeme wa kutosha chache unaoendelea (fasi moja 220V)
-
Mipango ya umeme ya chini ya kasi ya mtandaoni (kuingiza na kutokana na 3 fasi)
-
Modular UpS usaidizi wa umeme usiofunguka
Maelezo Yanayohusiana
-
Utafiti wa Athari za DC Bias katika Transformers kwenye Viwanda vya Nishati ya Mapumziko karibu na Elektrodi za UHVDCAthari ya DC Bias katika Transformers kwenye Viwanja vya Nishati Mpya karibu na UHVDC Grounding ElectrodesWakati grounding electrode wa mfumo wa uhamiaji wa umeme wa kiwango cha juu sana (UHVDC) unaokazwa karibu na viwanja vya nishati mpya, kivuko la kijani kilichopita kwa ardhi kinaweza kusababisha ongezeko la potential ya ardhi karibu na eneo la electrode. Hii inatofautiana kwa potential ya neutral-point ya transformers wanaokazwa karibu, kusababisha DC bias (au DC offset) katika cores zao. DC01/15/2026 -
HECI GCB kwa Mawimbi – Kifuniko la Kufunga Sifa ya SF₆ Haraka1. Maana na Kazi1.1 Uelewa wa Kitambaa cha Mzunguko wa Umeme wa MgeniKitambaa cha Mzunguko wa Umeme wa Mgeni (GCB) ni kitambaa chenye upatikanaji unaweza kutathmini kati ya mgeni na transformer wa kuongeza nguvu, kama msingi wa uhusiano kati ya mgeni na mtandao wa umeme. Mikazi yake muhimu zinazofaa ni kuzuia matukio katika upande wa mgeni na kuwasaidia mikakati za utaratibu wakati wa ushirikiano wa mgeni na mtandao wa umeme. Sera ya kufanya kazi ya GCB haijabadilika sana kutoka kwa kitambaa cha01/06/2026 -
Uchunguzi Mstari wa Mfumo wa Umeme Utekelezaji wa Programu na Huduma za IEE-Business Usimamizi wa Vifaa vya Kupanuliwa Usimamizi wa Vifaa vya Umeme Utambuzi wa Vifaa vya Umeme Usimamizi wa Vifaa vya Umeme1.Uchunguzi na Huduma ya Mfumo wa Transformer Fungua kitufe cha mzunguko wa chini (LV) cha transformer uliyochukua huduma, ooa fujo la nguvu ya mikakati, na egereka ishara inayosema "Usifunge" kwenye mfuko wa kitufe. Fungua kitufe cha mzunguko wa juu (HV) cha transformer uliyochukua huduma, funga kitufe cha kuenea ardhi, tofautisha kamili transformer, fungua sanduku la HV, na egereka ishara inayosema "Usifunge" kwenye mfuko wa kitufe. Kwa uchunguzi wa transformer wa kiwango cha ukoma: mwanzo saf12/25/2025 -
Jinsi ya Kutest Ukingo wa Kawaida wa Mawimbi ya UgawajiKatika kazi ya kinyume, uwiano wa upambanisho wa muktadha wa umeme unaokukabiliana mara mbili: uwiano wa upambanisho kati ya kioti za kiwango cha juu (HV) na kioti za kiwango cha chini (LV) zingine pamoja na bakuli la muktadha, na uwiano wa upambanisho kati ya kioti za LV na kioti za HV zingine pamoja na bakuli la muktadha.Ikiwa maonyesho yote miwili yanapato thamani inayotumaini, hii inaonesha kuwa upambanisho kati ya kioti za HV, kioti za LV, na bakuli la muktadha unafai. Ikiwa maonyesho moja12/25/2025 -
Mistari ya Ubuni kwa Mfumo wa Kukabiliana na Umeme wa Pole-MountedMistari ya Ujenzi kwa Transformers za Ugawaji zenye Mti(1) Mistari ya Eneo na MipangoVituo vya transformers vilivyowekwa kwenye miti yanapaswa kuweka karibu na kituo cha ongezeko au karibu na ongezeko muhimu, kufuata sera ya "ukubwa mdogo, maeneo mengi" ili kusaidia uabadilishaji na huduma. Kwa ugawaji wa nyumba, transformers zinazokuwa tatu zinaweza kuwekwa karibu kutegemea na matumizi ya sasa na projesheni za ukuaji wa baadaye.(2) Chaguzi ya Upeo kwa Transformers Zenye Mti TatuUpeo wa viwango12/25/2025 -
Suluhisho za Kudhibiti Samimi wa Muundo kwa Matumizi Yoyote1. Uchunguzi wa Mwito kwa Nyumba za Tengeji Mstari Zinazokuwa na Uhuru wa KijijiStrategia ya Uchunguzi:Awali, fanya utafiti wa umeme usiwe na mshumaa na huduma za tengeji, ikiwa kinachohitaji kubadilisha mafuta yasiyo jadida, kutathmini na kutimiza vyombo vingine, na kutofautisha chakula kutoka kwenye kitengo.Pili, zidhibiti msingi wa tangeji au weka vifaa vya uchunguzi wa vibale—kama mitumbo ya gomvi au spring isolators—kutegemea kwa ukuu wa vibale.Taishan, zidhibiti mwito wa maeneo madogo: bad12/25/2025
