技术特征：
　　三相鼠笼转子
　　380V额定电压
　　50 Hz额定频率
　　进口轴承
　　防护等级 IP 55
　　F级绝缘：温升80K
　　服务系数 1.0
　　输出功率0.18kW至315kW
　　机座80至355
　　安装尺寸：IEC72
　　连续工作制
　　环境温度：40℃；海拔1000米及以下
　　安装方式 B3T
　　冷却方式 IC411
　　接线方式：3kW及以下为Y形接法；4kW及以上为△接法

优势：
　　更精确的加工工艺和配平，使噪音更小
　　双浸漆可增加绕组的绝缘强度并延长电机寿命

应用：
　　通用机械，如金属切削机床、泵、风机、运输机械、搅拌机、农业机械、食品机械等。

 

WEG公司成立于1961年，是拉丁美洲最大的电机制造厂和世界最大的电机制造厂家之一。公司在资金能力、技术力量、管理经验等方面与西门子公司、ABB公司、艾默生公司、通用GE公司实力相当，并驾齐驱，同为当今世界电机五强企业之一。

万高（南通）电机制造有限公司成立于2004年，位于南通市经济技术开发区，占地面积67351.79平方米，现有员工450人，是WEG公司在中国建立的专业制造厂，主要生产各种类型的电机及销售WEG集团生产的所有产品。目前新增投资1.8亿元，并在实施扩建改造工程，已成为WEG公司在亚太地区的生产制造基地，公司具有广阔的发展空间和前景。

技术特征：
　　三相鼠笼转子
　　380V额定电压
　　50 Hz额定频率
　　进口轴承
　　防护等级 IP 55
　　F级绝缘：温升80K

优势：
　　更精确的加工工艺和配平，使噪音更小
　　双浸漆可增加绕组的绝缘强度并延长电机寿命

 

1.M Line Master

技术特征:
输出功率至50,000KW（70,000HP）
电压220-13800V
转速3600-300rpm
WEG M LINE优势包括：
高效
保护方式 IP23(WE-I),IP(W)24(WP-II) or IP(W)55/IP(W)56/IP(W)65
降低噪音等级
维护方便
API541标准
全新设计轴承、外观鼠笼设计
与现有的电机的互换性
应用：风机 、压缩机、水泵、破碎机、切削机等其它机械设备。

 

2.H Line Master

技术特征:
输出功率至100-3150KW（135-4000HP）
电压220-6900V
转速3600-600rpm
WEG M LINE优势包括：
高效
保护方式 IP(W)55/IP(W)56/IP(W)65 (TEFC,TEBV)
降低噪音等级
维护方便
全新设计轴承、外观鼠笼设计
高强度铸铁
与现有的电机的互换性
自我冷却 内部气流
不需要热转换器
应用：风机 、压缩机、水泵、破碎机、切削机等其它机械设备。

 

高压三相异步电动机

1.YJK系列紧凑型高压三向异步电动机

技术特征:
6kV或10kV额定电压 50Hz额定频率其它选择特征:
防护等级IP54 F级绝缘 温升80K温升其它电机60ZH
服务系数 1.0IP55或IP23双轴伸
输出功率160kW至1600kW其它安装方式轴尺寸根据客户要求
机座 355至630其它安装结构专用面漆
安装方式 B3R 安装尺寸:IEC72H级绝缘带服务系数运行
连续工作制(S1)SKF轴承根据要求的其它更改
环境温度:15℃~40℃;海拔1000米及以下
冷却方式 IC411
加热带 热保护（电阻）

 

2.Y系列6kV/10KV高压三相异步电动机

技术特征:
6kV额定电压 50Hz额定频率其它电机60ZH
防护等级IP23 F级绝缘 温升80K温升双轴伸轴尺寸根据客户要求
服务系数 1.0其它安装结构专用面漆
输出功率 6kV:200-3150kW 10kV:220-2240kWH级绝缘带服务系数运行
机座 355至630SKF轴承根据要求的其它更改
安装方式 B3R 安装尺寸:IEC72
连续工作制(S1)
环境温度:15℃~40℃;海拔1000米及以下
冷却方式 IC01
加热带 热保护（热敏电阻）

 

3.YKK系列6kV/10kV高压三相异步电动机

技术特征:
6kV额定电压 50Hz额定频率其它电机60ZH
防护等级IP44或IP54 F级绝缘温升80K温升双轴伸轴尺寸根据客户要求
服务系数1.0其它安装结构专用面漆
输出功率 6kV:185-3150kW 10kV:220-2000kWH级绝缘带服务系数运行
机座355至630SKF轴承根据要求的其它更改
安装方式B3R 安装尺寸:IEC72
连续工作制(S1)
环境温度:15℃~40℃;海拔1000米及以下
冷却方式IC611
加热带 热保护（热敏电阻）

 

Synchronous Generators GTA Generators GTA Line

Solid state electronic controlled devices which utilize thyristors or SCR firing circuits such as VFD's (Variable Frequency Drives for induction motor controls), PE's (Power Electronics), no-break powered battery chargers, electronic frequency converters, etc. can introduce high frequency harmonics which adversely affect the normal waveform of the generator.

"This creates additional heat in the generator stator and rotor and can cause overheating.Even though most generators are capable of working with high levels of waveform distortion without detrimental effects to themselves, other devices will do present problems when operating under such circumstances. "

Therefore, the problems which can occur are not limited to the generator itself, rather, they can affect the solid state control device, the equipment it controls, the voltage regulator, other associated loads, monitoring devices or a number of combinations over the entire system. It is very important that the control manufacturer, the generator manufacturer, and the systems engineer work together to insure the proper selection of all components. In order to accept ¿some¿ levels of waveform distortion, it is important to know what type of non-linear load is going to be powered and whether or not there are other loads in the system to be considered. The following minimum information is generally required:

1. Number of system pulses: 6, 12 or 18.
2. Level of Total Harmonic Distortion (Voltage and Current) produced by the non-linear load (typically 35-40% for a 6 pulse, 15% for a 12 pulse and 6% for an 18 pulse).
3. Are distortion filters or line reactors installed? Depending on the answer for question 2 (above) it becomes obvious. DF or LR¿s can bring THD down to acceptable levels from any 6 or 12 pulse devices.
4. What is the maximum acceptable level of voltage distortion the individual equipments connected to the main generating system can accept?
5. Operating voltage and frequency.
6. The non-linear load power requirement should be stated in kVA.

"Based on the answers for questions 1 to 6, typical factory recommendations* can include:
Add line reactors or distortion filters to limit THD
Add an external PMG or auxiliary exciter
Limit the direct axis sub transient reactance (X'd), this means supplying a non-standard generator"

"*IMPORTANT: These recommendations can be only one or a combination of the above. Please, consult your WEG representative for further information as these recommendations and general information are subject to change without notice. "

 

Synchronous Generators GTA Generators GTA Line

Solid state electronic controlled devices which utilize thyristors or SCR firing circuits such as VFD's (Variable Frequency Drives for induction motor controls), PE's (Power Electronics), no-break powered battery chargers, electronic frequency converters, etc. can introduce high frequency harmonics which adversely affect the normal waveform of the generator.

"This creates additional heat in the generator stator and rotor and can cause overheating.Even though most generators are capable of working with high levels of waveform distortion without detrimental effects to themselves, other devices will do present problems when operating under such circumstances. "

Therefore, the problems which can occur are not limited to the generator itself, rather, they can affect the solid state control device, the equipment it controls, the voltage regulator, other associated loads, monitoring devices or a number of combinations over the entire system. It is very important that the control manufacturer, the generator manufacturer, and the systems engineer work together to insure the proper selection of all components. In order to accept ¿some¿ levels of waveform distortion, it is important to know what type of non-linear load is going to be powered and whether or not there are other loads in the system to be considered. The following minimum information is generally required:

1. Number of system pulses: 6, 12 or 18.
2. Level of Total Harmonic Distortion (Voltage and Current) produced by the non-linear load (typically 35-40% for a 6 pulse, 15% for a 12 pulse and 6% for an 18 pulse).
3. Are distortion filters or line reactors installed? Depending on the answer for question 2 (above) it becomes obvious. DF or LR¿s can bring THD down to acceptable levels from any 6 or 12 pulse devices.
4. What is the maximum acceptable level of voltage distortion the individual equipments connected to the main generating system can accept?
5. Operating voltage and frequency.
6. The non-linear load power requirement should be stated in kVA.

"Based on the answers for questions 1 to 6, typical factory recommendations* can include:
Add line reactors or distortion filters to limit THD
Add an external PMG or auxiliary exciter
Limit the direct axis sub transient reactance (X'd), this means supplying a non-standard generator"

"*IMPORTANT: These recommendations can be only one or a combination of the above. Please, consult your WEG representative for further information as these recommendations and general information are subject to change without notice. "