EDCOR Electronics Corporation Datasheets for Transformers
Transformers are electrical devices that are designed to transfer energy from one circuit to another by electromagnetic induction. They are used typically to increase or decrease voltage as it passes from one side of the device through the other.
Transformers: Learn more
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| Product Name | Notes |
|---|---|
| "A Mighty Midget" A simple single-ended pentode amp that uses inexpensive compactron TV tubes. It puts out about 3 watts per channel, and uses only one (two-section) tube per channel. | |
| Boadcast Quality Sound These audio matchers use high quality low noise components to deliver broadcast and recording quality sound. Continuous Use Design Each unit is designed to operate continuously. Stereo... | |
| Broadcast Quality Sound These audio matchers use high quality low noise components to deliver broadcast and recording quality sound. Continuous Use Design Each unit is designed to operate continuously. Balanced... | |
| Broadcast Quality Sound These audio matchers use high quality low noise components to deliver broadcast and recording quality sound. Continuous Use Design Each unit is designed to operate continuously. Dual... | |
| Broadcast Quality Sound These audio matchers use high quality low noise components to deliver broadcast and recording quality sound. Continuous Use Design Each unit is designed to operate continuously. Stereo... | |
| Broadcast Quality Sound These audio matchers use high quality low noise components to deliver broadcast and recording quality sound. Continuous Use Design Each unit is designed to operate continuously. Unbalanced... | |
| Design Mathematical and design analysis of the highly successful 1953 RCA ribbon microphone transformer together with new materials offer a new standard. Magnet Wire All units are wound with the... | |
| Design Mathematically designed to match and produce the specified voltage(s) when loaded. Primary (Input) Designed for 100V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 240V, 230V and 220V... | |
| Design Mathematically designed to match and produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 240V, 230V and 220V... | |
| Design Mathematically designed to match and produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 240V, 230V and 220V... | |
| Design Mathematically designed to match and produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 240V, 230V and 220V... | |
| Design Mathematically designed to match line level signals. Primary (Input) Designed for an unbalanced 10K Ohms or 7K Ohms line level signal. Secondary (Output) Designed for an unbalanced 300 Ohms... | |
| Design Mathematically designed to produce a turns ratio of 1.2:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced 15K Ohms line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1.6:1 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 2.5K Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced 10K Ohms line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced 150 Ohms line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced 15K Ohms line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced 600 Ohms line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 10K Ohms impedance. Secondary (Output)... | |
| Design Mathematically designed to produce a turns ratio of 1:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 600 Ohms impedance. Secondary (Output)... | |
| Design Mathematically designed to produce a turns ratio of 1:1 for microphone level signals. Primary (Input) Designed for a balanced or unbalanced microphone level signal. Secondary (Output) Designed for a... | |
| Design Mathematically designed to produce a turns ratio of 1:1 for microphone level signals. Primary (Input) Designed for a balanced or unbalanced microphone or line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:1 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 100 Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:1 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 10K Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:1 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 150 Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:1 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 600 Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:1.2 for line level signals. Primary (Input) Designed for a balanced or unbalanced 10K Ohms line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:1.6 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 1K Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:10 for microphone level signals. Primary (Input) Designed for a balanced or unbalanced microphone or line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:2 for microphone level signals. Primary (Input) Designed for a balanced or unbalanced microphone level signal. Secondary (Output) Designed for a... | |
| Design Mathematically designed to produce a turns ratio of 1:2 for microphone level signals. Primary (Input) Designed for a balanced or unbalanced microphone or line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:2 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 150 Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:4.1 for line level signals. Primary (Input) Designed for a balanced or unbalanced 600 Ohms line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:4.1 for line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 600 Ohms impedance. Secondary (Output)... | |
| Design Mathematically designed to produce a turns ratio of 1:4.1 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 600 Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:5 for line level signals. Primary (Input) Designed for a balanced or unbalanced 600 Ohms line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:5 for microphone level signals. Primary (Input) Designed for a balanced or unbalanced microphone level signal. Secondary (Output) Designed for a... | |
| Design Mathematically designed to produce a turns ratio of 1:5 for microphone level signals. Primary (Input) Designed for a balanced or unbalanced microphone or line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:5 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 600 Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:8 for microphone level signals. Primary (Input) Designed for a balanced or unbalanced microphone level signal. Secondary (Output) Designed for a... | |
| Design Mathematically designed to produce a turns ratio of 1:8 for microphone level signals. Primary (Input) Designed for a balanced or unbalanced microphone or line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 1:8.2 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 150 Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 2.5:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 48 Ohms impedance. Secondary (Output)... | |
| Design Mathematically designed to produce a turns ratio of 2:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced 600 Ohms line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 2:1 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 600 Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 3.5:1 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 100 Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 3.9:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 120 Ohms impedance. Secondary (Output)... | |
| Design Mathematically designed to produce a turns ratio of 4.1:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced 10K Ohms line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 4.1:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 10K Ohms impedance. Secondary (Output)... | |
| Design Mathematically designed to produce a turns ratio of 4.1:1 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 10K Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 5:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced 15K Ohms line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 5:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 200 Ohms impedance. Secondary (Output)... | |
| Design Mathematically designed to produce a turns ratio of 5:1 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 15K Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 5:1 line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 200 Ohms impedance. Secondary (Output) Designed... | |
| Design Mathematically designed to produce a turns ratio of 7.9:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced signal with a 500 Ohms impedance. Secondary (Output)... | |
| Design Mathematically designed to produce a turns ratio of 8.2:1 for line level signals. Primary (Input) Designed for a balanced or unbalanced 10K Ohms line level signal. Secondary (Output) Designed... | |
| Design Mathematically designed to produce exact plate and 23% screen voltages. Primary (Input) The input is designed for a 8K Ohms impedance source. Secondary (Output) The output is designed for... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 1.25K... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 1.7K... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 10K... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 150... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 15K... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 2.5K... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 3.2K... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 3.5K... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 3.75K... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 300... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 3K... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 5.5K... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 5K... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 6.5K... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 600... | |
| Design Mathematically designed to produce exact plate and screen voltages. These transformers are precision gapped to adjust for unbalanced DC current. Primary (Input) The input is designed for a 8K... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 1.7K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 10K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 12K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 16K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 2.2K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 2.4K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 2.5K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 3.3K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 3.4K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 3.5K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 3.8K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 4.2K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 4K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 5K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 6.6K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 7.6K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 8.4K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 8.6K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce exact plate and screen voltages. Primary (Input) The input is designed for a 8K Ohms impedance source. Secondary (Output) The output is designed for a... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 100V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 100V (50-40-30-20-10-0 0-10-20-30-40-50) at 3A center... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 100V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 200V (100-80-70-60-50-0 0-50-60-70-80-100) at 1A center... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 100V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 20V (10-7.5-5-3.16-2.5-0 0-2.5-3.15-5-7.5-10) at 4A center... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 100V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 600V (300-275-250-225-200 -0 0-200-225-250-275-30 0) at... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 100V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 900V (450-425-400-375-350 -0 0-350-375-400-425-45 0) at... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 10V (5-0-5) at 1.5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 10V (5-0-5) at 1A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 12.6V (6.3-0-6.3) at 1.25A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 12.6V (6.3-0-6.3) at 3A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 2.5V (1.25-0-1.25) at 3A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 2.5V (1.25-0-1.25) at 6A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 20V (10-0-10) at 2A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 40V (20-0-20) at 1A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 5V (2.5-0-2.5) at 2A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 5V (2.5-0-2.5) at 3A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 5V (2.5-0-2.5) at 6A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 6.3V (3.15-0-3.15) at 1.5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 6.3V (3.15-0-3.15) at 2.5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 115V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 6.3V (3.15-0-3.15) at 5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 100V (50-40-30-20-10-0 0-10-20-30-40-50) at 3A center... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 10V (5-0-5) at 1.5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 10V (5-0-5) at 1A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 12.6V (6.3-0-6.3) at 1.25A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 12.6V (6.3-0-6.3) at 3A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 2.5V (1.25-0-1.25) at 3A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 2.5V (1.25-0-1.25) at 6A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 200V (100-80-70-60-50-0 0-50-60-70-80-100) at 1A center... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 20V (10-0-10) at 2A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 20V (10-7.5-5-3.16-2.5-0 0-2.5-3.15-5-7.5-10) at 4A center... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 40V (20-0-20) at 1A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 5V (2.5-0-2.5) at 2A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 5V (2.5-0-2.5) at 3A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 5V (2.5-0-2.5) at 6A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 6.3V (3.15-0-3.15) at 1.5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 6.3V (3.15-0-3.15) at 2.5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 6.3V (3.15-0-3.15) at 5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 600V (300-275-250-225-200 -0 0-200-225-250-275-30 0) at... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 120V, 60Hz. Secondary (Output) This transformer has multiple voltage windings, 900V (450-425-400-375-350 -0 0-350-375-400-425-45 0) at... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 100V (50-40-30-20-10-0 0-10-20-30-40-50) at 3A center... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 10V (5-0-5) at 1.5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 10V (5-0-5) at 1A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 12.6V (6.3-0-6.3) at 1.25A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 12.6V (6.3-0-6.3) at 3A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 2.5V (1.25-0-1.25) at 3A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 2.5V (1.25-0-1.25) at 6A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 200V (100-80-70-60-50-0 0-50-60-70-80-100) at 1A center... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 20V (10-0-10) at 2A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 20V (10-7.5-5-3.16-2.5-0 0-2.5-3.15-5-7.5-10) at 4A center... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 40V (20-0-20) at 1A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 5V (2.5-0-2.5) at 2A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 5V (2.5-0-2.5) at 3A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 5V (2.5-0-2.5) at 6A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 6.3V (3.15-0-3.15) at 1.5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 6.3V (3.15-0-3.15) at 2.5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 6.3V (3.15-0-3.15) at 5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 600V (300-275-250-225-200 -0 0-200-225-250-275-30 0) at... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 230V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 900V (450-425-400-375-350 -0 0-350-375-400-425-45 0) at... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 100V (50-40-30-20-10-0 0-10-20-30-40-50) at 3A center... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 10V (5-0-5) at 1.5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 10V (5-0-5) at 1A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 12.6V (6.3-0-6.3) at 1.25A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 12.6V (6.3-0-6.3) at 3A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 2.5V (1.25-0-1.25) at 3A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 2.5V (1.25-0-1.25) at 6A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 200V (100-80-70-60-50-0 0-50-60-70-80-100) at 1A center... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 20V (10-0-10) at 2A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 20V (10-7.5-5-3.16-2.5-0 0-2.5-3.15-5-7.5-10) at 4A center... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 40V (20-0-20) at 1A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 5V (2.5-0-2.5) at 2A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 5V (2.5-0-2.5) at 3A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 5V (2.5-0-2.5) at 6A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 6.3V (3.15-0-3.15) at 1.5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 6.3V (3.15-0-3.15) at 2.5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 6.3V (3.15-0-3.15) at 5A center tapped. | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 600V (300-275-250-225-200 -0 0-200-225-250-275-30 0) at... | |
| Design Mathematically designed to produce the specified voltage(s) when loaded. Primary (Input) Designed for 240V, 50/60Hz. Secondary (Output) This transformer has multiple voltage windings, 900V (450-425-400-375-350 -0 0-350-375-400-425-45 0) at... | |
| Design The EM3000 series auto distribution transformers are designed for the amplifier or the speaker side of a voltage speaker distribution system. Because they are bidirectional they can be used... | |
| Design The EX-101 is a multi ratio isolated matching transformer. It can be used as a step up or step down matching transformer. This EX-101 is bidirectional. Primary/Secondary (Input/Output) The... | |
| Design The EX-102 is a multi ratio auto matching transformer. It can be used as a step up or step down matching transformer. Input/Output The input impedance is a reflective... | |
| Design The PC2570/600 audio matching transformer is designed for matching a 25V or 70V speaker distribution line to a balanced or unbalanced line level. Primary (Input) Designed for a 25V... | |
| EDCOR | |
| High Quality Sound The EZ series audio distribution transformers are designed for the speaker side of a voltage speaker distribution system. Continuous Use Design Each unit is designed to operate... | |
| High Quality Sound The TPC2570/600 audio matching transformers are designed for matching a 25V or 70V speaker distribution line to a balanced or unbalanced line level. Continuous Use Design Each... | |
| High Quality Sound The TTPC2570/600 audio matching transformers are designed for matching a 25V or 70V speaker distribution line to a balanced or unbalanced line level. Continuous Use Design Each... | |
| High Quality Sound The WA series audio distribution transformers are designed for the amplifier output side of a voltage speaker distribution system. Continuous Use Design Each unit is designed to... | |
| Matching power transformer for matching a 240V, 50/60Hz. line to 240V, 230V or 220V at 1.5A or 120V, 117V, 115V or 100V at 3A. | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 10V (5-0-5) at 2A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 12.6V (6.3-0-6.3) at 1.5A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 12.6V (6.3-0-6.3) at 3A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 120V (60-0-60) at 0.3A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 120V (60-0-60) at 0.5A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 160V at 10mA and 12V at 500mA Magnet Wire All... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 16V (8-0-8) at 1.2A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 16V (8-0-8) at 2.5A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 20V (10-0-10) at 1A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 20V (10-0-10) at 2A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 20V (10-0-10) at 3A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 24V (12-0-12) at 0.8A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 24V (12-0-12) at 1.6A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 24V (12-0-12) at 2.5A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 36V (18-0-18) at 0.5A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 36V (18-0-18) at 1.5A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 36V (18-0-18) at 1A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 48V (24-0-24) at 0.4A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 48V (24-0-24) at 0.8A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 48V (24-0-24) at 1.2A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 120V, 60Hz power line. Secondary (Output) The output has multiple voltage windings, 6.3V (3.15-0-3.15) at 3A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 10V (5-0-5) at 2A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 12.6V (6.3-0-6.3) at 1.5A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 12.6V (6.3-0-6.3) at 3A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 120V (60-0-60) at 0.3A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 120V (60-0-60) at 0.5A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 160V at 10mA and 12V at 500mA Magnet Wire All... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 16V (8-0-8) at 1.2A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 16V (8-0-8) at 2.5A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 20V (10-0-10) at 1A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 20V (10-0-10) at 2A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 20V (10-0-10) at 3A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 24V (12-0-12) at 0.8A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 24V (12-0-12) at 1.6A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 24V (12-0-12) at 2.5A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 36V (18-0-18) at 0.5A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 36V (18-0-18) at 1.5A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 36V (18-0-18) at 1A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 48V (24-0-24) at 0.4A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 48V (24-0-24) at 0.8A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 48V (24-0-24) at 1.2A, center tapped. Magnet Wire All units... | |
| Primary (Input) The input is designed for a 240V, 50/60Hz power line. Secondary (Output) The output has multiple voltage windings, 6.3V (3.15-0-3.15) at 3A, center tapped. Magnet Wire All units... | |
| The "Engineer's Amplifier" A desktop tube headphone amplifier design that can also drive small, efficient speakers (like computer speakers)using 13EM7 tubes designed by Pete Millett. For more information, schematics and... | |
| The "Engineer's Amplifier" A distortion canceling push-pull amp using cheap TV tubes designed by Pete Millett. For more information, schematics and circuit boards see Pete Millett's DIY Audio pages on... | |
| The EA series are similar to the Altec and Electro Voice 15000* series audio transformers and meet or exceed their specifications. Bidirectional Design The EA series audio distribution transformers are... | |
| 6.1-ounce, 100% cotton (preshrunk) Double-needle sleeves and hem Taped neck and shoulders How To Measure Chest With arms down at sides, measure around the upper body, under arms and over... |
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