Additions:
I had the usual stack of 12 volt power supplies - one generic linear Astron, an Icom that matched the rig, and the occasional Astron switcher supply. My station is somewhat cramped for space, and I needed more DC power to run an HF Amplifier that requires up to 100 amps at 12VDC. I also wanted to be able to operate without mains power for awhile, which means I needed a storage battery integrated in with the power supply system. I have several rigs plus the amp, so it needed to be able to supply about 150A at 12V. I wanted the battery to be well managed, and the radios to be happy. The battery must be sealed, and not Gel - no liquid acid in the shack, and Gel batteries are too easily damaged with large charging currents.
Deletions:
I had the usual stack of 12 volt power supplies - one generic linear Astron, an Icom that matched the rig, and the occasional Astron switcher supply. My station is somewhat cramped for space, and I needed more DC power to run an HF Amplifier that requires up to 100 amps at 12VDC. I also wanted to be able to operate without mains power for awhile, which means I needed a storage battery integrated in with the power system supply. I have several rigs plus the amp, so it needed to be able to supply about 150A at 12V. I wanted the battery to be well managed, and the radios to be happy. The battery must be sealed, and not Gel - no liquid acid in the shack, and Gel batteries are too easily damaged with large charging currents.
Additions:
I had the usual stack of 12 volt power supplies - one generic linear Astron, an Icom that matched the rig, and the occasional Astron switcher supply. My station is somewhat cramped for space, and I needed more DC power to run an HF Amplifier that requires up to 100 amps at 12VDC. I also wanted to be able to operate without mains power for awhile, which means I needed a storage battery integrated in with the power system supply. I have several rigs plus the amp, so it needed to be able to supply about 150A at 12V. I wanted the battery to be well managed, and the radios to be happy. The battery must be sealed, and not Gel - no liquid acid in the shack, and Gel batteries are too easily damaged with large charging currents.
I looked at the West Mountain Radio Powergate and the Astron battery-friendly supplies (special versions). I considered building my own similar power control device. I looked at putting batteries across switcher power supplies. I considered diodes, VMos PowerFETs, and microprocessors. I wanted something simple and reliable. There are a lot of ways to solve this problem, but most of them are compromises, or they are complex or they are not known to be within manufacturer's ratings. A particular problem is when the AC is removed from the power supply, but the DC remains from the battery. Does the power supply self destruct? When the AC is returned, does the power supply charge the battery so heavily that it overheats the supply or battery, boils the battery, or etc??
Batteries are not so difficult to specify for this project. The available Absorbed Glass Mat (AGM) sealed lead acid (SLA) batteries meet my requirements for avoiding liquid acid in the station, and have exceedingly low impedance to handle the load and also recharge quickly. These are pricey but are often available surplus as pullouts from large Uninterruptible Power Supplies (UPS). (For more info on AGM batteries see
AgmBatteries). Gel batteries are less desirable as they cannot handle the high charge or discharge currents. Commonly available AGM batteries include Group 24 size 75 amp hour models and less common group 27 size 100 amp hour, as well as the popular smaller 17 amp hour units (and many other less common sizes). UPS Batteries usually are rated for a 10 year service life, and are often pulled at 5 years, so surplus batteries with several years of life remaining are available at attractive pricing via flea markets and other venues.
A simple solution that is frequently used in Amateur Radio stations is an RV deep cycle battery with a low or moderate current battery charger floating across it. This is fine for low current applications, but the 100 amps for the amplifier really puts a load on the battery. So a high current charger is needed to offset this. However the high current chargers are expensive and often subject the battery to voltages too high for electronics equipment, as well as RF switching noise that creates interference in receivers. So the charger has to be chosen carefully.
I am still designing the final system (7/2007), but the present plan is to recycle a computer case to contain the battery, converter and various bits of switching gear. I plan to use a 100 amp hour AGM battery that I obtained at a flea market, a Dynasty group 27 size unit. The computer cabinet will contain all the proper fuses and AC and DC switching. Since we discarded our old computers I have to find a suitable case to reuse...
Deletions:
I had the usual stack of 12 volt power supplies - one generic linear Astron, an Icom that matched the rig, and the occasional Astron switcher supply. My station is somewhat cramped for space, and I needed more DC power to run an HF Amplifier that requires up to 100A of 12V current. I also wanted to be able to operate without mains power for awhile, which means I needed a storage battery integrated in with the power supply. I have several rigs plus the amp, so it needed to be able to supply about 150A at 12V. I wanted the battery to be happy, and the radios to be happy. The battery must be sealed, and not Gel - no liquid acid in the shack, and Gel batteries are too easily damaged.
I looked at the West Mountain Radio Powergate and the Astron battery-friendly supplies (special versions). I considered building my own similar power control device. I looked at putting batteries across switcher power supplies. I considered diodes, VMos PowerFETs, and microprocessors. I wanted something simple and reliable. There are a lot of ways to solve this problem, but most of them are compromises, or they are complex or they are not known to be within manufacturer's ratings. A particular problem is when the AC is removed from the power supply, but the DC remains from the battery. Does the power supply self destruct? When the AC is returned, does the power supply charge the battery so heavily that it overheats, boils the battery, etc??
Batteries are not so difficult to specify. The available Absorbed Glass Mat (AGM) sealed lead acid (SLA) batteries meet my requirements for avoiding liquid acid in the station, and have exceedingly low impedance to handle the load and also recharge quickly. These are pricey but are often available surplus as pullouts from large Uninterruptible Power Supplies (UPS). (For more info on AGM batteries see
AgmBatteries). Gel batteries are less desirable as they cannot handle the high charge or discharge currents. Commonly available AGM batteries include Group 24 size 75 amp hour models and less common group 27 size 100 amp hour, as well as the popular smaller 17 amp hour units. UPS Batteries usually are rated for a 10 year service life, and are often pulled at 5 years, so surplus batteries with several years of life remaining are available at attractive pricing via flea markets and other venues.
A simple solution that is frequently used in Amateur Radio stations is an RV battery with a charger floating across it. This is fine for low current applications, but the 100 amps for the amplifier really puts a load on the battery. So a high current charger is needed to offset this. However the high current chargers are expensive and often subject the battery to voltages too high for electronics equipment, as well as noise that creates interference in receivers. So the charger has to be chosen carefully.
I am still designing the final system (7/2007), but the present plan is to recycle a computer case to contain the battery, converter and various bits of switching gear. I plan to use a 100 amp hour AGM battery that I obtained at a flea market, a Dynasty group 27 size unit. The computer cabinet will contain all the proper fuses and AC and DC switching. Since we discarded our old computers I have to find a suitable case to recycle...
Additions:
Batteries are not so difficult to specify. The available Absorbed Glass Mat (AGM) sealed lead acid (SLA) batteries meet my requirements for avoiding liquid acid in the station, and have exceedingly low impedance to handle the load and also recharge quickly. These are pricey but are often available surplus as pullouts from large Uninterruptible Power Supplies (UPS). (For more info on AGM batteries see
AgmBatteries). Gel batteries are less desirable as they cannot handle the high charge or discharge currents. Commonly available AGM batteries include Group 24 size 75 amp hour models and less common group 27 size 100 amp hour, as well as the popular smaller 17 amp hour units. UPS Batteries usually are rated for a 10 year service life, and are often pulled at 5 years, so surplus batteries with several years of life remaining are available at attractive pricing via flea markets and other venues.
Another common solution is a regulated power supply with an isolation diode to the battery. It is difficult to obtain the proper voltage for the battery with this setup as the diode voltage drop varies with current. A discharged battery also presents a heavy load to the supply which can cause problems with the supply. Some switching power supplies can safely be connected directly across batteries as the switcher design includes a diode as part of the system, but again they are not designed for this service and some can be damaged if the AC is removed.
A variation on that solution is a charger/power supply made for the Recreational Vehicle (RV) industry. They call these RV Converters. They are designed to power the 12 volt equipment in a trailer or motorhome, as well as charging the house batteries from the 120 VAC line "shore power". The better quality units have the proper charge regimen for bulk boost, normal and storage voltages, and they put out clean DC that is electronics equipment and battery friendly. Some of these converters are RF noisy, so we need to select a quality unit that is AGM battery friendly and RF quiet.
The RV Converters without a "Charge Wizard" are also suitable for this use. They generally put out a fixed 13.6 VDC which is "safe" for equipment and batteries. They don't charge as fast, and they don't drop to a lower voltage when idle, so in general battery performance with a "Charge Wizard" is slightly better than without. If you plan to use a RV Converter for a power supply without a battery, then the "Charge Wizard" is not required. Many units without a built-in "Charge Wizard" have a connector for an optional unit to add this capability.
I took the Progressive Dynamics 60 Amp RV Converter and installed an Anderson Powerpole 30 amp connector. I put some heavy resistive loads on it courtesy of Eric WD6CMU and we measured voltage. It was well behaved under varying loads. The fan does not run at all until the load exceeds about 15 amps. Then it comes on so quietly at low speed you can hardly hear it, and ramps up depending on temperature and load current.
I took it to the field and used it to power a Yaesu FT897 both with and without a battery across the 12V line. We could not find any power supply RF noise in field conditions with the antenna directly overhead. I have not tried wrapping the antenna around the supply, but in actual use we have not found any noise thus far. The test protocol is to tune the bands looking for something that sounds like it might be power supply noise, then remove AC power and see if the noise goes away, allowing the battery to power the radio. If the noise remains it is not the converter.
On Field Day 2007 I decided to try the amplifier on the supply with a pair of 49 amp hour AGM batteries - one for the rig, and one for the amp, both connected to the RV Converter. I also added a 1 Farad capacitor to the amp battery. It all worked quite well. The converter was powered by a Honda EU2000i generator set in ECOnomy mode where the engine idles down on light loads. On CW the generator really was modulated by the heavy on-off load as the generator kicked up to full speed, but it kept working and the amp put out 500 watts of RF. Success!
For those stations not requiring power for an amplifier, the RV converters come in 25 to 45 amp versions that would handle the station load with or without a float battery. Models without Charge Wizards will also work, they just do not charge the battery as quickly or do the periodic equalization cycle. They also do not drop to the lower voltage when idle, so the battery life may be slightly reduced (and water consumption increased). If you turn the converter / power supply off when not in use, the batteries will use less water and last longer (as long as you don't let them run down and sit). If your batteries are located in a vented area you can also consider the most cost effective battery setup - a pair of 6V Golf Car batteries in series. These batteries are available new at about $60 each from places like Sam's Club and some WalMart stores. They are rated about 200 or more amp hours, so you will have a very capable system. The water level must be periodically checked and ventilation is important. Make sure there is a fuse within a foot or so of the battery for safety's sake with any battery setup.
Deletions:
Batteries are not so difficult to specify. The available Absorbed Glass Mat (AGM) sealed lead acid (SLA) batteries meet my requirements for avoiding liquid acid in the station, and have exceedingly low impedance to handle the load and also recharge quickly. These are pricey but are often available surplus as pullouts from large Uninterruptible Power Supplies (UPS). (For more info on AGM batteries see
AgmBatteries). Gel batteries are less desirable as they cannot handle the high charge or discharge currents.
Another common solution is a regulated power supply with an isolation diode to the battery. It is difficult to obtain the proper voltage for the battery with this setup as the diode drop varies with current. A discharged battery also presents a heavy load to the supply which can cause problems with the supply. Some switching power supplies can safely be connected across batteries, but again they are not designed for this service and some can be damaged if the AC is removed.
A variation on that solution is a charger/power supply made for the Recreational Vehicle (RV) industry. They call these RV Converters. They are designed to power the 12 volt equipment in a trailer or motorhome, as well as charging the house batteries. The better quality units have the proper charge regimen for bulk boost, normal and storage voltages, and they put out clean DC that is electronics equipment and battery friendly. Some of these converters are RF noisy, so we need to select a quality unit that is AGM battery friendly and RF quiet.
I took this supply and added an Anderson Powerpole 30 amp connector. I put some heavy resistive loads on it courtesy of Eric WD6CMU and we measured voltage. It was well behaved. The fan does not run until the load exceeds about 15 amps. Then it comes on so quietly at low speed you can hardly hear it, and ramps up depending on temperature and load current.
I took it to the field and used it to power a Yaesu FT897 both with and without a battery across the 12V line. We could not find any power supply RF noise in field conditions. I have not tried wrapping the antenna around the supply, but in actual use we have not found any noise thus far.
On Field Day 2007 I decided to try the amplifier on the supply with a pair of 49 amp hour AGM batteries - one for the rig, and one for the amp. I also added a 1 Farad capacitor to the amp battery. It all worked quite well. The converter was powered by a Honda EU2000i generator set in ECO mode. On CW the generator really was modulated by the heavy on-off load, but it kept working and the amp put out 500 watts of RF. Success!
For those stations not requiring power for an amplifier, the RV converters come in 25 to 45 amp versions that would handle the station load with or without a float battery. Models without Charge Wizards will also work, they just do not charge the battery as quickly or do the periodic equalization cycle. They also do not drop to the lower voltage when idle, so the battery life may be slightly reduced. If you turn the converter / power supply off when not in use, the batteries will use less water and last longer (as long as you don't let them run down and sit). If your batteries are located in a vented area you can also consider the most cost effective battery setup - a pair of 6V Golf Car batteries in series. These batteries are available new at about $60 each from places like Sam's Club and some WalMart stores. They are rated about 200 amp hours, so you will have a very capable system. The water level must be periodically checked and ventilation is important. Make sure there is a fuse within a foot or so of the battery for safety's sake with any battery.
Additions:
For those stations not requiring power for an amplifier, the RV converters come in 25 to 45 amp versions that would handle the station load with or without a float battery. Models without Charge Wizards will also work, they just do not charge the battery as quickly or do the periodic equalization cycle. They also do not drop to the lower voltage when idle, so the battery life may be slightly reduced. If you turn the converter / power supply off when not in use, the batteries will use less water and last longer (as long as you don't let them run down and sit). If your batteries are located in a vented area you can also consider the most cost effective battery setup - a pair of 6V Golf Car batteries in series. These batteries are available new at about $60 each from places like Sam's Club and some WalMart stores. They are rated about 200 amp hours, so you will have a very capable system. The water level must be periodically checked and ventilation is important. Make sure there is a fuse within a foot or so of the battery for safety's sake with any battery.
Deletions:
For those stations not requiring power for an amplifier, the RV converters come in 25 to 45 amp versions that would handle the station load with or without a float battery. Models without Charge Wizards will also work, they just do not charge the battery as quickly or do the periodic equalization cycle. They also do not drop to the lower voltage when idle, so the battery life may be slightly reduced. If you turn the converter / power supply off when not in use, the batteries will use less water and last longer (as long as you don't let them run down and sit). If your batteries are located in a vented area you can also consider the most cost effective battery setup - a pair of 6V Golf Car batteries in series. These batteries are available new at about $60 each from places like Sam's Club and some
WalMart stores. They are rated about 200 amp hours, so you will have a very capable system. The water level must be periodically checked and ventilation is important. Make sure there is a fuse within a foot or so of the battery for safety's sake with any battery.
Additions:
I looked at the West Mountain Radio Powergate and the Astron battery-friendly supplies (special versions). I considered building my own similar power control device. I looked at putting batteries across switcher power supplies. I considered diodes, VMos PowerFETs, and microprocessors. I wanted something simple and reliable. There are a lot of ways to solve this problem, but most of them are compromises, or they are complex or they are not known to be within manufacturer's ratings. A particular problem is when the AC is removed from the power supply, but the DC remains from the battery. Does the power supply self destruct? When the AC is returned, does the power supply charge the battery so heavily that it overheats, boils the battery, etc??
Deletions:
I looked at the West Mountain Radio Powergate and the Astron battery-friendly supplies (special versions). I considered building my own similar power control device. I looked at putting batteries across switcher power supplies. I considered diodes, VMos
PowerFETs, and microprocessors. I wanted something simple and reliable. There are a lot of ways to solve this problem, but most of them are compromises, or they are complex or they are not known to be within manufacturer's ratings. A particular problem is when the AC is removed from the power supply, but the DC remains from the battery. Does the power supply self destruct? When the AC is returned, does the power supply charge the battery so heavily that it overheats, boils the battery, etc??
Additions:
Batteries are not so difficult to specify. The available Absorbed Glass Mat (AGM) sealed lead acid (SLA) batteries meet my requirements for avoiding liquid acid in the station, and have exceedingly low impedance to handle the load and also recharge quickly. These are pricey but are often available surplus as pullouts from large Uninterruptible Power Supplies (UPS). (For more info on AGM batteries see
AgmBatteries). Gel batteries are less desirable as they cannot handle the high charge or discharge currents.
A simple solution that is frequently used in Amateur Radio stations is an RV battery with a charger floating across it. This is fine for low current applications, but the 100 amps for the amplifier really puts a load on the battery. So a high current charger is needed to offset this. However the high current chargers are expensive and often subject the battery to voltages too high for electronics equipment, as well as noise that creates interference in receivers. So the charger has to be chosen carefully.
Another common solution is a regulated power supply with an isolation diode to the battery. It is difficult to obtain the proper voltage for the battery with this setup as the diode drop varies with current. A discharged battery also presents a heavy load to the supply which can cause problems with the supply. Some switching power supplies can safely be connected across batteries, but again they are not designed for this service and some can be damaged if the AC is removed.
A variation on that solution is a charger/power supply made for the Recreational Vehicle (RV) industry. They call these RV Converters. They are designed to power the 12 volt equipment in a trailer or motorhome, as well as charging the house batteries. The better quality units have the proper charge regimen for bulk boost, normal and storage voltages, and they put out clean DC that is electronics equipment and battery friendly. Some of these converters are RF noisy, so we need to select a quality unit that is AGM battery friendly and RF quiet.
I took it to the field and used it to power a Yaesu FT897 both with and without a battery across the 12V line. We could not find any power supply RF noise in field conditions. I have not tried wrapping the antenna around the supply, but in actual use we have not found any noise thus far.
On Field Day 2007 I decided to try the amplifier on the supply with a pair of 49 amp hour AGM batteries - one for the rig, and one for the amp. I also added a 1 Farad capacitor to the amp battery. It all worked quite well. The converter was powered by a Honda EU2000i generator set in ECO mode. On CW the generator really was modulated by the heavy on-off load, but it kept working and the amp put out 500 watts of RF. Success!
I put together a temporary installation at home to continue the testing after Field Day 2007. This setup includes a single 49 amp hour AGM Lifeline battery, the Converter/Power Supply, and some heavy cabling to the amp with 6 gauge wire and Anderson SB50 connectors. It seems to work quite well, though for the final system even lower loss cable is planned. Testing continues..
For fuses I plan to use Mega Fuses for the 2 gauge at 100 amps, Maxi Fuses at 60A for the 6 gauge, and 30 amp ATC fuses for the 10 gauge
PowerPole 30 wiring. Two switches will be provided, one for the AC to the converter/charger, and one high current DC separating the battery from the rest of the system. This will allow me to run from AC or DC or both, and to remove power from the rigs. A little known fact is that most radios and amplifiers leave power on the final transistors even when turned off. It is a good idea to remove DC entirely when equipment is not in use. I will also put casters on the case, and connectors on the back panel for all input and output power. Some accessory
PowerPole 30's and an SB50 will be available in the front of the case as well, and possibly a voltmeter. Some handles may be added for moving it, the battery weighs about 70 pounds so the whole box will approach 100. I plan to use some form of secondary containment on the battery (a battery box), and make it somewhat easy to change the battery by minimizing the quantity of connections that bolt to the battery directly.
More later as it develops..
For those not requiring High Current
For those stations not requiring power for an amplifier, the RV converters come in 25 to 45 amp versions that would handle the station load with or without a float battery. Models without Charge Wizards will also work, they just do not charge the battery as quickly or do the periodic equalization cycle. They also do not drop to the lower voltage when idle, so the battery life may be slightly reduced. If you turn the converter / power supply off when not in use, the batteries will use less water and last longer (as long as you don't let them run down and sit). If your batteries are located in a vented area you can also consider the most cost effective battery setup - a pair of 6V Golf Car batteries in series. These batteries are available new at about $60 each from places like Sam's Club and some
WalMart stores. They are rated about 200 amp hours, so you will have a very capable system. The water level must be periodically checked and ventilation is important. Make sure there is a fuse within a foot or so of the battery for safety's sake with any battery.
Deletions:
Batteries are not so difficult to specify. The available Absorbed Glass Mat (AGM) sealed lead acid (SLA) batteries meet my requirements for avoiding liquid acid in the station, and have exceedingly low impedance to handle the load and also recharge quickly. These are pricey but are often available surplus as pullouts from large Uninterruptible Power Supplies (UPS). (For more info on AGM batteries see
AgmBatteries).
A simple solution that is frequently used in Amateur Radio stations is an RV battery with a charger floating across it. This is fine for low current applications, but the 100 amps for the amplifier really puts a load on the battery. So a high current charger is needed to offset this. However the high current chargers are expensive and often subject the battery to voltages too high for electronics equipment, as well as noise that creates interference in receivers. So the charger has to be chosen carefully.
A variation on that solution is a charger/power supply made for the Recreational Vehicle (RV) industry. They call these RV Converters. They are designed to power the 12 volt equipment in a trailer or motorhome, as well as charging the batteries. The better quality units have the proper charge regimen for bulk boost, normal and storage voltages, and they put out clean DC that is electronics equipment and battery friendly. Some of these converters are very RF noisy, so we need to select a quality unit that is AGM battery friendly and RF quiet.
I took it to the field and used it to power a Yaesu FT897 both with and without a battery across the 12V line. We could not find any power supply noise in field conditions. I have not tried wrapping the antenna around the supply, but in actual use we have not found any noise thus far.
On Field Day 2007 I decided to try the amplifier on the supply with a pair of 49 amp hour AGM batteries - one for the rig, and one for the amp. I also added a 1 Farad capacitor to the amp battery. It worked quite well. The converter was powered by a Honda EU2000i generator set in ECO mode. On CW the generator really was modulated by the heavy on-off load, but it kept working and the amp put out 500 watts of RF. Success!
I put together a temporary installation at home to continue the testing. This setup includes a single 49 amp hour AGM Lifeline battery, the Converter/Power Supply, and some heavy cabling to the amp with 6 gauge wire and Anderson SB50 connectors. It seems to work quite well, though for the final system even lower loss cable is planned. Testing continues..
For fuses I plan to use Mega Fuses for the 2 gauge at 100 amps, Maxi Fuses at 60A for the 6 gauge, and 30 amp ATC fuses for the 10 gauge wiring. Two switches will be provided, one for the AC to the converter/charger, and one high current DC separating the battery from the rest of the system. This will allow me to run from AC or DC or both, and to remove power from the rigs. A little known fact is that most radios and amplifiers leave power on the final transistors even when turned off. It is a good idea to remove DC entirely when equipment is not in use. I will also put casters on the case, and connectors on the back panel for all input and output power. Some accessory
PowerPole 30's will be available in the front of the case as well, and possibly a voltmeter. Some handles may be added for moving it, the battery weighs about 70 pounds so the whole box will approach 100. I plan to use some form of secondary containment on the battery (a battery box), and make it somewhat easy to change the battery by minimizing the quantity of connections that bolt to the battery directly.
More later..
Additions:
I had the usual stack of 12 volt power supplies - one generic linear Astron, an Icom that matched the rig, and the occasional Astron switcher supply. My station is somewhat cramped for space, and I needed more DC power to run an HF Amplifier that requires up to 100A of 12V current. I also wanted to be able to operate without mains power for awhile, which means I needed a storage battery integrated in with the power supply. I have several rigs plus the amp, so it needed to be able to supply about 150A at 12V. I wanted the battery to be happy, and the radios to be happy. The battery must be sealed, and not Gel - no liquid acid in the shack, and Gel batteries are too easily damaged.
Batteries are not so difficult to specify. The available Absorbed Glass Mat (AGM) sealed lead acid (SLA) batteries meet my requirements for avoiding liquid acid in the station, and have exceedingly low impedance to handle the load and also recharge quickly. These are pricey but are often available surplus as pullouts from large Uninterruptible Power Supplies (UPS). (For more info on AGM batteries see
AgmBatteries).
Deletions:
I had the usual stack of 12 volt power supplies - one generic linear Astron, an Icom that matched the rig, and the occasional Astron switcher supply. My station is somewhat cramped for space, and I needed more DC power to run an HF Amplifier that requires up to 100A of 12V current. I also wanted to be able to operate without mains power for awhile, which means I needed a storage battery integrated in with the power supply. I have several rigs plus the amp, so it needed to be able to supply about 150A at 12V. I wanted the battery to be happy, and the radios to be happy. The battery must be sealed, and not Gel - no liquid acid in the shack.
Batteries are not so difficult to specify. The available Absorbed Glass Mat (AGM) sealed lead acid (SLA) batteries meet my requirements for avoiding liquid acid in the station, and have exceedingly low impedance to handle the load and also recharge quickly. These are pricey but are often available surplus as pullouts from large Uninterruptible Power Supplies (UPS).
Additions:
Additions:
I am still designing the final system (7/2007), but the present plan is to recycle a computer case to contain the battery, converter and various bits of switching gear. I plan to use a 100 amp hour AGM battery that I obtained at a flea market, a Dynasty group 27 size unit. The computer cabinet will contain all the proper fuses and AC and DC switching. Since we discarded our old computers I have to find a suitable case to recycle...
For fuses I plan to use Mega Fuses for the 2 gauge at 100 amps, Maxi Fuses at 60A for the 6 gauge, and 30 amp ATC fuses for the 10 gauge wiring. Two switches will be provided, one for the AC to the converter/charger, and one high current DC separating the battery from the rest of the system. This will allow me to run from AC or DC or both, and to remove power from the rigs. A little known fact is that most radios and amplifiers leave power on the final transistors even when turned off. It is a good idea to remove DC entirely when equipment is not in use. I will also put casters on the case, and connectors on the back panel for all input and output power. Some accessory
PowerPole 30's will be available in the front of the case as well, and possibly a voltmeter. Some handles may be added for moving it, the battery weighs about 70 pounds so the whole box will approach 100. I plan to use some form of secondary containment on the battery (a battery box), and make it somewhat easy to change the battery by minimizing the quantity of connections that bolt to the battery directly.
Deletions:
I am still designing the final system (7/2007), but the present plan is to recycle a computer case to contain the battery, converter and various bits of switching gear. I plan to use a 100 amp hour AGM battery that I obtained at a flea market, a Dynasty group 27 size unit. The computer cabinet will contain all the proper fuses and AC and DC switching. Since we discarded the old computers I have to find a suitable case to recycle...
For fuses I plan to use
MegaFuses for the 2 gauge at 100 amps,
MaxiFuses at 60A for the 6 gauge, and 30 amp ATC fuses for the 10 gauge wiring. Two switches will be provided, one for the AC to the converter/charger, and one high current DC separating the battery from the rest of the system. I will also put casters on the case, and connectors on the back panel for all input and output power. Some accessory
PowerPole 30's will be available in the front of the case as well, and possibly a voltmeter.
Additions:
A DC Power System for the Amateur Radio Station
I had the usual stack of 12 volt power supplies - one generic linear Astron, an Icom that matched the rig, and the occasional Astron switcher supply. My station is somewhat cramped for space, and I needed more DC power to run an HF Amplifier that requires up to 100A of 12V current. I also wanted to be able to operate without mains power for awhile, which means I needed a storage battery integrated in with the power supply. I have several rigs plus the amp, so it needed to be able to supply about 150A at 12V. I wanted the battery to be happy, and the radios to be happy. The battery must be sealed, and not Gel - no liquid acid in the shack.
I looked at the West Mountain Radio Powergate and the Astron battery-friendly supplies (special versions). I considered building my own similar power control device. I looked at putting batteries across switcher power supplies. I considered diodes, VMos
PowerFETs, and microprocessors. I wanted something simple and reliable. There are a lot of ways to solve this problem, but most of them are compromises, or they are complex or they are not known to be within manufacturer's ratings. A particular problem is when the AC is removed from the power supply, but the DC remains from the battery. Does the power supply self destruct? When the AC is returned, does the power supply charge the battery so heavily that it overheats, boils the battery, etc??
A simple solution that is frequently used in Amateur Radio stations is an RV battery with a charger floating across it. This is fine for low current applications, but the 100 amps for the amplifier really puts a load on the battery. So a high current charger is needed to offset this. However the high current chargers are expensive and often subject the battery to voltages too high for electronics equipment, as well as noise that creates interference in receivers. So the charger has to be chosen carefully.
A variation on that solution is a charger/power supply made for the Recreational Vehicle (RV) industry. They call these RV Converters. They are designed to power the 12 volt equipment in a trailer or motorhome, as well as charging the batteries. The better quality units have the proper charge regimen for bulk boost, normal and storage voltages, and they put out clean DC that is electronics equipment and battery friendly. Some of these converters are very RF noisy, so we need to select a quality unit that is AGM battery friendly and RF quiet.
So I set out to choose one of these supplies. There are a few reviews on www.eHam.net. They are sparse but show that some brands are RF quiet, and that the larger converters (over 70 amps) tend to be more troublesome from a noise standpoint. I also noted that the higher current models require 20 amp 120 volt outlets, so another requirement was to stay with standard 15A AC plugs, which limits the 12V output to approximately 60 amps.
I took it to the field and used it to power a Yaesu FT897 both with and without a battery across the 12V line. We could not find any power supply noise in field conditions. I have not tried wrapping the antenna around the supply, but in actual use we have not found any noise thus far.
On Field Day 2007 I decided to try the amplifier on the supply with a pair of 49 amp hour AGM batteries - one for the rig, and one for the amp. I also added a 1 Farad capacitor to the amp battery. It worked quite well. The converter was powered by a Honda EU2000i generator set in ECO mode. On CW the generator really was modulated by the heavy on-off load, but it kept working and the amp put out 500 watts of RF. Success!
The cable is an important part of the plan. 6 Gauge wire is rated for about 40 amps of continuous current, but the amplifier can draw more than this in key down service like RTTY. So I plan to use 2 gauge cable and Anderson SB120 connectors for the amplifier in the final system. This cable is rated for about 95A in a multiwire cable, and it is the largest cable that will fit the SB120's. The SB120's are rated for 120 amps. This cable will carry only power for the amp, separate cables will be provided for an SB50 outlet (6 gauge) and a few
PowerPole 30's (10 gauge cable on them). In each case I am planning to use the largest cable size recommended for the connectors to minimize voltage drops.
For fuses I plan to use
MegaFuses for the 2 gauge at 100 amps,
MaxiFuses at 60A for the 6 gauge, and 30 amp ATC fuses for the 10 gauge wiring. Two switches will be provided, one for the AC to the converter/charger, and one high current DC separating the battery from the rest of the system. I will also put casters on the case, and connectors on the back panel for all input and output power. Some accessory
PowerPole 30's will be available in the front of the case as well, and possibly a voltmeter.
More later..
Deletions:
A DC Power System for Amateur Radio Station
I had the usual stack of 12 volt power supplies - one generic linear Astron, an Icom that matched the rig, and the occasional Astron switcher supply. My station is somewhat cramped for space, and I needed more DC power to run an HF Amplifier that requires up to 100A of 12V current. I also wanted to be able to operate without mains power for awhile, which means I needed a storage battery integrated in with the power supply. I have several rigs plus the amp, so it needed to be able to supply about 150A at 12V. I wanted the battery to be happy, and the radios to be happy. The battery must be sealed, and not Gel.
I looked at the West Mountain Radio Powergate and the Astron battery-friendly supplies (special versions). I considered building my own similar power control device. I looked at putting batteries across switcher power supplies. I considered diodes, Vmos Power FETs, and microprocessors. I wanted something simple and reliable. There are a lot of ways to solve this problem, but most of them are compromises, or they are complex or they are not known to be within manufacturer's ratings. A particular problem is when the AC is removed from the power supply, but the DC remains from the battery. Does the power supply self destruct? When the AC is returned, does the power supply charge the battery so heavily that it overheats??
A simple solution that is frequently used in Amateur Radio stations is a battery with a charger floating across it. This is fine for low current applications, but the 100 amps for the amplifier really puts a load on the battery. So a high current charger is needed to offset this. However the high current chargers are expensive and often subject the battery to voltages too high for electronics equipment, as well as noise that creates interference in receivers.
A variation on that solution is a charger/power supply made for the Recreational Vehicle (RV) industry. They call these RV Converters. They are designed to power the 12 volt equipment in a trailer or motorhome, as well as charging the batteries. The better quality units have the proper charge regimen for bulk boost, normal and storage voltages, and they put out clean DC that is electronics equipment and battery friendly. Some of these converters are very RF noisy, so we need to select a quality unit that is AGM battery friendly.
So I set out to choose one of these supplies. There are a few reviews on www.eHam.net. They are sparse but show that some brands are RF quiet, and that the larger converters (over 70 amps) tend to be more troublesome from a noise standpoint. I also noted that the higher current models require 20 amp 120 volt outlets, so another requirement was to stay with standard 15A AC plugs.
I took it to the field and used it to power a Yaesu FT897. We could not find any power supply noise in field conditions. I have not tried wrapping the antenna around the supply, but in actual use we have not found any noise thus far.
On Field Day 2007 I decided to try the amplifier on the supply with a pair of 49 amp hour AGM batteries - one for the rig, and one for the amp. I also added a 1 Farad capacitor to the amp battery. It worked quite well. The converter was powered by a Honda EU2000i generator set in ECO mode. On CW the generator really was modulated, but it never faltered and the amp put out 500 watts of RF. Success!
The cable is an important part of the plan. 6 Gauge wire is rated for about 40 amps of continuous current, but the amplifier can draw more than this in key down service like RTTY. So I plan to use 2 gauge cable and Anderson SB120 connectors for the amplifier in the final system.
Additions:
A DC Power System for Amateur Radio Station
Deletions:
DC Power System for Amateur Radio Station
Additions:
The Requirements
The Search
A Solution
Preliminary Testing
Temporary Home Installation
The Final System
Deletions:
The Requirements
The Search
A Solution
Preliminary Testing
Temporary Home Installation
The Final System
The oldest known version of this page was edited on
2007-07-08 04:14:55 by AlanB
[initial draft]
DC Power System for Amateur Radio Station
The Requirements
I had the usual stack of 12 volt power supplies - one generic linear Astron, an Icom that matched the rig, and the occasional Astron switcher supply. My station is somewhat cramped for space, and I needed more DC power to run an HF Amplifier that requires up to 100A of 12V current. I also wanted to be able to operate without mains power for awhile, which means I needed a storage battery integrated in with the power supply. I have several rigs plus the amp, so it needed to be able to supply about 150A at 12V. I wanted the battery to be happy, and the radios to be happy. The battery must be sealed, and not Gel.
The Search
I looked at the West Mountain Radio Powergate and the Astron battery-friendly supplies (special versions). I considered building my own similar power control device. I looked at putting batteries across switcher power supplies. I considered diodes, Vmos Power FETs, and microprocessors. I wanted something simple and reliable. There are a lot of ways to solve this problem, but most of them are compromises, or they are complex or they are not known to be within manufacturer's ratings. A particular problem is when the AC is removed from the power supply, but the DC remains from the battery. Does the power supply self destruct? When the AC is returned, does the power supply charge the battery so heavily that it overheats??
Batteries are not so difficult to specify. The available Absorbed Glass Mat (AGM) sealed lead acid (SLA) batteries meet my requirements for avoiding liquid acid in the station, and have exceedingly low impedance to handle the load and also recharge quickly. These are pricey but are often available surplus as pullouts from large Uninterruptible Power Supplies (UPS).
A Solution
A simple solution that is frequently used in Amateur Radio stations is a battery with a charger floating across it. This is fine for low current applications, but the 100 amps for the amplifier really puts a load on the battery. So a high current charger is needed to offset this. However the high current chargers are expensive and often subject the battery to voltages too high for electronics equipment, as well as noise that creates interference in receivers.
A variation on that solution is a charger/power supply made for the Recreational Vehicle (RV) industry. They call these RV Converters. They are designed to power the 12 volt equipment in a trailer or motorhome, as well as charging the batteries. The better quality units have the proper charge regimen for bulk boost, normal and storage voltages, and they put out clean DC that is electronics equipment and battery friendly. Some of these converters are very RF noisy, so we need to select a quality unit that is AGM battery friendly.
So I set out to choose one of these supplies. There are a few reviews on www.eHam.net. They are sparse but show that some brands are RF quiet, and that the larger converters (over 70 amps) tend to be more troublesome from a noise standpoint. I also noted that the higher current models require 20 amp 120 volt outlets, so another requirement was to stay with standard 15A AC plugs.
The particular unit I chose is made by Progressive Dynamics (www.progressivedyn.com). They seemed to have expertise in producing low noise power supplies and high quality RV converters. They were also available at good prices on the internet. I purchased one to evaluate, a model 9260C. This unit produces 60 amps of 12 volt power. It has a built in "Charge Wizard" that manages the voltage for proper battery charging. It charges at 14.4 volts during the bulk/boost phase, then drops to 13.6, and finally drops to 13.2 volts as the current demands fall off. It weighs under six pounds, is less than 4" by 8" by 9" and has a large heatsink and speed controlled fan. It comes with a short AC cord, no power switch, and connectors to take two sets of heavy DC cabling up to 2 gauge (and down to 14 gauge).
Preliminary Testing
I took this supply and added an Anderson Powerpole 30 amp connector. I put some heavy resistive loads on it courtesy of Eric WD6CMU and we measured voltage. It was well behaved. The fan does not run until the load exceeds about 15 amps. Then it comes on so quietly at low speed you can hardly hear it, and ramps up depending on temperature and load current.
I took it to the field and used it to power a Yaesu FT897. We could not find any power supply noise in field conditions. I have not tried wrapping the antenna around the supply, but in actual use we have not found any noise thus far.
On Field Day 2007 I decided to try the amplifier on the supply with a pair of 49 amp hour AGM batteries - one for the rig, and one for the amp. I also added a 1 Farad capacitor to the amp battery. It worked quite well. The converter was powered by a Honda EU2000i generator set in ECO mode. On CW the generator really was modulated, but it never faltered and the amp put out 500 watts of RF. Success!
Temporary Home Installation
I put together a temporary installation at home to continue the testing. This setup includes a single 49 amp hour AGM Lifeline battery, the Converter/Power Supply, and some heavy cabling to the amp with 6 gauge wire and Anderson SB50 connectors. It seems to work quite well, though for the final system even lower loss cable is planned. Testing continues..
The Final System
I am still designing the final system (7/2007), but the present plan is to recycle a computer case to contain the battery, converter and various bits of switching gear. I plan to use a 100 amp hour AGM battery that I obtained at a flea market, a Dynasty group 27 size unit. The computer cabinet will contain all the proper fuses and AC and DC switching. Since we discarded the old computers I have to find a suitable case to recycle...
The cable is an important part of the plan. 6 Gauge wire is rated for about 40 amps of continuous current, but the amplifier can draw more than this in key down service like RTTY. So I plan to use 2 gauge cable and Anderson SB120 connectors for the amplifier in the final system.
AlanB