东阿县天齐阿胶怎么样:制作10英尺的风力发电机组(8)
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第九部分:叶片装配
At this point you've carved 3 nearly identical wind turbine blades. This next section will detail how we assemble them. Following is the list of materials and hardware required to assemble the blades. Some of this is optional, certain things could be done differently. Some folks prefer to glue the blades/hubs togther - this design is such that you can disassemble the blade set should you ever need to replace parts.
- 1.25" galvanized wood screws, qty 60
- 5/16 - 18tpi 3" long carriage bolts, qty 6
- 5/16" washers, qty 6
- 5/16" lock washers, qty 6
- 5/6" - 13tpi nuts, qty 6
- 11" diameter disk cut from 1/2" plywood (preferably Baltic Birch), qty 2
The blades for the 10' diameter wind turbine will be sandwiched between two plywood hubs, 11" in diameter. Baltic Birch plywood is much stronger than normal plywood and holds up to weather well - we prefer to use it for the blade hubs. Normal plywood will do if the Baltic Birch is difficult to find. Baltic Birch ply is rarely available from normal lumber yards, but you can find it at shops that sell more exotic woods for cabinet making and fine woodworking. It's not expensive. Divide the hubs into three parts and drill about 15 holes in the areas where the roots of the blades will be between them. Easiest is to drill them out together. Use a compass to lay out neatly where the screws will be before you drill the holes. Then countersink the holes so the screw heads will be flush with the top of the plywood. Drill a small hole (About 3/16" is good) in the center of both hubs - this will make centering and alignment of the two hubs easy.
Lay out the 3 blades with the flat sides (the side that will face into the wind) up as shown in the picture. If you cut the 120 deg. angles accurately they should fit together fairly tightly. There should be a tiny flat spot on the center of each blade where they meet each other so that when they come together there is a hole in the center of it all big enough for a small drill bit to help make sure we get everything (the blades and hubs) centered perfectly.
Center one of the Birch hubs over the blades and line up the screw holes you drilled over the blades. It's helpful to place a small drill bit between the blades and through the center hole in the hub to get things centered up well.
第十部分:整流器
Building the 3 phase Rectifier
The alternator you've built produces 3 phase alternating current. In order to charge batteries you need direct current. You can convert the alternating current into direct current by running it through an array of rectifiers (diodes).
Materials list
3 full wave bridge rectifiers, minimum 35 amp rating
1 Aluminum heat sink
Terminal blocks
Silicone heat sink compound
12 Spade connectors for 10 gage wire
A few feet of 10 gage wire
The full wave bridge rectifier has 4 leads. Two leads (on opposite corners) accept incoming alternating current, and the other two give Direct Current out. Sometimes all 4 leads are marked, but in most cases only the positive (+) DC lead is marked. Usually the positive lead will have a flat corner near it, and the spade is usually at 90 deg to all the other spades. Negative is on the opposite corner from Positive. The heat sink is simply a piece of finned Aluminum. They can be fairly expensive to buy, but they are easily salvaged from electronics. You'll find nice big ones on old car stereo power amplifiers, power inverters and lots of other places. We've used finned Aluminum cylinder heads from small engines as well. The heat sink draws heat off the rectifiers. There is approximately a 1.4 volt drop across the bridge rectifier. You can multiply that number by the current flowing through them to figure out how much heat will be generated in the rectifiers. For example - if the wind turbine is producing 10 amps then 14 watts will be wasted as heat at the rectifiers. Without a heat sink, the heat will build up in the rectifiers and they'll over heat and fail. The lower the system voltage, the higher the current through the rectifiers will be so a larger heat sink is required. In 12 volt systems about 10% of the energy produced by the wind turbine is wasted in heat and a large heat sink is required (if the wind turbine is producing 100 amps then your rectifier is a 140 watt heater!). This is one of many reas** to avoid lower voltage systems. It's a good idea when you finish your homebrew wind turbine system to watch the rectifiers closely, see how hot they get in high winds. If it seems to be getting hot, rebuild the rectifiers on a larger heat sink.
Pictured above is the schematic of the system. You need 3 rectifiers and they should be rated for the full current you expect from the wind turbine. In reality, each rectifier must handle about 2/3 of the total current but if you rate them for at least (preferably a bit more) the full current that your wind turbine will ever produce then you have a bit of a safety factor. For this 10' diameter machine figure maximum output to be around 1200 watts. At 48 Volts that would be about 30 amps so you can use 3 35 amp bridge rectifiers safely. At lower voltages you'll need heavier rectifiers - or - you can wire up multiple rectifiers in parallel. The schematic above shows it fairly clearly. Each line from the wind turbine will connect to both AC leads of it's own bridge rectifier. The DC leads of the three rectifiers are in parallel and can wire to the battery. The schematic also shows a 'kill switch' and sometimes the rectifier block is a nice place to mount this. A DPST switch will serve to stop the wind turbine - to do this you need to wire it up such that it will short all three of the AC leads together when the switch is closed, and leave them all open when the switch is open.
The first step is to pick locati** on your heat sink for the rectifiers and the terminal blocks. Drill holes and tap them, usually 10-24tpi screws are appropriate for mounting the rectifiers.
回复 引用TOP
hog
论坛元老
78#
发表于 2010-8-30 14:21 | 只看该作者
第十部分:整流器
Building the 3 phase Rectifier
The alternator you've built produces 3 phase alternating current. In order to charge batteries you need direct current. You can convert the alternating current into direct current by running it through an array of rectifiers (diodes).
Materials list
3 full wave bridge rectifiers, minimum 35 amp rating
1 Aluminum heat sink
Terminal blocks
Silicone heat sink compound
12 Spade connectors for 10 gage wire
A few feet of 10 gage wire
The full wave bridge rectifier has 4 leads. Two leads (on opposite corners) accept incoming alternating current, and the other two give Direct Current out. Sometimes all 4 leads are marked, but in most cases only the positive (+) DC lead is marked. Usually the positive lead will have a flat corner near it, and the spade is usually at 90 deg to all the other spades. Negative is on the opposite corner from Positive. The heat sink is simply a piece of finned Aluminum. They can be fairly expensive to buy, but they are easily salvaged from electronics. You'll find nice big ones on old car stereo power amplifiers, power inverters and lots of other places. We've used finned Aluminum cylinder heads from small engines as well. The heat sink draws heat off the rectifiers. There is approximately a 1.4 volt drop across the bridge rectifier. You can multiply that number by the current flowing through them to figure out how much heat will be generated in the rectifiers. For example - if the wind turbine is producing 10 amps then 14 watts will be wasted as heat at the rectifiers. Without a heat sink, the heat will build up in the rectifiers and they'll over heat and fail. The lower the system voltage, the higher the current through the rectifiers will be so a larger heat sink is required. In 12 volt systems about 10% of the energy produced by the wind turbine is wasted in heat and a large heat sink is required (if the wind turbine is producing 100 amps then your rectifier is a 140 watt heater!). This is one of many reas** to avoid lower voltage systems. It's a good idea when you finish your homebrew wind turbine system to watch the rectifiers closely, see how hot they get in high winds. If it seems to be getting hot, rebuild the rectifiers on a larger heat sink.
Pictured above is the schematic of the system. You need 3 rectifiers and they should be rated for the full current you expect from the wind turbine. In reality, each rectifier must handle about 2/3 of the total current but if you rate them for at least (preferably a bit more) the full current that your wind turbine will ever produce then you have a bit of a safety factor. For this 10' diameter machine figure maximum output to be around 1200 watts. At 48 Volts that would be about 30 amps so you can use 3 35 amp bridge rectifiers safely. At lower voltages you'll need heavier rectifiers - or - you can wire up multiple rectifiers in parallel. The schematic above shows it fairly clearly. Each line from the wind turbine will connect to both AC leads of it's own bridge rectifier. The DC leads of the three rectifiers are in parallel and can wire to the battery. The schematic also shows a 'kill switch' and sometimes the rectifier block is a nice place to mount this. A DPST switch will serve to stop the wind turbine - to do this you need to wire it up such that it will short all three of the AC leads together when the switch is closed, and leave them all open when the switch is open.
The first step is to pick locati** on your heat sink for the rectifiers and the terminal blocks. Drill holes and tap them, usually 10-24tpi screws are appropriate for mounting the rectifiers.
回复 引用TOP
hog
论坛元老
79#
发表于 2010-8-30 14:28 | 只看该作者
Put a bit of silicone heat sink compound on the bottom of each rectifier before you screw it down. It's a sort of grease that helps the heat sink draw heat off the rectifier.
Mount the rectifiers and the terminal blocks to the heat sink. The terminal blocks in the picture are larger than necessary but that sort of thing is typical when you're salvaging parts from other equipment. Better to have things oversized than undersized!
In the picture above the AC leads of all 3 rectifiers are connected to the 3 terminal blocks which will connect to the wind turbine. Now we have only to connect all the (+) leads together and bring them to the (+) terminal block, and do the same with the (-) leads.
回复 引用TOP
hog
论坛元老
80#
发表于 2010-8-30 14:28 | 只看该作者
Pictured above is a finished rectifier. The one in the picture also has an ammeter in series with the negative DC line so that the output from the wind turbine can be monitored, and a kill switch (to stop the wind turbine) wired into the AC end. It's nice to get all the components in one clean unit like this. Also there should be some kind of bracket (or box) so that the rectifier can be mounted to a wall. The rectifier should be mounted so that the heat sink is vertical, (not laying flat) and the fins should run vertical - not horizontal so that air flows up between them more efficiently (this improves their ability to transfer heat to the air).
At this point you've carved 3 nearly identical wind turbine blades. This next section will detail how we assemble them. Following is the list of materials and hardware required to assemble the blades. Some of this is optional, certain things could be done differently. Some folks prefer to glue the blades/hubs togther - this design is such that you can disassemble the blade set should you ever need to replace parts.
- 1.25" galvanized wood screws, qty 60
- 5/16 - 18tpi 3" long carriage bolts, qty 6
- 5/16" washers, qty 6
- 5/16" lock washers, qty 6
- 5/6" - 13tpi nuts, qty 6
- 11" diameter disk cut from 1/2" plywood (preferably Baltic Birch), qty 2
The blades for the 10' diameter wind turbine will be sandwiched between two plywood hubs, 11" in diameter. Baltic Birch plywood is much stronger than normal plywood and holds up to weather well - we prefer to use it for the blade hubs. Normal plywood will do if the Baltic Birch is difficult to find. Baltic Birch ply is rarely available from normal lumber yards, but you can find it at shops that sell more exotic woods for cabinet making and fine woodworking. It's not expensive. Divide the hubs into three parts and drill about 15 holes in the areas where the roots of the blades will be between them. Easiest is to drill them out together. Use a compass to lay out neatly where the screws will be before you drill the holes. Then countersink the holes so the screw heads will be flush with the top of the plywood. Drill a small hole (About 3/16" is good) in the center of both hubs - this will make centering and alignment of the two hubs easy.
Lay out the 3 blades with the flat sides (the side that will face into the wind) up as shown in the picture. If you cut the 120 deg. angles accurately they should fit together fairly tightly. There should be a tiny flat spot on the center of each blade where they meet each other so that when they come together there is a hole in the center of it all big enough for a small drill bit to help make sure we get everything (the blades and hubs) centered perfectly.
Center one of the Birch hubs over the blades and line up the screw holes you drilled over the blades. It's helpful to place a small drill bit between the blades and through the center hole in the hub to get things centered up well.
第十部分:整流器
Building the 3 phase Rectifier
The alternator you've built produces 3 phase alternating current. In order to charge batteries you need direct current. You can convert the alternating current into direct current by running it through an array of rectifiers (diodes).
Materials list
3 full wave bridge rectifiers, minimum 35 amp rating
1 Aluminum heat sink
Terminal blocks
Silicone heat sink compound
12 Spade connectors for 10 gage wire
A few feet of 10 gage wire
The full wave bridge rectifier has 4 leads. Two leads (on opposite corners) accept incoming alternating current, and the other two give Direct Current out. Sometimes all 4 leads are marked, but in most cases only the positive (+) DC lead is marked. Usually the positive lead will have a flat corner near it, and the spade is usually at 90 deg to all the other spades. Negative is on the opposite corner from Positive. The heat sink is simply a piece of finned Aluminum. They can be fairly expensive to buy, but they are easily salvaged from electronics. You'll find nice big ones on old car stereo power amplifiers, power inverters and lots of other places. We've used finned Aluminum cylinder heads from small engines as well. The heat sink draws heat off the rectifiers. There is approximately a 1.4 volt drop across the bridge rectifier. You can multiply that number by the current flowing through them to figure out how much heat will be generated in the rectifiers. For example - if the wind turbine is producing 10 amps then 14 watts will be wasted as heat at the rectifiers. Without a heat sink, the heat will build up in the rectifiers and they'll over heat and fail. The lower the system voltage, the higher the current through the rectifiers will be so a larger heat sink is required. In 12 volt systems about 10% of the energy produced by the wind turbine is wasted in heat and a large heat sink is required (if the wind turbine is producing 100 amps then your rectifier is a 140 watt heater!). This is one of many reas** to avoid lower voltage systems. It's a good idea when you finish your homebrew wind turbine system to watch the rectifiers closely, see how hot they get in high winds. If it seems to be getting hot, rebuild the rectifiers on a larger heat sink.
Pictured above is the schematic of the system. You need 3 rectifiers and they should be rated for the full current you expect from the wind turbine. In reality, each rectifier must handle about 2/3 of the total current but if you rate them for at least (preferably a bit more) the full current that your wind turbine will ever produce then you have a bit of a safety factor. For this 10' diameter machine figure maximum output to be around 1200 watts. At 48 Volts that would be about 30 amps so you can use 3 35 amp bridge rectifiers safely. At lower voltages you'll need heavier rectifiers - or - you can wire up multiple rectifiers in parallel. The schematic above shows it fairly clearly. Each line from the wind turbine will connect to both AC leads of it's own bridge rectifier. The DC leads of the three rectifiers are in parallel and can wire to the battery. The schematic also shows a 'kill switch' and sometimes the rectifier block is a nice place to mount this. A DPST switch will serve to stop the wind turbine - to do this you need to wire it up such that it will short all three of the AC leads together when the switch is closed, and leave them all open when the switch is open.
The first step is to pick locati** on your heat sink for the rectifiers and the terminal blocks. Drill holes and tap them, usually 10-24tpi screws are appropriate for mounting the rectifiers.
回复 引用TOP
hog
论坛元老
78#
发表于 2010-8-30 14:21 | 只看该作者
第十部分:整流器
Building the 3 phase Rectifier
The alternator you've built produces 3 phase alternating current. In order to charge batteries you need direct current. You can convert the alternating current into direct current by running it through an array of rectifiers (diodes).
Materials list
3 full wave bridge rectifiers, minimum 35 amp rating
1 Aluminum heat sink
Terminal blocks
Silicone heat sink compound
12 Spade connectors for 10 gage wire
A few feet of 10 gage wire
The full wave bridge rectifier has 4 leads. Two leads (on opposite corners) accept incoming alternating current, and the other two give Direct Current out. Sometimes all 4 leads are marked, but in most cases only the positive (+) DC lead is marked. Usually the positive lead will have a flat corner near it, and the spade is usually at 90 deg to all the other spades. Negative is on the opposite corner from Positive. The heat sink is simply a piece of finned Aluminum. They can be fairly expensive to buy, but they are easily salvaged from electronics. You'll find nice big ones on old car stereo power amplifiers, power inverters and lots of other places. We've used finned Aluminum cylinder heads from small engines as well. The heat sink draws heat off the rectifiers. There is approximately a 1.4 volt drop across the bridge rectifier. You can multiply that number by the current flowing through them to figure out how much heat will be generated in the rectifiers. For example - if the wind turbine is producing 10 amps then 14 watts will be wasted as heat at the rectifiers. Without a heat sink, the heat will build up in the rectifiers and they'll over heat and fail. The lower the system voltage, the higher the current through the rectifiers will be so a larger heat sink is required. In 12 volt systems about 10% of the energy produced by the wind turbine is wasted in heat and a large heat sink is required (if the wind turbine is producing 100 amps then your rectifier is a 140 watt heater!). This is one of many reas** to avoid lower voltage systems. It's a good idea when you finish your homebrew wind turbine system to watch the rectifiers closely, see how hot they get in high winds. If it seems to be getting hot, rebuild the rectifiers on a larger heat sink.
Pictured above is the schematic of the system. You need 3 rectifiers and they should be rated for the full current you expect from the wind turbine. In reality, each rectifier must handle about 2/3 of the total current but if you rate them for at least (preferably a bit more) the full current that your wind turbine will ever produce then you have a bit of a safety factor. For this 10' diameter machine figure maximum output to be around 1200 watts. At 48 Volts that would be about 30 amps so you can use 3 35 amp bridge rectifiers safely. At lower voltages you'll need heavier rectifiers - or - you can wire up multiple rectifiers in parallel. The schematic above shows it fairly clearly. Each line from the wind turbine will connect to both AC leads of it's own bridge rectifier. The DC leads of the three rectifiers are in parallel and can wire to the battery. The schematic also shows a 'kill switch' and sometimes the rectifier block is a nice place to mount this. A DPST switch will serve to stop the wind turbine - to do this you need to wire it up such that it will short all three of the AC leads together when the switch is closed, and leave them all open when the switch is open.
The first step is to pick locati** on your heat sink for the rectifiers and the terminal blocks. Drill holes and tap them, usually 10-24tpi screws are appropriate for mounting the rectifiers.
回复 引用TOP
hog
论坛元老
79#
发表于 2010-8-30 14:28 | 只看该作者
Put a bit of silicone heat sink compound on the bottom of each rectifier before you screw it down. It's a sort of grease that helps the heat sink draw heat off the rectifier.
Mount the rectifiers and the terminal blocks to the heat sink. The terminal blocks in the picture are larger than necessary but that sort of thing is typical when you're salvaging parts from other equipment. Better to have things oversized than undersized!
In the picture above the AC leads of all 3 rectifiers are connected to the 3 terminal blocks which will connect to the wind turbine. Now we have only to connect all the (+) leads together and bring them to the (+) terminal block, and do the same with the (-) leads.
回复 引用TOP
hog
论坛元老
80#
发表于 2010-8-30 14:28 | 只看该作者
Pictured above is a finished rectifier. The one in the picture also has an ammeter in series with the negative DC line so that the output from the wind turbine can be monitored, and a kill switch (to stop the wind turbine) wired into the AC end. It's nice to get all the components in one clean unit like this. Also there should be some kind of bracket (or box) so that the rectifier can be mounted to a wall. The rectifier should be mounted so that the heat sink is vertical, (not laying flat) and the fins should run vertical - not horizontal so that air flows up between them more efficiently (this improves their ability to transfer heat to the air).
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