I am starting this thread because this forum in general is host to many people that own electrostatic speakers, in addition to ML made ones. Some even build their own. I own a unique set of loudspeakers, that I had since 1978, and have been non-functional for about 25 years. Did not spend any time trying to rebuild them because of job and family priorities. The Dayton Wright loudspeakers probably went out of production in the early 80s. because of the design features and Mike Wright being a physicist they had serious reliability issues. They were basically a dream for an electrical engineer to keep repairing them., haha. I suspect that mike Wright has passed away since his web domain is up for sale and it seems all the design information he had posted is now gone. I was on the phone with him many times to get some idea how to repair them. I will share this information for those interested in building their own high output panels. This will be quite technical in nature.
First a few pictures of the cells themselves. For the completer speaker, there are many pictures on the internet, so I won't bother. I am going to show you the guts, so to speak .Below are the first of a series of pictures.
Item 1 is the bias feed. There is an additional resistor to prevent current hogging from the other cells. Because the resistance of the diaphragm is very high, maybe about a Gigaohm, the charge flows very slowly. Because of the current limit of the bias supply to keep arcing damage low, it can take up to a week to fully charge from completely discharged.
Item 2 are the stator supports and are recessed to prevent arcing. The dark spots on the stator are previous deposits of the diaphragm coating. You notice the curvature of the edges of the stator to gradually reduce the electrostatic field at the edges. The diaphragm has no coating where it curves.
Item 3 is the dead space to allow the diaphragm to flex as it is only attached at the top and bottom and NOT the sides.
The whole design relies on minimizing the parasitic capacitance. I have seen may designs that completely ignore this and attach the coated diaphragm to the edge where is adds useless capacitance but no sound. In this design, not even the stator is attached to the outside of the frame. Also the diaphragm is allowed to freely move the length of the edges for a distortion-less motion. The gap between the stator and diaphragm is about 0.25 inches. I believe that is larger than any other. The other thing to note is that there is no insulation on the stator. Mike Wright explained to me that if you add insulation which typically has a dielectric constant of between 3 and 5, it reduces the active gap and even worse it limits the dynamics and as the diaphragm moves closer to the stator, the electric field compresses in the dielectric and the motion becomes compressed at high excursion levels. I found this effect very obvious when listening to a lot of percussion and comparing it to other electrostatics. Some of these things don't work that well when using air, but Sulfur hexaflouride extinguishes the arc very quickly.
First a few pictures of the cells themselves. For the completer speaker, there are many pictures on the internet, so I won't bother. I am going to show you the guts, so to speak .Below are the first of a series of pictures.
Item 1 is the bias feed. There is an additional resistor to prevent current hogging from the other cells. Because the resistance of the diaphragm is very high, maybe about a Gigaohm, the charge flows very slowly. Because of the current limit of the bias supply to keep arcing damage low, it can take up to a week to fully charge from completely discharged.
Item 2 are the stator supports and are recessed to prevent arcing. The dark spots on the stator are previous deposits of the diaphragm coating. You notice the curvature of the edges of the stator to gradually reduce the electrostatic field at the edges. The diaphragm has no coating where it curves.
Item 3 is the dead space to allow the diaphragm to flex as it is only attached at the top and bottom and NOT the sides.
The whole design relies on minimizing the parasitic capacitance. I have seen may designs that completely ignore this and attach the coated diaphragm to the edge where is adds useless capacitance but no sound. In this design, not even the stator is attached to the outside of the frame. Also the diaphragm is allowed to freely move the length of the edges for a distortion-less motion. The gap between the stator and diaphragm is about 0.25 inches. I believe that is larger than any other. The other thing to note is that there is no insulation on the stator. Mike Wright explained to me that if you add insulation which typically has a dielectric constant of between 3 and 5, it reduces the active gap and even worse it limits the dynamics and as the diaphragm moves closer to the stator, the electric field compresses in the dielectric and the motion becomes compressed at high excursion levels. I found this effect very obvious when listening to a lot of percussion and comparing it to other electrostatics. Some of these things don't work that well when using air, but Sulfur hexaflouride extinguishes the arc very quickly.
