convection cooled tubes - use a chimney, you can also use a fan SUCKING the air from top (DONT blow, sucking the air away works better and reduces thermal stress).
watercooling tubes with a metal can - circulate the water at 0.5m/sec-1.5m/sec in a copper coil wound around the tube.
water cooling of tubes intended for watercooling - use the original coolerassembly and use a polyethylenehose for isolation, use a min. length of 0.8m/kV for destilled water or at least 1.4m/kVp
for tap water (tapwater MUST be drained, dont circulate), consult the datasheet or use at least 1L/min/kW.
contactcooling - has high straycapacitance (even with expensive isolators) but works for tubes with external anode,
consult the datasheet for the highest hotspot temp (usually around 200degC)
oilcooling of glasstubes - have no expirience with it, but my guess is it wont bring much (low thermal capacity, thermal stress, dielectric losses), i think it is better to use a chimney instead, but if you want to try use at least transformeroil, use pressure regulation and overpressureguards and prevent aircontact.
watercooling tubes with a metal can - circulate the water at 0.5m/sec-1.5m/sec in a copper coil wound around the tube.
water cooling of tubes intended for watercooling - use the original coolerassembly and use a polyethylenehose for isolation, use a min. length of 0.8m/kV for destilled water or at least 1.4m/kVp
for tap water (tapwater MUST be drained, dont circulate), consult the datasheet or use at least 1L/min/kW.
contactcooling - has high straycapacitance (even with expensive isolators) but works for tubes with external anode,
consult the datasheet for the highest hotspot temp (usually around 200degC)
oilcooling of glasstubes - have no expirience with it, but my guess is it wont bring much (low thermal capacity, thermal stress, dielectric losses), i think it is better to use a chimney instead, but if you want to try use at least transformeroil, use pressure regulation and overpressureguards and prevent aircontact.