The discussion centers on the specifications and functioning of electron guns in CRT televisions, specifically addressing the cathode's role and the associated current levels. It is established that CRTs can operate at high voltages up to 35 kV with a typical cathode current ranging from a few milliamps to picoamperes. The electron gun utilizes a heated cathode to emit electrons, which are then accelerated towards the phosphor-coated screen, producing the visible image. Concerns regarding the emission of harmful bremsstrahlung radiation due to the electron beam hitting the screen are also highlighted.
PREREQUISITESElectronics engineers, physicists, and technicians involved in CRT technology, as well as anyone interested in the historical and technical aspects of television manufacturing and electron beam technology.
berkeman said:Google can give you lots of hits to read through. Here's one:
from http://hypertextbook.com/facts/2000/MichelleHong.shtml
"TVs and monitors may have up to 35 KV on the CRT but the current is low -- a couple of milliamps."
Basically, the electron gun has a heated element at the back end called the cathode. The cathode is coated with a material that boils off electrons when heated. The electron gun is put in the back end of the vacuum TV tube, and the cathode is held at a negative potential and the CRT screen is held at a high positive potential to attract the electrons. There are several metal plates of various shapes in the gun itself, and these are held at several intermediate voltages to form electron lenses that contain and shape the beam as it flies forward toward the CRT face. Two magnetic coils are placed at the neck of the CRT (where the tube for the electron gun expands out to mate with the CRT faceplate). These magnetic coils are driven with the horizontal and vertical deflection currents, to cause the electron beam to sweep in the raster pattern across the CRT face. When the electron beam hits the phospurs on the inside of the CRT face, that's what causes the light that we see as the picture.
TVs and computer monitors involve some pretty interesting and fun technologies. And the manufacturing techniques used to make the color shadow mask CRT faceplates is pretty amazing.
Here's a link to a discussion about TVs at HowStuffWorks.com for further reading:
http://electronics.howstuffworks.com/tv.htm
That's why CRTs have lead in their glass envelopes, and that's why you can't just throw out a TV or monitor (lead = hazardous substance).vatly said:Thanks ,
But I still have a doubt about the number of few mA current. Since this few mA current is actually can produce a considerable bunch of bremstralung rays when the hit the phosphorus coated screen, so harful to the audiences. So if you or anyone has some specifications of a tv from the manufactures ? Some even says the current is just few pA. Please help this out
The link you post is questionable. The way he calculates the beam current is very roundabout. The reason I posted the link to the flyback transformer info is that the flyback current is the current that results from the electron beam that hits the anode material on the faceplate of the CRT. This is the same as the cathode current back at the electron gun. The extra energy to boil off the electrons comes from the filament circuit, not from the cathode drive circuit itself.vatly said:Thanks berkeman,
Here is a link mentioned the pA of the currents: http://www.coursework.info/i/172.html
I agree with you that a CRT needs lead mixed glass envelope to shield the EM radiation. I went through the link you gave but it seems that the mentioned few mA current is the current run through the cathode and this current boils the es in the cathode off then those es are speeded up by the electric field btw the cathode and anode, then heading towards the phosphorus screen.
My woder was about those es current ( or e beam). How much is this e beam ?
Thanks.
vatly said:I just got an equation which governs the electron emission of a hot body. That is the so call Richardson equation : I = A T^2 exp(-b/T), where A and b are the two constants. = ampere/cm^2. I used this formula and assumed that the emission area of a tungsten cathode in a television is around 1 mm^2 to 1 cm^2, and the temperature of this cathode within a range of 100 K to 200 K, then the currents were from the orders of 10^(-9) (A) to few mA.
The energy of this electron beam is the order of KeV.
But i am not sure about the real working current and energy for a spectific television since I don't have the whole specific engineering information.