we can apply 230v ac to kbpc2510
maximum peak voltage is 325v (for 230v)
and its blocking capacity is about 1000v
so we can use it
(I used for the same application)
The conversion from one DC voltage to another requires electronic circuitry.
Unless otherwise specified, all a.c. voltages and currents are expressed in root-mean-square (rms) values. An rms value is exactly equivalent to a corresponding d.c. value. So, 230 V a.c. is exactly equivalent to 230 V d.c., and 10 A a.c. is exactly equivalent to 10 A d.c.Incidentally, the symbol for volt is 'V' (not 'v') and the symbol for ampere is 'A' (not 'a').
Yes you can .connect the 230 volt capacitor series with the relay coil.AnswerIf you are referring to the operating coil, then the answer is of course not, as you will be subjecting the coil to nearly 20 times its rated voltage! If you are referring to the contacts, then you need to check the nameplate data for the relay to find out what voltage the contacts are designed to operate at.
The quantity you're looking for is current, measured in amps. Electrical appliances are generally rated by power (P, in watts) which is related to voltage (V, in volts) and current (I, in amps) by Joule's law: P=V*I So to calculate current, I=P/V, you need to know V and P. Voltage is 120 V in the US and 230 V in Europe/UK, and you'll have to look up the AC unit's power from it's label.
A 400/230-V three-phase generator hase three line terminals, together with a neutral terminal. The line voltage (i.e. the voltage between any pair of line terminals) is 400 V, while the phase voltage (i.e. the voltage between any line terminal and the neutral terminal) is 230 V.
A lamp will only operate at its rated power at its rated voltage. So if you connected a 230-V lamp to a 110-V supply, its brightness would be very low. It does not matter whether the supply is AC or DC; a lamp would have the same brilliance at 230 V (AC) as at 230 V (DC).As a rule of thumb for fixed-value resistances, a 10% drop in voltage results in a 19% drop in power.
It is an AC supply with an rms voltage of 230 v and a frequency of 50 Hz, as used throughout Europe.
NZ uses 230 V ac, 50 Hz.
The conversion from one DC voltage to another requires electronic circuitry.
yes it is 230 v is deadly, it doesn't matter if it's ac or dc. Some people say one is more dangerous than the other. That implies that there is some voltage, lower than 230 v, at which one will kill you but the other will not. There is no conclusive evidence for that, so it can't be said that ac is more dangerous than dc or vice versa.
Two separate voltages with same magnitude, if are in phase, the voltage or potential difference across their terminal will be approximately zero. This can be identified using an AC voltmeter. Practically speaking, the voltage difference should not exceed 5 V ( 2%) in case of each phase voltage being 230 V. Again, if the two sources are of different magnitude as well, then in case of they being co-phaser, the potentail difference across their terminal will be the difference of their independent voltage. As in, Source A = 230 V AC, Source B = 110 V AC, then in case of they being co-phaser, P.D. will be 120 V.
the Transformer depends up on the Voltage transformer input Voltage 230 V . out put volt depend upon the secondary winding of the coil with swg coil ( copper Thickness) Ex 230 V input = step-up Transformer = above 230 v ( like 440 v, 1000v but same current) 230 V input = step-down Transformer = below 230 v ( like 3 ,6,9,12,24,110v, but same current)
it is possible to .connect two led in reverse polarity. and then one end connect with a 100k resistance then it can connect directly to230 volts
Unless otherwise specified, all a.c. voltages and currents are expressed in root-mean-square (rms) values. An rms value is exactly equivalent to a corresponding d.c. value. So, 230 V a.c. is exactly equivalent to 230 V d.c., and 10 A a.c. is exactly equivalent to 10 A d.c.Incidentally, the symbol for volt is 'V' (not 'v') and the symbol for ampere is 'A' (not 'a').
230 V
P=VI so I=P/V I= 60/230 I=0.261 A
Assuming you can get a three-phase 230 v supply, which has 133 v between neutral and each live, the full-load current assuming a 30% increase for power-factor and efficiency considerations would be 120 amps. In Europe the standard three-phase supply is 400 v. In the US three-phase supplies are normally 208 v or 480 v and an alternative option is a 240/480 v split-phase (single-phase) supply.