I have been planning on going down there in person to ask. I meant to go this month but it was on the 12th and I missed it.

Brilliant discussions of theory. Way over my head in most cases. I try to reduce things to the simplest thing that I can visualize or experiment with mechanical analogs and whatnot. Has served me pretty well, but has its limitations.

I do have a working theory and I would like comments from some of you more theoretically minded individuals.


Simple question: When the charge density of a conductor (like a capacitive top load) changes over time, resulting in a propagating wave in whatever medium that EM waves propagate in, is any energy consumed by the wave?

At first blush it would appear 'no', given that when I push charge into a sphere it stores energy as 0.5*C*V^2, where C is the effective capacity of the sphere and V=q/C, and when I discharge the sphere I get that energy back minus resistive losses.

Somebody please correct me...I keep arriving at the conclusion that the longitudinal wave emitted by the top load consumes no energy, even though it clearly possesses some.

Mechanical break

[QUOTE=Nhopa;179124]Hi all:
Reading the notes, the name of two items often come up , the "sensitive device" and the "mercury break" or "Thomas clockwork with wheel". The sensitive device looks very similar to a Reed switch, so the question is, can one use the Reed switch, inserted into a coil, in lieu of the sensitive device's glass tube with the two wires?
The question about the break is what kind of mechanical device, if any, can be used instead of the mercury break or the Thomas clockwork? Is there anything commercially available out there? If not, are there plans available to build one of these devices at home?

Hi all:

A few weeks-ago I have asked the above questions but got no response. If we are going to experiment I think it is important to know what equipment to use. Any suggestions?

[QUOTE=Nhopa;181206]Hi

I'm wondering if it was Seth Thomas, whom Tesla was rererring to; a well known clockmaker who also made clockwork electrical items, for switching stage lighting etc. There is a book by Tran Duy Ly, on S Thomas, but I haven't managed to find a web copy.

Regards

John

TRT calculator

In an effort to make friends and get an answer to the question above. I put together an Excel calculator with the equations Eric posted. It works pretty well, except for the extra coil calculations end up with a negative number. Maybe one of you can figure out what I did wrong.

Now would someone please point me in the direction where I can find and answer to the question above. I know Eric said it was a requirement for but why 62%.

Just point me to a page in a document and I can do the rest.

Thanks,


p.s. I just noticed I cant post Excel files if you want it. I will send it to you just pm me.

Energy, Work, Power and Misc.

I thought I'd pop in and give my two cents on this whole energy, work and power debate, it's application to power magnification and to help clear up a few things which have been asked. This is just a summary of my current understanding which may or may not be able to help those concerned come to a further understanding of what Eric is trying to say.

First of all we'll go back to our fundamental dimensional relations of the difference between energy, work and power. Energy measured is measured in joules, or plancks per second where the Planck was defined by Eric as being of dimensions joule-seconds. Energy is an implied quantity which is only of interest when conditions in a system are changing. If something in our universe changes in any way energy must be equally exchanged between it's various forms (electromagnetic, kinetic, etc.) as to remain a constant quantity as per the Law of the Conservation of Energy or for the Mr Heaviside's out there - 'The Law of the Continuity of Energy'.

When something changes and energy is exchanged there are two more quantities we can talk about and they are work and power. Work is also measured in Joules and is the difference in the energy magnitude from before the system changed to after the system changed. It should be noted that here we have 2 quantities, being energy and work, which have the same dimesions of Joules but represent two slightly different things which is a theme which pops up in the work of Mr Dollard (E,e,I,i being an example).

Power is measured in Watts, Joules per second or Plancks per second per second as per Dollard's units. Power and work are very closely related in that power is measured as the work per second. So basically when the level of energy changes within a system the magnitude of the change is the work and the rapidity of the change is the power.

Okay now let's apply our now defined quantities into a practical situation - the charging and discharging of a capacitor. Let's say I have a 12v battery and I want to charge a 1 Farad capacitor and I am going to charge it through a 1k ohm resistor. The energy stored within a capacitor is given by;
1.

So, from the above equation, after we charge the capacitor we can conclude that we have 72 Joules of energy stored in the dielectric field of the capacitor. The work done in charging this capacitor is given by;
2.

Since we started off with a totally uncharged capacitor (v=0 so E=0) we have done 72-0=72 Joules of work. It should be noted that if the capacitor was charged to any non-zero voltage our values of work and energy wouldn't be equal and so here we have a case of two quantities with the same dimensions having two different meanings for if they had the same meaning they would be equivilent at all times.

So now we want to know how much power or activity we just caused from our charging. Our formula for power is given by;
3.

We already know our work (72 joules) but how much time elapsed in charging our capacitor? Luckily know that the time to charge/discharge a capacitor through a resistance r to just over 63% of it's final value is given by;
4.

I will not try to prove this as it can easily be googled by the time for it to be charged, practically that is since theoretically it is never exactly 12v, is given by 5 times our time constant and so the time taken to charge or discharge our capacitor is given by;
5.

Therefore combining equation 1,2,3 and 5 we get;
6.

So in charging our capacitor of 1 Farad through a 1k resistor to 12 volts we get 0.0144 Watts of electrical activity. Now let's disconnect but not discharge the capacitor and connect it to a separate circuit so that the capacitor discharges into a 10 ohm resistor. Plugging 10 ohms into equation 6 gives 1.44 Watts discharge. The energy stored in the capacitor on charging is the same amount of energy released by the capacitor on discharging, use the above equations to prove this for yourself if don't wish to take my word for it.

I do not have a full chart to prove what I am saying but how about we look at a simple circuit simulator. Here is an example of what I am saying. Notice the peak values for power measured across each resistor.

--

Now for another matter which has come up; 'I do not follow your conclusions at all. Low r or high 1/r (conductance) aids or creates a better condition for transfering energy et al. so I cant even imagine how you are applying the word consumes.' Your thinking in terms of energy when you should be thinking in terms of fields and their actions on the circuit.

Think of resistance as opening the circuit a tiny bit, the magnitude of which depends on the resistor. As we add resistance the voltage delivered by a collapsing magnetic field (or discharging inductor) climbs. I believe you are aware of this as you mentioned it in an earlier post. Current is usually associated with a magnetic field and an inductor is a storehouse of the magnetic field. When we connect a large resistance (or open the circuit) the magnetic field is allowed to collapse and thus the inductor discharges which results in a high webers per second or voltage. The magnetic field is consumed by a resistance to produce a voltage, the lower the conductance the lower the voltage that will be developed. It can be shown here that a magnetic field is preserved by a conductance.

Now think of conductance as closing the circuit a tiny bit, the magnitude of which depends on the conductance. As we add conductance the current delivered by a collapsing dielectric field (or discharging capacitor) increases. Voltage is usually associated with a dielectric field and as we know a capacitor is the storehouse for the dielectric field. When we connect a large conductance (or close the circuit) the dielectric field is allowed to collapse and thus the capacitor discharges which results in a high coulombs per second or current. The dielectric field is consumed by a conductance to produce a voltage, the lower the resistance the lower the current that will be developed. It can be shown here that a dielectric field is preserved by resistance.

I hope this helps.

NOTE: Voltage is not just a phenomena of one field of induction and nor is current. Total voltage and current contain elements of both dielectric and magnetic fields. Hence Eric's E,e,I,i.
Raui

Raui,

That was an excellent and very thoughtful comment on the subject of Energy Work & Power and how they are interrelated. You've done a great job of describing the subject better than I did. Thanks.

I fear my explanations are prolix and opaque to most readers, most of my vocabulary and implied connotations are taken from the 1880s to 1920s so I can see why reading my posts might be confusing for some. Also I am an avid user of e E i & I and angular frequency instead of cycles per second in my own work and ironically find it hard to read V & I now. Its like watching a movie halfway though with subtitles on and then taking them off, its harder to follow the movie now, even though the subtitles were annoying at first.


Kokomoj0,

It would seem we can only agree to disagree on most anything remotely theoretical, at any rate, good luck in your Tesla Transformer construction efforts. Maybe someone else can answer your questions in away that you see fit.


Sputins,

Thanks for the info, I think I am going to ask them (if I can get a hold of anyone first) for another persons lecture and then when I am talking to them ask for the Dollard lectures, I don't think they would see that coming.


Madhatter,

One quick question to your response about L & C annulling in the Tesla Transformer. If the reactance of L & C sum to a zero magnitude vector or reactance X=0=XL-XC (saying they cancel isn't completely correct). Wouldn't that imply a RESONANT condition such as a series LC arrangement, this being in a very unfamiliar one wire (having no return wire) configuration? If so, this makes the "quadra-polar resonance" of LC & MK much more understandable for myself.

Garrett M

Thank you for your very kind comments. I have been a little unsure if my understanding of E,e,I,i was concrete. I know I'm on the right track though. From Symbolic Representation of the Alternating Electric Wave Eric gives the Total Voltage as E = IR - jIX and total Current being I = EG + jEB. So I always took it as meaning that e = jIX and i = jEB. Does this conform to your ideas of E,e,I,i?

Raui

you had my undivided attention until you got to where I highlighted.

It seems everyone is missing the point I was trying to convey that is that a cap integrates the pulse which can be computed in terms of power and presuming everyone understood this was in terms of a filter.

When in terms of transmission where we want the impulse to travel through the capacitor it exhibits the "appearance" of a series resistance in the form of reactance which has the highest "conductance" at fo, OR the lowest apparent "resistance" at fo. Just hit 1/x on your calculator to get one or the other, simple as that. Transmission line does not apply in the same sense as I used. (I better add here that it depends on what type of circuit you have, but I presume you all get my drift)

Just because you have higher voltages and shorter time frame pulses does not mean you have a magnification of "power".

Tesla used the term "power", so I use the term "power" and stayed in those units in my posts. It does not negate anything Eric said nor does anything that Eric said negate what I am saying.

I gave an example of how you could go to from 1 to a million volts in with narrower pulses and discharge roughly the same power in each case because it is time dependent. That was the point. Narrower pulses does not = magnification of power.



as I stated and you only need go as far as yahoo (ironicaly the first thing that popped up):
Now I do not intend to be a language cop here but consume is completely the wrong word to use and gives the exact opposite implication and in some cases does not even apply in any respect to what is in reality "scientifically" or "electrically" <--(used generically in its most expansive term) is happening.

It is simply the wrong word especially when talking about conductance resulting in conflation of terms.


aside from that you repeated "mostly" what I said until you got to the consume part

I will put the translation of what I said in [ brackets ]
fine but splitting it up into 4 quadrants and 4 elemental forces does not change the fact that somewhere in there is a power measurement and in a manner of speaking for simplification your voltage and current is if you will humor me a balancing scale.

[meaning an energized coil has a "finite" amount of total energy in its field, therefore, upon the collapse of the field, the higher the "resistance" or reciprocally the lower the "conductance" the less current will flow and higher the voltage will rise, power remains the same]

In other words when that magnetic field collapses if there is no where for the current to flow the voltage will try to go toward infinity.

[people for whatever reason are now trying to force the application of conductance for everything rather than just state high resistance as high resistance and appears to be becoming more of a word-smithing exercise than that of science.]

On the other hand when there is somewhere for the current to go the voltage will be based on the source resistance of the coil in reference to the load.

[meaning higher conductance OR LOWER resistance, it goes without saying that the voltage will be not rise as high across a load as it would have with NO load OR near infinite resistance which IS THE SAME as near 0 conductance.]

That said, with voltage and current we can measure power which will be based on the strength and quantity of the magnetic field and the coil characteristics.

[Keeping in mind both the source internal resistance and the load resistance will effect the voltage and current response.]

Nothing said so far negates my claim you see.


basically you started and did say pretty much the same thing I did only reversed it into conductance and you all really should loose words like harvest and consume if we want to talk engineer to engineer rather than like the power company talking to the clueless who would not know the difference anyway.

This is something that I was thinking about lately. We know for there to be electrical activity (and Planck's) there must be a dielectric and magnetic component. Then if we have a charging capacitor, we have a displacement current I. This consists of dielectric lines of force in the capacitor. However in order for there to be Planck's charging the capacitor there must be some magnetic component as well. So are there magnetic lines of force in the capacitor(dielectric) as well? Where is the magnetic component?

The dielectric lines of force, Psi, are dragging along the conductor as they fill in the dielectric of the capacitor. The dragging of Psi/second along the wires connected to the capacitor causes a displacement current which produces magnetism.

Dave

As best as I understand it that's correct. And yes, annulment or cancel would not be a technically correct term as it's a transform into counterspace as I understand it. Hence the need for further research.

they cancel in terms of appearing to the circuit to be inductively reactant or capacitvely reactant which occurs (off center to fo).

working together, their combination then appears to the circuit to be a pure or nonreactive resistance at fo absolute, (in ideal conditions).

as you say you are still left with the resistive elements

or if you prefer the low conductance side, it would be a nonreactive conductance.

Q&amp;A

LtBolo,

I don't know if I quite grasp what you're asking, but here's a shot in the dark for a reply:

I interpret "charge density", to be lines of psi per unit surface-area or psi/l^2 where l is unit length (for the surface of a sphere the equation is a little bit different). Following the concept that lines of dielectric induction are stored in all non-metallic space and terminate on all surrounding conductors, we can then say that the "charge density" definitely affects things in the vicinity of the metallic sphere. If we introduce time into this situation and surface-area of metallic sphere is unable to change, then the amount of lines moving in time being the only way to change the overall "density". This would then create a changing displacement current in the AIR and subsequent conduction current in the metallic surfaces of the end points of the lines of dielectric induction. The storage of dielectric energy into the air, or whatever medium chosen, is Work. The subsequent return of that stored energy is also Work. Energy lost is from multiple things; Hysteresis (losses due to polarization not following the fields), Mutual Capacity (energy transferred that can’t be returned), and resistance of metallic surfaces or wires.

I believe three "waves" can propagate here, the first is the polarization wave of the dielectric, the second being from mutual capacity, and the third from radiation resistance, caused by distance between surface-areas and specific wavelength used (via rate of change in the charge density). The hysteresis of the dielectric and the finite velocity of the electromagnetic wave in and of themselves are losses according to CP Steinmetz.

See:
CP Steinmetz - Theory & Calculation of Transient Electric Phenomena & Oscillations 3rd Ed, 5th Imp [1920]
Capacity of a Sphere in space, page 418, Transient Phenomena, Sub Section E
also
High-Frequency Conductors, page 420, Chapter IX

An interesting thought is that of electrostatic discharge. Walking across some carpet you "charge" your person to a high potential. If we think in-terms of lines of induction, we become an end terminal of these lines and our self-capacity is very small so we have a high electrostatic potential associated with our body relative to our surroundings. The reason this appears to be a "one wire" discharge can be seen through the eyes of mutual capacity. The lines of induction produced by rubbing our shoes on the carpet induced a field of flux surrounding our body; this field is mutual to all of our surroundings. The subsequent discharge is that of self-capacity, although we are mutual to many metallic surfaces we discharge, via dielectric saturation of the air, to only one surface. If that specific surfaces capacity relative to our mutual capacity is very small we are still somewhat "charged" and can continue to shock more things we come close to.

I don't know if that came close to answering your question but was at least it was an attempt.


Raui,

One thing to point out, is that in Symbolic Representation of Alternating Electric Waves only “Alternating” waves are discussed. E & I are assumed counter-rotating vectors. I is a mysterious quantity for me, if there is no capacitance in the system, if inductance can be looked at as a capacitor in certain respects then this is more comprehensible. Here the Voltage Drop of resistance is Ir (series resistance) and Current Drop of conductance is Eg (shunt conductance). The reason IX and EB are imaginary and negative is much like a rubber-band. If we expand the rubber-band we store kinetic energy as potential energy, the subsequent release of energy is kinetic but in the opposite direction (it contracts), thus a negative quantity. So for e+Ir to equal jIX, X would have to be Capacitive Reactance or X(sub)C. Also, for i+Eg to equal jEB, B would have to be Inductive Suceptance B(sub)L. Unless I am mistaken, which may be the case. Consider that the EMF of an inductor per unit Time (E=phi/t) is the Induction or release of stored Proportion i (i=phi/L or phi=Li), so It would follow that you can't get i from psi/t unless they were equal, which may be the case in an alternating current circuit (I haven’t tried to calculate i or e in an AC circuit from E & I). A free oscillation requires both capacity and inductance to happen, this being a double energy transient, but for a forced alternation such as a generator, apparently this isn’t the case, you can use only inductance or capacitance to have an alternating waveform. In these instances the usage of e E i & I are a bit confusing but very enlightening once figured out. The case of a generator and transformer, both being inductive elements with very small capacity would have almost no psi/t or Capacity current and the electrostatic potential of the system e=psi/C is a negligible figure as well. If the EMF of the inductor and electrostatic potential of the capacitor are considered equal then e and i could be calculated from other values. I believe the phase angles of the voltages and currents warrants consideration, resonance being a prime example. During Parallel resonance, the voltage’s vector magnitudes sum to zero, that of the source and LC tank. While in series resonance, the voltage’s vector magnitudes also sum to zero, but now being only those of L & C. So if not in a resonant state (180 degree phase angle) the currents and voltages of each element are at some arbitrary phase angle with reference to themselves and the source. This leads to problems from what I can see right off. The fact that measured voltages and currents are vector sums of source and load means you can’t just hookup a volt or amp meter to any arbitrary point in the circuit and get accurate results. During a parallel resonance state, you will measure three different currents, that of the source, the inductance L & capacity C all having a different phase. During a series resonance, you will measure three different voltages that of the source, the inductance L & capacity C these also all having a different phase.

I don't know if any of that makes sense, but is what I currently understand about alternating current circuits.


Kokomojo,

Using a capacitor to integrate the total energy doesn't directly relate to Magnification factor. As Raui has pointed out, Energy is the ability to do work, Work is energy used, Power is the time rate of Work or time rate of Energy used. For the Impulse circuit the discharge and charge times can have different values, therefore power would obviously have to change based upon that, seeing as how "time" is involved. Energy on the other hand is just the base substance, so the capacitive integrator you were talking about only integrates energy not power (you can derive power with a known time period or a waveform, but not without time). If you use the formulae for finding the amount of joules in the capacitor (by measuring the electrostatic potential and using a known value of capacity) from being "pulsed" then all you did was see how much energy was transferred this can be taken as Work but not Power, if time isn’t known. With what I have read of your comments, I don't think you will be understanding magnification factor as it relates to Power anytime soon. On a side note, the usage of Consumption is a correct word choice. While other words can be used to replace it I choose to use it in honor of CP Steinmetz and Mr. Dollard whom both use that "improper” word choice in their writings. And not only is it used in their writings, many books from the time period of 1880 to 1920, use it in similar context. Thus it has a well-established history of usage, therefore it is a technically correct choice, although a forgotten one at that.


To jpolakow and Web000x,

I believe the displacement current is only in a dielectric material, i.e. only flows through insulators. If a capacitor discharges there is a reverse displacement current in the dielectric and subsequent conduction current in the wire (dielectric displacement is much like a mechanical spring). The lines of dielectric induction do not travel in the wire. They agitate the "magic" electron into motion in metallic materials. Here then comes the question, what produces the magnetic field? Is it the electron (an effect) or the lines of dielectric induction (a cause). The proverbial chicken / egg, cause and effect scenario has me perplexed, its possible that something else is taking place which I don't understand at the moment. Much like watching a puppet, you think its alive (electron), until you see the strings (lines of induction), and finally the person manipulating it (haven't been able to figure this one out yet). Unless I am confused that's how I have come to understand the phenomena.

"So are there magnetic lines of force in the capacitor(dielectric) as well?"

I think this is a trick question. I'll attempt to answer this to the best of my ability, magnetic energy HAS TO CIRCULATE to be stored, if you break the connection of a closed current path you release the magnetic energy as a large voltage E or phi/t where phi=Li. During the transient case of the initial "charging" of the capacitor C/t there would be a high conduction current in the metallic parts joining to the dielectric of the capacitor this being seen in the connecting wires and plates of the capacitor in the circuit. In the most simplistic view the amount of magnetic energy as loops would be temporally stored around those metallic parts, where L=((Permeability)(Length))/(Cross-section Area). This is only a temporary event, as the suceptance of the capacitor decreases, so does the current in the conductors, subsequently the magnetic energy however small or large fades away. This is called parasitic inductance.

So to answer, I don't think for a single energy transient, such as a battery charging a capacitor to the same voltage, would involve the plank as Mr. Dollard has described it. But, there would be for a small amount of time, both magnetic and dielectric lines of induction in/around or near the dielectric of the capacitor.

Garrett M

Kokomoj0,
I'm not saying your wrong, a high resistance is a low conductance and visa versa but I fear that is a reductionist way of looking at things. Eric has stressed since the start that what he is trying to convey is more along the ideas of Goethe than conventional science, which should be attributed to Newton, as is shown in the following quote;

and here;
So with that in mind let's look at our disagreement on using conductance and resistance interchangeably instead of low resistance/high resistance. It actually has striking similarity to the battle waged between Goethe and Newton as to a theory of colours. Goethe believed that colour was an interaction between two polar opposites, being light and dark. Newton refuted Goethe's arguments claiming that darkness was only the absence of light and so colours could not possibly be an interaction between light and dark. It is interesting that the Heaviside equation (Off the top of my head it is (RG+XB)+j(RB-XG)), which Eric states is the most fundamental equation in electrical engineering, can be reduced to ZY. This implies that electricity is the interaction of two polar opposite quantities being impedence and admittance in the same way that Goethe said colour arose from the interaction of Light and Dark.

So let's contrast this with our current discussion- Your saying that I am wrong/misinformed because conductance is just a lack of/low resistance, in the same way Newton argued that darkness is an absence of light. Since we are learning Eric's theory we shouldn't try and bring in Newtonian scientific concepts into a concept which has been stressed, repeatedly, that it is Goethean. I am not saying that the Newtonian concepts aren't without their worth but we are moving beyond Newton into a different way of doing science. I feel you might be trying to force the square to be a triangle. Another T-Rex quote. (Yes I know we aren't necessarily talking dimensions here but I feel he'd say a very similar thing to this in response to what we're currently discussing)

Now as for the consumption/production problem. Yes I am aware that to a scientist/engineer trained under conventional theory thinking of the 'consumption' of electricity is a misleading term but again we aren't learning conventional theory we are learning an entirely different theory based on an entirely foreign method of scientific investigation. When a physicist here's the term 'consumption of electricity' they think that one is talking about the consumption of moving electrons which IS a wrong concept, however Eric is moving away from an electron based electricity.

When I say consumption and production I am talking about field lines issuing from the metallic-dielectric confines which seem to just appear out of the geometry with no apparent source (production) and disappear in the same fashion (consumption), what other words should I use? It's interesting to note that to a conventional physicist field lines are just useful analogies to teach students but to the people Eric is references (Heaviside, Thompson, Steinmetz) field lines have a concrete reality. Would you be happier if I used the term 'convert' instead of produce and consume? To me there is no difference between saying convert and saying something consumes one quantity whilst simultaneously producing another quantity and I'd say the answer you prefer would be a matter of philosophy. The other major reason I use the two terms is that Eric uses consume and produce to illustrate these concepts and so I have used these terms as not to further confuse people on an already confusing subject.

If you've never heard of Goethe here is some reading;
Light and Electricity by Tom Brown
Man or Matter by Ernst Lehrs

Garret,
Thanks for your response It's given me some things to think about, I will form a reply a little later.

Raui