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Where's Hartley?
Paper was cheap and readily available, and when properly baffled in a large horn or bass-reflex enclosure, to minimize its excursions (by maintaining efficient coupling to the air) and damp out its bass resonance, the paper cone seemed to be the ideal woofer diaphragm. But this was only because it had never been compared with anything better.
When Britain's Peter Walker demonstrated the first full-range electrostatic speaker system in 1955, the paper-cone systems sounded so muddy by comparison that dynamic-speaker designers scurried back to their labs to try to build dynamics that sounded like electrostatics.
They might have had some success, too, had not stereo created a demand for compactness in speakers. The small enclosure aggravated every problem that had existed in large enclosures, so instead of being able to improve the dynamic-speaker sound of the big systems, designers were hard put to equal it from a small box.
The effectiveness of the moving-coil loudspeaker depends on its diaphragm's ability to follow the motions of its voice-coil. The ideal diaphragm behaves like a piston, whose surface moves as a unified plane in accordance with the voice-coil's movements. Any cone motions that do not coincide with voice-coil motions represent distortion, and this is paper's major weakness.
A paper cone is inherently flexible, so the only part of it that follows precisely the motions of the voice-coil is that immediately surrounding the voice-coil. Beyond this small area, flexure of the cone absorbs increasing amounts of vibrations until, at the rim, much of the original vibratory motion has been lost. And because of this lack of control over the whole cone surface, large areas of the cone are left free to break into spurious vibrations on their own at certain frequencies.
Stroboscopic studies of cones in motion have shown that this breakup occurs at various frequencies throughout the speaker's entire range, and becomes worse as vibration amplitudes increase. It is particularly severe at low frequencies, where the cone must travel appreciable distances.
This is why small enclosures cause so much trouble. Without the efficient bass coupling of a more ideal enclosure, the speaker must be made to yield increasing excursions with diminishing frequency, to retain full bass response. This means its excursions in the bass range must be at least twice as great as they would otherwise be, and this in itself aggravates the normal flexing of the paper.
Some manufacturers, questioned about the boxiness, bass deficiency, and lack of clarity in their small speaker systems, tried to talk themselves out of the dilemma, claiming that those little problems really weren't problems at allstereo would restore the lost clarity and bass, and the boxiness was just a matter of personal opinion. Others, hoping to retain at least some of the quality standards that had been set by the mammoth horns and reflex systems, had to make some drastic changes in their speaker designs.
Various stuffing materials were used to eliminate the boxy sound of the small enclosure, but these caused some problems of their own, by absorbing certain frequencies more readily than others.
In attempting to ameliorate the cone breakup problem, designers tried stiffer cones, made of heavier paper, but these reduced the system's efficiency as well as the woofer's upper frequency response. The choice then was between ignoring the resulting midrange hole, or trying to design a crossover system to work in the region where their design problems are greatest (the 4002000Hz range).
Variable-density conesheavy and rigid near the voice-coil, and tapering to thin and light at the rimwere tried in an effort to combine the advantages of lightness and stiffness, but they suffered from the disadvantages of both. Their upper-range response was poor, and they, too, failed to operate like the ideal piston radiator.
Polymerized paper, light in weight but stiffened with a plastic impregnation, was a step in the right direction, but it tended to ring at certain frequencies, coloring the sound.
Impregnated linen cones with corrugations or spiral compliance rings, cambric cones with "dimples" on them, and thin metal-foil cones all showed some promise, particularly the metal-foil design, but the best of them were prohibitively expensive.
One of the most successful papercone variants was the brain child of Arthur Janszen, who needed a woofer to complement his electrostatic tweeter. Instead of thickening the cone paper, he reinforced it with a large conical "plug" of light, rigid polyurethane plastic. The woofer came closer to matching the electrostatic's clarity than had anything before it, and is still used with Janszen-designed electrostatic tweeters in systems made by Neshaminy Electronic Co.
Another engineer named Paul DeMars attached a foam plastic extension to a standard paper-cone woofer, to yield a 30" job whose main shortcoming was its lack of consumer enthusiasm.
Research into the full possibilities of other cone materials was not, however, the kind of project that the average speaker manufacturer could undertake. Most of them had been buying their cones and magnets ready-made for assembly, from the few suppliers of such items in the USA and Great Britain. So the initial research into new cone materials was done by the large speaker manufacturing outfits.
By late 1961, Electro-Voice was ready to announce a 30" woofer incorporating a radically new cone material: polystyrene foam. Almost simultaneously, Jensen unveiled their "Polytec" speakers, also with expanded (foam) polystyrene cones. Meanwhile, two British firms were announcing the fruits of their efforts along similar lines. Leak with a "sandwich" speaker, and Rola Celestion with their "Colaudio" speaker. Other designs followed.
In England, reviewers were highly enthusiastic about the new speakers, but the "official" US reaction has been more tentatively favorable, perhaps because our audio press doesn't understand just what the new cone material does for the dynamic speaker.
All the designers are working with the same material: some form of expanded polystyrene. It is available in a wide variety of densities and textures, it does not absorb water in damp weather (as does paper), it does not dry out and become brittle, and it is chemically very stable. It can be molded, turned, or formed into practically any shape, and it can be chemically treated during manufacture to provide virtually any frequency or damping characteristic. But its most attractive feature is that it can be made far more rigid than the same weight of paper. Hence, it can be both lightweight and stiff, to yield much better piston action than the best of the paper cones.
Let's look at some of its currently available forms. Electro-Voice's 30" woofer has the standard cone shape. The Jensen Polytec woofer uses a hollow "cantilever" plug, with a shallow conical rear and a flat front surface that is driven from around its edge. Jensen's tweeter has a polytec cone of fairly conventional shape, while the supertweeter has a convex dome-shaped diaphragm that is driven from its outer edge. The British IMF styrene woofer's radiator is conical at the rear, convex and dome-shaped in front, and of solid foam all the way through. The Leak "sandwich" is conventional in shape, but its cone is of 3/8"-thick styrene foam covered with duraluminum foil. The British KEF woofer (soon to be available here), and the GE-GO Orthophase speaker are "sandwich" systemsflat on both sides, and driven over their entire front surface by a system of duraluminum ribbons.
All polystyrene speakers do not sound alike, but they do share a certain clarity and freedom from the turgid, mushy coloration of the small-box wide-range paper-cone systems. Indeed, they sound much more like electrostatics than do conventional dynamics, and have a quality of crispness that we used to associate only with the large horn or reflex-loaded systems. The reason is obvious: the electrical energy is being used for sound production, rather than for cone flexing.
An A-B comparison with a paper-cone speaker reveals another interesting difference: the polystyrene's superior rigidity and lower mass allow it to reproduce more of the program's dynamic range, because so much less of the voice-coil's movement is lost in flexure of the polystyrene cone.
Are polystyrenes here? Definitely. However, as is true of electrostatics, the good ones are expensive. There are still some design and production problems that must be ironed out before they can be made well and cheaply, but as the techniques are perfected, we can safely predict that all high-quality loudspeakers will eventually abandon the venerable, obsolete paper cone.Irving Fried
... https://www.stereophile.com/artdudleylistening/106listen/index.html
Yeah but I wonder why Bud didn't mention him.
... the conclusions were generally positive, but there didn't seem to be the sense that a genuine breakthrough was at hand.
Maybe the complete speaker systems weren't realizing the full potential of the drivers?
By comparison, an early 1960s review of the IMF(ried) Styrene Pressure speaker seemed quite a bit more enthusiastic.
Comments noted that "reproduction of voice was extremely lifelike" and that there was "virtually no coloration imparted to the sound".
Yes, it is likely that the complete systems were not as successful as the drivers and that most of their business was selling the latter, both to consumers and to other loudspeaker companies, e.g., Wilson.
Still, in a retrospective such as this one, the absence of any mention remains curious to me.
... "Almost no one knows Hartley speakers and we'd like to keep it that way." Maybe Bud was just trying to comply with their wishes.
Wilson Audio among many others, still use paper cones in 2019 :-) .........
Get Greg Timbers of JBL fame on line 1 please.
Mark Levinson HQD system used two 24" Hartley woofers :-) ............
... it seems inexplicable why Salk chose paper cone woofers for their effort to recreate a Fried design after Bud passed away:
http://www.friedproducts.com/
... plastic speaker cones from the 1960s to the present date:
https://www.audioxpress.com/article/Plastic-Speaker-Cone-History
Paper or plastic? :-) ..........
We are happy that, it is not styrofoam ........ That stuff is banned in some cities now :-) ..........
Thanks for combing the archives to publish retrospectives. This one was particularly potent thanks to the miracle of hindsight. There's a lot to be learned here just from watching the arguments evolve.
I appreciate the historical perspective. But, the old pistonic technology of cone and flat membrane transducers has already been supplanted by the Planot pivotal diaphragm technology. My patented design not only eliminates the need for an enclosure to block the back-wave but is inherently not subject to all to the other deficiencies you listed. And as well it is motor agnostic.
http://www.planotspeaker.com/
Extraordinary how an otherwise talented designer can be proven so wrong throughout the history of a technology. So many generalities unsupported by data, such a narrow view of the job of a loudspeaker cone, and such dismissiveness of nature's ideal non-woven fiber composite.
There are so many things that can be done with paper, and the speakers that have the most natural midrange reproduction are those that successfully marry the strength-to-weight ratio of paper with careful control of breakup (which is experienced by ALL cone materials in different ways) to produce a cone which essentially varies its piston diameter with increasing frequency. Paper can be coated, resin impregnated, lacquer-dipped, easily formed into a variety of thicknesses and profiles, and filled with fibrous and powdered materials that change its properties in a dizzying variety of ways. The industry's most successful raw-driver products are those that use paper cones, because designers have noted and prized the versatility of paper as a loudspeaker cone material, with variable loss, variable density, variable stiffness, and variable geometry among the range of available designs. What they have in common is very orderly disposal of vibration energy in random directions through the non-woven fibers, relatively low density among common cone materials, reduced height of breakup modes (easier to control with a passive crossover), and low cost to obtain all of this, compared to alternative materials which maximize one of those characteristics at the cost of the others.
Much is made by Fried of the ability of a speaker cone to act as a piston. As time has gone by, the industry has begun to realize that as you design a cone to work as a perfect piston over more of its operating bandwidth, you end up with much taller and less-damped breakup modes at the upper end of the "piston band" in the natural frequency response of the device, which require a more complex crossover to fully filter out these breakup modes that otherwise impart a characteristic "sound" to the speaker. This is why people say that poly cones, paper cones, and aluminum cones have a characteristic "sound" - they ring, buzz, honk, scratch, muffle, or shriek according to the internal self-damping qualities of the material, which are much as one could gather by intuition, which is why it has so much power to say "XYZ cone sounds like a metal cone", or "ABC cone sounds like a plastic cone". The industry is now considering the ability of a speaker cone to operate in a bending mode with effective damping of its own resonances to be superior to pure pistonic operation for the purposes of midrange reproduction, because the self-damped but less rigid cone presents fewer challenges for integrating into the system through the crossover network, often with better controlled off-axis sound power distribution. This is similar to the enduring popularity of the fabric dome tweeter, which is lightweight but not very rigid, and instead is very heavily self-damped (to the point where some fabric domes consist, by mass, of more damping compound than the fabric itself). As frequency increases to the highest frequencies the soft dome tweeter reproduces, the pistonic area of the tweeter is reduced to the area within a few mm radius of the voice coil, with the rest of the diaphragm remaining as motionless as possible. Furthermore, the synthetic cones with the widest acceptance by designers are those composite cones that attempt to mimic the strength to weight ratio offered by paper as well as the internal self-damping properties and anisotropic strength properties of individual fibers laid in multiple axes (such as in a woven synthetic fiber fabric with a flexible coating layer applied for improved damping). Where pistonic behavior is most beneficial, with the fewest drawbacks in other areas, is in dedicated woofers of a three-way system or subwoofers. For these, I recommend aluminum as the most cost-effective material for achieving light weight and pistonic behavior with low internal loss where sensitivity is not paramout, and a resin-impregnated thick-section paper cone with a lightly-applied damping coating where sensitivity is more important.
As audio enthusiasts, engineers, and designers, we should take full advantage of today's understanding of non-pistonic behavior of diaphragms based on material choice, processing, and geometry, using that understanding to produce superior state-of-the-art speakers, and move beyond the limited understanding reflected by Bud Fried in this piece. It reads more like a designer-as-salesperson attempting to establish a technical basis for hawking whatever he is selling, rather than an engineer's fair-minded and rational analysis of the benefits of available speaker cone materials.
I totally agree that paper cones have the potential to excel in music reproduction. I just auditioned the Acora Acoustics SC2 with twin 7" paper mid-woofers. They plumb the depths in bass and have tremendous punch/dynamic movement of air. It's how the speaker was designed (100% granite cabinet) which permits those small paper drivers to excel. Everyone who experiences them is surprised by the sound quality.