US2032741A

US2032741A - Mechanical recording

Info

Publication number: US2032741A
Application number: US757957A
Authority: US
Inventors: Dippel Cornelis Johannes
Original assignee: Philips Gloeilampenfabrieken NV
Current assignee: Koninklijke Philips NV
Priority date: 1934-01-09
Filing date: 1934-12-17
Publication date: 1936-03-03
Anticipated expiration: 1953-03-03

Description

March 3, 1936. c. J. DIPPEL 2,o32;741

MECHANICAL RECORDING Filed Dec. 17, 1934 Invert/for: OCJ. 1 90p 6 I Patented Mar. 3, 1936 )UNITED STATES PATENT OFFICE lands, assignor to N. V. Philips tabrieken, Eindhoven, Netherlands Gloeilampen- Application December 17, 1934, Serial No. 157,957

In Germany January 9, 1934 0; Claims. (01. 274-43) The present invention relates to carriers for use .in the mechanical recording of vibrations and more particularly to carriers provided with gelatin layers.

I have found that when vibrations are mechanically recorded on a layer formed of gelatin, the properties of the vibration track are greatly dependent upon certain conditions of such a layer.

In my copending application Ser. No. 748,144, filed October 12, 1934, I have described a process whereby, by a suitable drying operation to give the gelatin layer a correct degree of dryness, a great improvement in its cutting properties can be obtained.

The measures which I describe in this application, form one condition, which has to be fulfilled in order to obtain gelatin with good cutting properties.

Further investigations, which I have made re- 1. e. to that point at which the solid colloidal particles possess no electric charge--the layer is diiiicult to cut and the surface of the track cut into such a layer has a frosted appearance. Furthermore, the surface of the track appears rough as compared with a clean cut track, and the border lines are less clearly defined.

The difficulty in cutting manifests itself by the fact that when cutting such a frosted track the tool used for this purpose encounters a considerably higher cutting resistance than when cutting a clean-cut track. This increased cutting resistance requires greater power and also may cause considerable heating of the tool, with a resulting deterioration of its cutting .edge. Even if a sapphire cutter is used for this purpose the heating has deleterious efiects, for instance it may melt the cement by which the sapphire is secured to its holder, with the result that the sapphire becomes loosened.

Also, under such conditions the edge of the cutter is subjected to an abnormally high degree of wear, which in its turn deleteriously afiects the quality of the recorded track.

If such a frosted vibration track is to be optically reproduced-and by optical reproduction is meant a photo-electric reproduction of the track, as well as a photographic copying of samethe frosted condition of the track surface, the decreased definition of the border lines of the track, 5

the difiiculties brought about by the increased cutting resistance, and possibly the loosening of the cutter, etc. will markedly afiect the quality of the optical reproduction.

The above dimculties encountered with a track 10 having a pH value corresponding to the iso-electric point seem to be due to the tendency of the colloidal particles to separate out oi. the solution 1 as a flocculent precipitate, when the pH value of the solution is at or about the iso-electric point and thus when these particles are substantia devoid of electrical charge.

This can be explained as follows: When the 2 colloidal particles are charged, the charges are of a like polarity and cause them to repel each other, and to assume a definite distance from each other. However, at the Leo-electric point,

the colloidal particles, having no electric charge, 25

no longer repel each other, but w ll be attracted in accordance with the general law of gravitation, and by such attraction will form smaller or larger conglomerates of particles; 1. e., iioccules which precipitate from the solvent. This precipitation 3 of fioccules in the case of gelatin having a pH value corresponding closely to its is0-electric point, can take place both during the gelatinization of the solution, as well as during the first stag-e oi the drying, so that the finally formed 5 layer exhibits," throughout its entire depth, a more or less granular structure.

While such a granular structure does not imply that the formed gelatin layer is non-coherent, nevertheless, its coherence is not uniform; i. e. the coherence between the parts of a given con glomerate, is much greater than the adherence between individual conglomerates. Because of this, when cutting, instead of removing the desired exact amounts of material, conglomerates 45 may be removed which are greater or smaller than the amount of material desired to be removed.

In such gelatin solutions the iso-electric point corresponds, on the average, to a pH value of 50 I have foundthat, irrespective of whether the pH value of the gelatin solution used falls below or above that of the iso-electric point, as long as this value does not materially differ from the latter value, the above drawbacks, which are the most pronounced at the iso-electric point, still persist to a marked degree.

The present invention is, therefore, based on the recognition that, to obtain satisfactory cutting properties of gelatin, it is necessary to use a colloidal solution whose pH value considerably difiers from the pH value corresponding to the iso-electric point of thesolution. Thereby to get good results the solution has to be either alkaline, i. e., having a pH value of '7 or more, or has to be strongly acidic, to an extent of having a pH value less than 4.

For pratical considerations, alkaline solution should preferably have a pH value between 7 and 10, and acidic solutions between 1 and 4. As a rule, for reasons later to be stated, properly acidified solutions give slightly better results than alkaline solutions.

In order that the invention may be clearly understoodand readily carried into effect, it will be further described with reference to the ac-= companying drawing, in which:

Figure 1 is an enlarged top view of a film. portion carrying a mechanically-recorded. vibration track.

Figure 2 is a cr ss section through the film of Fig 1, taken at 11-11, and also shows the cutting tool while cutting the track.

The carrier shown in the drawing may consist of three superimposed layers. The base or supporting layer i is made of a suitable transparent material, for instance, of celluloid, while the second or cutting layer 2 is of gelatin. Layer 21s the cutting layer into which the vibration track is cut and with which my invention is concerned. The top layer 3 is a comparatively thin opaque layer applied to layer '2 and may be of paint or dye, and ofi'ers a practically negligible cutting resistance. The tool used for the recording is shown as a chisel having two cutting edges d-fi forming with each other an angle 20:. In practicethe angle 20: has a value of about 174, however for clarity a smaller angle is shown in the drawing. By moving the chisel perpendicularly to the surface of the carrier, in accordance with amplification of the vibration to be recorded, a

vibration track is cut into the carrier, the width of which varies with the amplitudes of the vibra: tion to be recorded, and are an amplification of the vertical movement of the chisel. Y

When cutting the vibration track the chise removesportions of both layer 2 and layer 3, the layer 3 serving merely to provide a difference in the translucency of the track and of the background, so as to permitfoptical reproduction.

The left side of Fig.1 represents the appearance, as viewed under a microscope, of the track when the cutting layer 2 is made of a gelatin in which the pH value of the colloidal solution is at, or near, that corresponding to its iso-electric point. In this case the surface of the track has a rough and frosty appearance. Furthermore, particles 5 may be removed at the boundary line of the track, which causes theboundary line to be less definite. I

The above diificulties can be eliminated by providing a cutting layer in accordance with the present invention, in which case a vibration track as shown at the right side of Figure i will be obtained, which track has a smooth surface and clearly defined boundary lines. I

A layer according to the invention can be prepared, for example, as follows: 60 grams of purifled iso-electric gelatin is soaked in 800 cc. of water, and the so-dissolved gelatin is heated to 45 C., and 10 cc. of a neutral sulphonated castor oil, for example, the preparation known. commercially as Turkonol A, is added while the solution is agitated. The solution is then pref erably filtered, after which it is given the proper pH value by the addition of an acidic or alkaline agent, for instance, by the addition of 35 cc. of 1 n Hcl. Such a solution will have a pH value between 2 and 2.5.'-The solution is then no out in the form of a thin layer on a suitable carrier, for example on a celluloid film. The above amount of solution sufiices for the coverage of 1 sq. meter of celluloid, whereby a cutting layer .of a thickness of 50 microns is obtained.

Instead of using hydrochloric acid otheracids, for instance, acetic acid can be used; or if an alkali is at hand, such alkalies as, for instance a solution of caustic soda, caustic potash or spirit of sal-ammoniac can be added.

as Although I mention above some acids and bases,

which have proven useful for this purpose, I do not wish to be limited thereto.

While good results can be obtained by either rendering the colloidal solution alkaline or acidic provided it is rendered sufiiciently alkaline or acidic to considerably change its p'l-I value from that corresponding to the iso-elect'ric point, as a rule slightly better resuits'are obtained with acids, which may be due to the fact that the large molecules of the iso-electric gelatin are hydroli'zed into smaller -molecules without actually changing the general composition of the gelatin. This action is generally lmown and takes place, for instance, when a large molecule of cane sugar is hydrolized by an acid into smaller molecules e.g. glycose and fructose. This reduction in the size of the molecules may also contribute to the improvements of the cutting properties of the gelatin. However, the improvement in the cutting properties obtained,

are obtained primarily because of operating away from the iso-electric point of the solution-thus preventing the formation of conglomerates of uncharged particles-which is evidenced by the fact that alkaline solutions in which no such reduction of the size of the molecules takes place. also give satisfactory results.

The addition of materials such as Turkey red oil is not for the purpose of influencing the pH value of the solution, but such additionimproves the cutting property of the layer by other action.

- The addition of such materials as Turkey red is considerably difierent from the pH value corresponding to the iso-electric point of the gelatin.

2. A carrier for the mechanical recording of a5 an optically-reproducible vibration track comprising a gelatin cutting layer whose pH value falls outside at the range formed substantially by the values 4 to "I.

3. A carrier for the mechanical recording of an optically-reproducible vibration track comprising a gelatin cutting layer whose pH value is l to 4. A carrier for the mechanical recording of 10 an optically-reproducible vibration track comprising a gelatin cutting layer whose pH value is 7 to 10.

CORNELIS JOHANNES DIPPEL.