CH247105A - Electrically semiconducting composition intended for the protection of insulations of organs subjected to high voltages and process for the preparation of this composition. - Google Patents

Description

  

  Electrically semi-conductive composition intended for the protection of insulations of organs subjected to high voltages and process for the preparation of this composition. The present invention relates to an electrically semiconducting composition intended for the protection of electrical components subjected to high voltages, as well as to a process for the preparation of this composition.



  In high-voltage devices with organic material insulation, the formation of corona is liable to limit the duration of the insulation as well as the admissible voltage in the electrical and conductive parts, since these corona tend to destroy the insulation. organic matter, so that the electrical insulation is rendered ineffective. Scents, which in electrical devices ionize ambient gases, take place when air or other gaseous fluids are subjected to a high gradient of electrostatic voltage and molecules of oxygen or other gases are chemically or electrically highly active.

   Under these conditions, ozone, nitrous gases and other chemicals can be formed. Decomposition or deterioration of the organic isolation takes place so easily with these chemicals, and to such an extent, that in some cases the organic isolation may fail after a few months.

   In cases where the isolation consists of inorganic materials, such as, for example, mica combined with an organic binder, the action of said scents on the organic binder will require repair at frequent intervals.



  It has already been proposed previously to employ certain semiconductor compositions as paints for isolation surfaces to prevent voltage gradients which would ordinarily cause the formation of corona. For example, a colloidal graphite suspension has been applied to insulated conductors, in order to produce a semiconductor coating permitting to earth the surface of the electrical insulation, and to make it impossible thus the formation of effluvia.

   When this composition is applied to the surface of the electrical insulation, so that there is no gap between the insulation and the semiconductor paint coatings, no action occurs because the entire surface of the isolation: is very nearly under the same relative potential.



  These graphite-based semiconductor layers, while having a sensitive ohmic resistance, can only be used for low voltage electrical parts and only for certain special applications such as, for example, for slots in armatures. puff pastry. The resistance of the conductive paint is .100-10,000 ohms per 6.4515 cm2 of area for a film of 0.075 to 0.1 mm thickness. Such resistance, relatively small, is not entirely. satisfactory for preventing high electrostatic voltage gradients.

    The quantity of the current flowing through the conductive paint being inversely proportional to the resistance and directly proportional to the voltage in the conductor, a fine quantity of, relatively large current will flow through the conductive layers employed heretofore. when the voltage is of the order of 6600 volts or more in the conductor on which the insulation is applied the -paint. In fact, the insulation surface can heat up to the point that it cannot be touched.

   Excessive heat is at least as detrimental to organic isolation as scent. Therefore, most of the known conductive paints are unsuitable for high voltage insulation protection.



  It is impractical to reduce the proportion of graphite in a semi-conductive paint, in order to produce a high resistance, of, for example, the order of 1 megohm or more, since when the amount of graphite becomes relatively small, minimal errors in the composition of the paint would result in huge differences in strength.

   In addition, the resulting layers would be relatively unstable, since a film containing very few graphite particles would be so thin that by expansion, wear, aging or other factors the layer would easily become ineffective. . Such thin layers also exhibit excessive variation in resistance with variations in voltage.



  In order to produce a paint of much higher strength, wood can be heat treated at a predetermined temperature. The paints prepared with the material thus obtained have a greater resistance than those based on graphite:

       Unfortunately, a layer containing charcoal is not sufficiently stable, its strength increases after a certain time, so that after a few years it no longer meets the required conditions. It is believed that this phenomenon is mainly due to the fact that charcoal has large amounts of absorbed gases which react with the binder of the paint in which they are contained, thus causing a gradual change of this binder.

    Since it is necessary to incorporate a large amount of charcoal into the binder to prepare a suitable paint, organic-based binders, etc. are subject to change, continual and unwanted.



  Research on the required qualities of a conductive paint or composition which could be used for high voltage conductors indicates that the semi-conductive paint should preferably have a resistance of 1 to 120 megohms by 6. , 4515 cm 'of a film with a thickness of 0.075 to 0.1 mm,

   in order to sufficiently equalize the potential to avoid effluvia formation without allowing the passage of electric currents such that the coating of the conductor is subjected to harmful heating. The desired resistance depends on the tension of the conductor, the length of the conductor to be coated and other factors, so that particular values cannot be given.



  The composition according to the invention is characterized in that it comprises a finely divided electrically conductive material containing at least 15% anthracite having less than 10% of volatile matter and a binder capable of forming a film after application of said said composition. composition on a support.



  The process for the preparation of the aforesaid composition is characterized in that a finely divided electrically conductive material is prepared containing at least 15% of a mixture of anthracites from different sources and containing less than <B> 10 % </B> of volatile matter, in that the grinding of said material is carried out to colloidal fineness, grinding also being carried out in the presence of the binder until the mass is homogeneous.



  For the purpose of the invention, the anthracite employed should contain less than <B> 10% </B> of volatile matter and preferably be free of any earthy matter and other undesirable impurities. In view of the few sources of anthracite with the desired conditions and the differences in electrical resistance of anthracite, it has been found that for most applications it is necessary to mix two or more kinds of anthracite in order to ensure a determined electrical resistance.

    For example, six samples of anthracite from Pennsylvania were selected, and these pulverized and dried samples were examined for their electrical conductivity. The correlation between resistance and percent volatile matter is shown in the following table:
EMI0003.0010
  
    <I> Table <SEP> I: </I>
<tb> Sample <SEP>% <SEP> of <SEP> material <SEP> resistance <SEP> electri No <SEP> volatile <SEP> that <SEP> in <SEP> megohms
<tb> 1 <SEP> 2.9 <SEP> 0.009
<tb> 2 <SEP> 3.1 <SEP> 0.009
<tb> 3 <SEP> 4.9 <SEP> 0.23
<tb> 4 <SEP> 6.4 <SEP> 0.38
<tb> 6.7 <SEP> 1.4
<tb> 7,7 <SEP> 7,6 The resistances indicated are those of coal alone.

   The values obtained when anthracite is incorporated in different binders are obviously different, although varying substantially in the same ratio as those mentioned in Table I.



  The anthracite used may be ground anthracite, such as that which is known commercially as "Buck wheat" No. 5 (Buck wheat) with a diameter of 2.381 mm or finer, or ground anthracite fine enough to pass through a sieve at 15.5 meshes per cm '. It can be prepared by mixing two or more qualities of anthra cite, as determined by testing. Mixtures of anthracite and charcoal or other conductive solids can also be used.

   As the binder, for example, natural resins or synthetic resins can be employed. The choice of binder depends on the qualities required for the paint. Mention may be made, among the resins which may be used, of coumaric resins, various alkyd resins, such as resins based on glycerol phthalate and on glycol maleic anhydride, plenoplasts; the shellac.



  Other organic substances liable to form a film, such as cellulose esters and ethers, asphalt, can also be used. In some cases, inorganic film-forming materials, such as silicates or bentonites, can even be employed.



  Resins liable to harden under the action of heat; by the effect of condensation, polymerization or oxidation, after their application to the insulation of the conductors, have the drawback of providing layers whose resistance gradually increases to a maximum. On the other hand. a risk of softening by temperature rise is not to be feared. The substances, such as cellulose acetate for example, present this risk of softening, but immediately after drying provide layers of constant resistance.



  To prepare the composition according to the invention, one can proceed as follows: one part of charcoal and two parts of a mixture of linseed oil and resin- based on glycerol phthalate dissolved in 2 parts of gasoline of petroleum or other suitable solvent or part of ethyl cellulose dissolved in a solvent and 3 parts of anthracite are introduced into a ball mill and ground for a period of 2 to 24 hours. The charcoal is then reduced to colloidal fineness and the mass is homogeneous.



  It is also possible to first grind the anthra cite in the ball mill in the binder dissolver to colloidal fineness: Then add the binder and continue to grind for at least half an hour to ensure the formation of a homogeneous mixture.



       It is necessary to continue grinding until the mass is homogeneous in a ball or tube mill, for example, or in any other suitable device, to ensure uniform electrical resistance of the protective layer. The grinding operation reduces the anthracite to a perceptibly colloidal fineness.

   A practical method of determining the degree of spraying of good char is to introduce 0.01% of a carbon suspension into a solvent such as acetone and to determine the relative transmission of light passing through a color. photoelectric meter. A 5% light transmission appears to correspond to average particles of about 1 micron. Light transmission values of 1 / d at 10% seem to indicate sufficient grinding.



  In fig. 1 of the appended drawing is a graph showing the variations in electrical resistance, plotted on the y-axis, relative to the percentage of anthracite pigment, shown on the x-axis, contained in a composition in which the binder is an organic resin, composition used for coating a tape with a thickness of 0.25 mm, the total thickness after coating being about 0.37 mm.

   The curve shows that the resistance varies very quickly below about 10% pigment, so it is very difficult to predict the electrical resistance that will be obtained if the paint contains less than 10% pigment. .

   Semiconductor compositions containing 15-90% pigment based on the total weight of pigment and resin are preferable. Small changes in the makeup of the paint then do not produce excessive variations in electrical resistance. In most cases, it has been found that very satisfactory layers are produced,

   if these contain approximately <B> 50% </B> anthra cite and approximately <B> 50% </B> resin. It is not advantageous to exceed a content of 90% anthracite, since the film can then become mechanically too weak and easily turn to dust on contact. You can use virtually any proportion of solvent and apply the paint by brushing, by spraying. by spraying or by other methods.



  Resistance -varied can be obtained depending on the anthracite mixture chosen.



  Fig. 2 shows the behavior of protective layers obtained from different compositions all containing one part by weight of carbon for one part by weight of solid resin. These compositions were applied to strips 31.75 mm thick in a 0.25 mm layer and then dried. The tapes themselves were impregnated with the composition forming the layer.

   The curves shown were obtained by plotting on the abscissa the number of days during which the films of different semiconductor materials. were subjected to the aging action at a temperature of 200 ° C., and on the ordinate the electrical resistance of the films during the tests. The upper curve A, obtained with beech charcoal in a resin based on linseed oil and glycerol phthalate shows a resistance after 5 days of slightly more than 100 megohms.

   After this duration; the resistance of the layer increases very quickly and after 50 days it is approximately <B> 16, </B> 010'0 megohms. This final resistance value is naturally too high for any practical use and would not effectively prevent the formation of corona.



  Curve B relates to a particular mixture of anthracites pulverized and incorporated using a ball mill in the same resin based on linseed oil and glycerol phthalate. The obtained film had a resistance, after 5 days, of more than one megohm, and -t its resistance, after 5.0 days, did not increase noticeably.



  Another mixture of pulverized anthracites having greater strength has been incorporated into a coumaric resin as well as in asphalt. The resistance of the layers obtained after aging for 5 days was approximately 18% and 16x / 2 megohms respectively (see curves C and D).

   After aging for 50 days, the resistance had not increased significantly since it was then 2'2 and 2f1 megohms.



  Fig. 2 also contains a curve F representing the resistance of a strip prepared from a mixture of <B> 50% </B> thracite of the same quality as that relating to curve B and <B > 50% </B> of beech charcoal having a resistance similar to that used for the band relating to curve A.

   The resistance of the material containing this mixture is intermediate between the resistances represented by the curves <I> A </I> and <I> B. </I> They indicate a moderate increase from 9.3 to 43 megohms. during the testing period.



  The semiconductor composition according to the invention can be used in high voltage devices, such as generators, to protect the insulation of the terminal windings of the conductors, for example. The links or ligatures and spacers employed in the apparatus can be treated with the composition, for example by immersion, and then they can be applied to the conductors. In this way, the surface potential gradients on the conductors can be reduced to a value such that corona can not occur.



  Although the semiconductor paint can be applied in a single layer on the insulations of the electrical components while exhibiting good mechanical adhesion, it has however been found that it is advantageous to apply, as shown in FIG. 4, first a first layer 32 on the insulated conductor 18 and, when the latter is still wet, to coat this layer of semiconductor paint with a tape of porous fabric 34, for example of glass fibers or cotton or asbestos, so that the paint penetrates into the tape and oozes through the spaces of the latter:

       This tape is then painted with the second layer 36 of semi-conductive paint to cover the entire exterior surface thereof. The tape prevents the semiconductor paint from crumbling or peeling off by accidental impact or heat, and thereby increases its durability.



       In some cases, the winding heads can be interwoven using tape or yarn of fibrous material prepared beforehand by applying a semi-conductive paint thereto and drying it. The tape thus prepared is firmly wound around the insulated windings, with the aim of sufficiently equalizing the surface potential to substantially prevent the formation of odors. It is advantageous to still provide a semiconductor layer after having fixed the tape.

    In addition, after having applied the tape or the semiconductor wire to the windings, it can be coated with an additional layer of a paint resistant to atmospheric agents to prevent any contact of air or humidity with it. the windings.



  Fig. 3 shows a semiconductor tape 40 of the aforementioned type. The tape 40 is prepared by dipping a tape 42 of glass fibers, cotton fabric, asbestos or any other suitable material or a mixture of these products, in a semi-conductive paint according to the invention, containing for example a resin, and drying the paint, in order to remove the solvents from the resin. One or more coats of this paint can then be applied to the tape. The tape thus treated is then suitable for being applied to machines in service.

   A tape formed from glass fibers is particularly suitable as a ligature, since it presents exceptional strength.



  The composition according to the invention makes it possible to obtain a semiconductor layer whose resistance is substantially uniform. It makes it possible, for example, to limit the variation in resistance between the different parts of winding heads to about 20%, and such a result is considered to be good in practice.

 

Claims (1)

CLAIM I: Electrically semiconductive composition intended for the protection of the insulations of organs subjected to high voltages, characterized in that it comprises a finely divided electrically conductive material containing at least 15% anthracite containing less 10% volatile matter and a binder capable of forming a film after application of said composition to a support. SUB-CLAIMS: 1. Composition according to claim I, characterized in that the binder comprises a resin in solution. 2. Composition according to Claim I, characterized by the presence of 15 to 90% by weight of the finely divided material relative to the total weight of this material and of the binder. 3. Composition according to. claim I, characterized by the presence of 15 to 90% by weight of finely divided anthracite having less than 10% of volatile matter, constituting by itself the conductive material, relative to the total weight of this anthracite and of the binder, constituted by an organic resin. CLAIM II: Process for the preparation of the composition according to Claim I, characterized in that a finely divided electrically conductive material is prepared containing at least 15% of a mixture of anthracites from different sources and con holding less than <B> 10% </B> of volatile matter, in that the said material is grinded up to colloidal fineness, grinding also being carried out in the presence of the binder until homogeneous of the mass. SUB-CLAIMS 4. Process according to Claim II, characterized in that the finely divided conductive material is ground to colloidal fineness in the presence of a binder dissolver, then the binder-forming material is added and the binder is continued. grinding until the mass is homogeneous. 5. Method according to claim II, characterized in that the grinding to colloidal fineness is carried out in the presence of a solution of the binder.