US3076219A - Brush construction - Google Patents

Description

Feb. 5, 1963 R. o. PETERSON 3,076,219

BRUSH CONSTRUCTION Filed July 13, 1953 2 Sheets-Sheet 1 INVENTOR PUBE/V 0. PETER& O N

go-MAJ ATTOBNEXS.

Feb. 5, 1963 R. o. PETERSON 3,076,219

BRUSH CONSTRUCTION Filed July 13, 1953 2 Sheets-Sheet 2 INVENTOR. RUBEN 0. PETER 50 V i A T-rorz/ylsya United States Patent 3,076,219 BRUSH CONSTRUCTION Ruben 0. Peterson, University'Heights, Ohio, assignor to The flshorn Manufacturing Company, Cleveland, Ohio, a corporation of Ohio Filed July 13, 1953, Ser. No. 367,421 1 Claim. (Cl. 15-179) This invention relates to brush construction, and more particular to a novel form of high speed rotary brushing tool having operating characteristics never before achieved.

In the manufacture of power driven rotary brushes and the like and particularly wire brushes, it has always been considered necessary to employ brushing material which is as tough as possible and which consequently has relatively high damping capacity and low hardness. Numerous disadvantages always previously considered unavoidable have flowed from such limitations. Wire and the like having a high damping capacity is also relatively soft and the ends of the material accordingly wear back and round over, thereby losing their cutting ability rather rapidly. Materials of this type do not have the requisite hardness to afiord the degree of cutting action desired for the removal of flash, burrs, oxide coatings and the like. As a result, grinding wheels have generally been employed for this type of work. A grinding operation, however, unless performed with very accurately adjusted equipment, often mars the work surface to a degree requiring a further finishing operation, as by brushing, for example. It is accordingly a primary object of my invention to provitle a brushing tool in which the brush material may be of a relatively high degree of hardness and the brush con,- struction designed to provide adequately for the damping of destructive vibration.

Brush material of the type which I employ, e.g. hard tempered steel wire and glass fiber, is not only relatively brittle but its tendency to fracture in use is greatly increased by secondary factors. Very slight scratches on the surface of a glass fiber strand, such as result from interaction of such strands in a rapidly rotating brush are sufficient to cause fracture of the strands and rapid destruction of the brush. While this same effect is an important cause of self-destruction of wire brushes of the type in question, another effect, namely corrosion due to atmospheric, operating, and storage conditions is a still more serious cause of deterioration. In fact, when operating a power brush at a relatively high speed of rotation the impact of the brush wire against the air has the effect of raising the atmospheric pressure thereagainst, greatly increasing the ability of the air to oxidize steel wire, particularly at the somewhat elevated temperatures developed by operation of the brush. Changes in hu midity during storage and contact with sweaty fingers are other corrosion accelerators. Once corrosion has commenced, the percentage fracture of the brush material is greatly increased.

Since brushes of this type are commonly employed to apply powdered abrasive and the like to a work-piece, it is obvious that a certain amount of such abrasive will find its way between the strands or bristles and initiate further premature fracture of the same.

When suitable hard brush materials are mounted in a brush back for use as a power brush, there is a tendency for vibrations resulting from operation of the brush to be communicated to concentrated points or areas along the length of the brush material strands. tion of vibratory stresses induces fracture of the brush material at points well back from the working face of the brush and greatly reduces the life of the latter. Brush material such as wire has in the past'been crimped or twisted to minimize such concentrations of stress. .When

properly crimped for a given density of a given brush material, the strands support each other to a considerable extent and tend to confine the points of fracture near the working face of the brush. Similarly, when a tuft of brush wire, for example, is twisted to form a coiled knot of such wire, the individual wires thus closely associated tend to support each other and to diffuse the vibratory stresses in such manner as to reduce breakage at points far back from the working face of the brush. Extremely hard brush bristle material, however, usually cannot be crimped or twisted in a satisfactory manner and even when a degree of crimp may be imparted thereto (as when the material is heated) the tendency toward long fracture in use may nevertheless prove a serious disability.

Certain objects of this invention are therefore as follows:

To provide a brushing tool having improved cutting capacity and increased life;

To provide a tool of great cutting capacity yet capable of leaving a relatively smooth finish on the work as compared to the usual grinding wheel or similar fast cutting tool;

To provide a brushing tool modified for more effective application of abrasive;

To provide a brushing tool which will wear back evenly in use, providing a face of the same width and operating characteristics at all times;

To provide a brushing tool having hard brush material of low damping capacity associated with other material of a high damping capacity effective to prevent concentration of vibratory stresses at points far back from the working face with resultant long fracture of such brush material;

To provide a brushing tool in which the ends of the brush material will themselves progressively crumble or fracture in use and thereby remain sharp and effective rather than rounding over;

To provide a brushing tool in which the brush material is supported in a novel manner effective both to enhance its cutting capacity and to protect it from scratches, corrosion, and similar deteriorating influences.

Other objects of my invention will appear as the description proceeds.

To the accomplishment of the foregoing and related ends, said invention then comprises the features hereinafter fully described and particularly pointed out in the Such concentraclaims, the following description and the annexed drawing setting forth in detail certain illustrative embodiments of the invention, these being indicative, however, of but a few of the various ways in which the principle .of the invention may be employed.

In said annexed drawing:

FIG. 1 is a perspective view substantially in side elevation of a typical annular rotary brush section;

FIG. 2 is a similar view showing a brushing tool in ac-' cordance with my invention incorporating the brush of FIG. 1; v

FIG. 3 is a similar view of another embodiment of my invention incorporating several turns of helically coiled brush strip;

FIG. 4 is a perspective view of another type of brush adapted to be modified in accordance with my invention;

FIG. 5 is a side elevational view of a brushing tool formed in accordance with my invention and employing the brush of FIG. 4 as a constituent part thereof;

FIG. 6 is a perspective view of the brushing tool shown in FIG. 5;

FIG. 7 is a perspective view of a length of brush strip which has been modified in accordance with my invention;

FIG. 8 is a perspective semi-diagrammatic viewof one type of rotary tool utilizing the element of FIG. 7;

FIG. 9 is a side view of a rotary brushing tool generally similar to that of FIG. 2 but modified in that the inner end portions of the brush bristle material are left exposed adjacent the annular brush back;

FIG. 10 is a side view of a rotary brushing tool generally similar to that of FIG. 2 but having ventilating grooves in the sides thereof;

FIG. .11 is a side view of a brushing tool generally similar to that of FIG. 2 but formed with a slotted periphery; FIG. 12 is a much enlarged fragmentary view of a portion of the outer periphery of one embodiment of my new rotary tool wherein the brush bristles are individually coated with a resilient material prior to being embedded in a common resilient matrix; and

FIG. 13 is a similar fragmentary view where the brush bristles are individually coated with a cement to improve the bond to the plastic matrix.

As above indicated, I employ brush material which 'may be of a very high degree of hardness, and I embed such material in a supporting body or matrix of suitable high damping capacity material.

Construction Many well-known types of brushes are adapted to be modified in accordance with my invention to produce my new brushing tool. Reference may be had to my prior Patents Nos. 2,303,386; 2,316,185; and 2,421,647 as well as to Whittle Patent No. 2,288,337 and Bickel et al. Patent No. 2,062,047 for typical examples of well-known power "driven rotary brushes which are thus suitable for use.

Referring now more particularly to the drawing, FIG. 1 thereof shows an annular rotary brush section in which stranded brush material 1 extends substantially radially from an inner circular channelform back 2. I have modified brushes of this type by intruding a suitable plastic as described below between the strands of the brush material so that such material is completely embedded in the plastic matrix. Such brush material may be hard low damping capacity steel wire, and the intruded plastic may, for example, be neoprene having a certain amount of a filler such as bentonite incorporated therein together with the usual vulcanizing agents and the like. If desired, other abrasive powders may likewise be incorporated in the plastic material. The plastic is forced into the brush material within a suitable mold, the two sides of which may desirably be faced with cloth annuli 3 so that when, after curing, the finished article is removed from the mold, the cloth will adhere to the sides of the article as shown in FIG. 2. .Instead of cloth, similar sheets of nylon or a rubber-containing compound may be employed. These facings serve several purposes. The cloth will prevent the plastic from adhering to the mold, this sometimes being an annoying problem in the molding of rubber and like plastic materials, and especially so in the case of the materials preferred for use in accordance with this invention. The facing of cloth or like material reduces any tendency of the stranded brush material to break out laterally of the highly filled low tensile strength matrix in which it is preferably embedded. The nylon and high tensilerubber-like facings are, of course, also acid and alkali resistant and afford further protection to the tool under certain working conditions. One very satisfactory form of side facing consists of cloth im pregnated with a rubber compound, thereby providing both strength and protection from acids and the like. A typical example of a higher tensile strength facing layer material is given below by way of illustration:

The degree of resistance to abrasion of the plastic material which has been intruded into the brush material may be controlled by varying the amount of special filler therein, sufiicient filled content causing such plastic to become somewhat crumbly under operating conditions at the working face of the tool.

By properly selecting the brushing material and the plastic matrix, a tool of this type may be provided in which the plastic wears or crumbles away at a slightly more rapid rate than the hard wire or similar brush material wears back. As a result, the ends 4 of the strands 1 will protrude very slightly from the matrix material and afford a very high cutting capacity while at the same time being resiliently supported in a manner to achieve a long useful life. As the tool wears down in use, the plastic continues to erode and the bristles are progressively exposed so that there is no consequential alteration in the brushing face presented. As compared to the type of grinding wheel generally employed for such work, this new brushing tool, while having a very high cutting capacity which renders it useful for the removal of burrs, flash, and oxide coatings, for example, nevertheless provides a superior finish on the work-piece which usually obviates the necessity of any further finishing operation.

When my preferred hard brush material is employed in a resilient plastic composition as taught herein, any fracture due to impact or vibration will occur close to the working ends thereof which protrude slightly from the supporting matrix. This serves to keep such ends sharp without reducing the diameter of the tool with undue rapidity. Generally speaking, the less hard of the hard brush materials I may employ may protrude from such supporting matrix to a considerable extent without excessive long fracture in use. When, however, the Knoop hardness of the brush material exceeds 900 it becomes yery important that such material protrude only very slightly from such matrix. Similarly, the more resistant to fracture brush material, the more resistant the resilient plastic composition should be to abrasion so that it will crumble away from the working face only sufiiciently to expose very short lengths of such brush material. 'Various compromises may, of course, be effected to obtain a particular desired set of operating characteristics.

Instead of employing a single annular brush section as above described, a cylindrical brushing tool having a 'wider face may be provided by similarly intruding plasltic into several turns of helically wound brush strip 5 as shown in FIG. 3 and molding the same in an appropriate mold.

The brush illustrated in FIG. 4 of the drawing is of a type employed commercially for several years for brushing the interior surfaces of deep cavities such as connecting rod bearing holes and the like. It comprises a tuft of stranded brush material 6 tightly clamped between two straight parallel portions of a rebent wire 7, the two end portions of which are twisted together to form 'a stem 8. As shown in FIGS. 5 and 6, I intrude a "suitable plastic into the brush material of this brush and v mold the same with the brush material inclined downwardly so that in the finished article, after curing, the lower portions of the two work faces 9 and 10 are below the point 11 of bending of retaining wire 7. Consequently, this tool may be employed safely in blind holes without danger of the rebent portion 11 of the wire retaining member striking the bottom of such holes. It will be understood that tools of this type will ordinarily be mounted in the chuck of a rotary drill or the like.

Referring now to FIGS. 7 and 8 of the drawing, I may similarly intrude an appropriate plastic material between the strands of the brush material of any well-known type of brush strip such as that shown in my prior Patent No. 2,303,386 having a channelform back 12 and stranded brush material 13 retained therein by means of a retaining wire 14 permanently secured in such back by teeth punched in from the sides of the channel at 15. The

mold cavity in which the length of brush strip is placed for intrusion of the plastic will preferably have parallel side Walls so that the two sides of the finished article will be parallel instead of somewhat flaring as is generally the case with such brush strip. It is desirable not only that the thickness of the working portion of the element be uniform but also that such thickness be slightly greater than the width of the channelform back 12. This will ordinarily mean that a slight shoulder 16 will be provided a short distance above the upper edges of the channel sides. As shown somewhat diagrammatically in FIG. 8, brush elements of this type may be twisted slightly helically and mounted in this position in a suitable rotor 17.

It will be noted that While the brush bristles of the above-described embodiments of my invention are secured to a suitable rigid central member such as annulus 2 or stem 8, for example, in close mutually supporting sideby-side relationship, such bristles diverge as they extend therefrom to space apart their outer end portions. This is also true in the case of the brush strip of FIG. 7 which is adaptedto be mounted on rotatable central member 17, inasmuch as the brush bristles will ordinarily be densely compacted within the channelform back 12 but will flare somewhat therefrom so that their outer end portions are appreciably spaced apart.

The FIG. 9 embodiment of my invention is generally similar to that of FIG. 2 described above. The annular sheet metal channelform back 18, however, may desirably be radially indented as at 1? to facilitate radially outward flow of cooling air when the back is mounted on a ventilating adapter, for example. In this embodiment, the resilient plastic matrix 20 is molded to embed the outer circumferential portions of the bristles 1 only, leaving the inner end portions of such bristles adjacent the back 18 exposed as illustrated. With certain bristle materials this arrangement aifords adequate support and the other desired characteristics while reducing the amount of plastic material required, reducing the weight of the tool, and facilitating ventilation particularly if radially extending grooves are also provided as in the case of the FIG. embodiment described below.

The FIG. 10 embodiment of my invention is generally similar to that of FIG. 2 except that a plurality of radially extending shallow grooves 21 are molded in the sides of the body or. matrix of resilient plastic 22 embedding the bristle material 1. Such grooves 21 not only cooperate with indentations 19 to aiford a ventilating and cooling effect but, more importantly, they provide chip space which assists in preventing clogging of the working face of the tool in operation.

Chip space may also be provided in the manner illustrated in FIG. 11 of the drawing where a tool generally similar to that of the FIG. 2 embodiment is shown molded with a plurality of radially inwardly extending slots 23- in the outer periphery of the tool. Such slots may conveniently be provided by employing corresponding fins in the molds utilized to mold the plastic body 22 as above described. They may extend diagonally instead of parallel to the tool axis, if desired.

In certain embodiments of my invention, I may also employ a new and improved form of stranded brush material as shown in FIG. 12 of the drawing (much enlarged). Here, the brush bristles such as bristle 24, preferably of very hard material, are coated with a thin protective coating 25 of a plastic material such as nylon, rubber, neoprene, various vinyl synthetic plastics, and Pliofilm (rubber hydrochloride) prior to being embedded in the main body or matrix of resilient plastic 22. When such brush bristles are thus preliminarily individually coated with a plastic material which is adherent thereto but which preferably will crumble or erode in use (as discussed more in detail below) somewhat more readily than the end of the bristle 24 becomes shorter through repeated fracture, the very short portion of the bristle protruding from the outer peripheral surface of the ma trix body 22 will be additionally supported beyond such surface while nevertheless extending independently of the corresponding outer end portions of the other bristles. Such thin outer coating 25 furthermore additionally protects the strand 24 (in the case of wire) from corrosion.

Such plastic coating 25 may also desirably include fillers and abrasive similar to the matrix compositions employed in the manufacture of tools of the FIG. 2 type, and it may often be found advantageous to employ an appropriate lubricant absorbed in such filler to prevent smudging of the work.

The Brush Material The attitude of workers in the prior art toward the problem of brush material fracture has been to seek tougher materials. While toughness is a desirable qual ity, it is not as important as several other considerations. Tough steel wire is relatively soft so that the ends of the bristles round over in use and quickly lose their cutting ability. Nor do they have sufficient resistance to bending and snap action, which is such a desirable characteristic in brushes. Wire of this type has much higher damping capacity with consequent rapid absorption of vibrations. This self-absorption of vibratory stresses and strains develops internal friction and heat which is a primary cause of fracture. When such absorption of vibratory stresses becomes concentrated at points relatively far removed from the working ends of the strands, long fracture thereof results and the brush consequently has a very short life. By the means herein taught such concentration of stresses at undesired points can be prevented.

A rotary brush revolves at such speeds that each strand is kept vibrating at all times from repeated contact with the work, whether such strands be of the high or low damping capacity type. Low damping capacity material is much less susceptible to self-destruction from this particular cause, however, since it does not do as much work fighting against vibration. Hard brushing materials are therefore desirable not only for their increased cutting capacity but also for the relatively low damping capacity which is generally associated therewith.

In accordance with my invention, I employ brush bristle material having a Knoop hardness in excess of 600; and preferably in excess of 700 or even 800. Strands of materials such as the following are available having the requisite degree of hardness:

Hard steel wire (severe quench and a minimum draw back) Glass fiber Beryllium cooper wire Stainless steel wire Z nickel wire (hard drawn, heat treated, relatively pure nickel) The last two materials listed have somewhat greater damping capacity than the others. It is interesting to note that an ordinary brush employing stainles steel wire was observed to have about one-third the life expectancy of a brushing tool employing the same wire but constructed in accordance with my invention. The resilient plastic takes over much of the damping function and literally saves the life of the brush material.

It should be appreciated that most wire, including steel wire, as well as most glass fiber commercially available has a degree of hardness substantially below Knoop 600. The techniques are, however, well known for the production of such wire and glass fiber having a hardness of the order specified.

The Knoop hardness of fine metal wire filaments, glass fibers and the like may be determined by means of -apparatus known as the Knoop indenter which has been developed at the National Bureau of Standards and is now commercially available. The specification for Knoop indenters is set forth in detail in circular letter LC 819 of 7 the National Bureau of Standards, United States Department of Commerce, dated April 1, 1946. The Knoop indenter is also described in US. Patent No. 2,091,995, and such indenter meeting the specifications of the National Bureau of Standards is manufactured and sold by Wilson Mechanical Instrument Company, Inc., an associate company of American Chain & Cable Company, Inc., 230 Park Avenue, New York 17, New York. The relative hardness of different materials may be compared on a Knoop hardness scale in which the Knoop hardness number is expressed by the formula li-L AP l C'p where I =Knoop hardness number L=Load (in kilograms) applied to indenter Ap=Unrecovered projected area of indentation (in square mm.) I=Measured length of long diagonal of the indentation (in mm.) Cp=Constant relating l to the projected area In making the Knoop hardness test, it is standard practice to make a number of measurements and to take the average of the results obtained inasmuch as the hardness of some materials tested (e.g. steel) is not entirely uniform throughout. When materials such as steel wire used for brush bristle material are selected of increasing Knoop hardness, they become more and more brittle and susceptible to fracture whereas, as materials of lower Knoop hardness are selected, they become increasingly tough.

The degree of hardness obtainable will, of course, vary with the material employed. Thus glass fiber is available which is considerably harder than most harder grades of steel wire, and the latter may be had harder than stainless steel, for example. It is a general characteristic, however, that as hardness increases so does brittleness and notch sensitivity and the more important becomes the provision of my resilient, high damping capacity material in association therewith. With my modified construction I have employed stranded brush materials having a Knoop hardness in the 800 to 900 range with very great success.

In the case of steel wire, wire having a tensile strength of at least 300,000 p.s.i. attained by tempering (rather than by drawing) will ordinarily be in the upper range of Knoop hardness (and scratch hardness) which places it in the category of especially hard materials which I am now enabled to employ with superior results.

The Plastic The plastics employed should ordinarily be able to withstand reasonably high operating temperatures without softening or smearing the work. Examples include:

Rubber (if operating temperatures not too high) Neoprene (polychloroprene) Hycar (modified copolymers of butadiene and acrylonitrile) Nylon (polyamide resins) Vinyl plastics (vinyl polymers and copolymers) Melamine resins (melamineformaldehyde reaction products) It will be understood that in employing such plastics the same will ordinarily have included therewith suitable fillers as well as the usual vulcanizing agents or the like to produce the resilient plastic composition for my purpose.

The brush bristles will, of course, reinforce the plastic matrix to some extent and in all cases the plastic material must be strong enough to resist the outward pull of centrifugal force at operating speeds and should not break out in large pieces. It will be sufficiently resilient to prevent permanent deformation in use and should have a relatively high damping capacity. It is furthermore generally desirable that the plastic material be able to withstand a certain amount of contact with oil and grease.

When employing wire brush material, plastic compounds such as those having a neoprene base may have their bond to such brush material improved by first applying a cement C (FIG. 13) to the material, such cement preferably comprising a synthetic rubber and resin composition such as is commercially available under the name of Ty- Ply-S (Vanderbilt). The cement may be applied by spraying, dipping, or painting the previously thoroughly cleaned brush material. The brush should then be properly dried before intruding the plastic matrix material.

Fillers The plastic which is employed to embed the brush material substantially completely therein should not be so resistant to abrasion and wear that the ends of the brush bristles will not protrude therefrom. Thus, ordinary tire tread rubber containing certain selected carbon blacks is not suitable for my purpose as it is very resistant to abrasion and will not crumble or wear back at a rate appreciably greater than that of bristle material embedded therein. A bufling action is therefore obtained rather than the brushing or cutting action it is an object of my invention to provide. Moreover, it tends to smear the work.

To produce a tool of the type such as that illustrated in FIGS. 2 and 3 and described above, for example, I may first incorporate a selected filler in the plastic material so that such material, while still quite resilient, will be less abrasion resistant and will wear or crumble away in use at a rate slightly faster than the ends of the bristles wear back. The working face of the tool will therefore always consist of very short (in some cases on the order of V of an inch long) bristles projecting from the resilient plastic matrix. Such construction affords entirely novel characteristics in use, particularly fast cutting action coupled with a relatively smooth finish on the work-piece. It furthermore makes possible the use of brush material otherwise too brittle and makes such use advantageous. As extremely short bits fracture from the ends, such material constantly sharpens itself.

Typical examples of such suitable fillers include:

Finely crushed stone, such as limestone Asbestine powder (asbestos gangue) Kaolins Clays, such as bentonite Whiting Various mixtures of the above Rubber and the various synthetic plastics which may be employed are commonly combined with several other ingredients, including fillers, in a manner well known in the art. In fact, the final plastic material may comprise a composition of which only about one-fifth is constituted by the original pure plastic, such as neoprene, for example. The degree of abrasion resistance of such final plastic material relative to that of the brush material may be controlled and modified as necessary by employment of the proper proportion of filler-s. When cured, such final plastic material should display at least some degree of resilience and should neither be hard (like hard rubber) nor overly tough and abrasion resistant (like tire tread rubber).

I prefer to employ fillers which are themselves mildly abrasive and therefore afford a cleansing action on the work. Such fillers should ordinarily be relatively free from iron oxide and the like and without tendency to smudge the work so that there will not be deposition of fine corrosion promoting particles thereon. They may also desirably display an ability to absorb certain lubricants which assist in preventing smudging of the work (see below). Abrasives It is often desired to apply abrasive to a work-piece in addition to the cutting or polishing action which may be produced by the brush material. In fact, brushes are often employed primarily as a means of applying powdered abrasive.

Wire brush material would be an excellent applicator of such powdered or granular abrasive except for the difficulty in inducing it to hold the same, evenwhen the abrasive is supplied in the form of a paste to assist it in adhering to the wire strands. By incorporating the abrasive in the plastic employed in the short trim brushing tool above described, such abrasive is continuously supplied to the working face of the tool as the plastic crumbles away.

Typical examples of suitable abrasives for use in accordance with my invention include:

Aluminum oxide (Alundum, Aloxite) Silicon carbide (Carborundum, Corundum) Chrome oxide Natural abrasives (e.g. pumice, emery) Mixtures of the above The employment of abrasive in the plastic may further increase the heat generated by the tool in use. Some plastics, when heated sufiiciently, tend to smudge the work but I have found that inclusion of the above-mentioned fillers greatly reduces such tendency, the filler having a lubricating effect on the freshly cut surface of the work-piece, preventing adherence of the plastic. Small amounts of special lubricants such as paralfin wax, sulphonated oils, and cerotic acid (synthetic beeswax) may also be incorporated in the plastic to enhance such lubricating smudge-preventing effect. A preferred method of incorporating such lubricant is to treat the filler therewith before adding the latter to the plastic compound. Certain of the clays, such as bentonite, are especially satisfactory for such purpose.

Three specific examples of plastic compositions employed in the production of this type of tool follow:

Parts Hycar V 100 Filler (Whiting) 400 Rubber sub. 50 Softener 30 Sulphur 3 Altox 1 Thionex .l Zinc oxide 5 Stearic 1 Parts Neoprene 100 Filler (Whiting) 400 Rubber sub. 50 Softener 30 Zinc oxide 5 Stearic 1 Magnesium oxide 5 III Parts Neoprene 100 ZnO 5 MgO 5 Anti-oxidant 2 Rubber sub. 2 50 Softener 3 30 Stearic acid 1 Filler:

Limestone 250 Clay 100 lBoth Hycar and neoprene are synthetic rubberlike mate It will be noted that a great deal more filler'is employed in these examples than in the example of facing composition given above. In fact, the amount of filler may comprise three or four times the amount of pure plastic, and even more.

Annular rotary brush sections having hard, low damping capacity steel wire brush material with a high tensile strength of over 350,000 p.s.i. were placed in molds and the above plastic compositions intruded into such material. After curing, the resultant rotary tools were tested and showed notable effectiveness in such fields as burr removal, flash removal, and removal of oxide coatings from metal surfaces. A finish was left far superior to that obtainable with conventional grinding wheels applied by similar offhand methods. It was found that such tools would remove steel burrs in approximately five seconds time which required forty-five minutes to remove with the standard brush commercially available best suited for such purpose.

Not only are the more abrasion resistant plastic compositions such as tire tread rubber unsuitable for my purpose but, equally, the very soft plastic compositions such as soft rubber are entirely unsuitable. I have found (through observation of the rapidly rotating tool by means of a Strobotach) that with my hard, relatively brittle brush bristle materials it is essential to limit the amplitude of each bristle under impact with the work in use to less than one-third of the normal unimpeded free movement of the bristle in the absence of the restraining plastic matrix. Such plastic matrix must, however, be capable of yielding resiliently under normal operating conditions to an extent affording an amplitude of deflection of each bristle end portion at the point where it emerges from the supporting matrix at least equal to the diameter of the bristle. The resistance of a body of resilient plastic material may be measured by means of a durometer in accordance with ASTM standard D-676-49T (promulgated in 1942). Such durometers are available from Shore Instrument Manufacturing Company of Jamaica, New York, and also from other makers, and utilize a scale reading from 0 to durometer hardness Type D. On such scale the durometer gives a reading of 100 on plate glass and a reading of 0 upon penetration of A of 1 inch or more into the material being tested. Soft rubber and sponge rubber both read 0 when tested by the durometer.

I have found that the resilient plastic materials suitable for my purpose should give a reading of between 5 to 40 durometer hardness Type D, and preferably between 10 and 30. A durometer hardness reading of 20 will be preferred for a great many embodiments of the invention.

Not only must the resilient supporting plastic matrix have a durometer reading within the range indicated above properly resiliently to support my hard brittle brush bristles, but also such plastic material must be selected or prepared (ordinarily by compounding with suitable fillers as indicated above) to be appreciably less abrasion resistant than the bristle material. This is, of course, a relative matter in the sense that as the degree of abrasion resistance of the bristle material is changed, the degree of abrasion resistance of the supporting plastic matrix may likewise be changed, it only being important that the abrasion resistance of the plastic always be ap preciably less than that of the brush bristle. The relative abrasion resistance of the plastic and brush bristle material may be determined by any standard or convenient abrasion test, modelled for example on ASTM test D394-47, where the material being tested is pressed against a rapidly rotating abrasive disc and subjected to the action of an air blast. The rate of wear on a common abrasive surface under equal load and at the same speed should be at least twice as great for the plastic matrix as for the hard bristle material to be employed therewith, considering the rate of wear of the bristle to include progressive fracture of the extreme end of the exposed terminal portion.

By thus always employing resilient plastic material within the durometer range indicated, the flexing or deflection of the hard brush bristles will be adequately controlled by the resilient deformation of the plastic, the permitted deflection being sufiiciently great to reduce the shock of impact with the work and thereby prolong the life of the bristle and at the same time sufiiciently small to ensure that suchrapidly repeated deflections of the bristle in the region where it is secured to the support are insufficient to stress and fatigue the same to the point armature in such region.

By ensuring that the resilient plastic matrix is selected of an abrasion resistance substantially less than that of the bristles thereby to be more subject to erosion at the working face of the tool in use than'the ends of the bristles there exposed, extremely short end portions of the bi'istleswill continually project from the 'plastic matrix. Since such short, hard, outer bristle ends are brittle (although highly resistant to abrasion), they are thereby adapted to maintain sharp cutting edges by repeated. fracture at the extreme ends thereof upon impact with the Wo nu e This application is a continuation-in-part of my copending application Serial No. 50,850, filed September 23, 1948, now abandoned.

Certain subject matter disclosed but not claimed b lein is disclosed and claimed'in my visional application Serial No. 47,888, filed August 5, 19.60; Other modesfof applying the principle of the invention may be employed, change being made as regards the details described, provided the features stated in any of the following claimS Or the equivalent of such be employed. i I I therefore particularly point out and distinctly claim as inventioni A ro tary brushing tool including resiliently flexible wire brush bristles having a Knoop hardness of at least 609, the outer'working ends of'said bristles being'spaced apart; anda matrix of resilient high damping capacity 12 plastic material embedding and joining said bristles yieldingly to'hold the outer end portions of the same in such spaced apart relationship; said plastic material having a durometer reading of from 5 to 40 and being capable under normal operating conditions of yielding resiliently to a limited extent only to ensure that throughout the useful life of the brush the rapidly repeated deflections of the hard bristles are insufiicient to stress and fatigue such bristles to an extent to cause long' fracture thereof While at the same time cushioning impact with the work to prevent fracture of the protruding bristle end where it emerges from such supporting matrix; said plastic material being selected of an abrasion resistance substantially less than that of said bristles thereby to be more subject to erosion at the working face of the tool in use than the ends of said bristles there exposed so that extremely short bristle ends will continually project therefrom, said short, hard, outer bristle ends being brittle and thereby adapted to maintain sharp cutting edges by repeated fracture at the extreme ends thereof upon impact with the work in use; and a film of adhesive material coating said wire bristles and adhering said bristles to said matrix of high arnping capacity plastic material therebetween.

References Cited in the file of this patent UNITED STATES PATENTS 367,591 Bringold Aug. 2, 1887 587,048 Topp' July 27, 1897 634,617 Hansen Oct. 10, 1899 888,129 Tone May 19, 1908 927,164 Puffer July 6, 1909. 1,989,078 Brostrom Jan. 29, 1935 2,047,649 Robinson July 14, 1936 2,100,138 Heldt Nov. 23, 1937 2,129,279 Kingman Sept. 6, 1938 2,232,389 Jurkat Feb. 18, 1941 2,328,999 Radford Sept. 7, 1943 2,334,642 Moore Nov. 16, 1943 2,465,396 Peterson Mar. 29, 1949 2,648,084 Swart Aug. 11, 1953

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