US1893262A

US1893262A - Reenforced electrical coil

Info

Publication number: US1893262A
Application number: US496847A
Authority: US
Inventors: Herbert F Apple; Edward M Apple; Darroch Gourley
Original assignee: Individual
Current assignee: Individual
Priority date: 1930-11-20
Filing date: 1930-11-20
Publication date: 1933-01-03
Anticipated expiration: 1950-01-03

Description

V. G. APPLE REENFORCED ELEcTRicAL cUIL Filed Nov. 20, 1930 Z/ZIV/? Jan. 3, 1933..

m1 VEN-TOR Jar/V4 Fl G. 8

Patented Jan. 3, 1933 UNITED STATES PATENT OFFICE.

VINCENT G. APPLE, OF DAYTON, OHIO; HERBERT F. APPLE, EDWARD I. APPLE, AND.

GOURLEY DABROCH, EXECUTORS'OF SAID VINCENT G. APPLE, DECEASED anemones]: ELECTRICAL con.

Application filed November 20, 1830. Serial 10.498347.

This invention relates to electrical coils and has special reference to coils comprising Another ob ect is to provide a coil which is unusually accurate as to shape and size.

' Another object is to provide a coil having improved means for securing flexible terminals to the ends of the turns whereby less failures of the joints so made may occur.

Another object is to provide means and formulate a procedure for practicing the invention with minimum loss of labor or material.

I attain these objects by the structure, method and tools disclosed in thefollowing description, said description being facilitated by reference to the drawing, wherein,

Fig. 1 is an axial section through a winding spool as it appears when ready .to have a coil wound upon it.

Fig. 2 is a special washer which is part of the winding spool shown in Fig. 1. I

- Fig. 3 shows the spool with the winding in place.

Fig. 4 shows the spool after the several finishing turns have been wound.

Fi 5 is a spring ring used for accurately forming the outside of the coil.

Fig. 6 is a tool used to apply the shown in Fig. 5 to the coil.

Fi 7 is a spacing fork used to determine the t ickness of the coil.

Fi 8 is an axial section through a coil ring ' and its spool when the structure is ready to be baked.

Fig. 9 shows a completed coil.

Similar numerals refer to similar parts throughout the several views.

In my copending applications Serial No. 356,586, filed Aprll 19th, 1929, Serial No. 430,864, filed February 24th, 1930 and Serial No. 455,296, filed May 24th, 1930, I disclose a procedure whereby liquid insulation is deposited in a relatively thick la or around a l I wire while the wire is uncoile then dried just enough to prevent its being pressed out from between the turns when it is being wound into coils, but not heated enough to convert it into the insoluble and infusible state until after it is wound into the coils.

This method of applying liquid insulation to the individual turns of a coil may be substantially followed in the present invention, and while there are now available a number of liquid insulating materials which have the necessary insulating qualities as well as the requisite cementing properties, and which will harden by the application of heat to an insoluble and infusible state, the insulating material selected from those available must be determined with regard to the use to which the coils are to be put, some of the insulating materials being especially resistant to one thing and some to another. V

It is well known that, of all the sheet insulating materials available, those having the highest tensile strength and which will stand the greatest physical abuse are made by thor oughly saturating a sheet of loosely woven cloth or canvas with liquid insulation and compressing it to a thinner, section and curing out the insulation. I will therefore have attained the principal objects of my invention when I have selected a proper liquid insulation,-placed a considerable layer of it around each individual turn of the coil, formed a covering of insulation-impregnated non-metallic fabric completely around the outside of the coil and, while holding it to a definite size, converted the insulation into an insoluble and infusible state in which the insulation surrounding the wires and that in the meshes of the fabric has been fused together into one continuous mass from which stranded coil terminals emer e.

In the drawing a stud 11 as a head 12,

and is threaded on the end 13 for nut 14.

Washers

16 and 17 are slidably fitted to stud 11 while a third washer 18 is held against the shoulder 19 by nut 14. Washer 18 has a shallow annular groove 21 in the. inner face. Washer -17 is shown in detail in Fig. 2- and has a shallow groove extending through the edge of the central openin 22 as at 23 thence ra ially outward in the faceof the washer as at 24. The end 26 of'the stud 11 is adapted to be held in a revolving chuck or other device, not shown, to rotate the spool when the coil is being wound.

A length of loosely woven sleeving 27 of nonemetallic fabric of a size sufiicient to fill the

grooves

24 and 23 in, washer 17 and as much .longer asis required to make enough turns around the stud 11 to, cover it,'is provided. This'sleeving is thoroughly impregnated with suitable liquid insulation, "except that portion which lies in the

grooves

24 and 23. Y The liquid insulation absorbed by thesleeving 27- is dried sufficiently to expel.

thegreater part of the solvent'so thatit may be conveniently handled. The washers 28 are cut from thick loosely woven cloth which has been heavily impregnated with the liquid insulation, the fabric compressed and dried,

' not enough to bring about the reaction which converts the insulation into an infusible solid but just enough to make it sufficiently stiff to hold its shape while the coil is being wound The spool in condition to have the 'wire wound upon it is shown in Fig. 1, but the order in which the several parts of the spool are thus assembled may preferably be 'described. To assemblethe spool as shown in Fig. 1 the end 26 is preferably held in the chuck of the winding spindle, the washer 16 put on the stud 11, a length of stranded terminal wire 29, slightly longer than the sleeving 27 is joined to the end of the insulated wire 31, the terminal Wire 29 threaded shown in through the sleeving 27, the terminal wire and sleeving through the opening 22 of washer 17, and laid in

grooves

23 and 24,'the washer 17 placed on stud 11, two washers 28 put on, and the washer 18 secured to the stud 11 b the nut 14. After assembly as- Fig. 1 the coil may be wound, care being taken that the sleeving 27 is so wound as to completely cover the stud 11 thus forming the inner layer of the coil.

The wire 31' is preferably of'copper and preferably of the kind'having a cotton or other porous covering which has beeni-mregnated and coated with liquid insulation anddriedas described in my copending applications hereinbefore referred to, and when the proper number of turns have been wound on the spool the wire 31 is cut off and a length of stranded terminal wire 32 joined to it. Another length of sleeving 33 is laced over the terminal wire 32 as shown in ig. 3. This thoroughly impregnated in the liquid insulation and dried. The sleeving 33 is of suflicient length to compose the outer layer of the coil, but before it is wound on the coil the washers 28. are preferably turned inward as at 34, Fig. 4. The outer layer of the coil is then formed of the several turns of the sleeving 33 wound' over :the inturned edges 34 of the washers 28, the end of the sleeve being preferably inserted under the last round and drawn up taut.

When a coil has been wound as shown in Fig. 4 with the inner and outer layers covered with insulation treated? fabric sleeving and the sides covered with insulation treated fabric washers the coverings are preferably compressed slightly to make them more dense and to make the coil more accurate as to size. To so compress the covering I provide the several tools shown in Figs. 5, 6 and 7.

The spring ring 36, Fig. 5 has an inner diameter equal to the outer diameter of the finished coil when the ends 37 of the ring are brought together. Half holes 38 are provided in the ends 37 to clear the sleeving 27 and 33. The width of the ring 36 is equal to the width of the space between the

washers

16 and 18, Fig. 4.

The clamp 39, Fig. 6 is made in two main parts hinged at 41. The opening 42 is equal to the outside diameter of the ring 36 when the handles 43 are still spaced apart as at 44. The spacer 46, Fig. 7 comprises a handle 47 and the forked-ends 48, the opening 49 between the forked ends being slightly larger than the stud 11.

To compress the coverings tightly up to the coil Fig. 4, the ring 36 is first sprung over the washer 18 with the sleeving 27 and 33 coming out between the ends 37 of the ring. The clamp 39 is then placed around the ring with the ends 37 of the ring corresponding to the opening 44 between handles 43. The handles 43 are pressed together until the ends 37 come together with the sleeving 27 and 33 emanating from the half holes 38. The ring 36 now closely surrounds the washer 1 7 at one edge and at the other is in alignment with the annulargroove 21. The washer 16 being loose on stud 11 is now forced by a suitable press toward the washer 18 to compress the fabric washers 28 sidewise against the coil and to enter the edge of the ring 36 in the annular groove 21. When the edge of the ring 36 has been forced to the bottom of the annular groove 21 there will be just enough space between the head 12 and the washer 16 to permit the ends 48 of the tool 46 to be inserted. After insertion of the ends 48 under the head 12 the clamp 39 may be removed and the coil remains under pressure within the enclosing spool, but While the procedure comprising reduction of the dimensions of tion the coil is baked to bring about the final reaction of the insulating material whereby the insulation between the individual turns of the wire and the insulation carried by the fabric covering is first fused together into a single mass then by further heating con verted into an insoluble and infusible state. The baking is preferably -ke t at a low heat for a considerable period 0 time inasmuch as a too rapid baking tends to generate gas within the coil and drive the insulation to the surface, but with proper regulation of the baking temperature just enough of the insulating material is brought to the outside to make the fabric covering on-the coil a smooth surface.

When reaction of the insulating material is complete the coil may be removed from the spool. This is preferably done by a series of steps comprising removing the nut 14, holding the washer 18 under the edge 51 and by pressing on the end 13 removing the washer, then by holding under the edge 52 of washer 16 again pressing on the end 13 and removing the stud 11. The ring 36 is now removed after which the sleeving covered terminal 29 is raised out of the groove 24 in washer 17 whereupon washer 17 is readily removed. The completed coil now appearsas at 53, Fi 9 where

terminal wires

29 and 32 emerge rom a fabric reenforced insulation covered coil through the

sleeving

27 and 33 respectively.

It will be seen that both my coil and the method in which it is made differs radically from the conventional methods. Coils made by conventional methods are wound on a mandrel from which they must be removed in order to impre ate them, either by dipping them in liquid insulation or by enclosing a number of them in a pressure-tight tank of the liquid and forcing the liquid into the Wound coils. When these conventional methods are employed the coils may not be thoroughly impregnated unless they were removed from the mandrel and when so removed before impregnationthe several turns must be tied or taped together to keep the coils from coming apart while they are eing impregnated and baked. Further a coil and its mandrel could not well be dipped together into a body of liquid insulation because of.

the quantity of the liquid which would completely cover the mandrel and be baked upon it, such covering requiring much time to remove, and becausethe terminal ends of the coils would be cemented so thoroughly to the malndrel as to defy removal of the terminal en s.

Coils made Dy-conventional methods then must be removed from the mandrel before impregnation, they must be tied or taped, they do not have the conductive pprtion of their several turns spaced apart by a great enough amount of the liquid insulation and they lose a considerable part of that which is gotten between the conductive portion of their turns when the coils are baked, they do not hold a definite size or shape, and they do not have adequate protection on the outside against entry of foreign matter or against physical abuse.

The coil herein shown and described has a greater amount of the insulation mass separating the conductive portion of the several turns and an impervious covering of fabric reenforced insulation entirely surrounding the turns, it is extremely accurate as to size and shape, it is wound on and completed onthe same winding spool without loss of mater181- and wlthout getting any appreciable quantlty of the cementitious insulation on the winding spool itself, and no taping or tying operation is required in the process of making;

Believing that these advantages are both new and useful,

I claim,

1. An electrical coil comprising a single continuous mass of impervious cementitious insulation, reenforcing washers of nonme tallic fabricimbedded in and secured to said coil by said mass at the ends, a coil of insulatedl spaced apart turns of conductive wire 1m edded 1n the same mass between said reenforcing washers, and sleeving of non-metallic fabric, also imbedded in and secured by saidmass, surrounding the turns of wire comprising the entire first layer and the turns of wire comprising the entire last layer of said coil, ends of said wire surrounded by ends of said sleeving extending from said mass.

, 2. The method of making an electrical coil comprising a plurality of insulatedl spaced apart turns of conductive wire with end washers of porous non-metallic fabric, all imbedded in a single continuous mass of impervious cementitious insulation, which consists of coating the wire and impregnating the washers with the insulation in liquid form, dry ing the insulation until it becomes a yielding fusible solid, winding a coil of the wire between the washers, heating the coil and washers until the-insulation between the turns of the wire and in the pores of the washers fuses into a single continuous mass, and maintainlIO ing the heat until the insulation mass is converted into a single infusible body.

3. The method of making an electrical coil comprising a plurality of insulatedly spaced insulation until it tion between the turns of the wire and in the i the inner layer of two of the reenforcing end washers pores of the washers fuses into a single continuous mass, and maintaining the pressure and heat until the insulation mass is converted into a single infusible body.

1. The method of making an electrical coil comprising aplurality of insulatedly spaced apart turns of conductive wire with reenforcing end washers of porous non-metallic fabric and with the inner and outer layer of the coil covered'with non-metallic fabric sleeving, all imbedded in and solely supported by a single continuous mass of impervious cementitious insulation, which consists of coating the wire and im regnating the end washers and sleeving wit the insulation in liquid form, drying the insulation until it becomes a yielding fusible-solid, placing a length of sleeving over the and of the wire comprising the turns of the coil, winding the coil exception of the outer layer, placing a len h of sleeving over the wire comprising the turns of the outer layer, winding the outer layer, forcing the washers and the sleeving into more in ate contact with the coil by pressure, heat: the structure while the pressure is maintained until the insulation therein fuses into a single continuous mass, and maintaining the pressure and heat until the insulation mass is converted into a single I in fusible body.

"sists of impregnating and coating the fibrous covering on the wire, the fabric end washers and the sleeving with the insulation while in a liquid state, drying the insulation until it becomes a yielding fusible solid, placing a length of sleeving over the end of the wire comprising the coil, winding the coil between two of the reenforcing end washers with the exception of the outer layer, turning the outer edges of the end washers toward each other over the coil,

turns of the inner layer of the a length of sleeving over the wire placing d Wln comprising the turns of the outer layer,

ing the outer layer over the inturned edges v of the end washers, forcing the washers and the sleeving into more intimate contactwith the coil by pressure, heating the structure while the pressure 15 maintained until the 6. An electric coil comprising a plurality of insulatedly s aced apart convolutions of electrically con uctive material wound in layers, orous non-conductive material in the spaces of porous non-conductive material compressed tightly to the inside, outside and ends of the coil, said inside and outside coverin being composed of porous sleeving surroun ing the individual turns of the entire inside and outside layers of the coil, and a single smoothly compressed mass of hardened impervious insulating cement extending through and filling the pores of the nonconductive material between adjacent convolutions and extending through and containing the non-conductive coverings.

In testimony whereof I afiix my signature.

VINCENT G. APPLE.

tween said convolutions, coverings