US2133620A

US2133620A - Means for making tubular insulation

Info

Publication number: US2133620A
Application number: US15265A
Authority: US
Inventors: Hans D Iscnberg
Original assignee: Individual
Current assignee: Individual
Priority date: 1935-04-08
Filing date: 1935-04-08
Publication date: 1938-10-18
Anticipated expiration: 1955-10-18

Description

Oct. 18, 1938.

I H. D. ISENBERG 2,133,620

MEANS FOR MAKING TUBULAR INSULATION Filed April 8, 1935 2 Sheets-Sheet l Q QQ oct. 18, 1938. N G 2,133,620

MEANS FOR MAKING TUBULAR INSULATION Filed April 8, 1935 2 Sheets-Sheet 2 Hazel f 66372662? /7 Patented Oct. 18, 1938 2,133,620

UNITED STATES PATENT OFFICE MEANS FOR MAKING TUBULAR INSULA- TION Hans D. Isenberg, Chicago, Ill.

Application April 8, 1935, Serial No. 15,265

3 Claims. (01. 154-25) This invention relates generally stated to a 36 feet of tubing. These conditions are of course method and to means for making tubular insulareflected in the relatively high cost of the prodtion and is particularly concerned with the prouct. duction of sleeving or tubing for electrical insu- Other disadvantages of a character that be- 5 lating purposes. comes chiefly manifest in the use of the tubing The principles which I employ in realizing my reside in the difl'iculties in the way of controlling invention may be applied for making tubing of the flexibility and determining the dielectric various materials and for numerous difierent purstrength of the product. The flexibility is very poses and, as will be shown presently, the invenlargely dependent upon the material used for tion may also be successfully used for providing making the tubing and the yp of s ce e 10 insulation of the so-ca1led push-back type diployed for its impregnation. Inasmuch as both rectly to electrical conductors in a simpler and factors in turn determine the dielectric strength, more eflicient manner than was heretofore possiit will be understood that particular y where elecble. I will presently describe and explain my intrical conditions require high dielectric strength,

vention with reference to specific embodiments this can be obtained only at the expense of the 15 but it will be understood from the foregoin reflexibility of the tubing. A further drawback that marks and from explanations which are to follow ay be noted n this connection resides in the that this is being done merely for the purpose of fact that tubing of standard or customary size can facilitating the description and not in order to be impregnate y On t Outside; the pp demonstrate any particular inherent limitations. tion of impreg material Such as lacquer 20 The following remarks concerning the prior art varnish to the walls of the passage or inside of are made in order to furnish a basis for a better the tubin is ot fe b e fo Obvious reasons. understanding of my invention. Neither is it possible to furnish a braided or The tubing in which I am primarily interested Woven tubing with even and smooth inside walls is used mostly in the electrical industry and is which would permit its application on awire with- 25 known under various names such assleeving out any trouble. The very character of the manuvarnished tubing-and is also sometimes refacturing m t o used for br d ng r weaving ferred to as-spaghetti tubing. It consists usumaterial into tubular shape results in a product ally of fibrous material which is braided or woven having rough and uneven ins de Wa s w c ha d- .30 into tubular shape and varnished, impregnated or cap the work of slipp the b ng over the otherwise treated with suitable insulating lacquer wire. This drawback is particularly serious in the or the like according to the purpose for which the case of mass production requiring mass assembly tubing is intended. It may be furnished cut to of electrical apparatus such as radio sets and the size in any suitable and normal length, or stored like where a great many conductors must be pro- 5 on drums and cut to size at the place Where it is vided with insulating tubing 0r sleeving. The

ultimately put to use. Tubing of this type is used case of providing the previously intimated pushfor insulating electrical conductors in a great back type of insulation on electrical conductors many apparatus assemblies, e. g., in the case of may also be briefly considered. The termtransformers or radio sets and the like. It is push-backdenotes a type of insulation which simply cut to the desired size and slipped and is applied on a conductor in such a manner that 40 pushed into place over the corresponding conit can be pushed back from the end of a piece of ductor or conductors. wire without any diiliculties, thus exposing the The manufacturing drawbacks arising in the wire for connection to its proper terminal or case of the customary braided and/ or woven tubpoint of attachment and eliminating the Skinning i5 ing or sleeving of this type reside in the relatively operations which would otherwise be necessary. expensive machinery required for its production The insulation on such a wire is usually applied and in the relatively small output that can be ac by means of special braiding machines and the complished with existing methods. Among other inherent nature of the manufacturing process things, a core is required around which the mausually involved renders a rather expensive prodterial is woven or braided and this core must be uct. As I have stated previously, my invention is 50 manually removed from the finished tubing. It also adapted to be used for producing this pushmay be mentioned at this point that certain maback type of insulation in a simpler and less chinery used at the present time for producing expensive manner than was possible in the past. tubing of about 0.059 inch inside diameter is Briefly stated, instead of braiding or weaving adapted to furnish per hour only approximately the material to form the tubing or the insulation, 55

'rying out the process.

respectively, I pull suitable insulating material such as cambric in tape form through one or through a series of folding and forming dies or gauges, whereby the tape material is progressively folded and rotated from one or from both sides of the tape to form the desired tubing or the insulation on a wire. In the case of tubing, a mandrel is used for determining the diameter of the tube opening; in the case of insulating a conductor, the conductor wire itself functions in the manner of a mandrel. Binding material may be applied and the material of the tubing may be impregnated during the production process. There are no rotating parts as such, but the folding and forming dies or gauges through which the tape material is progressively pulled or advanced, cause rotation of the material intermediate of the first and the last die or gauge. The seam in the resulting tubing extends substantially parallel to the axis of the tubing. Single or multiple layer tubing and/or insulation can be produced if desired. The production speed will depend upon the tensile strength of the material and can be controlled in the case of multiple layer tubing or insulation by the number of layers into which the tape material is rolled, folded or rotated. I am enabled by this process to increase the speed of production many times as compared with the customary methods. In certain instances I am enabled to increase the speed one hundred times. Whereas only about thirty-six feet of tubing of a certain type and size could be produced in one hour with old methods, I can produce about thirty-six hundred feet of tubing of substantially the same type.

Some of the important objects and features of my invention may be separately listed as follows:

One object is concerned with furnishing a new method and novel means for producing tub-ing,

generally, and specifically insulating tubing of the character mentioned above and to do this in a simpler and more efiicient manner than was possible in the past. 7

Another object resides in eliminating during the production process the core formerly used for making tubing.

A further object is realized by the provision of a process and means for producing tubing wherein the flexibility'and the dielectric strength of the product can be definitely controlled and determined.

Another object has to do with the production of tubing having smooth and even inside walls.

Still another object is realized by a tube forming process and means whereby the'speed of production depends primarily and in most instances fully on the tensile strength of the material.

. Other objects which will be brought out as the description progresses refer to the elimination of rotating parts at present required in tube producing machinery and also to various other features, for example to means for applying varnish or suitable impregnating material in such a manner that it will appear on the inside as well as on the outside walls of the finished article, and means for simplifying the application of adhesive substance during the production process. These and other objects and features not specifically men tioned above will presently appear.

It will be clear from the foregoing that it is also an object of my invention to furnish a novel process for manufacturing tubing and the like as well as new and improved machinery for car- The product obtained by my new process and machinery is also new inasmuch as I furnish a tubing having smooth and substantially even inside walls and inasmuch as I am enabled to produce tubing which is varnished inside as well as outside. The fact that I am also able to determine and to control the dielectric strength as well as the flexibility of the product may be listed as an additional advantage.

The invention is illustrated diagrammatically in the accompanying drawings, in which:

Fig. 1 represents a schematic view of one embodiment of the machine and its salient parts illustrating the new method and itsapplication in practice;

Fig. 2 is a diagrammatic view along the line 2-2 of Fig. 1, showing on a larger scale the first forming or folding die or gauge and its function;

Figs. 3 and 4 are diagrammatic views along lines 33 and 4-4, respectively of Fig. 1, illustrating the successive forming or folding dies and their functions;

Figs. 5 to 12, inclusive, are diagrammatic views of successive forming or folding dies or gauges and their functions according to another embodiment of my invention.

superfluous structural matter which follows logically as a result of my teaching and which can be understood by those skilled in the art without any specific description is not being shown in the drawings in order to simplify the explanations and to facilitate understanding.

Referring now particularly to Figs. 1-4, inclusive, numeral H indicates a suitable bench or base having an elongated slot or channel l2 in which may be mounted the forming or folding dies such as l3, l4 and I5. Each die may be provided with a laterally extending flange such as indicated at l6, l1 and I8, respectively, and with an extension such as I9, 20 and 21 projecting into the channel l2 on the bench, and each .die may be secured in its proper place by suitable means such as the nuts 22, 23 and 24, respectively, engaging the corresponding threaded

studs

25, 26 and 2'5, each of which is a part of the corresponding dies l3, M or IE. t is thus possible to place each die or gauge on the bench and to determine the distance between the dies. Any given gang or set of dies will shape and fold tape material advanced or pulled therethrough in a predetermined manner yet to be described. The type and dimensions of the tape material which is to be formed into tubing or into insulation, respectively, will determine the proper distance between the dies which is most suitable for a speedy operation. Figs. 14 illustrate the manner of forming tubing, and the description furnished below is therefore principally concerned with this problem.

The gauge or die designated by numeral I3 is provided with a mandrel 28 (shown in Fig. 1 in to the function intended for it so as to meet any given requirement. A larger or a smaller mandrel may be used in place of mandrel 23 if called for, by the structure and nature of the tubing which is tobe produced.

The tape material may be taken from a drum 3!! suitably mounted at 3|. It may consist of any desired material such as treated-or untreated cambric or paper or the like. In the case of insulating tubing, cambric will be ordinarily the preferred material.

Let us now briefly examine the structure of the various dies before explaining their individual function, keeping in mind that it is the purpose of the apparatus to furnish means whereby a suitable tape material can be advanced or pulled successively and quickly through a series of dies, in a straight line, and emerge in the form of a tubing the same of which extends substantially parallel with the axis of the tubing, and also remembering that there should not be any rotating parts for accomplishing this purpose. However, if the tubing is to be produced from flat tape material it will be apparent that either one or both edges, or rather to say, sides of the tape material must be rolled or rotated so as to fold correctly toward the center and to form the tubing. This rotation of the tape takes place between the first and the final shaping die and is determined and controlled by all of the dies. Each die has its specific purpose, namely, the purpose of progressively rolling the tape material toward and around the mandrel (or, in the case of producing insulation on a wire, toward and around the wire).

As shown particularly in Fig. 2, the first die or gauge I3 is provided with a folding channel 35 which forms substantially an inverted U. The mandrel 28 extends from the die I3 in the direction of and through the successive dies as indicated in Fig. 1. The second die or gauge l4, as shown in Fig. 3, is provided with a guide skirt 36 adapted to guide the tape material circumferentially. The forming channel 31 has a different form, that is, one leg of the U-shaped channel, as shown in Fig. 3, has been eliminated in the case of the second die I and coiled toward the periphery of mandrel 28. The third die I5, as illustrated in Fig. 4, also carries a guide skirt 38 which is adapted to guide and to fold the tape from both sides toward the forming channel 39 which is closed around the mandrel 28. Ex-

pressed in other Words, the other left hand leg of the U-shaped channel shown in Fig. 2 has been coiled toward the center, that is, toward the periphery of mandrel 28.

Any suitable and necessary number of such forming and folding dies may be arranged on the bench H properly spaced from one another and performing the tube shaping operations. These are in detail as follows:

The tape material 40 is taken from the storage drum 3!) and the end is inserted into the U-shaped channel 35 of die l3 and then progressively into the channels 31 and 39 of dies l4 and I5 respectively. The tape will then emerge from the die l5 in tubular form, as indicated at 4|. Both sides of the tape are coiled around the mandrel 28 forming a tubing which is in this case composed of two layers. Devices such as indicated in dotted lines at 42 and 60, respectively, may be provided between the dies l3 and I4 and I4 and IS in order to feed adhesive to the tape so as to glue the folded layers in place. Either one or both devices may be used. If desired, the last shaping gauge or die l5 may be provided with a heating device generally indicated at 45 in order to accelerate the drying process. It is understood that I have shown an electrical heating means combined with the die l5 merely for convenience of description. It may be secured separately and independent of any die and any suitable heating device may be employed.

The automatic operation can now begin by suitably fastening the tubing end 4! to a device which exerts a substantially straight line pull in the direction of the arrow shown at the right end of Fig. 1. This device may be a drum such as the drum 30, Fig. 1, supplied with means for rotating it at the proper speed, and functioning as a takeup drum for the finished tubing.

The finished tubing which emerges progressively and continuously from the die l5 may be wound on a suitable storage drum. It will be apparent that the dies fold the tape to assume the shape indicated progressively in Figs. 2, 3 and 4 merely in response to a straight line pull. The rotation of the edges of the tape toward the mandrel 28, and, where multiple layers are desired, around the mandrel, 28, takes place intermediate of the dies. The speed of production, that is, the speed with which the tape can be pulled through the forming dies depends upon the tensile strength of the tape material at the point of emergence from the final forming die, in the present case, die l5. The tensile strength of the tubing having two layers is naturally approximately twice the tensile strength of the raw material in tape form. Therefore, in this particular instance the speed of production can actually be increased beyond the speed determined by the normal tensile strength of the material. The tubing thus produced may be wound flat on storage drums and can be used for sleeving to insulate wires.

If it is desired to produce impregnated varnished tubing, this can be done by providing-one or more impregnating devices generally indicated at 46 through which the finished tubing is drawn in the process of continuous production. Again, as in the former case, the varnished or impregnated insulating tubing may be stored on suitable drums or cut to size and suitably packaged. A suitable cutting device may be placed at the right of the apparatus shown in Fig. 1 so as to combine the cutting with the general production process.

Certain cases may call for a tubing which is varnished inside as Well as outside. can be produced by placing a suitable impregnation feeding device 4! between the storage drum 30 and the first forming die 13 and drawing the tape material through it. An outwardly flaring curved guide skirt 48 may extend from the die I3 as shown in Fig. 1 so as to facilitate the initial insertion of the tape and its feeding into the channel 35 of die I3.

The devices for supplying adhesive and in. pregnating media, varnish, etc. form as such no part of the invention. Any suitable device may be employed in each instance. The same is generally true of the heating device 45. If occasion demands, these means may also be placed differently than I have shown. It is understood, of course, that the use of these devices in combination with the different features and objects of my invention includes novel forms, products and novel results and wherever this is the such use constitutes part of my invention and teaching.

The invention thus far described may be briefly summed up by stating that it consists in a process and means for producing tubing comprising the requisite devices adapted to perform the steps of first folding or pro-shaping both edges of a tape material into a generally U- shaped form, then folding or rolling one leg of the resulting structure peripherally on a station- Such tubing ary mandrel and then folding or rolling the other leg of the pre-shaped structure against or around the mandrel to form the tubing, the preshaping and subsequent rolling and folding of the tape being accomplished by separate stationary dies or gauges which are adjustably arranged on a suitable foundation or base and through which the mandrel extends, and the feeding of the tape material though the dies being accomplished by automatically pulling or advancing the resulting tubing in a straight line, thus continuously feeding tape material from the other end of the device into the dies, together with means for applying adhesive or suitable impregnating or protecting media to the tape or to the resulting tubing, and means for applying heat at any desired point of the production process for accelerating the drying and solidifying of fiuid media applied.

Some of the advantages resulting from my invention are listed as follows: The choice of material in web form, e. g., suitable cambric and the like permits determining the flexibility of the tubing and its dielectric strength due to the uniformity of the material that can be achieved and due to the continuity of treatment that is applied. The production is speedier than in any process now known. There is no need for using a core in producing the tubing and the labor for removing the core from the finished product is therefore eliminated. The machine and its parts are extremely simple. Any suitable material may be employed for making the tubing. The process is not strictly limited to the production of insulating tubing. The ease with which adhesive or liquid or semi-liquid impregnating or insulating media can be applied at any point of the production process tends to enhance the utility of the invention considerably.

The above described method may be modified by employing a series of folding and forming devices or dies constructed so as to roll the tape material from one side progressively around a mandrel in order to produce a multiple layer tubing. The different successive steps in such modified application of the invention are illustrated in Figs. 5 to 12, inclusive, showing transverse diagrammatic views ofthe requisite dies or suc cessive folding steps.

In Fig. 5 numeral 59 designates a die in which is disposed a channel for taking the tape material 5!. It will be observed that only the upper edge of the tape material is at this instant connected with a suitable mandrel (not shown) whereas the remainder of the tape extends straight downwardly. In Fig.6 the downwardly extending end 52 of the tape 5i has been rotated slightly to the right. This operation may be performed by a separate die 53. In Fig. 7 a die 54 is provided with a channel forcing the edge 52 of the tape 5| in an upward direction as shown. In Fig. 8 the die 55 is provided with a channel forcing the edge 52 of the tape still further around the mandrel and almost completing the first layer of the tape around the same. In Fig. 9 the tape is shown advanced through an additional die 56 continuing the rotation of the side 52 of the tape 5| to coil the tape a second time around the mandrel. Fig. 10 shows the die 57 and a further step according to which the side 52 of the tape 5| is coiled around the mandrel. The second layer is almost completed in this figure. In Fig. 11 the forming die 58 is provided with a progressively curved channel as shown so as to force the side 52 of the tape material 5| to form the third layer of the tube structure; and Fig. 12 shows the final step which is accomplished in the last forming die 59. The edge 52 of the tape 5| is coiled completely around the mandrel and the multiple layer tubing is finished. At any point intermediate of these steps of the process,

adhesive or impregnating or insulating material may be applied to the tape or to the tubing as previously described.

Either the first or the second described method of successively rolling or rotating first one side and then the other side of a tape material over a suitable mandrel (Figs. 14) or of progressively rolling and folding only one side of the tape material over a mandrel to form a multiple layer tubing (Figs. 5-12) may be employed for insulating electrical conductors to form the previously mentioned push-back type of insulation. It is merely necessary to eliminate the mandrel 28 shown in Fig. 1 and to feed or advance the conductor into and through the shaping and folding dies simultaneously with the tape material, a straight line pull being applied to both. The tape will then be rotated and rolled or folded around the wire and the insulated wire will emerge from. the final die instead of tubing. Impregnation and the like may also be applied if desired or necessary. Adhesive may be employed at any step in the process as previously described.

Changes may be devised in order to meet any given condition, but it is expressly understood that all such changes are to be considered Within the scope of my invention which meet the terms of the appended claims.

I claim:

1. A device for producing tubing and particularly insulating tubing comprising, a support, a plurality of stationary forming dies adjustably secured on said support in a straight row and in predetermined spaced relation to each other, a mandrel extending from said first die through the successive dies into the last die in said row, means for supporting a supply of tape material at one end of said row of dies, said tape material extending through said dies, means at the other end of said row of dies for continuously moving said material through saidstationary dies whereby said material is circumferentially rolled around said mandrel to form said tubing, and means for applying adhesive to said material during the folding thereof, said stationary dies being arranged to roll only one side of said continuously moving tape material progressively around said mandrel to form said tubing.

2. A device for producing tubing and particularly insulating tubing comprising, a support, a plurality of stationary forming dies adjustably secured on said support in'a straight row and in predetermined spaced relation to each other, a mandrel extending from said first die through the successive dies into the last die in said row, means for supporting a supply of tape material at one end of said row of dies, said tape material extending through said dies, means at the other end of said row of dies for continuously moving said material through said stationary dies whereby said material is circumferentially rolled around said mandrel to form said tubing, and means for applying'adhesive to said material during the folding thereof, said stationary dies being arranged to roll both sides of said continuously moving tape material progressively around said mandrel to form said tubing.

3. A device for producing tubing and particularly insulating tubing comprising, a support, a plurality of stationary forming dies adjustably secured on said support in a straight row and in predetermined spaced relation to each other, a mandrel extending from said first die through the successive dies into the last die in said row, means for supporting a supply of tape material at one end of said row of dies, said tape material extending through said dies, means at the other end of said row of dies for continuously moving said material through said stationary dies whereby said material is circumferentially rolled around said mandrel to form said tubing, means for applying adhesive to said material during the rolling thereof, and means disposed posteriorly of the last die in said row for continuously impregnating said tubing.

HANS D. ISENBERG.