US3218187A

US3218187A - Coating method

Info

Publication number: US3218187A
Application number: US187514A
Authority: US
Inventors: Jr Ivan W Wade
Original assignee: Anaconda Wire and Cable Co
Current assignee: Anaconda Wire and Cable Co
Priority date: 1962-04-16
Filing date: 1962-04-16
Publication date: 1965-11-16
Anticipated expiration: 1982-11-16

Description

I. W. WADE, JR

COATING METHOD Nov. 16, 1965 Filed April 16, 1962 INVENTOR.

IVAN w. WADE, Jr. M 5 a 3,218,187 Patented Nov. 16, 1965 ice 3,218,187 COATING METHOD Ivan W. Wade, Jr., Muskegon, Mich., assignor to Anaconda Wire and Cable Company Filed Apr. 16, 1962, Ser. No. 187,514 11 Claims. (Cl. 117-43) My invention relates to the application of curable resinous coatings and particularly to the application of said coatings to narrow edges.

In the application of coatings it has always been diflicult to obtain a coating of adequate thickness on objects having both broad surfaces and narrow edges since the coatings on the edges tend to drain off much more rapidly than the coatings on the surfaces. This problem is of particular concern when efforts are made to coat aluminum and copper strip conductors with resinous coatings for the purpose of electrical insulation. Particularly where the coated materials are to be used in electrical apparatus with no additional materials interleaved between the layers in the winding it is essential that the edges of the foil should be properly insulated as well as the broad surfaces, but no satisfactory method of assuring proper edge coating is known.

I have discovered that if the edges of the strip or other object to be coated are first wetted with a compound capable of accelerating the cure of the resinous material while the broad surfaces of the object are not so treated, the coating material does not drain from the edges during the coating operation and a satisfactory layer remains on the edges as well as the broad surfaces. I have invented the method of applying a coating of resinous material to an object having at least one broad surface and at least one narrow edge comprising the steps of coating the edge with an accelerator for the resinous material while maintaining the broad surface free from accelerator, covering both the surface and the'edge with a layer of the resinous material and then hardening the material. Where the resinous material is thermocuring, the hardening step comprises heating the material to cure it.

My method is particularly adapted to resinous materials selected from the group consisting of epoxies, polyesters, urethanes, polyamides, polyimides and polyacetals, and most particularly to the epoxy resins. With regard to accelerator my method is particularly adapted to accelerators selected from the group consisting of nonylphenol, resorcinol, and triphenyl phosphite. Furthermore my method has special application to the coating of objects in the form of elongated strips such as metallic foils and particularly aluminum and copper. In a preferred method of application I feed my accelerator to a capillary applicator and wet the edge of the strip to be coated by applying the applicator to it. I then immerse the strip in a supply of the resinous material and deposit a coating on the strip and heat the strip sufiiciently to cure the resin.

A more thorough understanding of my invention may be gained by a study of the appended drawing.

In the drawing:

FIGURE 1 is a schematic representation of the process of my invention.

FIGURE -2 is an enlarged detail of a step in the process of FIGURE 1.

Referring to the figures a foil strip 11 is guided over a roller 12 from a supply source, not shown, between applicators 13, 1 4, through an enamel tank 16 metering die bars 17, curing oven 18, and guide rolls 1-9, 20, 2 1 to a take-up mechanism, not shown. Although I have shown the object to be coated as a foil strip 11 it will be appreciated that my invention is not limited thereto nor is it limited to continuous processes but may be used to coat any objects which combine a broad surface and a narrow edge. The

applicators

13, 14 are shown in greater detail in FIGURE 2 to comprise

felt wipes

22, 23. The

wipes

22, 23 project from

respective tubes

24, 25 connected to

respective tanks

26, 27 holding a supply of accelerator in solution. The

tubes

24, 25 are closed by plates 28, 29 to retain the fluid accelerator but the plates have

openings

31, 32 which fit closely to the

wipes

22, 23 and permit them to project through the plates 28, 29 to make a wiping contact with the strip 11. Although I prefer to use felt wipes which have the ability to act as wicks because of their capillary structure, other capillary wipes such as sponges may also be used and, indeed, I do not want to be limited to any particular method of application so long as a coating of accelerator is applied to the narrow edge of the objects prior to enamelling. In the drawing the

tanks

26, 27 are large enough to make it practicable to fill them by hand but it will be understood that the

tubes

24, 25 might be automatically supplied from a remote source of accelerator solution without departing from by invention. The tank 16 has a slit 33 through which the strip 11 can enter and become coated with enamel 34. The enamel 34 is relatively viscous so that it does not flow back through the opening 33 when the strip 11 is moving upward at operating speeds. Excess enamel is removed by the die bars 17 and in the oven 18 the enamel is cured so that there is no tendency for it to stick to the .rolls 19, 20, 21.

An enamel 34 for which my method is particularly adapted is an epoxy resin and the resins made by the Jones-iDabney Co. of Louisville, Ky., and known as Epi Rez 510, Epi Rez 504, and Epi Rez 507 are preferred examples and are cured by an amine agent in a known rnanner. Other curing agents are known for epoxy resins and my invention is not limited to the use of amines as curing agents. Other resinous materials can be used for the enamel 34 such as epoxies, polyesters, urethanes, polyamides, polyimides, and polyacetals. It will be understood that most of the resinous materials suitable for strip coating require the addition of curing agents and Where reference is made to resins or resinous materials in this application it includes the curing agents where they are required. The accelerator in the

tanks

26, 27 is preferably dissolved in a volatile solvent such as methyl alcohol. The dilution is suflicient to deposit the minimum quantity of accelerator that will produce the desired effect but should be sufficient to produce proper wicking in the

capillary felts

22, 23. I have found that nonylphenol, resorcinol, and triphenyl phosphite produce the desired efiect and I particularly prefer resorcinol for my accelerator. However, with regard to accelerators my method is adapted to any compound or combination which has the effect of causing rapid curing of a particular coating.

Example A 33% solution of resorcinol in methyl alcohol was applied to the edges of a foil at a distance of six inches below the enamelling tank. The foil was then coated with an enamel comprising parts by weight of epoxy resin (Epi Rez 510) and 30 parts by weight of amine curing agent (Epi Cure 81 furnished by Jones-Dabney).

The enamelled strip of the example was compared to a control strip coated under identical conditions except for the omission of the resorcinol. "Both strips were examined under a microscope and the strip of the example showed a definite increase in build-up of enamel on the edges, over the control strip. Dielectric strengths of the enamel on the edges of both strips were measured, with the results shown in Table I.

Table I The improvement in dielectric strength of strip coated in accordance with my invention is very striking as shown by Table I.

I have invented a new and useful method of applying resinous coatings for which I desire an award of Letters Patent.

I claim:

1. The method of applying a coating of thermocuring resinous material to an object having at least one broad surface and at least one narrow edge comprising the steps of first coating said edge with an accelerator for said material while maintaining said surface free from said accelerator, covering said surface and said edge with a layer of said material and heating said layer to cure said material.

2. The method of applying a coating of a resinous material selected from the group consisting of epoxies, polyesters, urethanes, polyamides, polyimides, and polyacetals to an elongated strip having at least one broad surface and at least one narrow edge comprising the steps of first coating said edge with an accelerator for said material while maintaining said surface free from said accelerator, covering said surface and said edge with a layer of said material and curing said material.

3. The method of applying a coating of epoxy resin to an elongated strip having at least one broad surface and at least one narrow edge comprising the steps of first coating said edge with an accelerator selected from the group consisting of nonylphenol, resorcinol, and triphenyl phosphite while maintaining said surface free from said accelerator, covering said surface and said edge with a layer of said resin and curing said resin.

4. The method of applying a coating of thermocuring resinous material to a metallic foil strip comprising the steps of coating at least one edge of said strip with an accelerator for said material, passing said strip through a supply of said resin said resin surrounding said strip and being in contact therewith whereby a layer of said ma: terial is deposited on said strip and heating said strip sufiiciently to cure said material.

5. The method of applying a coating of thermocuring resinous material to a metallic foil strip comprising the steps of feeding an accelerator for said material to a capillary applicator, applying said applicator to an edge of said strip thereby wetting said edge with said accelerator, immersing said strip in a supply of said material whereby a coating of said material is deposited on said strip, and heating said strip sufiiciently to cure said material.

6. The method of claim 5 wherein said material is se-' lected from the group consisting of epoxies, polyesters,

' urethanes, polyamides, polyimides and polyacetals.

7. The method of claim 5 wherein said accelerator is selected from the group consisting of nonylphenol, resorcinol, and triphenyl phosphite.

8. The method of claim 5 wherein said strip is aluminurn.

9. The method of claim 5 wherein said strip is copper.

ll). The method of claim 5 wherein said material-is epoxy resin.

1'1. The method of claim 10 wherein said material is epoxy resin and said accelerator is resorcinol.

References Iited by the Examiner UNITED STATES PATENTS 1,989,717 2/1935 Szegvar. 1,996,072 4/1935 King. 2,978,345 4/1961 Lesser 117-47 FOREIGN PATENTS 1,189,893 10/1959 France.

OTHER REFERENCES Slceist: Epoxy Resins, p. (Reinhold Pub. Corp, 1958).

RICHARD D. NEVIUS, Primary Examiner.

Claims

4. THE METHOD OF APPLYING A COATING OF THERMOCURING RESINOUS MATERIAL TO A METALLIC FOIL STRIP COMPRISING THE STEPS OF COATING AT LEAST ONE EDGE OF SAID STRIP WITH AN ACCELERATOR FOR SAID MATERIAL, PASSING SAID STRIP THROUGH A SUPPLY OF SAID RESIN SURROUNDING SAID STRIP AND BEING IN CONTACT THEREWITH WHEREBY A LAYER OF SAID MA-