US2262080A - Method of waving hair - Google Patents

Description

Nov. 11, 1941.

E. J. YVEN 2,262,080

METHOD OF WAV ING HAIR Filed Jan. 27, 1941 4 Shets-Sheet l Nov. 11, 1941.

E. J. YVEN 2,262,080

METHOD OF WAVING HAIR Filed Jan. 27, 194i 4 Sheets-Sheet 2 F'IG. l3.

Nov. 11, 1941. E. J. YVEN' METHOD OF WAVING HAIR Filed Jan. 27, 1941 4 Sheets-Sheet 3 FIG.26.

Nov. 11, 1941.

E. J. YVEN 2,262,080

METHOD OF WAVING HAIR Filed Jan. 27, 1941 4 Sheets-Sheet 4 Patented Nov. 11, 1941 2,262,080 METHOD OF WAVING HAIR Emile J. Yvon, Jackson Heights, N. Y., assignor to Clairol Incorporated, Stamford, Conn., a corporation of Connecticut Application January 27, 1941, Serial No. 376,072

8 Claims.

tus for permanent hair Waving.

Up to the present time, inpermanent hair waving methods and apparatus, be they of the Croquignole or Spiral systems, strands of hair have been tightly wound respectively from the tip towards the scalp or vice versa, in fiat or spiral coils about mandrels of fixed contour and wetted with a hair treating lotion, and enclosed within an envelope or chamber and subjected to heat developed internally or externally of the mandrel within such envelope or chamber, the shaping of the hair being efiectuated through the softening thereof by the development of heat and the reaction thereon of the treating lotion at elevated temperatures, and the subsequent hardening of the thus treated hair on cooling. In such methods the tightly wound hair, by virtue of the action of heat and the waving lotion at elevated temperatures, becomes soft or plastic and stretches, independently of and out of conformity with the mandrel, with the result that the circular or spiral coil formation in which the hair strands are wound, becomes distorted and spaced away from the mandrel upon which they are wound, and upon hardening during the cooling step, such coils do not return to the original circular or spiral contour as wound, such effect being developed whether the heat is applied interiorly or exteriorly of the Wound coils.

As one feature of the present invention, I over-. come the defects inherent in the prior art methods of waving hair by positively stretching and simultaneously maintaining under tension the wound hair throughout the softening stage and thereafter the hardening stage thereof; sothat in accordance with my invention, the treated hair assumes a desired, predetermined spiral or circular coil contour when hardened by cooling, or

otherwise.

(Cl. 132-33) This invention relates to methods and appara- Other advantages of my method of waving hair will be apparent from the following detail description of several illustrative embodiments in accordance with my invention, illustrated in the drawings and of their manner of use.

Referring to the drawings:

Figures 1 to 6 illustrate the elements incorporated and the steps applied in forming a mandrel in accordance with one embodiment of my In carrying out the present invention to impart a socalled permanent wave to a strand of hair, the strand is wound'in circular or spiral coil formation about a mandrel designed to expand during the hair softening treatment.

In my preferred practice, the strand is wound about a-mandrel charged with exothermic material which, when the exothermic material is activated to generate heat, expands peripherally by an irreversible reaction to stretch the wound strand of hair as it is being softened, the hair being thus maintained under tension throughout the softening stage and thereafter the hardening stage, which may be effectuated by cooling. or

otherwise.

invention. I

Figure 7 is an end elevation in section taken along lines l-l of Figure 6.

Figure 8 is a perspective View partly cut out showing the assembly incorporating the mandrel made in accordance with the embodiment of Figures 1 to 5.

Figures 9 and 10 are end elevations in section taken along lines 99 and l0-l0 of Figure 8 before and after the exothermic reaction takes place.

Figures 11 and 12 illustrate the elementsincorporated and the steps applied in accordance with another embodiment of my invention.

Figure 13 is an end elevation in section taken along lines l3-l3 of Figure 12.

Figures 14 and 15 are end elevations in section showing the relative positions of the elements of the mandrel of the embodiment of Figure 12 in an assembly of the character shown in Figure 8, before and after the exothermic reaction.

Figures 16 and 17 illustrate the elements incorporated and the steps applied in forminga mandrel in accordance with a still further embodiment of my invention.

Figures 18, 19 and 20 illustrate the elements incorporated and steps applied in forming one embodimentof a core for the mandrel of Figure 17.

Figures 21 and 22 illustrate the elements incorporated and the steps applied in forming another embodiment of a core for the mandrel'of Figure 18.

Figures 23 and 24 illustrate the elements incorporated and the steps applied in forming a still further embodiment of acore for the mandrel of Figure 1'7. Y

Figure 25 illustrates the elements incorporated and the steps applied in forming still another embodiment of a core for the mandrel or Figure 17. v

Figure 26 is a perspective View of a still'further embodiment of an expansible mandrel applied in my invention.

Figures 27 and 28 are end elevations in section showing the relative positions of the elements exothermic reaction.

Figures 29 to 31 illustrate the elements incorporated and the steps applied in forming a mandrel in accordance with an embodiment of my invention applicable for Spiral permanent wav- In Figures 1 to 10 of the drawings there is disclosed one of the preferred embodiments of a Croquignole structural assembly adapted for carrying out my method of permanent hair waving, the respective figures of such group serving to progressively illustrate the structural and operative functions involved. A

In constructing the envelope mandrel applied in this embodiment of my invention, I employ a rectangular blank 50 of preferably porous paper relatively flexible when wetted and, as shown in Figure 1, one face thereof carries adhesive at the edges 5l5l, along the short ends and at the spaced edge portions 52 ---52 leading for a short distance inwardly along one of the longer ends. As; shown in Figure 2, I bend the blankinwardly along spaced vertical fold lines 53 53 with the edges of the short ends thereof being positioned in abutting relationship, so that as the contacting surfaces of the blank are joined through moistening and pressure at the adhesive areas, an envelope is formed having two pockets 54 54 open only at the top, as at 55 The respective pockets 54=-54 have a width equal to the distance between the fold lines j 5353, which form the extreme ends thereof and the inner edge of the adhesive zones; the pockets -be ing laterally spaced one from the other for a distance egual to the additive width of the adjoining'adhes'ive areas defined along edges 5 l 5 l Into each of the respective pockets 5 l54 of the envelope there is applied a measured charge of exothermic material E, which upon activation with liquid simultaneously develops heat and expands as the reaction end product is being formed, and may, for example, be of the character shown in the patent to Goldifarb and Michaels, No. 2,173,683. As shown in Figures 3 and 4, the respective pockets 545e are sealed at their open ends by crimping thereon a U-shaped sealing bar 55preferably formed of rigid material such as sheet metal, said sealing element having at one end a winding key 56.

Referring to Figures 4, 5 and 6, the blank is spirally rolled about the sealing element 55 as an axis forming thereby two spaced substantially conical coiled units 51-51, each charged with exothermic material E, the opposing apices of which lead from a constricted substantially cylir'idrical uncharged section 58 defined in rolling by the adhering edges of the pockets; the conical units 5T51'be'irig contoured as to provide substantially cylindrical body portions adjacent the bases or ends 59'59. As shown in Figure 5, when the spiral winding of the charged envelope about the sealing element 55% an axis is nearly completed a porous perforated sealing closure sheet 60 is inserted between the adjacent conof the mandrel in Figure 26 before and after the although if desired the closure sheet 60 may be,

of greater length than the charged envelope beingrolled and sealing of the coiled mandrel accomplished without adhesive by bending the edges of the sheet over the bases or ends 59-59 of the formed mandrel; such sealing being a temporary expedient used only to prevent uncoiling of the mandrel prior to its use in the process and 1 does not prevent or impede the expansion of the mandrel in the operative steps of the process.

In Figures 8, 9 and 10 are shown respectively the operative assembly of the embodiment of Figures 1 to 7 as applied for permanent hair waving and sections therethrough defining the operative functions carried out thereby.

In preparing the assembly shown in Figure 8, I wet the mandrel of Figure 6 by dipping the same in a solution adapted on passing through the porous walls of the envelope to activate the exothermic material contained in the pockets 54-54; the solution at the same time serving to dissolve any adhesive used to seal the closure sheet; thereafter, I wind a strand of hair from the ends thereof towards the scalp after having first inserted a protector 62 adjacent the scalp; thereafter I apply a hair waving lotion to the coil of hair H wound on a mandrel, if such has not been previously applied; thereafter I apply c'i'rcumferentially of the wound coil of hair on the mandrel a moistened absorbent pad 63, and envelopa'llof the same as assembled above the protector in awater-proof wrapper W, the free ends of which are gripped by clamp C to form a substantially fully enclosed assembly, a detailed enlarged section of which is shown in Figure 9. By the time the steps to form the assembly aforesaid have been completed, the exothermic material in the pockets 54-54 has commenced to develop heat through chemical reaction incited by the activator and as the reaction progresses, the exothermic material expands simultaneously as it'fu'rther develops heat. The heat thus developed by the exothermic reaction heats and vaporizes the hair waving lotion applied to the hair and present in the absorbent pad 63, thus providing for the hair softening treatment. Upon the expansion of the exothermic material, the now wetted flexible walls of the mandrel enclosing the same are displaced and the mandrel, by virtue of the spiral coil formation thereof expands peripherally and outwardly and substantially evenly along its entire length except that portion thereof defined by the central constricted zone 58, in which no exothermic material is present; with the result that the coil of hair wound during the period of softening treatment is" simultaneously peripherally stretched all along its length. The stretched hair is maintained under tension during the entire heat developing exothermic reaction and during the hair hardenifi period as the mandrel is cooled, for the expansion reaction of the exothermic material being chemically non-reversible, no change in contour of the expanded mandrel or the pressure exerted thereby is developed, even on cooling.

Since'the "activating solution for the exothermic material is preferably a dilute ammonium-com poiind, any excess thereof not required in the heat developing chemical reaction of the exo thermic material becomes vaporized and such vapor as developed acts in aid of the expanding exothermic material, in expanding wetted flexible walls of the envelope winding forming" the mandrel coils; and when suificient pressureis built up during such reaction, the vapor passes through the pores of the envelope walls andinto contact with the hair being treated,.and at that time functions in aid of the then heated and vaporized hair treating lotion on the hair and in the .ab-'

sorbent pad 63 to soften the coiled hair.

Since the hair treated in accordance with this embodiment of my invention is subjected to the effect of heat,.and heated'or vaporized permanent waving lotion, all of which cause softening of the fibres of the hair, and, since while being so softened, upon being stretched and maintained under tension by the expansion of the spirally wound mandrel, the hair assumes a predetermined curled conformation'defined by the substantially circular and regular periphery of the mandrel and such conformation is maintained during the hardening and setting stage, since the mandrel on which it is wound is expanded by a non-reversible chemical reaction, imparted thereto by the expanded mandrel;

As to the portion of the hair strand wound adjacent the constricted zone 58, the same being the end of the strand and the most brittle portion thereof, will be subjected to substantially only the radiated heat developed in the mandrel and the vaporized; hair waving solution and vapor developed within the mandrel, but the stretching and tensioning thereof will be considerably less than that wound relatively flexible portion of the strand around the charge containing zones of the mandrel.

A comparison of the sectional view of Figure with that of Figure 9 discloses the expansion effects described in the operative functions above outlined.

In the arrangement shown in Figures 11 to 15, there is disclosed anembodiment incorporating the spirally coiled mandrel made in accordance with the disclosure of Figures 1 to 6, wherein the mandrel is enclosed within a thin metallic shell 65 of Figure 12 defining opposing conical receptacles formed by rolling the perforated blank 64 of Figure 11; the longitudinal edges 66 of the metal blank 64 being brought into substantial abutment to define the substantially longitudinal slit along the shell 65 from end to end. The vertical edges of the blank 64 are serrated as at 61 to provide radial segments which when bent over form end closures 6868 for the shell 65 enclosing the coiled mandrel of Figure 6, the winding key 55 of which extends through one of the end closures 68.

With reference to Figures 13 to 15, disclosing the operative steps of the embodiment involved are identical to those specified with respect to Figures 7 to 10, except that by the use of the thin metal shell 65 as the enclosure for the spirally wound exothermic material carrying envelope of Figure 6, the following advantages are attained. Since the shell defining the mandrel closure is metallic, the same provides, through its conductivity characteristics, a, more even distribution of heat developed in the envelope throughout its length, and as exothermic material therein contained expands during the progress of the heat developing reaction, the shell under the efiect of the heat of reaction and the pressure of the expanding coiledenvelope upon displacement develops a more even peripheral expansion for stretching and maintaining under tension the coiled hair wound thereon. Since the shell is both thin and resilient and the end products of the non-reversible exothermic reaction within the coiled envelope walls are relatively firm, there is no effective contraction of the shell during the cooling period which would reduce the tension imparted to the coiled hair stretched by the expansion of the mandrel and particularly the envelope and shell'thereof.

Referring to Figures 16 to 26, further modifications are shown with reference to the mandrel construction for Croquignole permanent Waving assemblies wherein each mandrel comprises an expansible shell carrying at opposite ends thereof expansible envelopes containing exothermic material.

vIn Figures 16 and 1'7 are shown respectively the shell 65 rolled from a fiat blank 64 and having along its serrated edges 61 slits 69 serving as gripping surfaces for a winder and the completed mandrel containing at opposite ends two substantially conical expansible envelopes Hl'l[l, the apices of which face each other and are spaced by an amount equal to the length of the constricted centralzone 58, the ends of which are sealed in by the bent-in serrations 61.

Referring to Figures 18 to 20, one type of conical envelope may be formed by shaping a porous paper blank "H in the form of a quarter circular segment applying adhesive along radius 12 and part of .the smaller arcuate edge 13 and bending along fold lines 14 to form the envelope of Figure 19, after filling the envelope with exothermic material E up to a point near the top of the open end 15 thereof and sealing the same by bending or crimping, the envelope is rolled about the end '14 defined by the fold line as an axis to form the spirally wound envelope shown in Figure 20.

Two such envelopes may be inserted, as shown in Figure 17, in theopposing conical receptacles of the shell 65, and sealed therein by folding over the serrated edges 61 as disclosed, the apices of the respective conical exothermic rolled envelopes being spaced from each other at the zone defined by the constricted cylindrical formation 58 of the shell.

As shown in Figures 21 and 22, I may form conical envelopes for containing the charge of exothermic material E by rolling a porous paper blank 16 cut in quarter circular segments, and having perforations H at one segment thereof, about one of its radius ends 18, as an axis to form a hollow receptacle shown in Figure 22, the edge of the rolled blank being bent inwardly to form a sealed apex 19, and after the thus formed hollow conical receptacle is filled with a requisite charge of exothermic material E, the end defining the base is sealed by bending in the edges thereof. Two such conical envelopes are inserted within the opposing conical receptacles of the shell in a manner that is disclosed in'Figure 17.

As shown in Figures 23 and 24, I may form the'conical envelope by radially creasing a cirin the conical receptacles of the shell, as shown in Figure 17.

Instead of rolling or folding a porous paper blank of respectively segmental or circular shape into a hollow conical form, as shown in Figures 21 to 24, I may, as shown in Figure 25,: form: such receptacle R by molding paper pulp particles into a hollow conical shell of porous wall conformation capable of expansion upon wetting and under pressure, the apex being integral and the open ended base being sealed by bending in the edge of the shell after charging with exothermic material.

With reference to the operative functions of an assembly incorporating conical mandrels in a shell formed as shown in Figures 16 and 17, the coiled conical mandrels of Figures 18 to 20, upon the development of the reaction of the exothermic charge upon application of the activator, expand concentrically at the coils thereof and impart a displacement causing peripheral expansion of the metallic shell containing the same in accordance with the description heretofore outlined, with relation to Figures 8 to 10 and 13 to 15, while with respect to the hollow conical mandrels, the formation of which is disclosed in the embodiments respectively of Figures 21 and 22 and 26, on the one hand, the exothermic charge upon reaction expands against the walls of the envelope, which walls being porous and resilient when wetted are displaced thereby, resulting in a peripheral displacement of the enclosing shell of Figure 17, in conjunction with the expansion of the shell upon development of heat in the exothermic charge and on the other hand, with respect to the envelope of Figures 23 and 24, as the exothermic material reacts and expands during the formation of the end product, the overlapping folds of the shell are spread, and as a result of such spreading displace the shell of Figure 17 in which they are enclosed.

In the embodiment shown in Figures 26 to 28 a modified embodiment of the shell is disclosed, wherein the same may be formed of two half sections 8484, gripped at opposite ends by spit rings 8585 to form a shell enclosure having conical receptacles or pockets spaced by constricted cylindrical zone 58 in which are carried envelopes of the character shown in Figure 6, 20, 22, 24 or 25. Upon carrying out the exothermic reaction in a Croquignole waving assembly of the character heretofore described, shown in Figure 26, both the split rings 8585 and the split shell segments 8484 expand uniformly, except that as shown in Figure 28, in conjunction with the peripheral expansion, there are longitudinal separations along the diametrically opposite abutting lines of the respective shell segments.

Referring to Figures 29 to 34, there is disclosed a further embodiment of a mandrel construction in accordance with my invention, for application to Spiral winding. In this embodiment the envelope is formed from a substantially square porous paper blank 86 carrying adhesive along edge portions 8'l-8l and alongside central fold line 88. Upon bending the blank 85 along fold line 88 and sealing the same along the adhesive areas, a rectangular envelope open at edge 89 is formed.

As shown in Figures 30 and 31, upon charging the envelope with a predetermined amount of exothermic material E and sealing the open end 89 thereof as by bending over and crimping, the envelope is rolledv or wound abou'tfoldi line.88 as arr axis to form. a coiledenvelope; there being ins'ertible between adjacent concentric coils thereof priorto the completion of winding, a' porous perforated sealing closure sheet '90, the edge of the closure sheet carrying the water soluble adhesive for sealing the coiled mandrel along its length as shown, or as an alternative, the sheet may be of such length asto provide edges extending beyond the ends of the coiled envelope which projecting edges when bent over form both an end and longitudinal seal for the mandrel.

Referring to Figures 32 and. 33, a rectangular blank 9| of thin metal having serratedv edges/92 at its vertical ends and perforated throughout its area, is rolled about the spirally coiled envelope of Figure 33, to form an'enclosure' shell therefor; the longitudinal edges 93-93 of the blank 9| being in substantial abutting. relationship to define the shell enclosure while the serrated edges 92 are bent inwardly to form an end seal.

Referring to Figures 34 to 36 in carrying. out

- the Spiral permanent waving process with the mandrel described in the above embodiments, reference will be had to the mandrel of Figure 33, although the mandrel of Figure 31 may be similarly applied. First, the mandrel is dipped in a solution for activating the exothermic material and a coil of hair is wound aboutthe mandrel from the scalp towards the free ends, as shown in Figure 34, the coiled hair I-I being hooked or tied respectively adjacent the scalp and the free ends thereof, as in normal Spiral waving practice, hair waving lotion being applied to the hair before or after the winding thereof in spiral form about the mandrel. A protector 95 disposedadjacent the scalp to: onclose' the strand of hair being treated and'an absorbent pad 96 superimposed by a water-proof wrapper 96R are applied to enclose the mandrel carrying the wound hair, the wrapper being clasped and sealed adjacent its opposite ends by elastics or strings 9'l91.

The reaction involved is substantially identical with that described heretofore in relation to the Croquignole process insofar as the stretching of the hair and the maintenance of the same under tension, by virtue of the expansion of the mandrel developed simultaneously with the development of heat in the exothermic reaction while the hair undergoes the softening treatment effectuated under heat, except that in this instance the expansion of the mandrel is equal through the length of the mandrel, for substantially all of the hair coiled about the mandrel may be safely subjected to the softening and stretching effect involved, the brittle free ends of the hair not being treated in this process. The operative functions involved in the reaction are disclosed in detail in the sectional views of Figures 35 and 36, which illustrate the conditions within the assembly before and after the exothermic reaction.

Although in all the embodiments herein shown the mandrel is in the form of. an envelope or a series of spaced envelopes carrying charges of exothermic material in powder form, it is within the province of this invention to apply the exothermic material in the form of a coating for, or as an impregnating material in, a porous or absorbent paper or like material which thereafter may be rolled in coiled form and applied directly by winding thereon the strand of hair to be treated, or disposing the same within a metallic shell about which the strand of hair is wound, to serve as a core capable of expansion as a mandrel when used directly or for displacing the shell in which it is carried, so that the latter serving as a mandrel is by it peripherally expanded, in accordance with and for the purpose of those embodiments heretofore described. Commercially, I prefer to make this expansible mandrel or mandrel core element as follows: I impregnate an absorbent paper or like sheet with calomel by soaking the same in a solution of mercurous nitrate or other soluble mercurous salt and then dip or pass the paper when substantially dry into a solution of sodium chloride or other reagent containing an ion which precipitates mercurous mercury, as for example, a bromide sulphate carbonate or the like, among the inorganic salts, or a citrate tartrate or benzoate among the organic salts, the thus impregnated absorbent paper or like material carrying a precipitated mercurous mercury salt is then cut into strips of suitable size, backed by a foil of aluminum which may be perforated or not as desired, and the thus laminated sheets may be rolled into any desired shape in accordance with the disclosures of Figures 6, 20, 22, 24 and 30.

As indicated, by applying substantially porous paper or like material to form the envelope enclosing medium or carrier for the charge of exothermic material, I am able to produce an expansible mandrel adapted for use directly or in connection with an enclosing, metallic shell in both Croquignole and Spiral winding, which not only is of light weight, formed of inexpensive materials, and readily assembled, but the same has the added advantage that it provides for a sanitary permanent hair waving process in that the mandrel, by virtue of the aforesaid qualities, is applicable as a single use unit.

By the expression intrathermal exothermic unit, as applied in this application and in reference to hair waving apparatus and methods referred to herein, is meant an interior heating device, the heat effect of which is developed by exothermic material.

This application is a continuation-in-part of my co-pending application, Serial No. 280,903, filed June 24, 1939, and entitled Hair waving apparatus and methods of making and using the same.

It is obvious that various changes and modifications may be made to the details of construction without departing from the general spirit of the invention as set forth in the appended claims.

I claim:

1. The method of waving hair, comprising winding hair about a heat generating expansible mandrel, and activating the mandrel for heating and stretching the wound hair simultaneously to impart a wave thereto.

2. The method of waving hair, comprising winding hair about an expansible mandrel carrying interiorly thereof an exothermic material,

enclosing the wound hair in a heat-confining wrapper and effecting reaction of said exothermic material to develop heat and consequent expansion of the exothermic material, and, in turn, of the mandrel, thereby heating and stretching the wound hair simultaneously to impart a wave thereto.

3. The method of waving hair, comprising winding hair about an expansible mandrel carrying interiorly thereof an exothermic material, enclosing the wound hair in a heat-confining wrapper, and effecting reaction of said exothermic material to develop heat and vapor on the one hand for consequent expansion of the exothermic material and, in turn, of the mandrel, and on the other hand, for consequent heating of the hair, thereby softening and stretching the wound hair simultaneously to impart a Wave thereto.

4. The method of Waving hair, comprising winding hair about an expansible mandrel carrying interiorly thereof an exothermic material, enclosing the wound hair in a heat-confining wrapper, and effecting reaction of said exothermic material to develop heat and vapor on the one hand for consequent expansion of the exothermic material and, in turn, of the mandrel, and on the other hand, for consequent heating of the hair, thereby softening and stretching the wound hair simultaneously, and thereafter maintaining the thus treated hair under tension until it hardens in a defined wave contour.

5. The method of waving hair comprising winding hair about a heat generating irreversibly expansible mandrel and activating the mandrel for heating and stretching the wound hair simultaneously to impart a wave thereto.

6. The method of waving hair comprising winding hair about a heat generating irreversibly expansible mandrel and activating the mandrel to develop heat and irreversibly expand, for in turn simultaneously softening and stretching the hair, and thereafter maintaining the softened and stretched hair under tension until it hardens in a defined wave contour.

7. The method of Waving hair comprising winding hair about an expansible mandrel carrying interiorly thereof an exothermic material, and effecting reaction of said exothermic material to develop heat and consequent expansion of the exothermic material and in turn of the mandrel, thereby softening and stretching the wound hair simultaneously to impart a wave thereto. I

8. The method of waving hair comprising winding hair about a heat conducting expansible mandrel carrying interiorly thereof an irreversibly expansible exothermic material, and activating the exothermic material to develop heat and expansion of the same, and, in turn, of the mandrel, thereby simultaneously softening and stretching the wound hair, and thereafter maintaining the thus treated hair under tension until it hardens in a defined wave contour.

EMILE J. YVEN.

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