US2047772A - Process of protecting underground metallic surfaces - Google Patents
Process of protecting underground metallic surfaces Download PDFInfo
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- US2047772A US2047772A US2804A US280435A US2047772A US 2047772 A US2047772 A US 2047772A US 2804 A US2804 A US 2804A US 280435 A US280435 A US 280435A US 2047772 A US2047772 A US 2047772A
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- Prior art keywords
- pitch
- mica
- composition
- coating
- enamel
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Classifications
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- C—CHEMISTRY; METALLURGY
- C09—DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
- C09D—COATING COMPOSITIONS, e.g. PAINTS, VARNISHES OR LACQUERS; FILLING PASTES; CHEMICAL PAINT OR INK REMOVERS; INKS; CORRECTING FLUIDS; WOODSTAINS; PASTES OR SOLIDS FOR COLOURING OR PRINTING; USE OF MATERIALS THEREFOR
- C09D195/00—Coating compositions based on bituminous materials, e.g. asphalt, tar, pitch
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S118/00—Coating apparatus
- Y10S118/11—Pipe and tube outside
Definitions
- This invention relates to a method of protecting metal surfaces adapted to be placed underground so that corrosion of the surface is inhibit ed, the method involving application of the mica pitch composition disclosed in my co-pending application Serial No. 475,839 filed August 16, 1930, and in application Serial No. 334,608 filed January 23, 1929, the latter application having issued as Patent No. 1,773,131 on August-19, 1930.
- one object of my invention is to provide a toughened pitch composition which will the highest temperatures encountered in use and, on the other hand, will not break or shatter at low temperatures which may times.
- Coal tar and oil tar pitches have heretofore been used for coating and surfacing but present the difliculty that if the melting point of the pitch is made sufliciently high to overcome flow when exposed to maximum summer temwhen exposed tolow temperatures, 1. e., winter temperatures.
- the surfacing and coating properties of pitch are improved by intermingling infusorial earth of kieselguhr therewith in such quantities and proportions as to render the'finished product plastic.
- Infusorial earth it has been found, clings together in. lumps and it is diflicult to homogeneously disperse it in the pitch. When dispersed it readily settles out of the pitch upon melting of the pitch-infusorial' earth mixture. Due to the physical structure of the infusorial earth, it serves merely as a filler and does not substantially increase the tensile strength, of the coating resultingfrom the application of infusorial earth-pitch mixtures to the surface to be protected. In other words, the effect of the infusorial earth on the pitch is com.- parable to the effect of a stone ag regate incorporated in concrete on the concrete, 1. e... it increases the compressive strength but does not materially increase the tensile strength of the concrete.
- mica is mixed'with pitch to produce a toughened-pitch composition.
- Mica is less expensive" than infusorial earth. does not cause foaming when mixed with pitch, remains in suspension without 5n appreciable tendency to settle out, is flaky in structure and not bleed or run at be encountered at be excessively brittle has greattensile strength so thatwhen admixed.
- the eflect that mica has of increasing the tensile strength of the coating may be considered analogous to the eifect of reinforcing steel incorporated in concrete on the concrete.
- Per unit of 5 mica in the mica pitch composition as compared with "spheroidaP fillers such as infusorial earth in earth pitch compositions, the surface of mica contacting with the pitch is far greater and hence far greater reenforcement is obtained by incor- 10 porating mica in pitch.
- the mica pitch composition contains less mica filler than the infusorial earth filler, and the mica pitch is correspondingly more fluid at any temperature above its melting point than an earth .fllled composition. It follows, therefore, be applied satisfactorily at lower temperatures. Hence, less evaporation of volatile content from thecomposition takes place. Furthermore the pitch content of 'the coating is the important protective 25 agent. 'With mica pitch compositions more pitch is present for each pound of composition or unit of thickness of coating produced thereby and, hence, the surface covered with the with pitch to form this improved composition. I
- the mica of the above mesh composition is known as No. 80 mica.
- the resultant mixture is made by admixing a major proportion of pitch with a minor proportion of mica, in the particular embodiment disclosed, 10 to 30 per cent mica.
- a pitch of sufiiciently high initial melting point to give a mixture of the desired melting point is of course used as the starting pitch.
- a pitch of lower melting point may be distilled in the usual manner to remove distillate oils until the resultant pitch is of the desired melting point and then the resultant pitch may be mixed with mica of from to mesh to form the desired mica-pitchmixture.
- mice. is used as the sole filler for the pitch.
- micapitch compositions serve to emphasize the difi'erences between mica-pitch compositions and corresponding untreated pitches:
- Example'8 involving a roofing pitch of 143 F. melting point and. having 21% mica incorporated therein
- Example 9 involving a water gas tar pitch having a melting point of F. and having 20% mica admixed therewith.
- the physical characteristics of the 'mica-pitch composition are dependent upon the particular pitch used and the amount of mica admixed therewith. Further, the preferred composition disclosed herein consists only of two ingredients, to wit, pitch and mica.
- Pipe lines are particularly subject to corrosion underground because of the electrolytic action of ground currents which cause rapid deterioration of the pipe line in the field of the electric current, particularly where the ground is moist or contains ground water, as is frequently the case over long sections of pipe lines used for transporting oil and gas, and in the case of pipe lines in cities which are necessarily adjacent sewers and water lines.
- mica-pitch composition described herein whenapplied as hereinbelow described to form a smooth, uniform coating, acts to inhibit to a remarkable degree the corrosive action of ground currents on the metal surfaces to which it is applied. I attribute this property of the composition to the insulating quality of the pitch and of the flat flakes of mica homogeneously distributed therein which form nae throughout the composition. the mica enhances the permeability to water of the coating composition, the tendency of ground currents to follow lines of moisture penetrating the composition is greatly reduced.
- This non-permeability of the mica-pitch composition to moisture and ground currents with resulting corrosive action on the pipe line, is further minimized by reason of the smooth, glossy outer surface which is a characteristic of my micar-pitch composition, which smooth outer surface does not present irregular- Further, since insulating lamitensile strength and nonities and rough spots constituting points of atapplying to such surfaces a substantially 'uniform coatin my invention.
- This to pipes or metals by dipping the pipes or metals after priming into a bath containing the micapitch mixture or by wiping or pouring the micapitch composition onto the material or article to be coated or by. any other suitable means such as spraying and the like.
- the mica-pitch composition .at temperatures below the melting point is substantially solid but upon being heated to ing point becomes freely'iluid, forming aliquid which is substantially homogeneous throughout and which I have found is admirably suited for of the mica-pitch composition of purposes of coating or enameling metal.
- the maximum temperature at which the enamel is maintained during application should not be greater than about 350 F. to about 400 F.
- the enamel By keeping the enamel within this temperature range its composition will not be radically changed, i. e., substantial evaporation of the oil content cf the pitch and substantial decomposition of the pitch content with free carbon formation will not take place.
- the enamel to be coated and bond with the primer usually employed, and a certain degree of flow of the enamel must take place be-v fore it-sets in order to permit the formation of a smooth even surface.
- a certain minimum temperature hereinabove pointed outwhen applied so that premature setting of the enamel is avoided.
- the primer for the pipe 2; bitumilllers, free flowing and con. taining .a volatile solvent which evaporates upon application of the primer to the pipe may be dissolved in a solvent, which upon application, forms a thin coating with which the mica pitch composition bonds has been found a satisfactory primer.
- the minimum temperature of the enamel during ap plication should be from about 275 F. to about of the pitch took 325 F. respectively.- while the enamel might a lower temperature than that be applied at herein indicated, for the best results the temperature should be at least about 125 F. above its melting point.
- the temperature of the mica-pitch composition be maintained not lower than that at which it will flow readily to produce a smooth, uniform coating. If to be dipped into. a bath of the enamel and then removed, the desired smooth, uniform, glossy coating in accordance with this invention is produced by the excess enamel draining from the dipped pipe. If the temperature of the enamel the pipe to be protected is not drain uniformly from the pipe but the excess enamel will set and harden on the pipe, resulting in a coating of different thicknesses in which weak spots appear.
- the enamel may hot wet the pipe no! bond with the primer usually employed and will not flow over and uniformly coat the pipe but will set on the pipe during covering the complete surface thereof.
- mica-pitch compositions applied to pipe, while maintained at a temperature falling within the range hereinabove speci fied, result in a smooth, glossy, uniform coating through which the mica particles are substantially uniformly distributed in the form of laminae.
- the thickness of the coating will depend upon the particular temperature of application of the enamel. For example, with an enamel having a melting point of about 200 F. and applied at a temperature of about 395 F., a coating approximately inch thick resulted. When the temperature of application of this enamel was lowered to 335 F. a coating approximately a; inch thick resulted.
- the melting point of the mica-pitch mixture herein given is determined by the Ring and Ball Method, A. S. T. M. Standard Method 13-36-26.
- the method of coating metallic pipes which comprises applying in heat liquefied condition a composition constituted of a major proportion of pitch and a minor proportion of finely divided mica, said composition having a melting point of 5 from about 150 F. to about 200 F., to the pipe condition at a temperature of from about 325 F.
- the pipe and then set thereon to produce a comprises applying a p tc prime to: the P 1 575 applying in heat liquefied condition a, composition constituted of from 70 to 90 per cent coal tar pitch and from 10 to 30'per cent finely divided mica, said composition having a. melting-joint of from about 150 F; to'about 200 F. to the primed pipe while the said composition is in-hea.t
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- Chemical & Material Sciences (AREA)
- Life Sciences & Earth Sciences (AREA)
- Engineering & Computer Science (AREA)
- Materials Engineering (AREA)
- Wood Science & Technology (AREA)
- Organic Chemistry (AREA)
- Paints Or Removers (AREA)
Description
peratures, the pitch will Patent ed July 14,, 1936 Process or morso'rma m smrsmc soar-sons Clarence n. Eckert,
Englewood, N. 1., assignor to The Barrett Company, New York, N. Y a corporation of New Jersey No-nrawing. Application January 21', 1935.
Serial No.
z (o1. iii- 10) This invention relates to a method of protecting metal surfaces adapted to be placed underground so that corrosion of the surface is inhibit ed, the method involving application of the mica pitch composition disclosed in my co-pending application Serial No. 475,839 filed August 16, 1930, and in application Serial No. 334,608 filed January 23, 1929, the latter application having issued as Patent No. 1,773,131 on August-19, 1930.
As disclosed in my co-pending application, one object of my invention is to provide a toughened pitch composition which will the highest temperatures encountered in use and, on the other hand, will not break or shatter at low temperatures which may times. Coal tar and oil tar pitches have heretofore been used for coating and surfacing but present the difliculty that if the melting point of the pitch is made sufliciently high to overcome flow when exposed to maximum summer temwhen exposed tolow temperatures, 1. e., winter temperatures. According to the Manhayfer Patent No. 1,112,817 of October 6,, 1914, the surfacing and coating properties of pitch are improved by intermingling infusorial earth of kieselguhr therewith in such quantities and proportions as to render the'finished product plastic. Infusorial earth, it has been found, clings together in. lumps and it is diflicult to homogeneously disperse it in the pitch. When dispersed it readily settles out of the pitch upon melting of the pitch-infusorial' earth mixture. Due to the physical structure of the infusorial earth, it serves merely as a filler and does not substantially increase the tensile strength, of the coating resultingfrom the application of infusorial earth-pitch mixtures to the surface to be protected. In other words, the effect of the infusorial earth on the pitch is com.- parable to the effect of a stone ag regate incorporated in concrete on the concrete, 1. e... it increases the compressive strength but does not materially increase the tensile strength of the concrete.
According to my invention, mica is mixed'with pitch to produce a toughened-pitch composition. Mica is less expensive" than infusorial earth. does not cause foaming when mixed with pitch, remains in suspension without 5n appreciable tendency to settle out, is flaky in structure and not bleed or run at be encountered at be excessively brittle has greattensile strength so thatwhen admixed.
with pitch it impartsbinding strength to the mixthereof at low temperatures. Due to the leaf.
like structure of mica it greatly increases the =ture and thus prevents breaking and shattering that-the mica-pitch composition can tensile strength of the resultant coating. The eflect that mica has of increasing the tensile strength of the coating may be considered analogous to the eifect of reinforcing steel incorporated in concrete on the concrete. Per unit of 5 mica in the mica pitch composition, as compared with "spheroidaP fillers such as infusorial earth in earth pitch compositions, the surface of mica contacting with the pitch is far greater and hence far greater reenforcement is obtained by incor- 10 porating mica in pitch. Due to the increased reenforcement obtained by the use of mica less mica than infusorial earth is required to produce a composition resulting in a coating of desired strength. Hence, for a given strength coating the mica pitch composition contains less mica filler than the infusorial earth filler, and the mica pitch is correspondingly more fluid at any temperature above its melting point than an earth .fllled composition. It follows, therefore, be applied satisfactorily at lower temperatures. Hence, less evaporation of volatile content from thecomposition takes place. Furthermore the pitch content of 'the coating is the important protective 25 agent. 'With mica pitch compositions more pitch is present for each pound of composition or unit of thickness of coating produced thereby and, hence, the surface covered with the with pitch to form this improved composition. I
have found that satisfactory and improved results may be obtained with a ground white mica the following mesh composition: 40
' Per cent Retained on 28 mesh 0.1 Passing 28 mesh retained on 48 mesh 13.8 Passing 48 mesh retained on mesh 11.2 Passing 60 meshretained on mesh 11.7 415 Passing 80 mesh retained on mesh"... 13.0 Passing 100 mesh retained on mesh. 10.9 Passing .150 mesh retained on 200 mesh 6.5
200 mesh... .31. 8 Loss 1 1,0 60
Tota 100:0
' The mica of the above mesh composition is known as No. 80 mica.
' corporated in pitch raises the melting point a;
ing from 10 to 30 per cent mica thereto, agitating the pitch while adding the mica. and agitating the mixture of pitch and mica. preferably by a suitable mechanical agitator or stirrer until a substantially homogeneous mixture of pitch and mipa is formed. It will be noted that the resultant mixture is made by admixing a major proportion of pitch with a minor proportion of mica, in the particular embodiment disclosed, 10 to 30 per cent mica. A pitch of sufiiciently high initial melting point to give a mixture of the desired melting point is of course used as the starting pitch. A pitch of lower melting point may be distilled in the usual manner to remove distillate oils until the resultant pitch is of the desired melting point and then the resultant pitch may be mixed with mica of from to mesh to form the desired mica-pitchmixture. I have found bestos without deleteriously affecting the surfacing and coating properties of the mixture. Preferably, however, mice. is used as the sole filler for the pitch.
The following tabulated properties of micapitch compositions serve to emphasize the difi'erences between mica-pitch compositions and corresponding untreated pitches:
It is evident from the foregoing that micainconsiderable extent, to wit, 62 in the case of example 5 involving a paving pitch having a melt ing point of It; 21'' in the case of Example 6 involving a paving pitch; 24 in the case of Exampie 7 involving a roofing pitch of the melting point of 143 1". and having 18% mice incorporatprepared by first melting the pitch and then addthat a part of the mica may be replaced by as- Melting fi Composition point pitch mixture a no use 4 71.5 a in? i? sud in Example Meltin int itch 7 Composition ga l m- 7 2 1 6 .4 mice.... }l25 I. (known as 187 F-.. )6"
78.6 9 itch..- Davin pitch). 6 18 F. own as F... m"
pitch---.- paving pitch). 7 l8 0 mice 43 F. (known as 167 F... 134'" pitch.--.- roofin pitch). 8 mioa. }l43 F. %known as 187 F... H." pitch...-- oggoiiingkgitch). 180 F u U own as a 9 sam as). W
ed therein; 44 in the case of Example'8 involving a roofing pitch of 143 F. melting point and. having 21% mica incorporated therein and 15 in the case of Example 9 involving a water gas tar pitch having a melting point of F. and having 20% mica admixed therewith. It will be noted that the physical characteristics of the 'mica-pitch composition are dependent upon the particular pitch used and the amount of mica admixed therewith. Further, the preferred composition disclosed herein consists only of two ingredients, to wit, pitch and mica.
' As disclosed in my co-pending application,
the mica-pitch mixtures described herein have been found particularly valuable as a coating medium for pipe lines and metals generally to prevent corrosion. Pipe lines are particularly subject to corrosion underground because of the electrolytic action of ground currents which cause rapid deterioration of the pipe line in the field of the electric current, particularly where the ground is moist or contains ground water, as is frequently the case over long sections of pipe lines used for transporting oil and gas, and in the case of pipe lines in cities which are necessarily adjacent sewers and water lines. The
mica-pitch composition described herein, whenapplied as hereinbelow described to form a smooth, uniform coating, acts to inhibit to a remarkable degree the corrosive action of ground currents on the metal surfaces to which it is applied. I attribute this property of the composition to the insulating quality of the pitch and of the flat flakes of mica homogeneously distributed therein which form nae throughout the composition. the mica enhances the permeability to water of the coating composition, the tendency of ground currents to follow lines of moisture penetrating the composition is greatly reduced. This non-permeability of the mica-pitch composition to moisture and ground currents with resulting corrosive action on the pipe line, is further minimized by reason of the smooth, glossy outer surface which is a characteristic of my micar-pitch composition, which smooth outer surface does not present irregular- Further, since insulating lamitensile strength and nonities and rough spots constituting points of atapplying to such surfaces a substantially 'uniform coatin my invention. This to pipes or metals by dipping the pipes or metals after priming into a bath containing the micapitch mixture or by wiping or pouring the micapitch composition onto the material or article to be coated or by. any other suitable means such as spraying and the like.
The property of the mica-pitch mixture to become freely fluid at elevated temperatures, 1. e., at temperatures somewhat above the melting point of the mica-pitch mixture, renders the mixture 'as hereinabove indicated particularly suitable for application to pipes or metals by dipping, wiping, pouring, or spraying processes. The mica-pitch composition .at temperatures below the melting point is substantially solid but upon being heated to ing point becomes freely'iluid, forming aliquid which is substantially homogeneous throughout and which I have found is admirably suited for of the mica-pitch composition of purposes of coating or enameling metal.
somewhat above the meltcomposition may be applied As above iii dicated, in order to adequately 7o mica fillers for must wet the surface the enamel mustr be inous paint free of employed. Pitch 2,047,772" protect the metal surface it is important that a smooth, substantially uniform coating, 1. e., free from pits and openings and of substantially uniform thickness, be formed on the metal surface so that no portion thereof is exposed to soil conditions upon burial. I have found that the mica-pitch composition of 'my invention forms such coating somewhat above its melting point and such that the composition is freely fluid. The temperature of application of. the mica-pitch enamel should not be greater than 200- F. above its melting point. Thus, for the mica-pitch composition disclosed herein having a melting point, in round numbers, of from about 150 F. to 200 F., the maximum temperature at which the enamel is maintained during application should not be greater than about 350 F. to about 400 F. By keeping the enamel within this temperature range its composition will not be radically changed, i. e., substantial evaporation of the oil content cf the pitch and substantial decomposition of the pitch content with free carbon formation will not take place. With other than pitch in order to produce a composition which can be applied to pipe to form a uniform coating thereon, it was found necessary to heat the composition to such high temperatures "that degradation place.
To form a satisfactory coating, the enamel to be coated and bond with the primer usually employed, anda certain degree of flow of the enamel must take place be-v fore it-sets in order to permit the formation of a smooth even surface. To meet these conditions, above a certain minimum temperature hereinabove pointed outwhen applied, so that premature setting of the enamel is avoided. As the primer for the, pipe 2; bitumilllers, free flowing and con. taining .a volatile solvent which evaporates upon application of the primer to the pipe may be dissolved in a solvent, which upon application, forms a thin coating with which the mica pitch composition bonds has been found a satisfactory primer.-
1 have found that an eminently satisfactory coating can be produced by applying the micapitch enamel at a temperature at least about 125 F. above its melting point. 7 Thus, for micapitch enamels' herein disclosed having a melting point of from about 150 F. toabout 200 F., the minimum temperature of the enamel during ap plication should be from about 275 F. to about of the pitch took 325 F. respectively.- while the enamel might a lower temperature than that be applied at herein indicated, for the best results the temperature should be at least about 125 F. above its melting point. Q
(one possible theory which may provide an additional reason why optimum results follow from 1 applying the enamel at the minimum tempera? plant time interval .ture indicated is as follows: In order to obtain an effective coating it is important that the mica particles thereinbe coordinated with respectto' the surface of .the coating, e. g., the mica flakes be arranged parallel to the surface forming laminae which reinforce the coating and improve the non-conducting qualities thereof. A ummust be'allowed between the time. of application of the enamel and the time of setting for the mica particles to become properly coordinated with respect to the surface. If the temperature of application is below the optiapplying the enamel when applied at a temperature draining or spraying,
mum temperature specified the enamel will set before an opportunity is afforded the mica.
particles to become properly coordinated. By withinthe range speci. ed, i. e., for enamels having a melting point of om about 150 to about 200 F. at a temperature of from about 325 to about 400 R, an opportunity is afiorded the mica particles to become properly coordinated with respect to the surface of the coating and a smooth, uniform, glossy coating results.
Whether the coating is ,applied' by dipping, it is important, as noted above, that the temperature of the mica-pitch composition be maintained not lower than that at which it will flow readily to produce a smooth, uniform coating. If to be dipped into. a bath of the enamel and then removed, the desired smooth, uniform, glossy coating in accordance with this invention is produced by the excess enamel draining from the dipped pipe. If the temperature of the enamel the pipe to be protected is not drain uniformly from the pipe but the excess enamel will set and harden on the pipe, resulting in a coating of different thicknesses in which weak spots appear. Likewise ifthe enamel is applied to the pipe by pouring it on while rotating the pipe and the temperature of the enamel is below the optimum minimum temperature hereinabove pointed out, the enamel may hot wet the pipe no! bond with the primer usually employed and will not flow over and uniformly coat the pipe but will set on the pipe during covering the complete surface thereof.
I have found that mica-pitch compositions, applied to pipe, while maintained at a temperature falling within the range hereinabove speci fied, result in a smooth, glossy, uniform coating through which the mica particles are substantially uniformly distributed in the form of laminae. The thickness of the coating will depend upon the particular temperature of application of the enamel. For example, with an enamel having a melting point of about 200 F. and applied at a temperature of about 395 F., a coating approximately inch thick resulted. When the temperature of application of this enamel was lowered to 335 F. a coating approximately a; inch thick resulted.
The melting point of the mica-pitch mixture herein given is determined by the Ring and Ball Method, A. S. T. M. Standard Method 13-36-26.
While preferred embodiments of this invention have been described, it will be, understood that this invention is not to be limited by the disclosure herein but only by the scope of the appended claims.
I claim:
its rotation without 3 00 1. The method of coating metallic pipes which comprises applying in heat liquefied condition a composition constituted of a major proportion of pitch and a minor proportion of finely divided mica, said composition having a melting point of 5 from about 150 F. to about 200 F., to the pipe condition at a temperature of from about 325 F.
while the said composition is in heat liquefied to about 400 F., causing the said compositiondn said heat liquefied condition to completely cover 7 .the pipe and then set thereon to produce a comprises applying a p tc prime to: the P 1 575 applying in heat liquefied condition a, composition constituted of from 70 to 90 per cent coal tar pitch and from 10 to 30'per cent finely divided mica, said composition having a. melting-joint of from about 150 F; to'about 200 F. to the primed pipe while the said composition is in-hea.t
liquefied condition at a temperature of from about 325 F. to about 400 F., causing the said composition in said heat liquefied condition to completely cover the pipe and then set thereon to produce a. smooth, uniform coating covering the exterior of the pipe.
' CLARENCE R. ECKERT.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US2804A US2047772A (en) | 1935-01-21 | 1935-01-21 | Process of protecting underground metallic surfaces |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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US2804A US2047772A (en) | 1935-01-21 | 1935-01-21 | Process of protecting underground metallic surfaces |
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US2047772A true US2047772A (en) | 1936-07-14 |
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US2804A Expired - Lifetime US2047772A (en) | 1935-01-21 | 1935-01-21 | Process of protecting underground metallic surfaces |
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Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2615820A (en) * | 1949-03-01 | 1952-10-28 | Nox Rust Chemical Corp | Removable protective coating |
US2636834A (en) * | 1950-02-15 | 1953-04-28 | Byerlyte Corp | Asphaltic-composition application |
US2654676A (en) * | 1949-06-28 | 1953-10-06 | Dryden Ian Gordon Cumming | Method of coating with a coal extract and baking |
US2656857A (en) * | 1946-08-23 | 1953-10-27 | Pompes Noel Soc | Coated pipe |
US2749250A (en) * | 1954-04-05 | 1956-06-05 | Koppers Co Inc | Process of coating a metallic structural article and a marine organism resistant composition therefor |
US2787557A (en) * | 1954-05-11 | 1957-04-02 | Koppers Co Inc | Marine organism resistant composition and method of coating structural articles therewith |
-
1935
- 1935-01-21 US US2804A patent/US2047772A/en not_active Expired - Lifetime
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2656857A (en) * | 1946-08-23 | 1953-10-27 | Pompes Noel Soc | Coated pipe |
US2615820A (en) * | 1949-03-01 | 1952-10-28 | Nox Rust Chemical Corp | Removable protective coating |
US2654676A (en) * | 1949-06-28 | 1953-10-06 | Dryden Ian Gordon Cumming | Method of coating with a coal extract and baking |
US2636834A (en) * | 1950-02-15 | 1953-04-28 | Byerlyte Corp | Asphaltic-composition application |
US2749250A (en) * | 1954-04-05 | 1956-06-05 | Koppers Co Inc | Process of coating a metallic structural article and a marine organism resistant composition therefor |
US2787557A (en) * | 1954-05-11 | 1957-04-02 | Koppers Co Inc | Marine organism resistant composition and method of coating structural articles therewith |
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