US1821080A

US1821080A - Radiator

Info

Publication number: US1821080A
Application number: US488713A
Authority: US
Inventors: Severn D Sprong
Original assignee: ENGINEERING PRODUCTS CORP Inc
Current assignee: ENGINEERING PRODUCTS Corp Inc
Priority date: 1930-10-15
Filing date: 1930-10-15
Publication date: 1931-09-01
Anticipated expiration: 1948-09-01

Description

S. D. SPRONG Sept. 1, 1931.

RADIATOR Filed voct. 15, 12950 INVENTOR euer/L S//J/olzgg BY ATTORNEYS patented Sept. 1, 1931 miran STATES PATENT- onirica SEVERN D. SPRONG, BROOKLYN, NEW YORK, ASSIGNOR TO ENGINEERING PRODUCTS CORPORATION, INC., OF NEW YORK, N. Y., A CORPORATION OF NEW YORK RADIATOR Application tiled ctobei 15, 1930. Serial No, 488,713.

of substantially lower melting point than` the metal of which the pipe and fins are composed. v

The invention will be fully apparent from the following specification when read in connection with the accompanying drawings t sirable characteristic of rapidly conducting and will be defined with the appended claim.

Fig. 1 is a side elevation of a radiator embodying the invention; l

Fig. 2 is an enlar ed perspective view of a portion` of one o shown in Fig. 1;

Fig. 3 is a horizontal section illustrating a step in the method of production of my improved radiator;

Fig. 4 isa longitudinal section on line 4-4 of Fig. 3;

Fig. 5 is a view similar to Fig. 4, but illustrating a further step in the method of manufacturing a radiator;

Fig. 6 is an enlarged edge view of one of the radiating fins shown in Figs, 2 to 4 inclusive;

Fig. 7 is a section on line 7 7 of Fig. 6;

Figs. 8 and 9 are detail views of a modi- 'edform of vthe invention, Fig. 9 being a horizontal section, on line 9 9 of Fig. 8;

particularity v1n Fig. 10 is a view illustrating a modiiica-- tion in which the heat radiating fins are secured to the' pipe by means of a body of metal cast therearound.

Referring first to Fig. lof the drawings, numerals 10 designate as a whole radiator elements, each comprising a length of pipe 12 anda multiplicity of radiating fins 14. In the radiator illustrated in Fig. 1, three such radiator elements 10 are indicated,

the radiator elements these being connected by

unions

16 and 18 with inlet-and outlet`

pipes

20 and 22, respectively, the inlet pipebeing provided with suitable control valve 24.

- The number of radiating elements 10 may of course be varied to suit the particular requirements depending upon. the amount of radiation required for the particular room in which the radiator is installed. Each radiating element 10 is of identical construction hence a detailed description of one will suflice for all. j

The heat radiating` fins 14 are formed of sheet metal such as sheet iron and cold rolled steel. Or, if desired, in some cases, the elements may bemade of sheet copper or aluminum, both of which possess the deheat.

Eachfin 14 in the construction of Figs.

2 to 7 inclusive is provided with a series of oppositely projecting ears or lugs 26-28 which are adapted to be seated flush against the substantially cylindrical surface of the pipe 12. The ears on adjacent fins are so arranged thatthey stagger so that the ear of a given fin lies about midway between two ears of an adjacent iin. This arrangement of the ears also provides for securing a good heat conducting joint between the iin and the pipe. In the production of the radiator unit of Figs. 1 to 7 inclusive, the several fins are positioned and held by any suitable temporary fastening means so that the ears seat against the outer surface of 'a pipe. The assemblage is then dipped into4 a hot galvanizing bath such as spelter or molten zinc. When the fins and pipe are made of ferrous metal such as iron or steel, this' dipping operation kserves 'the double purpose of coating the metal with a noncorrodible skin and also eii'ectively bonds the heat yradiating fins to the pipe so as to -make a good heat conducting joint. After the assemblage has been held in the galvanizing bath for a' short time, it is withdrawn. This operation will deposit a thin film or coat of zinc or the like over the entire surface of the in's and will also cover the exterior of the pipe. This galvanized 1 film of metal enveloping the fins and the pipe is indicated at 30 injFig. 5.

Prior to dipping the pipe and the assembled fins in' the galvanizing bath, the assemblage may be preheated and also dipped in a suitable iux such as Sal ammoniac. Also after the galvanized assemblage has been removed from the bath, it may be subjected to a suitably controlled cooling or annealing treatment so as to improve the surface appearance or texture of the coating.

The fins or heat radiating members in Figs. 2` and 3 extend substantially radially in plan and extend longitudinally of the pipe. In some cases, the pipe may be bent from a round to a substantiall elliptical shape in plan and some ofthe lins may be of greater length than others as shown in plan in Fig. 3 so that the outer ends of the lins lie within the outline of a fairly flat ellipse. This arrangement provides considerable radiating surface andY yet A"the lins do not project an objectionablev distance out 4 25 into the room. The major axis of the el llpse will .usually extend parallel with the wall adjacent to which the radiator is located.

InFigs.`8 and 9, I have illustrated .a gomodilication wherein the radiator element consists of a pipe 12a which is surrounded by a plurality of ribbon-like helical fins 32. These fins, it will be understood ,are bonded to the pipe by means'of a body or film of metal of substantially lower melting point than that of the pipe and fins.

Insteadof securing the iins by dipping the assembled parts in a bath of galvanizing material or the like, I also contemplate securing them in place by 'a cast body of molteninet'al. For example, as shown in Fig. 10, I may assemble the fins 34 around y the pipe 12b and provide separable mold sections 36. I can then pour molten iron, lead -or the like into the runner 38. This will feed through gates 40 and thus cast the body of metal 42 about the pipe 12b and in contact with the several -fins 34. Thus the fins and j the pipe will be secured to one another with a good heat conducting joint.

Ittead of securing fins to pipe by dipping`the assemblage in\a galvanizing bath or by casting a'body of molten metal around lthe parts, I contemplate in some cases the use of a metal spray gun. By using such /a gun, the fins will be assembled with the pipe and ,molten metal will be sprayed under pressure over the surface of thev fins.

. 'Upon cooling of this metal, the parts will so thus be effectively bonded to one another with a good heat conducting joint.

From the v'foregoing it will be apparent that my improved radiator can be expeditiously manufactured from stock pipe and sheet metal punchngs at low cost with a minimum expenditure for labor in assembly. Practically all foundry work is avoided and this materially cuts down the cost of production.

While I have described quite specifically certain embodiments of the invention herein illustrated and I have indicated the preferred method of producing my improved radiator, it is not to be construed that I am limited thereto since/various changes may be made by those skilled in the art without departing from the invention as dened in the appended claim.

What I claim is v A radiator comprising a pipe, a plurality of ns extendingsubstantiallv longitudinally thereof, said fins having ears seated against and curved to lit the pipe and a thin lilm of metal bonding the ears to the pipe, the ears on said fins being bent outwardly from opposite surfaces thereof, the ears on a given iin being staggered with respect to those on an adjacent lin.

In witness whereof, I have hereunto signed my name.

SEVERN D. SPRONG.