US3656547A

US3656547A - Thermal radiation system for soil stabilizer

Info

Publication number: US3656547A
Application number: US35629A
Authority: US
Inventors: Winfield G Beach
Original assignee: Individual
Current assignee: Individual
Priority date: 1970-05-08
Filing date: 1970-05-08
Publication date: 1972-04-18
Anticipated expiration: 1989-04-18

Abstract

A thermal stabilizer assembly consisting of a vertical tubular convection cell mounted in a body which is to be thermally stabilized, the convection cell being provided with a heattransmitting fin configuration at its upper portion for heat transmission to the atmosphere. The fin configuration may consist of auxiliary metal tubes clamped to the cell by metal straps. The auxiliary tubes may be arranged in layers. The auxiliary tubes may consist of relatively small auxiliary tubes clamped in relatively large auxiliary tubes, both in heat-conducting contact with the main convection cell. The fin configuration may alternatively consist of flanged vertical bars clamped around the vertical convection cell by metal straps.

Description

[54] THERMAL RADIATION SYSTEM FOR SOIL STABILIZER [is] 3,656,547 [451 Apr. 18, 1972 FOREIGN PATENTS OR APPLICATIONS 647,675 7/1928 France ..l65/ 164 [72] Inventor: Winfield G. Beach, 808 Lakeview Trailer 215,616 7/1941 Switzerland'" "165/183 Court, Fairbanks, Alaska 9970} 530,900 8/1931 Germany ..165/183 [22] Filed: May 8, 1970 Primary Examiner-Alb ert W. Davis, Jr. [2 pp NO; 35,629 Attorney-Herman, Davidson and Herman v [57] ABSTRACT [52] [1.5. CI ..l65/l06, 165/45, 165/128, A thermal Stabilizer assembly consisting of a vertical tubular 165/183 convection cell mounted in a body which is to be thermally Int.Cl stabilized the convection cell being provided with a heat. Field of Search transmitting fin configuration at its upper portion for heat 165/45 transmission to the atmosphere. The fin configuration may consist of auxiliary metal tubes clamped to the cell by metal [56] References Cited straps. The auxiliary tubes may be arranged in layers. The auxiliary tubes may consist of relatively small auxiliary tubes UNITED STATES PATENTS A clamped in relatively large auxiliary tubes, both in heat-conducting contact with the main convection cell. The fin con- 34723l4 10/1969 figuration may alternatively consist of flanged vertical bars 3,305,013 2/1967 clamped around the vertical convection cell by metal straps.

596,330 12/1897 1,721,808 7/1929 Kettering ..165/183 X 7 Claims, 14 Drawing Figures j .30 i I i I i i i I I l I I i l i I l i l I i l i i l J 34 i i i \l i a, l, J'

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PATENTEDA'F-RIBISYE 3,656,547

sum 3 0F 3 THERMAL RADIATION SYSTEM FOR SOIL STABILIZER This invention relates to heat transfer systems, and more particularly to thermal stabilizer assemblies for stabilizing soil masses or bodies of water subjected to freezing and thawing effects.

A main object of the invention is to provide a novel and improved thermal stabilizer assembly adapted for use in areas subject to soil heaving and other undesirable actions induced by changing temperatures, the assembly being relatively simple in construction, being efficient in operation, and involving inexpensive parts.

A further object of the invention is to provide an improved thermal stabilizer assembly which may be employed for stabilizing bodies of water or masses of soil by the action of liquid in a convection cell inserted in the material to be thermally stabilized, the improved assembly providing more efficient and more rapid heat transmission to or from the atmosphere with respect to the convection cell, involving very simple components, being relatively compact in size, being arranged so that it will operate continuously without attention or maintenance once filled with appropriate liquid, and providing improved heat radiating or absorbing capacity for the associated thermal stabilizing system.

A still further object of the invention is to provide an improved fin configuration for a thermal stabilizer convection cell, the configuration having high heat transmission capacity, having maximum heat conductivity with respect to the convection cell, and providing effective stabilizer effects continuously over long periods of time without requiring attention, adjustment or other types of maintenance operations.

Further objects and advantages of the invention will become apparent from the following description and claims, and from the accompanying drawings, wherein:

FIG. 1 is a perspective view of a thermal stabilizer convection cell provided with one form of improved fin configuration in accordance with the present invention.

FIG. 2 is a horizontal cross-sectional view, to a somewhat enlarged scale, taken substantially on the line 2-2 of FIG. 1.

FIG. 3 is an enlarged fragmentary top plan view of a modified form of improved convection cell and fin assembly according to the present invention.

FIG. 4 is a top plan view of another modification of an improved convection cell and fin assembly constructed in accordance with the present invention.

FIG. 5 is an elevational view of the thermal stabilizer assembly of FIG. 4.

FIG. 6 is a fragmentary top plan view of a further modification of convection cell and fin assembly according to the present invention.

FIG. 7 is a fragmentary top plan view, similar to FIG. 6, but showing an additional modification of the fin assembly.

FIG. 8 is a fragmentary top plan view, similar to FIG. 6, but showing another modification of the improved fin assembly of the present invention.

FIG. 9 is a fragmentary top plan view, similar to FIG. 6, but showing still another modification of the improved stabilizer assembly of the present invention.

FIG. 10 is a fragmentary top plan view, similar to FIG. 6, but showing still another form of fin configuration according to the present invention.

FIG. 11 is a top view of another modification of an improved thermal stabilizer assembly according to the present invention, employing flanged vertical bars as fins.

FIG. 12 is an elevational view of the thermal stabilizer assembly of FIG. 11.

FIG. 13 is an enlarged end elevational view of one of the flanged fins employed in the assembly of FIGS. 11 and 12.

FIG. 14 is an enlarged perspective view of a heat-transmitting fin employed in the thermal stabilizer assembly of FIGS. 11 and 12.

Referring to the drawings, and more particularly to FIGS. 1 and 2, 15 generally designates an improved heat transfer assembly constructed in accordance with the present invention.

such as soil, or the like, to prevent undesirable ground heaving and similar effects caused by differences in temperature between the surface portions of the mass, for example, the portions at the top, exposed to the atmosphere, and the lower portions of the mass, remote from the ground surface. In regions having a cold climate, the ground temperatures are naturally much lower at the surface than beneath the surface during the fall, winter and spring months. This substantial difference in temperature produces undesirable effects, such as ground heaving, and it is therefore highly important to -minimize the differences in temperature, for example, ad-

jacent structures, such as piles or the like associated with structural assemblies. The device 15 is designed to remove heat from the soil mass, or from any other material in which it is employed.

The stabilizing device 15 comprises a metal inner casing 16 with a closed bottom end and being adapted to contain a suitable liquid which can circulate by convection therein responsive to the presence of a substantial temperature differential between its upper and lower portions.

Secured on the upper portion of the casing 16 is a heat transfer assembly, designated generally at 17, for transferring heat from the top portion of casing 16 to the atmosphere at a relatively rapid rate. The heat transfer assembly 17 comprises a plurality of metal tubular fins 18 positioned around the upper portion of the casing 16 and clamped thereagainst by a plurality of spaced peripheral metal clamping bands 19 which bind the tubular fins 18 into close heat-conductive contact with the casing 16. As shown in FIG. 2, the tubular fins 18 are relatively small in diameter as compared with the inner casing 16 and completely surround the inner casing, being held in firm heat-conductive contact with each other as well as with the inner casing by the clamping action of the bands 19.

The temperature stabilizing apparatus 15 is mounted in the soil adjacent to the structure where soil stabilization is required, the lower portion of the casing 16 being buried in the ground, for example, in the manner illustrated in FIG. 1, where ground level is designated at 20. Thus, the lower portion of casing 16 extends downwardly into the ground to a substantial depth, whereas the heat transfer assembly 17 carried by the upper portion of the device is supported somewhat above ground level. Thus, the assembly 17 is sufficiently elevated to allow free circulation by convection of air through the tubular fins 18.

In operation, assuming that a substantial temperature differential exists between the atmosphere and the region in the ground adjacent to the lower portion of casing 16, the temperature differential will generate convection of liquid in the casing 16, causing the liquid in the casing 16 to develop convection action causing the liquid to move past the wall of the casing and transfer heat thereto.

In a typical situation, liquid flows upwardly through the central portion of the casing toward the top surface of the liquid and then flows outwardly and downwardly past the inside surface of the casing wall. Heat is transferred through the casing wall to the tubular fins l8. Atmospheric air moves upwardly through the fins 18 because of the temperature differential thus created, and the upwardly moving air passing through the fins carries off a substantial amount of heat from the fins, the heated atmospheric air emerging from the top ends of the fins, as shown by the arrows in FIG. 1. Thus, an atmospheric convection action is generated around the fins 18 which transfers the heat to the atmosphere. The net result is to reduce the temperature differential between the atmosphere and the region in the soil adjacent to the lower end of casing 16, thereby providing the desired soil stabilization effect.

FIG. 3 diagrammatically illustrates a modification of the system shown in FIG. 2 wherein a plurality of layers of heattransfer fins are employed instead of a single layer. Thus, in FIG. 3 a continuous inner layer of tubular cooling fins 18 is provided extending completely around the inner casing 16, and superimposed on the inner layer of fins are additional tu- The assembly 15 is intended to stabilize a region of material, bular fins 22 which are clamped against

adjacent fins

18,18 by the outer metal clamping bands, shown at 23. It will be seen that as in the case of the embodiment of FIGS. 1 and 2, the inner tubular fins 18 are clamped against the casing 16 and are also held in contact with each other, but the adjacent pairs of tubular fins 18 are further conductively bridged by respective outer tubular fins 22, which serve as heat conductors, as well as auxiliary convectors acting in the same manner as the inner fins 18. The heat-radiating surface is thereby considerably increased, as well as the convection action, providing a substantial increase in the ability of the resultant assembly to transfer heat away from the upper portion of the liquid convection casing 16.

FIGS. 4 and illustrate a further embodiment of the invention employing the above-described general principles. The embodiment illustrated in FIGS. 4 and 5 is especially suitable for conditions such as those wherein the snow level is unpredictable and may possibly be of substantial height. The assembly shown in FIGS. 4 and 5 comprises an inner liquid convection casing 16, as above described, with a heat transfer assembly, shown generally at 30, clamped thereto at its upper portion. The assembly 30 comprises a plurality of relatively small-diameter metal tubular fins 31 which are clampingly secured in respective larger-diameter outer fins in the manner illustrated in FIGS. 4 and 5 by metal tension bands. Thus, each tubular fin 31 is received in a larger metal tubular fin 32 with the top ends of the metal tubular inner fins 31 protruding upwardly from the top ends of the larger tubular fins 32 and clampingly engaged by a circumposed metal clamping band 33. The larger fins 32 are formed with circumferential slots 34 at their lower portions and another clamping band is tightly engaged around the lower portions of the inner metal tubes 31, the slots 34 providing clearance for the lower clamping band 35. As shown in FIG. 5, the lower ends of the inner tubes 31 terminate substantial distances above the lower ends of the metal tubes 32, and the lower portions of the larger metal tubes 32 are clamped against the casing 16 by the provision of a circumferential metal clamping band 36. The slots 34 are preferably located above the highest expected snow level.

As shown in FIG. 5, the top ends of the outer tubular fins 32 slope downwardly and outwardly and the bottom ends of said tubular fins slope upwardly and outwardly. The top ends of the inner tubular fins 31 slope upwardly and outwardly and the bottom ends of said inner fins slope upwardly and outwardly. The lower ends of the inner fins 31 are located a substantial distance above the expected maximum snow level.

In operation of the assembly of FIGS. 4 and 5, heat is conducted away from the top portion of the convection casing 16 to the large fins 32 and also to the small fins 31. Under conditions where the snow level is relatively low, falling below the open bottom ends of the large tubular fins 32, cooling convection currents of air from the atmosphere flow through the fins in the same manner as above described in connection with the preceding embodiments of the invention. This would provide the desired stabilization action, since the heat conducted to the small and large tubes is carried off by the atmospheric air circulating upwardly through the tubes. If the snow level should rise above the lower ends of the large tubes 32, sealing said lower ends, atmospheric air enters the top ends of the large tubes 32 and circulates downwardly therein and then upwardly through the smaller inner tubes 31, providing the desired cooling action. Also, atmospheric air can flow into the larger tubes 32 through the slots 34 and then flow through the lower ends of inner tubes 31 upwardly through the inner tubes, adding to the transfer of heat from the upper portion of casing 16 to the atmosphere. The resultant effect is to insure proper temperature stabilization of the soil, or other material with which the apparatus is used, under a wide range of snow level conditions.

As above mentioned, outer clamping bands 36 are employed at the lower portion of the assembly, as well as of the upper portion thereof around the upper portions of outer tubes 32 to clamp said outer tubes against the casing 16 as well as against each other. Thus, as shown in FIG. 5, a pair of clamping bands 36 may be employed at the upper and lower portions of the larger tubular fins 32, and additional clamping bands 33 and 35 may be employed around the upper and lower end portions of the inner tubular fins 31, as above described, the lower clamping bands 35 being engaged through the slots 34.

In the modification illustrated in FIG. 6, the inner tubular fins 31 are of circular cross-section, whereas the larger tubular fins, shown at 40, are of elliptical cross-section with their major axes directed radially outwardly. The assembly of FIG. 6 is therefore substantially similar to that of FIGS. 4 and 5, except that a larger number of relatively large diameter outer tubular fins 40 may be employed than in the assembly of FIGS. 4 and 5 wherein the outer tubular fins 32 are of circular crosssectional shape.

In the modification illustrated in FIG. 7, both the smaller tubular fins, shown at 45, and the larger tubular fins 40 are of elliptical cross-section and are positioned with their major axes directed radially outwardly, with the smaller elliptical tubular fins 45 received in the inner portions of the larger elliptical tubular fins 40.

In the embodiment illustrated in FIG. 8, the assembly is similar to that illustrated in FIG. 6 except that he larger fins, shown at 50, are generally elliptical in cross-section except that their inner end portions are conforrnably shaped so as to seat against the casing 16 with substantially continuous surface contact. Thus, the inner edge portions of the otherwise elliptically shaped fins 50 are arcuately indented to conform with the arcuate surface contour of casing 16. As shown in FIG. 8, the relatively large tubular fins 50 completely surround the inner casing 16 and contain the cylindrical inner fins 31, said inner fins being clamped against the arcuately indented inner edge portions of fins 50 by their clamping bands 33 and 35.

As in the previously described embodiments of the invention, the outer fins 50 are clamped against the casing 16 by their metal clamping bands 36.

In the modification shown in FIG. 9, the inner tubular fins, shown at 60, are likewise of substantially elliptical cross-sectional shape and are located inside the larger elliptical fins 50 with their major axes substantially coincident, both the larger tubular fins 50 and the smaller tubular fins 60 being arcuately indented so as to conform with the arcuate contour of the liquid convection casing 16. The inner tubular fins 60 are clamped inwardly by their clamping bands 33 and 35 and the larger tubular fins 50 are clamped inwardly by their metal clamping bands 36, as in the previously described forms of the invention.

In the modification illustrated in FIG. 10, the arrangement is generally similar to that of FIGS. 4 and 5 except that the inner portions of the smaller and larger tubular fins are arcuately indented so as to conform with the arcuate contour of the liquid convection casing 16. Thus, the larger tubular fins, shown at 70, are arcuately indented at their inner portions to conform with the arcuate contour of casing 16, and the respective smaller tubular fins 71, received in the tubular fins 70, are likewise arcuately indented to conform with the arcuately indented inner portions of the larger fins 70, the inner fins 71 being clamped inwardly by their metal clamping bands 33 and 35, and the larger tubular fins 70 being clamped in-v wardly by their metal clamping bands 36 in the same manner as above described. Clamping bands 36 clamp the fins 70 tightly against the liquid convection casing 16 and also tightly against each other.

Referring now to the form of the invention shown in FIGS. 11 to 14, a modified form of heat transfer assembly is provided on the upper portion of the liquid convection casing 16. The transfer assembly 80 comprises a plurality of elongated fin members 81 of generally T-shape clamped together contiguously and also clamped inwardly against the liquid convection casing 16 by a pair of

metal clamping bands

82 and 83 surrounding their upper and lower end portions. Each fin 81 has an inner flange 84 having an arcuately concave inner end surface 85 conforming with the arcuate contour of the liquid convection casing 16. Each fin 81 is provided with an outer flange 86 having an arcuately convex outer contour 87 concentric with the arcuate contour of the inside surface 85 of the fin. Thus, as shown in FIG. 13, each fin may subtend an angle of 30: with reference to the center line of the associated liquid convection casing 16. The outer flange 86 may be provided with abutment ribs 87 providing for smooth abutment between adjacent fins with substantial heat-transmitting contact area.

A continuous set of fins 81 is clamped around the upper portion of the casing 16 by the

metal clamping bands

82 and 83, the contact ribs 87 of the fins being in abutting engagement with each other whereby the assembly defined is of substantially continuous outside radiation surface and a substantially continuous inside heat-conduction surface in tight and flush contact with the liquid casing 16. The adjacent fins 81 thereby define between them respective convection channels 88 allowing atmospheric air to flow upwardly therethrough in the manner described in connection with FIGS. 1 and 2, to carry off heat conducted to the fins from the upper portion of casing 16.

The assembly 80 may be mounted on the casing 16 at any desired position at its upper portion, preferably at a substantial height above ground level, as shown in FIG. 12.

The convection casing 16 is preferably closed at its top end as well as its bottom end, so that it defines a closed fluid system. The liquid convection system in casing 16 is in itself of well known construction and therefore it is deemed unnecessary to describe the details thereof.

While certain specific embodiments of an improved thermal stabilizer assembly for use in stabilizing the temperature of masses of soil or other materials have been disclosed in the foregoing description, it will be understood that various modifications within the spirit of the invention may occur to those skilled in the art. Therefore it is intended that no limitations be placed on the invention except as defined by the scope of the appended claims.

What is claimed is:

1. A thermal stabilizer assembly comprising an elongated heat-conductive liquid convection casing adapted to be positioned upright in a body of matter with its upper potions projecting therefrom into the atmosphere, said casing containing fluid in which convection currents can be generated responsive to differences in temperature between the top and bottom portions of the casing, and a heat-transmitting assembly secured around the upper portion of said casing, said heattransmitting assembly comprising a plurality of elongated heat-conductive fin elements disposed parallel and outwardly adjacent to the upper portion of the casing, means securing said fin elements to the casing, and means on the fin elements defining laterally closed air ducts leading from the bottom to the top ends of the fin elements, whereby convection atmospheric air currents may flow upwardly through said ducts and transfer heat from the upper portion of the casing to the atmosphere, wherein said fin elements are provided with lateral abutting portions held in abutting contact by said securing means, wherein said securing means comprises a plurality of heat-conductive clamping bands surrounding and clampingly engaging spaced portions of said fin elements, wherein said fin elements include metal tubes, wherein said fin elements comprise relatively large tubes disposed around and engaging the casing and relatively smaller tubes inside the large tubes and disposed against and engaging the inner wall portions of the large tubes, and wherein the lower ends of the smaller tubes are spaced above the lower ends of the large tubes.

2. The thermal stabilizer assembly of claim 1, and wherein the large tubes have indented inner wall portions substantially conforming in contour with the casing.

3. The thermal stabilizer assembly of claim 1, and wherein both the large and the smaller tubes have abutting inner wall portions indented to substantially conform with the contour of the casing.

4. The thermal stabilizer assembly of dam 1, and wherein the large tubes are substantially elliptical in cross-sectional shape and are positioned with their major axial planes extending substantially radially relative to the casing.

5. The thermal stabilizer assembly of claim 1, and wherein the upper portions of the smaller tubes project above the top ends of the large tubes.

6. The thermal stabilizer assembly of claim 5, and wherein said large tubes are formed with outwardly facing horizontal slots spaced above the lower ends of the smaller tubes and said securing means includes a metal clamping band engaged in the slots and clampingly engaging the smaller tubes.

7. The thermal stabilizer assembly of claim 6, and wherein said securing means also includes a metal clamping band clampingly engaged around the upper portions of the smaller tubes above the top ends of the large tubes.

Claims

1. A thermal stabilizer assembly comprising an elongated heatconductive liquid convection casing adapted to be positioned upright in a body of matter with its upper portion projecting therefrom into the atmosphere, said casing containing fluid in which convection currents can be generated responsive to differences in temperature between the top and bottom portions of the casing, and a heat-transmitting assembly secured around the upper portion of said casing, said heat-transmitting assembly comprising a plurality of elongated heat-conductive fin elements disposed parallel and outwardly adjacent to the upper portion of the casing, means securing said fin elements to the casing, and means on the fin elements defining laterally closed air ducts leading from the bottom to the top ends of the fin elements, whereby convection atmospheric air currents may flow upwardly through said ducts and transfer heat from the upper portion of the casing to the atmosphere, wherein said fin elements are provided with lateral abutting portions held in abutting contact by said securing means, wherein said securing means comprises a plurality of heat-conductive clamping bands surrounding and clampingly engaging spaced portions of said fin elements, wherein said fin elements include metal tubes, wherein said fin elements comprise relatively large tubes disposed around and engaging the casing and relatively smaller tubes inside the large tubes and disposed against and engaging the inner wall portions of the large tubes, and wherein the lower ends of the smaller tubes are spaced above the lower ends of the large tubes.

4. The thermal stabilizer assembly of claim 1, and wherein the large tubes are substantially elliptical in cross-sectional shape and are positioned with their major axial planes extending substantially radially relative to the casing.