DE2034353A1 - Arrangements provided with holes - Google Patents

Description

Holed. Arrangements

The invention relates to apertured assemblies and in particular heat exchangers.

The aim of the present invention is to provide a to create improved heat exchangers.

An apertured assembly according to the invention comprises a first sheet metal part and a second sheet metal part lying one above the other are spaced and are sealingly connected along their edges, so that a tunnel between the Sheet metal parts is formed, the arrangement from the sheet metal parts has a plurality of openings attached in pairs, each pair comprising an opening in each sheet and the openings of each pair are superposed, the sheet metal surrounding each opening of each pair being extending tubular projections to the opposite sheet metal part in a snug fit connection with the tubular projection, which protrudes from the sheet metal surrounding the other opening of the pair.

109816/1368

A heat exchange element according to the present invention comprises a first sheet metal part and a second sheet metal part which are arranged at a distance one above the other and along them Edges are sealingly connected, so that a tunnel between the sheet metal parts is formed. The arrangement of the sheet metal parts has a large number of openings arranged in pairs, each pair comprising an opening in each sheet metal part and ' the openings of each pair are superimposed. The sheet metal surrounding each opening of each pair extends as a tubular projection to the opposite Sheet metal part in a tight fit connection with the tubular Protrusion formed from the sheet metal surrounding the other opening of the pair.

According to the invention, a boiler comprises a heat exchanger element as described above, in connection with a burner element.

Embodiments of the present invention are illustrated in more detail by way of example with the aid of the accompanying drawings.

1 schematically shows a heat exchanger element in a top view.

FIG. 2 shows the element of FIG. 1 schematically in a partially sectioned view.

Fig. 3 shows schematically enlarged a detail of the element of Figs. 1 and 2 to illustrate the fluid flow.

FIG. K shows, schematically enlarged, a detail in section of the element of FIGS. 1 and 2.

10 9 8 16/1368

Fig. 5 shows schematically in a plan view a detail of a further embodiment of a heat exchanger element.

FIG. 6 shows schematically in a sectional view an arrangement of elements according to FIG. 5 ·

Fig. 7 shows schematically in a perspective view a boiler partially broken open.

Fig. 8 shows schematically in a side sectional view the boiler of Fig. 7

Fig. 9 shows a schematic perspective of a further boiler arrangement partially broken up.

The warehousing element 1 shown in Figures 1 and 2 consists of a first sheet metal part 2 and a second sheet metal part 3i which are arranged at a distance one above the other. The parts 2 and 3 are sealingly connected to one another along their edges by a connection k , in that the edge of the part 2 is folded over around the edge of the part 3 and is soldered to it. In this way, a tunnel 5 is formed between the sheet metal parts which is connected to a fluid inlet pipe 8 and a fluid outlet pipe 9 through inlet zones 6 and outlet zones 7, respectively. The inlet and outlet zones 6 and 7 are designed as trough-shaped impressions in the sheet metal part 2.

The sheet metal parts 2 and 3 each have a multiplicity of openings lo, which are 11 to 17 in a regular row pattern are arranged and extend transversely with respect to the direction of flow of the fluid through the tunnel. The openings of each row are offset with respect to the openings of the next 'adjacent row or rows (Fig. 3).

1098 1 R / 136 8-

The openings Io of the respective sheet metal parts are arranged in pairs lying one above the other, each pair having an opening included in each sheet. That surrounding every opening Io Sheet metal in the sheet metal part 2 extends as tubular Projection l8 to the opposite sheet metal part 3 in one interlocking snug fit with a corresponding tubular Projection 19 »which is formed from the sheet metal surrounding the other opening of the pair in sheet metal part 3, so that a pipe 18, 19 is formed.

The tubular projections 18 and 19 are in the respective Sheet metal part by a pressing process between a plate, which circular, arranged in the pattern shown Carries punch, and a die plate provided with corresponding openings. The protrusions are through the punches are formed and their ends are pierced in this operation, so that the openings Io are formed will. The projections 18, 19 have cylindrical outer ends, the diameter of which is such that the sheet metal parts can be connected to one another as shown, the projections 18 and 19 fitting into one another (FIG. 4). When assembling, the projections 18 and 19 are sealingly connected to one another by soldering or brazing the openings Io are created, which pass through the arrangement and are sealed off from the tunnel 5.

In order to improve the rigidity of the arrangement and to keep the sheet metal parts exactly at a predetermined distance hold, so that a predetermined distance between the walls and the tunnel is ensured, the sheet metal parts 2 and 3 with mutually engaging, in shape shoulder surfaces 2o, 21 formed by depressions, which can be soldered, welded or riveted together. Such fastenings can optionally be used in Spacer layers are provided in the surface of the element as well as on the edges.

1 098.1 R / 1 3R8

In operation, the heat exchanger element 1 can be placed in a boiler can be used, which has a burner from which hot gases are discharged through the openings Io, as indicated by the arrows in Fig. shown, can flow. Water circulates through the element from the inlet pipe 8 to the outlet pipe 9. When passing through through the tunnel 5 it is also subject to forced convection turbulent flow around the tubes l8, 19, which surround the openings Io j (Fig. 3). This turbulent flow improves the heat transfer to the water »and the large number of air channels formed by the openings Io give this Element has good heat transfer properties at high throughputs. .

Due to the staggered arrangement of the openings Io in the successive rows 11 to 17 is the flow of the Fluid through the element even more turbulent when it flows through the element in the direction between the layers of the inlet and outlet as shown as it is would be the case if the liquid flowed parallel to the rows through 17. In the arrangement shown, each divides Tube l8, 19 the flow of liquid coming from the gap between the pipes in the next row on the upstream side.

A significant advantage of the heat exchanger element described above consists in the extremely simple structure, whereby the channels Io for the gas flow are made entirely of the material can be formed from two sheet metal parts by simple punching processes.

Two or more of the elements described above can be be arranged one behind the other, d. H. in a series of horizontally arranged elements to dissipate the heat from one ordinary source of hot gases. .

1098 16713 β 8

Pig. 5 and 6 show an arrangement in which the heat transfer between one fluid and two other fluids can be achieved. In this arrangement, an element 3o of the embodiment described with reference to FIGS. 1 to 4 is provided with further finned tubes 31 which pass through the openings 32 of the element (corresponding to the openings Io of FIGS. 1 to k). The tubes 31, each of which has four longitudinally extending ribs 33, can pass through more than one element 3 ° * ¹ », which is shown by dashed lines in FIG.

During operation, air can enter the spaces through the openings 32 between the ribs 33 and / or across the tubes in the spaces between successive elements 3o be performed. This allows separate fluids that both in the tubes 31 as well as in the tunnel of the element 3o circulate, be heated or cooled at the same time.

7 and 8 show the arrangement of the heat exchanger elements, as they were generally described with reference to FIGS. 1 to k , in a boiler arrangement 4o with gas burner elements which have a general shape similar to the heat exchanger elements of FIGS. 1 to 4, but are not sealed off Have grooved and interlocking tubular projections to allow the gas supplied to the tunnel to escape into a combustion zone where it burns with combustion air supplied through the openings. Such burner elements are described in patent application P ZsQ -? V 2-ft ,: £ (British patent application 3% 93V09) filed on the same day. $ ~ * ^ "{ί-S WXA '^

The boiler 4o consists of a housing 4l with a in Fig. smoke vent Λ2, not shown, an air blower% 3 to the generally upward movement of the combustion air

1 0 9 8 1 R / 1 3 6 8

through the arrangement to assist. Four burner elements of the type mentioned are in two pairs each in the shape of an inverted V and eight heat exchanger elements 45 in four pairs of spaced elements flanking the respective burner elements, are parallel thereto and are inclined to each other across the burner elements in the shape of an inverted V so that they. absorb the hot gases generated by the burners. A main gas supply line 46 is provided for the elements 44. A connecting pipe 47 is provided for the water circulation through the heat exchanger elements 45, the elements 45 of each pair are in a row. The flow of combustion gases by the elements 45 is shown schematically by the arrows in FIG. 8.

The heat exchanger elements 45 have openings 48, which from mutually engaging tubular projections are formed, as in the embodiment of the figures until 4 is the case. However, the fluid inlet and outlet zones have which are shown only schematically in Fig. 7, any convenient form.

Fig. 9 shows a further embodiment of a boiler arrangement 60 with an air supply from a compensation line 6l. The boiler housing 62 includes an outer outlet channel 63 for the vent while the combustion air passes through an inlet duct 64 is drawn in by a fan 65, which allows the air to flow downward into a burner and heat exchanger assembly, the three vertically arranged Has burner elements 66 arranged side by side in a triangular planar shape on a closed base are. Two heat exchanger elements 67 are each burner element 66 positioned adjacent to receive the hot combustion gases as shown by arrows.

1.09-81. R / 1 3R8

The burner and heat exchanger elements correspond to the embodiment described with reference to FIGS. 7 and 8. The elements of each pair of heat exchange elements 67 are arranged in series and are supplied with water through inlet pipes 68, which flows out through the outlets 69.

The examples described above relate to heat exchanger elements, but the structures according to the invention provided with holes can also be used for gas distribution systems or evaporators in which the gas or liquid to be distributed is guided to tunnels or channels and, for example, through grooves
or other means, which do not connect sealingly to the tubular projections, can escape. The gas or the
Liquid can then be removed from the foraminous structure by forced convection of the air flow through the holes.

A combined evaporator and distributor of this type can be used for the dispersion of liquid nitrogen, to create a stream of cold gas for use in quick freezing food. More examples of the use of such a device is the evaporation of water, the device as a temperature reduction and humidification element in one air conditioning system works.

10981R / 13B8

Claims (1)

PATENT CLAIMS 1. Structure provided with holes, especially for use as a heat exchanger with a first sheet metal part and a second sheet metal part, which are arranged at a distance one above the other and are sealingly connected along their edges to form a tunnel between the sheet metal parts. The arrangement of the sheet metal parts has a multitude of openings arranged in pairs, each pair has an opening (Λ tion in each sheet includes and the openings of one each pair lie one on top of the other, thereby identifying- shows that the sheet metal surrounding each opening (lo) of each pair of openings turns out to be tubular Projection (l8) to the opposite sheet metal part in a snug fit connection with the tubular Extends projection (19) formed from the sheet metal surrounding the other opening of the pair. 2. Heat exchanger element according to claim 1, characterized in that the one of the pairs of nested tubular projections (18, 19) formed- ^ j th tubes (lo) are arranged so that the fluid flow is turbulent through the tunnel from an inlet zone (8) to an outlet zone (9). 3 heat exchanger element according to claim 2, characterized in that that the tubes are arranged in rows (11 to 17) which extend transversely to the normal direction of fluid flow through the tunnel from an inlet zone to an outlet zone, the tubes of each row staggered relative to the tubes of the next adjacent row or rows are. 1098 1R / 13B8 - Io - 4. Heat exchanger element according to one of the claims 1 to 31 characterized in that at least one of the inlet and outlet zones is trough-shaped Press-fit (6, 7) is formed in a sheet metal part. 5 heat exchanger element according to claims 1 to 4, characterized in that at least one sheet metal part (2) with a shoulder surface (2o, 21) for the procedure is provided with the other sheet metal part to create a predetermined distance between the walls of the tunnel. 6. Heat exchanger element according to claim 5, characterized in that the sheet metal parts to one another in the Shoulder surfaces (2o, 21) are attached » 7. Heat exchanger element arrangement with an element according to one of Claims 1 to 6 _a dadmrcli characterized in that tubes (32) go through the openings (lo). 8. heat exchanger element arrangement according to claim 7s characterized in that the further tubes (3.2) have ribs (33). 9. Heat exchanger element according to one of claims i to 6, which is arranged in a boiler, characterized in that a source of hot gases (kk _t 46) allows hot gases to flow through the openings, (lo), so that through the tunnel ( 5) flowing liquid is heated. 109816/1368 Ιο. Heat exchanger element in a boiler arrangement according to Claim $, characterized in that the source of hot gases is formed by a similarly constructed burner element (44, 66). 11 .. Heat exchanger element ± in a boiler arrangement according to claim 9 or Io, characterized in that that the source of hot gas (44) is contained in a housing (4o) and on each side of Heat exchanger elements (45) is flanked, the are inclined towards each other above the source of hot gas (44) in an inverted V shape. 12. Heat exchanger element in a boiler arrangement according to claim 11, characterized in that two or more heat exchange elements (4, 5) are provided on each side of the source (44) of hot gas are. 13. Heat exchanger element in a boiler arrangement according to claim Io, characterized in that a vertically arranged burner element (66), which corresponds in structure to the heat exchanger elements, and at least one heat exchanger element (67) side Side arranged, and an air blower (65) combustion air down through the burner element (66) And allows the heat exchanger element (67) to flow. 14. Heat static element in a Boxler arrangement according to claim 13, characterized in that three vertically arranged burner elements (-66) are on the side Side in a flat triangular shape together with at least three associated heat exchanger elements (67) are arranged. 1-0981R / 13R8