DE3227326A1 - Pressureless large-surface heating system - Google Patents

Abstract

Large-surface heating system with a flowable heat carrier, a pump for the circulation of this heat carrier, and large-surface heating elements, characterised in that the heat carrier is hydraulically separated by a heat exchanger in a known manner from the heating circulation of a central heating plant, and the pump housing simultaneously forms the housing of the heat transfer device and is exposed at its heat-releasing surface to the swirl of the pump rotor.

Description

DK 1790 / 3a

Pressureless large area heating system

I.

The invention relates to a large area heating system with heat exchanger elements from extruding hollow bodies and pumps.

It is known to use plastic pipes for underfloor, wall or ceiling heating which do not corrode, but which, like all organic materials, allow gases to pass through.

As oxygen dissolves in water, there is a steady increase in concentration of oxygen instead. This oxygen leads to corrosion damage in the boiler and in the Piping system. Like all plastics, these pipes also tend to Cold cracks form over the years so that the pipes can leak. The formation of cold cracks is a result of high specific deformation. The specific Deformation, in turn, depends on the pipe wall thickness and the bending radius. There are plastic pipes known in electrical installation technology that are very thin Have wall thicknesses that are corrugated, so that such pipes without significant specific deformation can be laid in very tight arcs.

The invention provides to use thin-walled hollow bodies, which are much cheaper than the plastic pipes that are customary today and which are significantly cheaper can be laid as rigid, thick-walled pipes. In addition, allow inexpensive Pipes are laid closer together, which means that they heat up almost without delay he follows. For large surface heating systems, however, thin-walled hollow bodies or rubber hoses have so far been ruled out because they do not deal with the pressure of the heating water have grown.

In order to avoid the above disadvantages, it is provided that the heat carrier circuit of the To separate large surface heating from the transformer with low heat capacity, so that the large surface heating heat transfer circuit works practically without pressure.

There are known heating systems, especially in connection with district heating which also have a heat exchanger. Such heat exchangers however, require a great deal of material and have a disruptively large heat capacity. In addition, the circulation pump not only has the frictional resistance e.g. in the pipes laid in the bottom of the barrel, but also to overcome the resistance in the coiled pipe in the heat exchanger. This increases the annual Power consumption increases significantly.

COPY

- r-

The invention therefore provides heat exchangers for large surface heating systems which can be manufactured with little material expenditure, therefore have a small heat capacity, and which do not generate any additional resistance and therefore work in an energy-saving manner. This is achieved according to the invention in that the surface of the actual heat transfer, e.g. a pipe coil, is acted upon by the swirl of the pump, whereby the convective heat transfer on the heat-emitting side of the heat exchanger pipes can assume the same values as on the heat-absorbing side, where the heat transfer due to the high The flow rate of the heat transfer medium on the heating circuit side has very high values.

The invention therefore consists in using thin-walled hollow bodies and these from the pressurized hot water line through a heat exchanger hydraulically operate separately. A particularly favorable embodiment provides a heat exchanger combined with the circulating pump to form a unit before. A heating resistor can also be arranged in the heat exchanger space will.

The invention is explained in more detail with the aid of the figures.

FIG. 1 shows a pump according to the invention in longitudinal section, in which the heating water flows through a coiled tubing arranged in the cylindrical outlet space of the pump is directed.

Figure 2 shows an arrangement in longitudinal section, in which the coiled tubing in the suction chamber the pump is arranged.

Figure 3 shows a section along the line IM-III.

FIG. 1 shows a method step for producing the helix.

Figure 5 shows an underfloor heating pipe with corrugation.

Figure 6 shows an extruded heating element as a large area heater.

Figure 7 shows an extruded plate.

FIG. 8 shows a plate according to FIG. 7 with a sheet metal support.

'BAD ORIGINAL

COPY

FIG. 1 shows that the water of the heating circuit, which is circulated by a heating pump, enters the coil tube 2 through the tube 1 and leaves the coil through the tube 3. The helix is located concentrically in a cylindrical pump housing 10 near the outer periphery of the same, so that a cylindrical interior 12 remains free. The large area heating is connected to the pump 11 via the pipes 4 and 5. The flow speed on the surface of the helix is 0.5 to 3 m per second, because despite the large cross section of the housing 10, a high relative speed is generated parallel to the coiled tubing 2 because the pump rotor 6 is arranged so that the outlet swirl 14 extends over the helix 8 developing in the same direction of rotation propagates upwards. Due to the high relative speed of the liquid to the coiled tubing 2, the high heat transfer is ensured, which is why only a small pipe length is required for the coiled tubing 2 and a small housing 10.

In the embodiment in Figure 2, the suction cup 17 of the rotor 6 'communicates with the interior of the housing 10 and in this way generates a suction-side swirl flow 16.

In FIG. 3, the cross section along the section line III-III in FIG. 1 is shown. The Snugleltung 4 runs in a spiral, so that the twist flow experiences only a small resistance. All connections 1, 3, 4 and 5 lead through the base ] 9 .

An improvement in the heat transfer through a larger surface with the same The length of the helix is achieved by designing the heat exchanger tubes with a flat cross section. For this purpose, according to the invention, a coiled tubing is made round tube 42 using conventional manufacturing methods. After that, the Coiled tubing axially compressed, which means that all tubes are evenly one Assume long-round cross-section 43.

Figure 4 shows a device in which two mold parts 40 and 41 under one is not press shown are driven against each other, and so the tube of the coiled tubing is deformed. After the flattened coiled tubing is removed from the device it has to be axially stretched a small amount so that a gap remains between adjacent turns.

COPY

Figure 5 shows a known thin-walled corrugated pipe, which according to the invention is used in connection with the heat exchange pump for underfloor heating. The non-bent areas are advantageously designed as a clatt tube 50.

FIG. 6 shows the cross section through tubes 60 which are produced simultaneously by means of extrusion and which are connected to one another by webs 61. As can be seen from the top view, these webs are subsequently provided with openings 62. They can be nailed in the areas 63 and the top layer of the floor structure can be glued to the layer below through the openings 62. At one end, the even tubes 60 are connected to the flow and the odd tubes to the return. At the other end, the even-numbered pipes are connected to the odd-numbered pipes via elbows or a common collecting pipe.

Figure 7 shows a double-walled sheet, also produced by extrusion, panel-shaped underfloor heating. The channels 70 can be penetrated with nails 73 for the purpose of fastening. The panels are at the ends closed by melting or gluing in strips 71. At one end is a trough-shaped collector 74 welded or glued to the side of the plate. This collector 71 has a partition wall 76 in the middle, as a result of which the flow area with the connector 77 is separated from the return area with the connector 78 is.

Breakthroughs 75 through the curtain surface 81 are provided within the tub 74, so that the channels 79, insofar as they are not penetrated by nails 73, communicate with the interior of the tub 74. The cross-sections of the openings 75 are smaller there where a dynamic pressure is formed in the channel element 74 than in the other areas. This ensures a uniform flow through all of the channels 79, 80 '. The heat transfer water enters via the connection stub 77 and leaves the large-area heating plate via the connection stub 78. At the other end of the cross-surface plot, the group of channels 79 that communicate with the connector 77 is connected to the group of channels 80 'that communicate with the connector 78. This requires, before the plate Vcrschliessen 83'herauszuschneiden through the strip 71, the webs 82 'across the width of the connecting channel. For better load distribution, the plate is given a support 84 'made of hard material. Sheet steel is particularly suitable for this.

COPY

Figure 8 shows the edge design IdUHg-. The edge strip 90 is offset by a sheet metal thickness and has a bead 89. On the left edge, an angle profile 91 is permanently connected to the sheet steel support 84 ′ along the seam 84. This angle profile also has a bead 85 which the bead 89 holds in a form-fitting manner. The width of the profile corresponds to the width of the edge strip 90, so that two adjacent panels are fixed to one another both in compression and in tension. The floor covering 86 is glued to the sheet steel support used for nailing.

It has proven to be advantageous to use an adhesive hydrolysis for the double wall sheets resistant material, e.g. PPO, blended with polystyrene or other plastic materials to use. It is also advantageous between the web plate and the sheet steel support Provide a layer of a viscous, non-evaporating liquid or a non-hardening paste, thereby reducing the shear forces between the sheet metal support and the floor can be enlarged.

COPY

Blank page

COPY

Claims (18)

'- / -' -: "■■" - ■ - ■ · "322732b claims 1. Large area heating with plastic material and in ceilings, Walls or floors can be integrated using a liquid heat transfer medium. penetrated channel-forming hollow bodies, one circulating the heat transfer medium Pump with a centrifugal impeller and a heat exchanger with a heat-emitting tube, the inlet side with the flow and the outlet side with the return of a pressurized hot water circuit is connected, characterized in that the compressive strength of the channels (50, 60, 79) is dimensioned for a pressure which is lower than that of the hot water circuit. 2. Large area heater according to claim 1, characterized in that the Channels are formed from rubber hoses. 3. Large area heater according to claim 1, characterized in that the Channels made of plastic pipe (50) are formed with a corrugated wall. 4. Large area heater according to claim 1, characterized in that the Channels are formed from tubes (60) integrally formed with one another by extruded strips (61). · 5. Large area heating according to claim 4, characterized in that the Strip (61) have a plurality of openings (62). 6. Large area heater according to claim 1, characterized in that one Double-walled sheet produced by extrusion and closed at both ends is used, the channels (79/80 ') of which via a collector (74) which is connected to the multi-wall plate is permanently connected, communicate with the connecting piece (77/78). 7. Large area heater according to claim 6, characterized in that one first plurality of channels (79) communicate with the flow-side connector (77) and a second multiplicity (80 ') with the return connection (78), and on the opposite end of the double wall plate through a channel 83 'hydraulically are connected to each other. COPY 8. large area agitation according to claim 6, characterized in that the The webs (82 ') are cut out of the web plate by a length sufficient to form a channel (83') before the end of the plate is closed. 9. Large area heater according to claim 6, characterized in that the Large surface heating element through a support plate 84 'made of a hard material, preferably sheet steel, is protected from inadmissible local loads. 10. Large area heater according to claim 9, characterized in that the Support plate 81 'through a non-hardening, viscous or pasty layer is connected to the double wall plate. 11. Large surface heating according to claim 9, characterized in that the support plate has stepped edge strips (90, 9 ~ \) . 12. Großflächecnhcizung according to claim 11, characterized in that the dnss Support plate on one side pocket-shaped, e.g. by means of an angle piece (91), is formed, and that the offset strip (90) has a projection (89) and the angle piece (91) has a projection (85), which cooperate Able to transfer tensile forces from plate to plate. 13. Large area heater according to claim 1, characterized in that the from Heat exchanger (2) through which heating water flows is arranged in the pump housing (10) and is exposed to the swirl (14/16) of the pump rotor (6/6 '). 14. Large area heater according to claim 13, characterized in that the outlet side of the pump rotor (6) communicates with the interior (12) of the housing (10) and that the outlet swirl (14) to increase the heat transfer is being used. 15. Large area heater according to claim 13, characterized in that the Suction side (17) of the pump rotor (6) mild interior (12) of the housing (10 communicates and that the inlet swirl (16) is used to increase the heat transfer. COPY 16. Large area heater according to claim 13, characterized in that the Tube cross-section of a round tube helix (42) brought into a flatter shape (43) by axial compression and then to generate a distance Pulled apart one turn to the next by a small amount will. 17. Floor heating according to claim 1, characterized in that the The heat exchanger (8) consists of a tube which runs on a helical line, the direction of rotation of which, when viewed from bottom to top, corresponds to the direction of rotation of the pump rotor (6) coincides. 18. Large area heater according to claim 1 and optionally 13, characterized characterized in that at least one electrical heating resistor is arranged in the pump housing (10). COPY