DE3609452C2 - - Google Patents

Description

The invention relates to a heating system for at least one interior of a building, the outer wall construction of which delimits the interior Has large flow paths for forced air.

A heating system for buildings is known from FR-PS 25 09 441, at that in an insulating material that is between load-bearing walls and a Cladding wall is located, channels are formed for guiding air. The Channels formed in this insulating material can be different Have course, but are always between the bulkheads and outer shell, d. H. essentially in one plane.

It is also known from the prior art to have an outer side Difficult to create flow path in that on the outer masonry of an outer wall z. B. a slatted construction with air and Counter battens are applied, on which a new outer skin is then formed Planking in the form of panels, stones or the like is attached. Here must be very precise on processing and processing of different materials Value is placed so that the rear ventilation to be created also the desired  Forms flow path, which must form a closed unit in itself. Problems occur especially at the floor transitions and at the Inside and outside corner connections. So far it was only possible to use a so-called double-skin wall system in the form of a separate facing use what a very costly and expensive labor and materials included. With such a method, however, was only one Flow path created. A second flow path close to the interior had to go through an also complex and using air and counter battens inner wall paneling to be produced.

The invention is based, the energy economy in such a task Heating systems for exterior wall structures for both new buildings and to increase significantly in the renovation of old buildings and with this goal as possible to achieve little effort.

To achieve this object, the invention proceeds from the known state of the art Technology according to FR-PS 25 09 441 and is characterized by a flow path near the interior, a flow path near the outside and one middle flow path lying between these flow paths, the middle flow path and the flow path on the interior side with one another are connected that the air flowing along the central flow path in crosses the interior flow path after heating along the interior flow path and heat flows to the interior Interior-side shell limiting the flow path for the purpose of radiation  releases into the interior and then flows into the interior, and further the flow path near the outside in the case of a south aligned wall construction the middle flow path in terms of flow is upstream and in the case of a north-facing wall construction serves to remove the air extracted from the interior.  

The air duct in such an outer wall construction can designed in a constructively and technically simple manner using individual Hollow components, especially hollow components on the Basis of z. B. cement-bound wood chip material. Such Hollow components are referred to below as hollow blocks. They point in the vertical direction and if necessary adjoining one another in the horizontal direction, cavities partially fillable with hardening binder on. The respective flow paths can be skilful Exploitation of the monolithic hollow blocks can be obtained practically without additional effort.

When designing the heating system according to claim 2, the heat of the sun used in heating periods for heating, without a large installation effort got to.

Furthermore, it can be advantageous if according to claim 3 - for exploitation the residual heat content of the outflowing used air - those from rooms with particularly bad odors extracted air after heat exchange with the living rooms Fresh air or recirculating air above the outside Flow path of the north-facing wall construction into the Free is fired.

According to claim 6, there is the outer wall construction for a building that is heated by a is heated above, from steel block elements. The masonry that forms the outer wall is made preferably thus from only one containing the channels monolithic building material, namely the hollow block element. This advantageously eliminates the need another brickwork, d. H. it is according to the invention just a brickwork in front of both the foundation stone as well as the formwork in one. The through the entire outer wall in the form of a rear ventilation, flow path near the outside is advantageous with the fact that the at least one interior delimiting  Building can be surrounded with a heat curtain. A so-called cross-flow heat exchanger for z. B. every living day, even better for every living unit, increases the individual Treatment of the targeted air flow in the respective Exterior walls.

In a further advantageous embodiment of the invention also inside and outside corner stones with the invention provide flow path near the outside. So there is no interruption in the air flow between them connected outer walls.

For the renovation of old buildings, an additional wall construction is required, in which the respective hollow blocks, as well as the Inside and outside corners each with half-stone elements an air flow path according to the invention and z. B. an insulating body are formed. The mode of action  the rear ventilation and the air flow is as described compact hollow blocks. The air outlets in the outer wall can usefully and easily in z. B. the cornices of the individual floors can be installed.

According to a further advantageous embodiment of the invention are the hollow block elements on their faces with at least one Provide tongue and groove connection. For better and more precise processing of the hollow block elements the tongue and groove connections are doubled in each level executed. This in turn has the advantage that the Seams of the individual hollow block elements no from Backfilling the remaining voids to undesirable concrete Cold or thermal bridges can lead.

About the composite necessary for stability when building to obtain, it is necessary that the hollow block elements available in various dimensional versions stand. That means that the z. B. in length different hollow block elements at least one have a channel forming an outside flow path, which then varies according to the individual stone length Diversity in such a hollow block element can occur.

The basic aim of the solutions according to the invention is in the outer air duct a flow of one if possible to achieve a large proportion of the wall material. Continue the air flow in the individual flow paths must be as possible be kept tight to avoid any uncontrolled To maintain air flows between the individual flow paths.

The ventilated, created by means of the invention, self-supporting and monolithic outer wall construction offers excellent heat and sound insulation and is for all climates optimally cool in summer and optimal in winter warm. This ensures that the masonry is always dry and an associated healthy indoor climate.

The system for an outer wall construction resulting from the invention can be used both in single family house construction can be used for the multi-storey high-rise building. Indeed  it makes sense for a multi-storey house The outer walls of the individual floors are separate and separate to be provided with the ventilation according to the invention. Each Projectile would then have its own air intake or Air outlet. The mode of action is then the same as for one Detached house.

The invention is illustrated by one in the drawing Embodiment explained in more detail below. It represent

Fig. 1 shows an embodiment of the invention with an additional flow path, in each case on the outer side of the outer wall structure, applied to a detached house;

Fig. 2 shows another design option for the outer wall construction in a modification of Fig. 1;

Fig. 3 shows an embodiment of the hollow block element with z. B. two chambers, in a graphical representation;

Fig. 4 is a hollow block-outside corner in perspective view;

Figure 5 is a hollow block-internal corner in perspective view.

Fig. 6, in a modification of Fig. 3, a hollow block half-stone element in a diagrammatic representation;

Fig. 7 in a modification of Figure 4, a hollow block half-stone outside corner in a diagrammatic representation.

Fig. 8, in a modification of Fig. 5, a hollow block half-stone inside corner in a diagrammatic representation;

Fig. 9 shows the air flow path through a built with the inventive hollow block elements and outer wall

Fig. 10 is a flow scheme according to the embodiment of FIG. 1.

According to FIG. 1, a further flow path 111 S is provided outside of a central flow path 120 , namely a flow path 111 S close to the outside, which, as the arrow direction in the left half of FIG. 1 shows, flows through from bottom to top. This flow path leads to a cross-flow heat exchanger 146 , e.g. B. in the storage room of the house. It is believed that the left wall construction of the house in Fig. 1 faces south, ie is exposed to the sun. Therefore, preheating of the air drawn in at 113 occurs in the flow path 111 S near the outside before it flows to the cross-flow heat exchanger 146 , in order to then flow back into the middle flow path 120 .

In the example of Fig. 1, the wall construction shown on the right is directed north. The flow path 111 N near the outside is flowed through there from top to bottom and ends in an outlet to the outside, which is designated by 115 . Through this flow path 111 N , the air drawn off from the odor-laden rooms flows, provided that after the heat exchange in the cross-flow heat exchanger 146 with the sucked-in air it still has a usable heat content, so that this residual heat is released via the flow path 111 N near the outside to the north-side outer wall construction.

In the same amount and speed is against the inflowing air in z. B. living rooms, in wet rooms and kitchens, the used air is sucked off again, as shown in FIG. 1 at 150 . In the cross flow heat exchanger 146 then this odorous poor air passes into the outer side flow path 111 near N and leaves the outer wall structure 117 N at outlet 115th

In FIG. 2, the external basement wall is shown, for example 110, whereupon the basement or floor slab is placed 112th Still lying on the basement outer wall 110 and adjoining the basement or storey ceiling 112 , it can be seen that a hollow block half-stone element or ceiling edge stone element 128 is used which, in addition to the insulation 114, forms the flow path 111 S or 111 N near the outside. In addition, as a masonry, the hollow block element 131 as a whole, in turn, in addition to the insulation 114 and for z. B. the concrete backfill 116 necessary chambers 118 of the flow path 111 S or 111 N near the outside can be seen.

Fig. 3 shows the hollow block element 131 with z. B. two recesses forming the flow path 111 S or 111 N near the outside and, in addition to the insulation 114, the chambers 118 necessary for the concrete filling 116 . The number of recesses that form the flow path 111 S or 111 N near the outside depends on the size of the hollow block element 131 .

The hollow block elements 131/132/133 have tongue and groove connections on their end faces 157/158 , meaningfully in a double version. A tongue-like recess 164 adjoins a tongue-like elevation 163 of the end face 157 . The order is reversed on the face 158 . Here follows a groove-shaped recess 164 'to a spring-like increase 163' . In addition to the tongue and groove connections on the end faces 157/158 , the horizontal surfaces 165/166 of the hollow block elements 131/132/133 again have sensible double tongue and groove connections. In the horizontal surface 165 z. B. to the groove-shaped recess 167 a spring-like elevation 168 . In contrast, in the horizontal surface 166 to the spring-like elevation 168 ', the groove-shaped recess 167' . The multiple arrangement of these tongue and groove connections ensures that the masonry hollow block elements 131-133 always give a good bond and that when the concrete is filled 116 into the chambers 118 they are always sealed and there is no leakage of the concrete, which leads to undesirable cold - or would lead to thermal bridges. Since the hollow block half-stone elements 128-130 do not have these chambers 118 , there is also no need for the double version of the tongue and groove connection. Only a simple tongue and groove connection is shown here and provided with the same reference numerals.

The hollow block elements 128-133 on which the invention is based, corresponding to FIGS. 2 to 8, have in the flow path 111 S / 111 N near the outside and spacer and air line strips in the form of connecting webs 119 which serve the entire hollow block element for stability and which make it possible to that a targeted air transverse guidance, the so-called cross ventilation of the outer wall 117 S / 117 N is given. Both the air drawn in at 113 and the air discharged again at 115 , as illustrated in FIG. 9, are each distributed over the entire outer wall 117 S / 117 N. Lattices 121 block the openings of the flow path 111 S / 111 N near the outside against possible ingress of dirt and possibly also small animals at 113 or 115 .

Fig. 2 with FIGS. 6 to 8 shows that the hollow block half-stone elements 128 to 130 can also be used as ceiling edge elements. This not only results in individual monolithic hollow block elements for the outer wall, but also creates an entire, self-supporting outer wall 117 S / 117 N that forms a monolith. The same applies to the renovation of old buildings with only hollow block half-stone elements 128-130 .

The use of the respective hollow block outer or inner corners 132/133 or hollow block half stone outer or inner corners 129/130 as a connecting element to the hollow block element 131 or hollow block half stone element 128 ensures that the flow path 111 S / near the outside 111 N can enclose a building on all sides.

The legs 123/124, 134/135 , 141/142, 143/144 can each have different lengths for the best possible processing of these hollow block outer or inner corners 132/133 or hollow block half-stone outer or inner corners 129/130 .

The hollow block outside and inside corners 132/133 and the hollow block half stone outside and inside corners 129/130 shown can be supplemented by hollow block arch elements which are not shown but which contain the inventive concept, or by elements which form the 90 ° shown. Corner formation also result in other angular positions.

FIG. 10 shows a flow diagram as can be used in connection with the exemplary embodiment according to FIG. 1. This flow diagram is explained below using the mode of operation for different operating modes.

In heating mode, for example in winter, the fresh air is drawn in at 113 and flows through the flow path 111 S near the outside, in which heat is absorbed by the air flowing through due to the solar radiation.

The heated in the outside near the flow path 111 S reaches z. B. via a valve V ₁, a fan 138 and a filter 154, 140 in the heat-absorbing part 146 a of a cross heat exchanger 146 and this in the middle flow path 120 of the outer wall structures, this flow path being flowed through from top to bottom. The air then flows through the flow path 122 near the interior, absorbing additional heat from a heater 136 . Finally, the air passes through the air outlet openings 126 into the living rooms on the one hand and the kitchen, bathroom and toilet, which are odor-laden on the other. The air is sucked in at 156 from the non-odor-laden rooms living room and bedroom and passes via a mixing valve V ₂ back to the blower 138 , so that the used but not odor-laden air with the fresh air arriving at V ₁ in a variable, as desired adjustable ratio mixed and regenerated in the filter 154 , 140 . In this way, part of the air from the non-odor-laden living spaces is recirculated again and again, which is favorable for the overall heat balance.

The relatively warm air extracted from the odor-laden kitchen, bathroom and toilet at 150 passes through a blower 148 and possibly a filter 125 into the heat-emitting part 146 b of the cross-flow heat exchanger 146 , where it gives off at least part of its heat content to the air that flows to the middle flow path 120 via the heat-absorbing part 146 a . Then the odor-laden air, which still has a certain heat content, flows via the valve V ₃ into the flow path 111 N near the outside of the wall construction north 117 N. The residual heat is given off to the Nord 117 N wall construction and forms the heat curtain. The air then flows out at 115 . In the Fig. 10 to the connecting webs 119, shown as distance and air line strips schematically recognizes.

Part of the extracted air from the rooms not exposed to odors can also be combined at the location of the valve V ₂ with the air coming from the rooms exposed to odors, if this, for. B. is necessary for heavy cigarette smoke in the living room.

If not heated, the outside flow path 111 S of the outer wall construction 117 S will be short-circuited and fresh air drawn in at 127 , which is possible through the changeover valve V ₁. The fresh air is in this case also passed through the cross-flow heat exchanger 146 , assuming that the inside temperature of the house is lower than the outside temperature of the air, e.g. B. on hot, sunny summer days, so that the sucked-in fresh air gives off heat to the air coming from the odor-laden rooms and possibly from the non-odor-laden rooms, which is discharged through the chimney 152 into the open.

Claims (9)

1.Heating system for at least one interior of a building, the interior wall-defining outer wall construction of which has large flow paths for forced air, characterized by a flow path ( 122 ) close to the interior, a flow path ( 111 S / 111 N ) close to the outside and one between these flow paths ( 122, 111) S / 111 N ) lying middle flow path ( 120 ), the middle ( 120 ) and the interior-side flow path ( 122 ) being connected to one another in such a way that the air flowing along the middle flow path ( 120 ) passes into the interior-side flow path ( 122 ), after heating along the interior-side flow path ( 122 ), heat flows to an interior-side shell bounding the interior-side flow path ( 122 ) for radiation to the interior and then flows into the interior, and furthermore the flow path ( 111 S ) close to the exterior in the event of a subsequent South facing wall con Structure ( 117 S ) is upstream of the middle flow path ( 120 ) and in the case of a north-facing wall construction ( 117 N ) is used to remove the air extracted from the interior. 2. Heating system according to claim 1, characterized in that the flow path near the outside ( 111 S ) in the case of a south-facing wall construction with an outer wall ( 117 S ) through which the sucked-in air flows preferably from bottom to top, this air optionally via a Heat exchanger ( 146 ) flows to the middle flow path ( 120 ). 3. Heating system according to claim 1 or 2, wherein the interior of several rooms, for. B. Living rooms, characterized in that the air extracted from particularly odor-laden rooms via a fresh air or recirculating air flowing from the living rooms to the heat exchanger the outside flow path ( 111 N ) of the north-facing wall construction with outer wall ( 117 N ) and supplied at the end of this flow path ( 111 N ) is released into the open (at 115 ). 4. Heating system according to one of claims 1 to 3, characterized in that the outside flow path ( 111 S , 111 N ) is designed as a flat channel with spacer and air duct strips connecting webs ( 119 ). 5. Heating system according to claim 4, characterized in that the connecting webs ( 119 ) in hollow block elements ( 131-133 ) or in hollow block half-stone elements ( 128-130 ) are provided and mutually at intervals from the one horizontal end face ( 165 ) once extend downwards and once from the other horizontal end face ( 166 ) and in particular protrude approximately halfway into the respective element ( FIG. 9). 6. External wall construction, in particular for a building heated by a heating system according to claims 1 to 5, consisting of straight or angled hollow block elements with incorporated insulation, chambers for concrete filling and flow path close to the outside, in particular made of cement-bonded chipboard material, characterized in that the walled-in material Assembling hollow block elements ( 131 ) or hollow block half stone elements ( 128 ) with hollow block outside corners ( 132 ) and / or hollow block inside corners ( 133 ) the flow path near the outside ( 111 S , 111 N ) is continued around the respective corner. 7. outer wall construction according to claim 6, characterized in that the end faces ( 157-162 ) of the hollow block elements ( 128-133 ) alternately with at least one but preferably with two or more tongue and groove connections ( 163, 163 '; 164, 164' ) are provided. 8. outer wall construction according to claim 6 or 7, characterized in that the horizontal surfaces ( 165, 166 ) of the hollow block elements ( 128-133 ) with at least one tongue and groove connection ( 167, 167 '; 168, 168 ) are provided. 9. outer wall construction according to one of claims 6 to 8, characterized in that the legs ( 123, 124; 134, 135; 141, 142; 143, 144 ) of the hollow block outer and inner corners ( 132, 133 ) or the hollow block - Half-stone outer and inner corners ( 129, 130 ) each have different lengths.