NL194684C - Hot air heating for a church room. - Google Patents

Description

1 194684

Hot air heating for a church room

The invention relates to a hot air heating for a church room, comprising a central heating device and a central blowing device, which via at least one air guide channel arranged below the church floor with at least one housing arranged in the church floor with an upwardly opening into the church room hot air outlet is connected.

A hot air heating of the type described above is known from practice. With the known hot air heating, the air to be led into the church space is heated in an air heating appliance which is arranged outside the church building in a separate heating cellar. The warm air is then guided via at least one elongated air guide channel extending into the floor below the church floor to a warm air outlet opening, via which the air is blown into the church room to be heated. The air is then sucked in again from the church space via one or more intake grilles as recirculated air and, if necessary mixed with fresh air, returned to the air heater. The walls of the air ducts extending, bricked or concreted into the soil must be provided with good heat insulation in order to prevent heat losses on the surrounding soil as much as possible (Gesundheitsingenieur, Vol. 15/16, 1957, p. 239-). 241). The church heaters described in this pre-publication are in the most favorable case applicable to new-build churches, since in the illustrated and described examples the hot air outlets are arranged near the wall and at a distance above the ground.

These known church heaters have a major disadvantage because they lead to considerable differences in temperature between the upper and lower air layers in the vertical direction, which leads to damage to organs, paintings, sculptures and other works of art. When the hot air is blown away from a point-shaped aperture at high speed, an unfavorable temperature layer build-up can sometimes occur, which sometimes even leads to damage to the vaults, since they are blown on and heated too intensively. In addition, this can lead to draft phenomena, which are particularly noticeable during the heating process due to the so-called "heating draft". The reason for this mainly consists in that the air blown into the room flows up to the roof, without a significant mixing of the blown out warm air with the colder ambient air of the church room and then the air against the cold outer walls and against the cold walls. usually very large window surfaces flows down again. Since the air is cooled when it flows downwards and a corresponding circulation is created as a result of the induction effect of the outflowing hot air, an airflow noticeable as an unpleasant draft arises across the bottom of the space. This unfavorable transverse flow cannot even be completely prevented even with an optimum distribution of several hot air outlets over the space, since the circulated air drawn out of the space can usually only be sucked back at one or two suction grilles.

The air guide ducts described in the preamble must now have at least a smallest creep dimension of approximately 65 x 60 cm for cleaning and checking thereof. With the usual heat requirement and the usual warm air temperatures, the speed with such channels is about 4 to 6 m / s. The manufacture of such large canals is not only extremely expensive, but in many cases - in particular in churches protected by monuments - impossible in view of the considerable ground work and the large floor surfaces to be broken up. It has therefore been attempted to replace the air ducts with tubes of very small diameter. This overcomes the difficulties described above with regard to the threat to the floor and any valuable floor covering on large surfaces and spaces, as well as the high manufacturing costs and the difficult maintenance, since the construction of such pipes is simple and less expensive. However, it was found that the air had to be released by the high pressure required because of the high speed of about 10 m / s, since, as stated above, the air may only be released from the grid at low speeds and without noise and pressure. come. In connection with such tubes, therefore, relaxation cabinets have been provided, into which the hot air tubes open out, from which the hot air comes out via the outlet grilles. In order to achieve the necessary relaxation and thus a correspondingly lower exit speed, a relaxation cabinet was proposed in accordance with German publication 2,227,630, with which it is possible to supply air in narrow passages with high speed into the church room with the required low speed and practically silent to to come out. Despite the high flow rate in the narrow channels, however, it has been found that here too, for reasons of profitability, it is not possible to dispense with heat insulation of the supply pipes laid in the soil.

German Pat. No. 2,925,121 now discloses a 194684 2 hot air heater specially developed for heating churches, which is designed without installing a central air heater and the air ducts connected to it that are poorly insulated and poorly insulated. This hot air heating consists essentially of a heat station formed by an L-shaped housing, in which a heat exchanger is arranged, which are connected via a supply line with heat energy, for example well-insulated pipelines for liquid or vapor-shaped heat carriers, to a suitable external heating plant. The air to be heated is sucked out of the church space by means of a fan arranged in the housing itself via a cold air inlet located just next to the hot air outlet, this is drawn through the heat exchanger and then actually returns to the church space as a hot one at the suction point. air blown out. This form of hot air heating satisfies all the requirements that can be imposed on a church heating and has been used with great success in the past, in particular for the heating of monumental churches.

It has now been found that in a series of applications, in particular in the modernization of the air heating of churches, which are provided with air ducts laid in the ground, the above-described solution with the so-called heat station is rarely possible. The invention therefore has for its object to provide a hot air heating of the type described in the preamble which operates with the same efficiency and profitability as a church heating built on the basis of heat stations.

This object is achieved according to the invention in that the central heating device is suitable for heating a liquid heat carrier, at least one heat exchanger connected to the heating device for the air to be heated is arranged, the heat exchanger is arranged near the hot air outlet, the supply conduit and the return conduit for the liquid heat carrier are laid between the central heating device and the heat exchanger in the air conduit channel, and the air conduit channel the supply conduit and the return conduit are Insulation-free.

A hot air heating constructed in this way has a number of advantages: with this construction of a hot air heating, the warm heating air to be led into the church space need no longer be centrally heated and then be guided through well-insulated air ducts to the outlet locations in the church space. On the contrary, the air is only transported as cold air to the outlet locations with the help of a blower. The heating only takes place near the hot air outlet, so that it no longer depends on the quality of any heat insulation that may be present from the air ducts, and that it can be removed, or that in the case of new construction or expansion of existing installations the air ducts without thermal insulation can be installed.

The use of a central blower standing outside the church room to be heated means that the drive and transport noise of the blower is shielded in such a way that noise nuisance no longer occurs in the church room. The supply and return pipes, via which the individual heat exchangers 35 are connected to the central heating device, are now no longer installed separately, but are led through the air duct to the heat exchanger. In the case of branched air ducts or air ducts with several consecutive hot air outlets, there is furthermore the possibility, compared to the traditional hot air heating with central air heating, that each heat exchanger to which a warm air outlet opening has been added has a separate supply and return line at the central unit. heating device, so that a targeted heat output can be set for each hot air outlet opening and thus the distribution effectiveness and the profitability with respect to the central air heating can be considerably improved. Surprisingly, it appears here that it is not necessary to provide these supply and return pipes arranged in the air ducts to the heat exchangers with an insulating jacket. Apart from the fact that it is very difficult to provide these tubes with aging-resistant, non-flammable heat insulation, the amount of heat delivered by the outer wall of the tube to the cold air flowing into the air duct does not give any amount of heat. heat loss ”, because on the one hand the" heat exchanger effectiveness "of the tubes that are plowed in the longitudinal direction by the cold air is very poor in relation to the amount of air to be heated, ie only small amounts of heat are absorbed. amount of heat absorbed in the air duct channel is not lost, since heat dissipation on the walls of the air duct ducts is practically equal to zero due to the hardly measurable temperature difference and correspondingly with the cold air in the space to be heated up to the heat exchanger and thus into the heat exchanger space is taken in. Another advantage of the hot air The heating according to the invention consists in that because of the loss of heat insulation of the air ducts, these can get a small cross-section, since it is not possible to crawl. This also makes it possible for the hot air heating according to the invention to use tubes prefabricated for the air ducts, for example from concrete or plastic, such as are customary for sewer ducts, for example. In the meantime, suitable, frequently tried-and-tested bushings for the pipe ends have been developed for these pipes, so that air ducts made from these pipes or from other prefabricated channels are protected against the ingress of groundwater. The use of smaller cross-sections also reduces the size of the trenches to be excavated in the bottom of the church space, so that, in combination with the simple construction of such pipes, the costs of installing such air guide channels are noticeably reduced.

In an embodiment of the invention, a hot air heater is intended, at least comprising a warm air outlet opening upwards into the church space, which opening is formed by a housing to be built into the bottom, a cold air inlet with a cold air inlet having a bottom. air duct is connected, and wherein the hot air outlet is covered with a discharge grille, wherein in the housing between the cold air inlet and the hot air outlet a closed barrier wall covering the entire flow cross-section is provided, which is provided with at least a aperture covered by a heat exchanger, and wherein, viewed in the direction of flow of the air, after the weir provided with the heat exchanger and in front of the outlet grille at least one flat air-permeable equalization resistor is provided, to which the warm air flow coming from the heat exchanger is supplied while deflecting . Because there is a storage space between the cold air inlet and the heat exchanger by arranging the closed dam wall, the cold air entering through the air guide channel is braked and at the same time a flow influencing the entire cross-section of the heat exchanger is effected. At the same time, the dam wall achieves a certain sound damping with regard to the residual noise of the central blowing device. Because the heated air is guided by an air-permeable equalization resistor with simultaneous deflection, a further reduction of the flow velocity occurs, so that the warm air entering the church space upwards into the church space is only the desired speed of approximately 1-2 m / s possession. The provision of an equalization resistor at the same time offers the possibility of compensating different flow losses in the air ducts in the case of a hot air heating with several hot air outlet openings distributed over the space, in order to achieve uniform exit speeds at all hot air outlets. By means of the equalization resistors, however, it is also possible, in certain places, for example side chapels with a small vault height, to further reduce the exit speed of the warm air by means of an increased equalization resistance. Another advantage of the embodiment of the hot air outlet according to the invention is that also for the relaxation of the cold air supplied via the air ducts, also at high flow rates, with respect to the relaxation cabinets known until now, only a relatively small building volume is needed. When applying a central air filter for the cold air to be heated, the equalization resistance 35 can be formed by a perforated plate. In the absence of a central air filter installation, the equalization resistance can be formed by a filter mat in another embodiment.

In a preferred embodiment of the invention, it is provided that the hot air outlet part of the housing is of a box-like design and extends at a distance from at least one housing wall in the housing, the equalization resistance being in a sleeve wall extending at a distance from the housing wall. and wherein the space between the housing wall and the tube wall forms a flow channel for the hot air. The tubular shape of the hot air outlet section has the advantage that areas of the housing still lying under the outlet grille can also be used for the relaxation of the air flow.

In a further advantageous embodiment of the invention it is provided here that the tube wall facing the heat exchanger extends remotely relative to this and comprises a closable opening. This device has the advantage that the heat exchanger is accessible from the hot air outlet openings for checking and / or repair purposes.

In another embodiment of the invention it is provided that the tube walls near the hot air outlet part are formed at least partially by the housing walls and that the equalization resistance forms the bottom of the tube which extends at a distance above the housing floor. This device makes construction possible with large passage cross-sections near the outlet grille. Furthermore, this construction form also permits devices with a so-called long shape, i.e. when the hot air outlets have the shape of an elongated narrow rectangle.

In another more advantageous embodiment of the invention it is provided that with a compensation resistor arranged laterally 55, the bottom of the tube is formed by a flat tray for receiving water.

This device has the advantage that the filtered warm air for deflection in the outflow direction 194684 4 can be guided over a water surface. This makes it possible to influence the air humidity in the church space in a targeted way. The relative humidity in the church space is a decisive condition variable for the moisture balance of the organs, of artworks made of hygroscopic material, e.g. wood, as well as from the chairs. It must be taken into account here that the humidification of the air from rooms in churches is limited by the single glazing that is usually present. At an air temperature of 15 ° C in a room, humidification at 60% relative humidity can only be maintained up to an outside temperature of approx. 5 °. When the outside temperature falls below this value, the dew point on the windows falls below, and dew water falls down, which can lead to major damage to the building. This applies in particular to all parts made of wood from organs, works of art and church chairs. As a hygroscopic material, wood exchanges moisture with the surrounding air. After a suitable equalization and adjustment time, a wood moisture level is established which is in equilibrium with the vapor pressure of a partially saturated vapor of the surrounding air (the relative humidity). For example, at a relative humidity of 60% and a temperature of 8 ° C, the wood moisture is 11%. If the relative humidity drops to 35% with the same temperature, then the equilibrium humidity level of the wood drops to 7% after a corresponding adjustment time.

Depending on the increase and decrease of the wood moisture, the wood swells or shrinks. When the relative humidity falls, the wood releases its moisture to the dry ambient air. This results in a moisture gradient from the surface to the center of the wood body, for example from a sculpture, so that, for example, layers of paint that are not stretchable crack and become detached. Due to the amount of water to be supplied via dry water during the heating period during dry frost months, it is possible to adjust the microclimate in the church space with respect to the air humidity in such a way that the aforementioned damage cannot occur with careful operation of the heating.

The invention is further elucidated on the basis of a schematic drawing of exemplary embodiments.

Herein: figure 1 shows the plan of a hot air church heating as a flow chart, figure 2 in vertical section an embodiment of a hot air outlet, figure 3 in horizontal section along the line III-III in figure 2 the hot air outlet according to figure 2 Fig. 4 shows a further embodiment of a hot air outlet in a plan view, Fig. 5 shows a vertical section along the line VV in Fig. 4, a hot air outlet according to Fig. 4, Fig. 6 shows in vertical section a modified embodiment of the hot air outlet. air outlet according to figures 4 and 5, figure 7 a further embodiment of the hot air outlet with equalization resistance 35 near the bottom, figure 8 a modified embodiment of the hot air outlet according to figure 7, figures 9 + 10 a further embodiment, figure 11 a modification of the embodiment according to figure 9, figure 12 an embodiment with a moisture container, figure 13 a simplified embodiment.

The church heater shown diagrammatically in a plan view in Figure 1 consists essentially of an air duct channel 1, which extends below the church floor as a brickwork, concrete or formed from prefabricated pipes. The air guide channel 1 and the associated branches 45 open horizontally in hot air outlets 2, 3 and 4, while the hot air outlet openings lie in one plane with the church floor and are covered with a grid (not shown here). At the inlet side, the air guide channel 1 is connected to a central blowing device 5, by means of which the air to be heated is pressed into the air guide channels 1. Air is drawn out of the church room to be heated via a suction opening 6 and returned via a relevant suction channel 7 to the blower 50, whereby fresh air can be mixed in via a connecting piece 8 from outside. In the exemplary embodiment shown, the walls of the air ducts 1 are designed without any heat insulation, since only cold air is transported through the air ducts.

Near the hot air outlets 2, 3 and 4, heat exchangers 9 are now provided, to which a liquid heat carrier, for example water, is supplied. For heating the liquid heat carrier 55, a heating device 10, for example a suitably dimensioned, gas or oil fired heating boiler, is installed in a separate heating space, which heating device is on the supply side via one or more pipelines 11 with the heat exchangers 9 of the individual hot air outlets connected.

5, 194684

The individual heat exchangers 9 are connected to the return of the heating device 10 via one or more return lines. In this case, it is possible that each heat exchanger of the individual hot air outlets is always connected to the heating device 10 via a separate supply line. Each heat exchanger 9 of the individual hot air outlets 2, 3 and 4 can also be connected to the heating device 10 via a separate return line 12. The provision of separate supply lines makes it possible to centrally adjust the heat exchangers with regard to the amount of heat to be supplied from the heating space, in order thus to guarantee an optimum supply of warm air to the wings of the church space in question. The special feature of such a hot air heater is that both the supply lines 11 and the return lines 12, via which the individual heat exchangers 9 are connected to the heating device 10, are laid directly through the air duct channel 1. Since laying in the air duct would force a non-combustible heat insulation of the supply and / or return pipes, heat insulation of these tubes is dispensed with, since it has been found that the heat dissipation of the tube walls to the ducts in the air duct 1, the cold air flowing in is low and, moreover, the amount of heat delivered to the air flowing in the air ducts 1 remains virtually completely present in the flowing amount of air, since the temperature difference with the channel walls is too small to flow away into the ground here. The foregoing description shows that when modernizing an existing air duct heating within the church space, only construction measures should be taken near the hot air outlets. Incidentally, the church floor 20 remains unaffected. All construction and assembly measures can always be carried out above the mouths of the air ducts 1 in the heating cellar or in the hot air outlets 2, 3 and 4. The assembly measures required for laying pipelines 11 and 12 can be carried out from outside. With crawlable air ducts, these building measures can also be carried out in the ducts themselves. The description of the warm air heating with reference to Figure 1 shows that, in connection with modernisations of existing church heaters, these can also be expanded. It is now possible, insofar as the composition of the church floor or the subsurface allows, to lay extra air ducts in the ground, whereby the necessary building measures can be kept to a minimum, for example by laying prefabricated pipes of concrete, plastic or of other prefabricated channels, which are connected to an existing air conduction channel as a branch and through which suitable supply and return pipes are laid for the liquid heat carrier. Since heat insulation of the air ducts is not necessary, the requirement of a crawlability can be dispensed with, so that pipes with a correspondingly reduced cross-section can be laid, the cross-section having to be adjusted only with respect to the amount of air transported and the air velocity. size.

In order to be able to limit the construction measures near the hot air outlets 2, 3 and 4 on the one hand, and on the other hand, even at high flow rates of the cold air in the air ducts 1, a low exit speed of the air from the hot air outlet opening of the respective hot air outlet. air outlet 2, 3 and 4, according to Figure 2, a housing 13 40 is always installed in the bottom near the end of the hot air outlet 2, 3 and 4, the warm air outlet opening 14 being connected to the end of the vertical housing part thereof. which is covered in the plane of the church floor by an outlet grille 15. The end of the other housing part lying in the bottom has a passage opening 16 into which the air guide channel 1 opens.

At a distance from the mouth of the air guiding channel 1, a weir wall 17 is arranged in the housing which covers the entire flow cross-section of the housing and which is provided with an opening 18. The heat exchanger 9 is now arranged in the 45 opening 18 of the weir wall 17 , which is connected to the central heating device 10 via the supply and return lines 11, 12. The horizontal part of the housing 13 is divided by the weir wall 17 into a weir space 20 for the cold air and a relaxation space 21 for the warm air.

In the vertically extending housing part 22 a tubular, warm-air outlet part 23 is now placed from above, which extends at a distance from the two longitudinal side walls 24. The space 25 between the tube part 23 and the longitudinal side wall of the housing forms a flow and relaxation channel for the warm air emerging from the heat exchanger 9, which first flows against the tube wall 26 facing the heat exchanger 9 and then becomes sideways to the space 25 deflected. The walls of the tube 23 facing the longitudinal side walls 24 are here at least partially designed as flat, air-permeable equalization resistors 27. These equalization resistors can be formed by a perforated plate if a central air filter is arranged near the blower 5. If this is not the case, the equalization resistance can also be formed by a suitable filter mat 194684 6.

The provision of the weir space 20 offers the possibility of having the air guide channels open into the housing not only in the longitudinal direction but also sideways, as this is indicated in striped form in figure 3.

Figures 4 and 5 show a modified embodiment of the housing according to Figure 2 in a horizontal section and a vertical section. The shape of the weir space 20, the arrangement of the weir wall 17 with the heat exchanger 9 as well as the basic construction of the housing correspond to the shape according to figures 2 and 3, so that the same parts are given the same reference numbers here.

The difference with respect to the embodiment according to Figs. 2 and 3 is evident from the vertical section in Fig. 5. In this case, with a shape of the housing, wherein the longitudinal side walls 24 are parallel to the corresponding side surfaces of the air discharge opening 14, the tube 23 indented at some distance below the outlet grille 15, so that here too the air conduction and relaxation channels 25 are formed, which are closed towards the sleeve by the flat equalization resistors 27. At some distance below the outlet grille 15, guide vanes 28 are expediently arranged near the hot air outlet, through which the rising hot air flow is pulled apart over the entire width of the outlet grille 15. In this and the following exemplary embodiments, the supply and return lines 11, 12 are not shown in each case.

Both in the embodiment according to figures 2, 3 and in the embodiment according to figures 4, 5, the closed tube wall facing the heat exchanger 9 is provided with an opening closable by a door 29, so that via the hot air outlet opening after removal of the outlet grille 15, the heat exchanger 9 is accessible for checking and repair purposes.

Figure 6 shows a "longitudinal version" of the embodiment according to Figures 2 and 3, which can also be manufactured in the embodiment as described with reference to Figures 4 and 5.

Such a longitudinal version is then important if, for structural reasons, the air outlet opening 25 with its outlet grille 15 can only be designed as a rectangle. Similar components are designated by the same reference numerals, so that reference can be made to the embodiments of Figures 2, 3 and Figures 4, 5, respectively. Figure 6 furthermore shows the possibility that a dampening plate 30 covering the mouth section of the air duct 1 can be provided in the storage space 20 with a sound deflection, so that the flow of the cold air entering the housing onto the cold air entering by the arrow 31 indicated way. Such a sound deflection can also be used in the embodiments according to figures 2 and 3, respectively. Figures 4 and 5 are used in the weir space 20.

Figure 7 shows a constructional form in which the box-like shaped hot air outlet part 22 is formed laterally by the longitudinal side walls 24 of the housing 13, while the equalization resistance 27 forms the floor of the tubular part, which ends some distance above the housing floor 32. The arrow 31 shows the course of the air flow within the housing and around a sound deflection 30 placed in the weir space 20. The application of the equalization resistance, which can also be designed here as a perforated plate or as a filter mat, ensures an even distribution of the warm air flowing down into the hot air outlet. In the exemplary embodiment shown, the equalization resistance 27 is hingedly coupled to the housing, so that the equalization resistance for checking and / or repair work can be pivoted upwards, as indicated by the relevant arrow.

The tube wall 26 facing the heat exchanger is also rotatably connected to the housing, so that the heat exchanger 9 is accessible after pivoting upwards in the direction of the arrow. This part of the wall can, as is shown diagrammatically, also be provided with sound insulation, in order to prevent noise transmission from the air ducts in the warm air outlet. This also applies to the 45 embodiments described above.

Figure 8 also shows the embodiment according to Figure 7 in a so-called longitudinal version.

A further embodiment is shown in Figure 9 in longitudinal section and in the corresponding cross-section according to Figure 10. In this embodiment, the cold air emerging from the air guide channel 1 into the storage space 20 is propelled up again by a weir wall 17, which carries the heat exchanger 9 50. The air warmed up in the heat exchanger is deflected in the vicinity of the bottom wall via the shaft wall 26 facing the weir wall 17 and thereby relaxed, so that it can rise via the two roof-like equalization resistors 27, as shown in FIG. 10. .

Fig. 11 shows a modification of the device according to Figs. 9 and 10. The heat exchanger 55 is herein arranged horizontally beneath the two equalizing resistance resistors 27, wherein the closed walls 33 forming the bottom of the tube serve simultaneously as a barrier wall.

In the embodiment shown as a longitudinal version in Figure 12, the bottom is of the box-like one

Claims (9)

1. Hot air heating for a church room, comprising a central heating device and a central blowing device, which is connected via at least one air guide channel arranged below the church floor to at least one housing arranged in the church floor with a warm air outlet leading upwards into the church room, characterized in that the central heating device is suitable for heating a liquid heat carrier, at least one heat exchanger (9) connected to the heating device is arranged for the air to be heated, the heat exchanger is arranged near the hot air outlet, the supply line (11) and the liquid heat carrier return line (12) are laid between the central heating device (10) and the heat exchanger (9) in the air duct (1), and the air duct (1) the feed line (11) and the return line (12) are insulation-free. Hot air heating according to claim 1, characterized in that in the housing (13) between the cold air inlet (16) and the hot air outlet (15) a barrier wall (17) which covers the entire flow section and is closed by at least one a heat exchanger (9) covered aperture (18) is provided, and which, viewed in the direction of flow, behind the weir wall (17) provided with the heat exchanger (9) and at least one flat air-permeable equalization resistor (15) before the hot air outlet (15) 27) is provided to which, under deflection, the warm air stream coming from the heat exchanger (9) is supplied. Hot air heating according to claim 1 or 2, characterized in that the equalization resistance (27) is formed by a perforated plate. Hot air heating according to one of claims 1 to 3, characterized in that the equalization resistance (27) is formed by a filter mat. Hot air heating according to one of claims 1 to 4, characterized in that the hot air outlet part (22) of the housing (13) is of a tubular design and is spaced apart from at least one housing wall (24) in the housing ( 13), wherein the equalization resistance (27) is arranged in a tube wall (23) extending at a distance from the housing wall (24), and wherein the space between the housing wall (24) and the tube wall (23) is a flow channel (25) forms for the warm air. Hot air heating according to one of claims 1 to 5, characterized in that the tube wall (26) facing the heat exchanger (9) extends remotely relative to this and comprises a closable opening (29). Hot air heating according to one of claims 1 to 6, characterized in that the tube walls near 194684 8 the hot air outlet part (22) are formed at least partially by the housing walls and that the equalization resistance (27) forms the bottom of the tube , which extends at a distance above the housing floor (32). 7 194684 hot air outlet designed as a container 34 for receiving water. The walls of the tube facing the longitudinal side walls are formed either by the longitudinal walls of the housing or by their own walls arranged remotely therewith. In the exemplary embodiment shown, the end walls of the tube are each provided with equalization resistors 27, so that the air from the storage space 20 through the heat exchanger 9 enters the area 25 of the housing forming the relaxation and flow channels. At the transition through the equalization resistors 27 in the tube-like hot air outlet, moisture is delivered through the water surface at the tank 34 filled with water to the hot air passing over it and spread in the church room to be heated. Because, in the exemplary embodiment shown, the underside of the container is also circulated by hot air, the water vapor delivery from the container 34 to the hot air is even improved. The container 34 is herein filled from above through the outlet grille in accordance with the requirement for room humidity in the church room, so as to dry out wooden workpieces when the relative humidity in the church room drops to below 45% prevent targeted water supply. Figure 13 shows an embodiment for the hot air outlet, which in turn consists essentially of a housing 13, which with one end forms the hot air outlet opening 14, which is covered by an outlet grille 15. The air guide channel 1 opens at the other end above a passage opening 16 in the housing 1. The barrier wall 17 with the heat exchanger 9 is arranged at a large distance from the opening 16, preferably in the transition region to the hot air outlet opening 14, so that the barrier space 20 is already sufficient for the relaxation of the incoming cold air due to its length 20 supported by the passage resistance of the heat exchanger 9 and the filter mat 27, which acts as an equalization resistance, which is arranged below the outlet grille 15. The barrier wall 17 can be detachably attached to the housing 13 in order to be able to exchange the heat exchanger. Here too, sound-damping bodies 30 can be installed in the weir space 20 in the transverse or longitudinal direction. 25 Hot air heating according to one of claims 1 to 7, characterized in that with a compensation resistor (27) arranged laterally, the bottom of the tube is formed by a flat tray (34) for receiving water. Hot air heating according to one of claims 1 to 8, characterized in that at least one sound-absorbing element (30) is provided between at least the cold air inlet and the dam wall (17) provided with the heat exchanger (9). Hereby 12 sheets of drawing