LU87701A1 - WARM AIR HEATING EQUIPMENT FOR A CHURCH ROOM - Google Patents

Description

REVENDICATION DE LA PRIORITE de la demande de brevet / du modèle d'utilité

En RFA

You 11.4.89

No P 39 11 787.1 Mémoire Descriptif déposé à l'appui d'une demande de

BREVET D'INVENTION au

Luxembourg au nom de: Théod. mahr

SÖHNE GmbH Hüttenstrasse 27 D-5100 AACHEN pour: "Warm air heating device for a church room"

Description: Warm air heating device for one

Church interior

Description;

The invention relates to a warm air heating device for a church, consisting of a housing, the walls of which are provided with a heat and sound insulating material and which has a supply air inlet and a warm air outlet on the top, and is provided with at least one air fliter in the region of the supply air inlet , and in which the supply air inlet and the warm air outlet are arranged next to one another separated by an intermediate wall and are connected to one another via a flow channel running in the lower housing area, to which a blower and a heating register connected to an energy supply are assigned.

Church rooms can be heated from an economic and technical point of view practically only with an air heating system, whereby in the meantime it has started to install the warm air heating devices as a compact system in each case at the points in the floor where the warm air is blown out Should, so that the church floor is largely spared during installation and only the supply lines leading to the individual hot air heating devices in the form of power cables or insulated pipelines for a heat transfer medium are to be laid in the church floor. A very important requirement for church rooms is, on the one hand, that the warm air heating device described at the outset works practically "silently" and that, in particular, the blown out warm air exits at the lowest possible flow rate, so as to largely avoid cross stratification or cross currents and thus drafts. Such a warm air heater specially designed for heating a church interior is described in detail in DE-PS 29 25 121 with regard to the problems to be solved.

The invention is based on the object, starting from the arrangement described above, to provide a warm air heating device for church rooms which is improved in terms of installation, maintenance and operation, it being particularly important to achieve a uniform and noise-free hot air outlet.

This object is achieved according to the invention in that the upper opening formed by the inlet air inlet and the hot air outlet essentially corresponds to the length of the housing, but at least in the area of the hot air outlet has a smaller width in that the air duct is spaced below the level of the housing opening extends essentially over the length of the housing, so that there is an air distribution space underneath the supply air inlet and the hot air outlet, that at least in the area of the warm air outlet on at least one side of the air duct, a conduction space between the long side wall of the Housing and the air duct is arranged, which is connected to the air distribution space, that the air duct is provided with a warm air passage opening into the transition space, which preferably extends over the length of the transition space, that the air duct through an intermediate wall, preferably For example, the intermediate wall separating the supply air inlet from the hot air outlet is divided, which is provided with an opening which forms the air outlet of the fan and that the part of the air duct which runs in the region of the supply air inlet is provided at one end with at least one air inlet opening which is in the Channel interior the heating register is assigned. A warm air heating device designed in this way is not only simple in terms of design and therefore inexpensive to produce, but also has the advantage that the special design in the area of the hot air outlet with a relatively short design ensures a smooth, uniform flow over the entire cross section of the hot air outlet of warm air. In particular, the fact that the warm air emerging from the blower in the longitudinal direction emerges laterally into the conduction room and then flows upwards into the air distribution area and from there through the warm air outlet into the church room to be heated, is in all control phases of the blower, A perfect relaxation of the warm air jet is guaranteed, especially with full power. This means that there are only the smallest temperature differences in a vertical measuring axis, because the hot air escaping very quickly mixes with the surrounding room air. This is of crucial importance for the preservation of high-quality works of art in churches, such as figures, wall and / or ceiling frescoes as well as for the organ.

It is important here that the warm air exits the transfer duct into the air distribution space under the warm air outlet at a relatively high speed. The warm air is redirected and, with simultaneous relaxation in the transition area between the transfer duct and the air distribution space, forms a roller-shaped air vortex that extends over the entire length on the side of the air distribution space of the warm air outlet. This ensures that the warm air flows out slowly and evenly over the entire cross-section from the warm air outlet upwards.

In older-type heating stations, in which the rules of hot air heating mentioned in DE-PS 29 25 121 are not observed, the hot air emerges in the form of a so-called core jet, which is blown as a compact hot air jet up into the church interior, so that there are considerable temperature differences to the ambient air in the vertical measuring axis.

It is important here that, despite the absence of special silencers in the air distribution space, the arrangement works practically noiselessly, and that the pressure loss normally caused by the installation of silencers is eliminated. Since the blower is arranged in the part of the air duct which is closed off by the intermediate wall on the one hand and by the heating device on the other hand, the operating noises essentially caused by the blower are damped to such an extent that no disturbances can arise from these operating noises.

In a preferred embodiment of the invention it is provided that the warm air passage opening of the air duct runs essentially along the length of the air duct base. The elongated warm air passage opening thus formed causes that in all operating states, i.e. Both at partial load and at full load, the hot air jet emerging from the fan is inevitably deflected so that practically uniform flow takes place over the full cross-section in the transition space, so that the roller-shaped formation of the air vortex in the transition area between the transition space and air distribution space is further improved. Since the warm air passage opening is directed perpendicularly against the longitudinal side wall of the housing, which is lined with heat and sound insulation, the sound component coming out through the warm air passage opening is largely absorbed by the lining of the longitudinal side wall, so that practically no machine noise can escape to the outside.

In an advantageous further embodiment of the invention it is provided that in the area of the inlet air inlet on at least one side of the air duct, a conduction space is arranged between the long side wall of the housing and the air duct and that the air inlet opening is arranged in the side wall of the air duct facing the conduction space is. Here too, an opening arranged laterally in the air duct ensures that the noises largely attenuated by the closed arrangement of the blower in the air duct cannot reach the outside through the air inlet opening. Here, too, the soundproofed inner wall of the housing also acts as a silencer with respect to the air inlet opening.

In a particularly expedient embodiment, both in relation to the hot air outlet and to the supply air inlet, it is provided that transition spaces are arranged on both longitudinal side walls of the air duct. Such an arrangement results in multiply deflected symmetrical air flows both on the supply air inlet side and on the hot air outlet side. Particularly in the area of the hot air outlet, the two roller-shaped warm air swirls, which are aligned transversely to the longitudinal axis and are directed against each other in the air distribution space, are guided against one another, so that optimal swirling is achieved with further swirling and the grille closing the hot air outlet is evenly and slowly flowed through. This uniformly slow flow is particularly important for the heating effect, since immediately after exiting into the church interior there is already a mixing with the surrounding air, whereby in particular it is avoided that the warm air escaping as a "compact" jet up into the church interior is blown, but the mixing with the ambient air in the church has already taken place a few meters above the level of the warm air outlet.

In a further advantageous embodiment of the invention it is provided that the preferably plate-shaped air filter is arranged in the area of the inlet air inlet between the air distribution space and the transfer space. This arrangement has the advantage that the air distribution space and the conduction space are closed off from one another, so that an additional noise reduction is achieved by the arrangement of the air filter. Another advantage of this arrangement is that the air filter can be arranged outside the inlet air inlet and thus cannot be contaminated by coarse dirt falling in and by cleaning water, so that longer service lives, i.e. result in longer maintenance intervals for this part. It is particularly expedient here if the surface of the air filter runs essentially vertically below the side edge of the inlet air inlet. This has the advantage that the individual elements of the air filter can still be easily reached during maintenance work through the inlet air inlet after the grille has been removed and can therefore be easily replaced. The vertical arrangement has the effect that only the finest dust is retained in the filter material, while coarse dust can fall off the filter surface and then be easily extracted as coarse dirt during maintenance.

In a preferred embodiment of the invention it is provided that the ceiling and the side walls of the air duct are formed by detachably connected, preferably self-supporting insulation panels. The fact that the air duct is formed from insulating boards results in a small heat loss, since the amount of heat absorbed by the air when flowing through the heating register is practically full

Extent is given into the church space and is not undesirably derived by heat conduction and heat radiation in the building floor. The detachable structure has the advantage in particular for the area of the supply air inlet that, for example, the heating register and the blower are immediately accessible from above by simply removing the plate parts forming the ceiling. For assembly and repair work, this means in particular that both the heating register and the blower, both standing on the housing base, are easily accessible with simple lifting devices. The shape of the housing according to the invention allows a simple air duct composed of a few plate parts. The insulation panels are designed in the surface so that they have sound-absorbing functions. The limited by the insulation boards. Air-guiding ducts thus also represent silencers with very little pressure loss. The blower or fan is practically in a hood-shaped silencer.

In a further embodiment of the invention, it is provided that the ceiling of the air duct is covered with at least one dirt collecting tray both below the inlet air inlet and below the warm air outlet. The arrangement of a dirt collecting pan ensures; that no cleaning water can get into the area of the air duct. Another advantage is that the insulation panels forming the ceiling of the air duct can be walked on, especially for the more frequent air filter changes, since the dirt collecting shells on the air duct ceiling form a load-distributing tread surface.

In a further embodiment of the invention it is provided that the air filters are each formed by at least one frame formed with filter material, which rests against the associated wall parts in a sealed manner at the edge and which is preferably held in its operating position on the upper edge of the frame by at least one holding magnet.

Filter elements designed in this way can be replaced in a simple manner and without tools.

In a further embodiment of the invention it is provided that on the housing composed of at least two parts, the edges of the walls in the area of the dividing joints have a continuous, inwardly bent web, that the adjoining housing parts can be screwed together with the interposition of a permanently elastic seal and that the screw connections are arranged on the outside of the housing. This configuration has the advantage that in the case of the housing walls usually made of corrosion-resistant steel, the folds form a perfect, smooth-surface sealing surface for the parting line, since the screw connection is arranged on the outside of the building.

The width of the sealing surface, which is decisive for sealing, is not interrupted. The particular advantage of this arrangement, however, is that the housing in cases in which there was no risk of groundwater ingress when installing the housing in the ground, subsequently changing the groundwater level and penetrating the housing can still be sealed. This is done in that the inner edges of the inwardly bent webs can be welded watertight in place without the addition of welding material, for example in the TIG welding process. Since the wall parts on the inside are provided with a frame-shaped stiffener made of profiled tubes with regard to the side pressure acting on the side, this construction allows in extreme cases to deliver the housing in individual plates, which are then screwed together on site with the interposition of a seal and, if necessary, on the Can be welded tightly together on the inside. It is particularly expedient that the wall parts in the adjoining regions forming the dividing joint have mutually associated clamping claws which are provided on the outside and are provided with through holes for the screws.

The invention is explained in more detail with reference to schematic drawings of an exemplary embodiment. Show it:

1 shows a longitudinal section through a warm air heating device for a church room,

Fig. 2 shows a cross section. the line II-II in Fig. 1,

Fig. 3 shows a section. the line III-III in Fig. 1,

4 shows the detail "A" in FIG. 1 on a larger scale.

The warm air heating device shown in FIG. 1 in a vertical longitudinal section essentially consists of a housing 1, the walls of which are provided with a coating 2 made of a heat-insulating and sound-damping material. The housing 1 is provided on its upper side with a continuous housing opening 3, which is divided by an intermediate wall 4, which extends over the entire width of the housing down to the housing base. The intermediate wall 4 is provided on its upper edge with an adjustable fitting 5, through which the intermediate wall can be pushed up close to the support 6 for one grille each, which covers a warm air outlet 7 and a supply air inlet 8. The housing opening 3 is bounded in the area of the upper side by an adjustable frame 9, which makes it possible to align the grids exactly in the plane of the bottom surface 10. The housing opening 3 delimited by the frame 9 or the grating is dimensioned such that it is only slightly smaller in length than the length of the housing 1, but has a noticeably smaller width than the housing 1, as shown in the cross sections according to Fig. 2 and Fig. 3 can be seen.

The warm air outlet 7 and the inlet air inlet 8 are covered by the grilles.

A continuous air duct 11 is arranged on the bottom of the housing and is divided only in the region of the central transverse plane by the intermediate wall 4, which is provided with a passage opening 12 in the region of the air duct.

As can be seen from FIGS. 2 and 3, the air duct 11 is arranged such that it runs at a distance from the two longitudinal side walls 13 of the housing 1, so that a transition space 14 is formed between the longitudinal side wall of the housing and the air duct. Since the air duct in the floor area, i.e. that is, at a distance below the level of the inlet air inlet and the warm air outlet, an air distribution space 15 or 16 is formed above the air duct. In the area of the supply air inlet 8, the air distribution space 16 is separated from the transfer space 14 on both sides by frame-shaped filters 17 which are covered with a fine-pored, air-permeable filter material. As shown in FIG. 3, the frame-shaped filter elements are detachably inserted in such a way that they are folded down into the air distribution space 16 and can then be lifted upwards via the inlet air inlet. In the area of the upper edge, the filter elements 17 are connected to the housing via holding magnets 18.

In the air duct 11, which is divided into two parts by the intermediate wall 4, in the region of the air duct assigned to the supply air inlet 8, an air inlet opening 19 is provided at the front end on both sides, which opens out laterally into the transfer space 14. Immediately in the area of this air inlet opening, a heating register 20 is arranged in the interior of the duct, which extends over the entire cross section of the air duct and which is connected to a corresponding energy supply. This is a corresponding one for an electrically heated heating register

Power connection, in the case of a heating register charged with a liquid or vaporous heat transfer medium, this is an external boiler which is connected to the heating register 20 via correspondingly laid pipelines.

Also arranged in this part of the air duct is a preferably double-flow fan 21, which is connected with its pressure-side outlet opening to the opening 12 in the intermediate wall 4. The blower 21 is fixed in a vibration-isolated manner on a foundation frame 22 which is fixedly connected to the housing 1.

The part of the air duct 11 lying in the region of the warm air outlet 7 has warm air through openings 34 running on both sides along the bottom, which open out into the associated transfer space 14.

The ceiling and the side walls of the air duct are formed by individual plates, the plates 23 forming the ceiling resting on support frames 24 which are firmly connected to the housing.

In the area of the hot air outlet, the hot air passage opening 34 is practically formed by the lower edge of the plates 23 which run at a distance from the housing base 25 and which stand on corresponding supports 26.

On the top of the ceiling of the air duct, dirt collecting shells 27 are arranged both in the area of the inlet air outlet 8 and the warm air outlet 7, each of which covers the ceiling upwards and at the same time offer protection of the dam plate material if, after the grilles have been removed, the respective air distribution spaces 15 or 16 for inspection and cleaning purposes.

In operation, the supply air to be heated is drawn into the air distribution space 16 by the fan 21 and sucked through the air filter 17. The air in this case reaches the transfer space arranged to the side of the air duct 11 and initially flows essentially horizontally against the end face of the housing to the air inlet opening 19 and through this into the air duct 11. Here, the air is discharged through the heating register 20 Blower 21 sucked through and then blown as heated air into the part of the air duct 11 lying behind the intermediate wall 4. The air is still swirled inside the air duct interior and then passes laterally in the floor area through the warm air passage opening 34 into the transfer space 14. This transfer space 14 opens with its upper opening, which extends over the entire length of the air distribution space 15, against the ceiling part 36. The air is thereby deflected sharply into the air distribution space 15 and at the same time relaxed. Since the warm air flows through the transfer space 14 at a relatively high flow rate, a cylindrical vortex 35 is formed in the area of the ceiling part 36 on both sides of the housing. The two air vortices rotating in opposite directions meet in the middle. As a result, a uniform flow through the cross section of the warm air outlet is forced. For the above reasons, the width of the housing opening 3 is dimensioned such that the cross section of the transfer space 14 is covered by the cover part 34.

The course of the air flow is indicated in FIGS. 1, 2 and 3 by arrows.

In the exemplary embodiments shown, the housing 1 is designed to be somewhat longer in the longitudinal direction than the housing opening formed by inlet air inlet and hot air outlet. This end area located above the supply air inlet 8 of the air duct 11 can be used for receiving one or more switch cabinets 37.

The housing has an essentially cuboid shape and is completely let into the floor, the floor covering covering the upper edge region of the housing extending up to the housing opening, as can be seen from FIGS. 1 and 2. In order to facilitate the transportation of this relatively large cuboid housing, it is expediently produced in at least two parts, which are then connected to one another in a watertight manner on the construction site before being inserted into the excavated pit. In FIG. 4, the area identified by "A" in FIG. 1 is shown on an enlarged scale. The separating joint 28 running in this area in a vertical plane is formed in that the walls 29 made of stainless steel sheet each have an inwardly bent web 30 and that an intermediate layer 31 of a permanently elastic seal can be arranged between the smooth-faced end faces thus created . On the outside, the walls 29 are provided all around and at intervals with clamping claws 32, so that the two housing parts can be clamped together by means of clamping screws 33 while compressing the sealing intermediate layer 31. If the groundwater level is high or if the groundwater level changes subsequently, the inner edges of the webs 30 can also be subsequently welded tightly together, so that it can in any case be ensured that no groundwater can penetrate into the interior of the housing. lg-ks

Claims (11)

Expectations: 1. Warm air heating device for a church, consisting of a housing, the walls of which are provided with a heat-insulating and sound-absorbing material and which has a supply air inlet and a warm air outlet on the top, and is provided with at least one air filter in the area of the supply air inlet, and in which the supply air inlet and the warm air outlet are separated from one another by an intermediate wall, are arranged next to one another and are connected to one another via an air duct running in the lower housing area / to which a blower and a heating register connected to an energy supply are assigned / characterized in that the upper opening (3) formed by the supply air inlet (8) and the hot air outlet (7) essentially corresponds to the length of the housing (1), but at least in the area of the hot air outlet (7) has a smaller width that the air duct (11) by far below the level of the go The housing opening (3) extends essentially over the length of the housing (1), so that an air distribution space (15, 16) is provided below the supply air inlet (8) and the warm air outlet (7), at least in the area of the warm air outlet (7) on at least one side of the air duct (11) a transfer space (14) between the longitudinal side wall of the housing (1) and the air duct (11) is arranged, which is in communication with the air distribution space (15) that the air duct (11) is provided with a warm air passage opening (34) opening into the transfer space (14), which preferably extends over the length of the transfer space (14), that the air duct (11) through an intermediate wall, preferably the inlet air inlet (8 ) from the warm air outlet (7) separating partition (4) is divided, which is provided with an opening (12) which forms the air outlet of the blower (21) and that the part of the air duct running in the area of the inlet air inlet (8) anals (11) is provided at its front end with at least one air inlet opening (19) to which the heating register (20) is assigned in the interior of the air duct. 2. Warm air heating device according to claim 1, characterized in that the warm air passage opening (34) of the air duct (11) extends substantially along the length of the air duct base. 3. Warm air heating device according to claim 1 or 2, characterized in that in the area of the supply air inlet (8) on at least one side of the air duct (11) a transition space (14) between the longitudinal side wall of the housing (1) and the air duct (11) is arranged and that the air inlet opening (19) is arranged in the side wall of the air duct (11) facing the transfer space (14). 4. Warm air heating device according to one of claims 1 to 3, characterized in that transition spaces (14) 'are arranged on both longitudinal sides of the air duct (11). 5. Warm air heating device according to one of claims 1 to 4, characterized in that the preferably plate-shaped air filter (17) is arranged in the region of the inlet air inlet (8) between the air distribution space (16) and the transfer space (14). 6. Warm air heating device according to one of claims 1 to 5, characterized in that the surface of the air filter (17) extends substantially perpendicularly below the side edge of the inlet air inlet (8). 7. Warm air heating device according to one of claims 1 to 6, · 'characterized in that the ceiling and the side walls of the air duct (11) are formed by detachably connected, preferably self-supporting insulation panels (23). 8. Warm air heating device according to one of claims 1 to 7, characterized in that the ceiling of the air duct (11) both below the supply air inlet (8) and below the hot air outlet (7) is covered with at least one dirt collecting tray (27). 9. Warm air heating device according to one of claims 1 to 8, characterized in that the air filters (17) are each formed by at least one frame covered with filter material, which rests against the associated wall parts in a sealed manner and which preferably passes through the upper edge of the frame at least one holding magnet (18) is held in its operating position. 10. Warm air heating device according to one of claims 1 to 9, characterized in that the housing (1) composed of at least two parts, the edges of the walls (29) in the region of the dividing joint (28) a continuous, inwardly bent web (30) have that the adjoining housing parts can be screwed together with the interposition of a permanently elastic seal (31) and that the screw connections are arranged on the outside of the housing. 11. Warm air heating device according to claim 10, characterized in that the wall parts in the adjoining, the dividing joint (28) forming area lying on the outside, assigned to each other and provided with through holes for the screws claws. lg-ks