DE4220385C1 - Heat exchanger station for renovation and/or extension of hot air heating in church - involves central hot air producer connected to underfloor air conducting channels, which issue into church via hot air outlet apertures - Google Patents

Abstract

The heat exchanger station has a bearer for a heat exchanger which is fed with a fluid heat carrier. The bearer (15) is tubular or box-shaped and at its end facing the air feed channel (1) is connected to the heat exchanger (11) and at its other end is provided with fixture means (16). The fixtures are formed by a partly all-round collar, which covers the cross-section of the air feed channel in the transition to the hot air outlet aperture (2). The bearer (15) in the flow direction of the air is connected behind the heat exchanger with a filter (18).

Description

The invention relates to a method for renovation and / or Extension of a hot air heater in a church has a central heating air generator with the in Floor below the church floor, with a thermal insulation lined air duct is connected, which via hot air outlet openings open into the church space to be heated.

For warm air heaters of the type described above the heating air to be introduced into the church interior heated by an air heater and then at least over an elongated one, in the floor below the base of the church floor-running air duct to at least one Warm air outlet opening out, through which they in the to be heated space is blown out. From the church interior the air is then passed through one or more intake grilles  sucked in again as circulating air and, if necessary, with Fresh air mixed, fed back to the air heater. The walls of the walled, bricked or concreted air ducts are now with a good one Provide thermal insulation to prevent heat loss to the surrounding Prevent soil as far as possible (health Ingenieur, issue 15/16, 1957, pp. 239-241).

It has now been found that contrary to the original assumptions made on the inner walls of the air duct aging channels for insulation used and expire here, so that the insulating effect in increasing diminishes and the heat consumption by an un reasonable measure increases. The problem here is that such remedial measures, d. H. removing the rotten insulation and the introduction of new insulation, is at most possible in cases where the air flow ducts from the front when installing the warm air ducts had been dimensioned in such a way that they can be crawled. In all cases where the air ducts have less cross have cuts, renovation measures are only possible It is possible to open the air ducts upwards. Such Measures, d. H. the "digging up" of the air ducts through the church floor is in one Variety of cases, even for church buildings that are in were built after the war because of the ver bound destruction of the flooring, such as the Destruction of artistically designed floors, not justifiable. The introduction of new thermal insulation in crawlable air ducts comes with a significant cost expenses connected, but here again no guarantee is given that the newly introduced thermal insulation do not age by disintegrating the binders.

The invention is based on the object of a method to create a flawless, affordable and also permanent renovation of church heaters at the beginning allowed designated type.  

The object is achieved in that the central heating air generator by at least one fan and a central heating device for heating a liquid gene heat transfer is replaced that the thermal insulation is completely removed from the air ducts, that in the area of the hot air outlet openings each a heat exchanger station with a heat exchanger through which the air to be heated flows is arranged by the heated liquid heat is acted upon carrier and that the feed pipe and Return pipe that connects the heat exchanger to the central Connect the heating device, each in the air duct be relocated. Such a remediation process has a number of advantages: Since the air ducts both from the end previously connected to the heating air generator as well as accessible from the warm air outlet opening the old thermal insulation can be relatively simple be completely removed regardless of whether the air duct can be crawled or not. Instead of now the air ducts with new thermal insulation to be lined is in the area of the hot air outlet a heat connected to a central heating device exchanger connected, so that the heating of the in the Warm air to be introduced into the church room only directly in the Area of the hot air outlet. In the air duct channels only cold air is transported, which over the walls of the air ducts practically no heat can be withdrawn. The forward and return pipes, over the individual heat exchangers with the central heating direction are now not routed separately, but are through the air duct to heat exchanger passed through. With branched air ducts or in the case of air ducts with several successive the warm air outlet openings is such a system advantageous because each heat exchanger that a warm air access opening is assigned, with a separate advance and return line to the central heating device can be closed, so that a targeted heat emission  set for each hot air outlet opening and thus the distribution efficiency and the economy the central air heating can be significantly improved. Surprisingly, it turned out that it is not necessary is the flow line laid in the air duct and return pipes to the heat exchangers with an insulation coat. Except for the fact that it is very difficult, even these pipes with an aging to provide permanent non-combustible thermal insulation, represents that of the outer wall of the pipes to the cold air flowing in the air duct Amount of heat does not represent a "heat loss" because, on the one hand, the "Heat exchanger efficiency", which is in the longitudinal direction of of the cold air around the pipes in relation to the air quantities to be heated is very bad, d. H. just small amounts of heat are given off, go to the other those taken up by the cold air in the air duct Amounts of heat are not lost as heat is given off to the Walls of the air ducts because of the hardly measurable Temperature difference is practically zero and demented speaking with the cold air in the room to be heated up to the heat exchanger and thus up to the one to be heated Be taken with you.

In a further embodiment of the invention, that in the area of hot air outlet openings, in flow Direction of the air seen, preferably before the heat build-up shear, means to equalize the flow in the Air duct can be used. By such means To even out the flow, large-scale Eliminate vortices in the air flow so that the heat build-up shear of the air to be heated over the entire heat flow through the exchanger surface is even. With air duct leave systems with several hot air outlet openings the pressure conditions in the Influence the area of the individual warm air outlets, so that overall an approximately uniform application  the individual heat exchanger is possible. As a means of The flow can be evened over the channel perforated sheets with cross-section, adjustable blinds flaps, rear silencers or the like are provided. But it is it is also possible to use a filter mat for this, which also, seen in the direction of air flow, behind which heat exchanger can be arranged. Through the backwater up in the area of the heat exchanger also results here the desired equalization of the flow both down visibly the reduction of large-volume turbulence as also with regard to the air volume flow.

In another embodiment of the method according to the invention rens is provided for that covered by the heat exchanger Flow cross section is formed smaller than that clear cross section of the air duct. This will the flow cross section is constricted, which also leads to a backflow in the flow channel and thus improving the flow around the heat thaw schers leads.

The invention further relates to a heat exchanger station for warm air heating in a church, especially for implementation the restructuring process according to the previous claims, wherein the heat exchanger station one Has carrier for a heat exchanger which with a liquid Heat carrier is acted upon and is provided with means for equalizing the heating air flow.

While in the "classic" air duct systems in the area of the warm air outlet at most arranged a filter mat net, exists for warm air church heating where the air to be heated only by a fan through the Air duct system and in the area of the hot air outlet to be heated, the need here appropriate To provide internals, especially retrofit kits, the can be installed in existing systems without this requires construction work touching the church floor are.  

DE-29 25 121 C2 is a heat exchanger station known for a warm air church heating, in which in the Floor of the church interior is a housing with heat and sound insulated walls, which is an air inlet occurs, a warm air outlet and a fan as well a heating register to which a heating medium can be applied having. The heating register is arranged in a carrier and inserted into the housing. The supply of the heating registers with a liquid heat transfer medium from a central heating device is heated, takes place via Well insulated thin pipe laid separately in the floor cables. With this system, however, the one to be heated Air from the built-in fan at the point sucked into the room where the warm air comes back in the room is initiated. The installation of such Warming station requires considerable structural measures.

For the renovation of warm air heating in churches with air ducts otherwise the same, difficult to solve requirement must suffice, as described in the above Publication are set out in detail, however Systems are provided that are practically without the churches construction measures in contact with the floor can be used.

According to the invention, this object is achieved by that the carrier is tubular or box-shaped and at its end facing the air duct with connected to the heat exchanger and to its other End is provided with fasteners. This arrangement allows to wear the carrier through the usually with a removable grille covered warm air outlet to use. The warm air outlet is here usually shaft-shaped, the air guide channel in the shaft-shaped warm air outlet opening on the side. The carrier with the heat exchanger can be placed laterally in the air duct be inserted so that the shaft-shaped part of the Warm air outlet opening free  remains and thus as a relaxation space, d. H. for reduction tion of the flow rate of the heated air serves. The carrier and the associated heat exchanger can also enter the shaft-shaped warm air from above outlet opening can be hooked so that the heat exchanger practically horizontal in the shaft-shaped warm air opening hangs, so that through the air duct air introduced the box-shaped part of the carrier laterally flows around and is first diverted downwards before it can rise up through the heat exchanger. With the help of such tubular supports it is also possible Use heat exchangers in hot air outlet openings, which have an elongated narrow bottom opening.

It is useful if the fasteners formed by an at least partially circumferential collar be the cross section of the air duct in Covering the transition to the warm air outlet opening. Hereby can the junction of the air supply duct reliable and be tightly sealed so that the incoming, Cold air to be heated only by the heat exchanger flows.

The use of such a box-shaped carrier has the further advantage that in the direction of flow of the air seen, a filter mat can be detached behind the heat exchanger can be used.

In a further embodiment of the invention, that an extension protruding into the air duct the carrier is provided, which with a the channel cross cut covering dam element is provided. The traffic jam ment can be done through a perforated plate or an adjustable one Venetian blind flap are formed. This dam element on the one hand brings about an equalization of the flow before they come into contact with the heat exchanger and This is because the degree of turbulence of the flow is considerable  is increased and thus a large number behind the damming element is generated by highly turbulent filaments that transfer the heat Improved transition between the heat exchanger and the air. At the same time can reduce the free channel cross cut the flow resistance can be influenced, so that in the presence of several hot air outlets openings over the dam element from each warm air The amount of warm air exiting the outlet opening can be specified in a defined manner is. This configuration also has the advantage that the carrier with the damming element as a solid component built into the outlet end of the air duct can be and that the heat exchanger, backdrop silencer and / or a filter via an associated second Carrier detachable for maintenance purposes with the baffle element supporting carrier can be connected.

The invention is based on schematic drawings of Embodiments explained in more detail. Show it:

Fig. 1 in a flow chart of a warm air church heating system according to the prior art before refurbishment,

Fig. 2 warm air church heating acc. Fig. 1 after the rehabilitation,

Shows an embodiment of the opening. 3 for a connected to a heat exchanger carrier for incorporation into the hot air outlet,

Fig. 4 shows another embodiment for a carrier with a heat exchanger,

Fig. 5 shows a modified embodiment of the carrier acc. Fig. 3

Fig. 6 shows a modification of the embodiment of the carrier. Fig. 4.

The church heating shown schematically in Fig. 1 essentially consists of an air guide duct 1 , which runs below the church floor in the form of a brick or concrete channel. The air duct and the associated branches mün the horizontally in the shaft-like hot air outlet openings 2 , 3 and 4 , the openings in the plane of the church floor and are covered with a grid not shown here Darge. On the inlet side, the air duct 1 is connected to an air heater 5 , for example gas or oil-heated, through which the air to be heated is conveyed by means of a fan 6 . Air is sucked out of the church space to be heated via a suction opening 7 and led to the air heater 5 via a corresponding suction duct 8 , fresh air being able to be mixed in from the outside via a connecting piece 9 .

The inner walls of the air duct 1 and the shaft-like outlet openings 2 , 3 and 4 are coated for thermal insulation with a thermal insulation material that aging no longer meets the requirements and thus leads to significant heat losses. The air ducts 1 were dimensioned so large in the construction of the air duct systems that they can be crawled, so that removal of the outdated thermal insulation material and the introduction of a new thermal insulation material, albeit with a lot of work, is possible.

In order to renovate such an air duct heater, the insulating material is first removed completely and without replacement from the air duct ducts 1 . In addition, the air heater 5 is removed and replaced by an appropriately dimensioned fan 10 that is connected on the suction side to the intake duct 8 . ( Fig. 2).

In each case in the area of the opening of the air duct 1 in the shaft-like hot air outlet openings 2 , 3 and 4 , heat exchangers 11 are used, which are acted upon by a liquid heat transfer medium, for example water. To heat the liquid heat transfer medium, a heating device 12 , for example a correspondingly dimensioned, gas or oil-fired heating boiler, is installed, which is connected on the flow side via one or more pipes 13 to the heat exchanger 11 of the individual hot air outlet openings 2 , 3 and 4 . The individual heat exchangers 11 are in turn connected to the return line of the heating device 12 via one or more lines 14 . It is possible that each Wärmetau shear 11 of the individual hot air outlet openings 2 , 3 and 4 is in each case connected to the heating device 12 via a separate feed line. Likewise, each heat exchanger 11 of the individual warm air outlet openings 2 , 3 and 4 can communicate with the heating device 12 via a separate return line 14 . The arrangement of separate flow lines allows the heat exchangers to be regulated centrally in the amount of heat to be supplied from the boiler room, in order to ensure optimal warm air supply to the church room.

The peculiarity of the renovation process is that the air ducts 1 are no longer thermally insulated after the insulation is removed, but that the air is conducted through the air ducts unheated and the heating only occurs directly in the area of the air outlet openings 2 , 3 and 4 . The further peculiarity of this remedial measure is then that both the supply lines 13 and the return lines 14 , via which the individual heat exchanger 11 are connected to the heating device 12 , are immediately moved through the air duct 1 . Since the laying in the air duct 1 would require a non-combustible heat insulation of the pipes, heat insulation of the supply and return pipes is dispensed with, since it has surprisingly been found that the heat emission from the pipe walls to the flowing in the air duct 1 cold Air is low and, moreover, the amount of heat given off to the air flowing in the air guide channels 1 is almost completely retained in the amount of air flowing, since the temperature difference to the channel walls is too low to flow into the ground here. A comparison between FIG. 1 and FIG. 2 shows that, with the exception of the assembly work in the area of the boiler room, which is usually located under the sacristy, no building measures need to be carried out within the church space which touch the church floor. All construction and assembly work can be carried out via the mouths of the air duct 1 in the boiler room or in the warm air outlet openings 2 , 3 and 4 . The assembly measures necessary in connection with the laying of the pipelines 13 and 14 can be carried out in the air guide channels themselves due to the creepability of the air guide channels 1 .

Characterized in that each warm air outlet opening 2 , 3 and 4 is assigned its own heat exchanger 11 , which can be precisely adjusted with regard to the amount of heat to be released, an optimal heat distribution can be achieved in the church interior to be heated.

The remediation process described above allows in addition, the expansion of existing plants, since it is now possible as far as the design of the churches on the floor or the floor, additionally Install air ducts in the floor, the here necessary construction measures can be reduced to a minimum can, for example, by laying prefabricated Pipes connected to an existing duct can be connected as a branch and then through the  appropriate supply and return pipes for the liquid Heat transfer media are laid. The special advantage of Use of prefabricated pipes made of concrete or PVC, such as those used for sewers are, or prefabricated channels without insulation, consists of that they have appropriate, versatile seals are each sealable on the pipe joints, so that these Pipes also secured against the ingress of groundwater are. Since the loss of thermal insulation in the Air ducts the need for creepability omitted, pipes with a correspondingly reduced cross be laid with the cross section only in relation to the required air volume and speed is to be measured. Accordingly, that for Relocation of the air duct necessary for the expansion trenches to be created in its dimensions turn out to be much smaller than usual, especially since a defined load when using such pipes availability is given.

For the sanitation method described above with reference to FIG. 2, it is now necessary to install the heat exchangers 11 in the existing shaft-like hot air outlet openings 2 , 3 and 4 , into which the air guide channels 1 open horizontally. In Fig. 3 is a corresponding arrangement Darge provides in a sectional view. Here, the heat exchanger 11 is fastened in a box-shaped carrier 15 , which is inserted from above into the shaft-like hot air outlet opening 2 and is inserted into the horizontal mouth of the air duct 1 . The box-shaped carrier 15 is, depending on the design of the mouth of the air duct 1 in the Warmluftaus outlet opening 2 provided with a collar as a fastening means 16 with which the carrier 15 is fixed and at the same time the confluence in the warm air outlet opening is sealed at the edge. The cross-sectional shape of the carrier 15 corresponds approximately to the cross-sectional shape of the air duct 1 . Fig. 3 shows that the carrier 15 with the heat exchanger 11 attached to it can also be inserted through correspondingly narrow hot air outlet openings. The supply line 13 and the return line 14 , which are laid on the bottom of the air duct 1 , are expediently inserted into the carrier 15 via corresponding sealed openings, so that the heat exchanger 11 via hose lines 13 ', 14 ' releasably with pre and return line can be connected.

Seen in the flow direction of the air behind the Wärmetau shear 11 is expediently see a filter mat 18 , which is arranged so that it can be pulled out after removing the grille 19 closing the outlet opening upwards.

In a modification of this embodiment, according to Fig. 4 of the carrier 15 but also be hung from above into the opening, so that the heat exchanger 11 lies horizontally in the shaft-like hot air outlet opening and the air flowing in laterally via the air supply duct 1 flows around the carrier 15 , is deflected downward and only then vertically after can flow through the heat exchanger 11 above. At the top, the arrangement is covered again by a filter mat 18 below the grid 19 .

In Fig. 5, a further modification of the embodiment is gem. Fig. 3 shown. Here, in addition to a rohrförmi gene carrier 15 , which carries the heat exchanger 11 , an additional Licher carrier 15 'is provided which is provided at its end in the air guide duct 1 end with a free cross section of the tubular carrier 15 ' covering dam element 20 . This damming element 20 can either be formed by a perforated plate or by a plurality of adjustable louvre flaps, so that the amount of air flowing through can be adjusted. The connected to the dam member 20 carrier 15 'is fixed and the mouth of the air duct 1 anchored sealingly, while the heat exchanger 11 provided with the carrier 15 is releasably attached to the carrier 15 ', so that the heat exchanger 11 for maintenance and repair purposes in the shaft-shaped warm air outlet opening can be pulled out.

Since the filter mat must be replaced more often 18, the filter mat 18 is secured to the top can be pulled out to the carrier 15 as well.

The method described above is primarily intended for the renovation of existing air duct heaters. It can be done in the same way and with the same advantage also for new buildings, because the fact that the air ducts to create without thermal insulation len, also offers special advantages here. As in the extension described above can be used for Air ducts are now prefabricated pipes as they are as standard as sewage pipes in a wide variety Cross sections are available to be used the additional advantage is that on the one hand also prefabricated branches and manifolds are available and also for the laying of such Pipes also have reliable sealing systems for the pipe joints are a reliably sealed installation itself enable in groundwater endangered areas. Since the crawlability is also dispensed with can, the channels can be laid with smaller cross-sections be so that the earthworks, be it in the expansion in connection with a renovation, be it one New construction, can be significantly reduced. The cross sections of "main channels" and branching "side channels" can be coordinated with each other in a simple manner since for prefabricated pipes corresponding diameter gradations and matching connectors are available.  

Another advantage of the renovation ver invention driving is also that as a result of the funding of cold air through the duct system stronger branching Possibilities exist as before, because in remote Warm air outlet openings, for example in the area of side chapels, the pressing of the main fan by using a small additional fan reduced performance to overcome pressure drops can be used as a support. In the area of warm air outlet openings must have reduced duct cross-sections however, be made sure that the warm air is a there is enough space for relaxation, so that the warm air with little flow velocity leaks into the church space to be heated.

In FIG. 6, a modification of the embodiment according to the box-shaped carrier. Fig. 4 shown. In this case, the carrier 15 has an opening 21 in a side wall which faces the air duct 1 . The heat exchanger 11 is attached to the inner wall, so that the carrier 15 can be used from above in the warm air outlet opening in the floor. The load can be taken up via adjustable floor support elements 22 , so that the collar 16 has essentially only one sealing function.

Claims (8)

1.Procedure for the renovation and / or expansion of a warm air heating system in a church which has a central heating air generator which is connected to air duct channels which run in the floor below the church floor and are lined with thermal insulation and which open out into the church room to be heated via hot air outlet openings, characterized in that the central heating air generator is replaced by at least one blower and a central heating device for heating a liquid heat carrier, that the thermal insulation tion is completely removed from the air guide channels, that in the area of the hot air outlet openings each have a heat exchanger station with a heat exchanger through which the air to be heated flows is arranged, which is acted upon by the heated liquid heat transfer medium and that the feed pipe and the return pipe, which connect the heat exchanger to the central heating device, each in de n Air ducts are laid. 2. The method according to claim 1, characterized in that that the flow pipe and the return pipe insulation-free be relocated. 3. The method according to claim 1 or 2, characterized in that in the area of the hot air outlet, in flow seen in the direction of the air, preferably in front of the heat exchanger, Means for equalizing the flow in the air flow channel.   4. The method according to claim 1, 2 or 3, characterized net that the flow cross covered by the heat exchanger cut is made smaller than the clear cross section of the air duct. 5. Heat exchanger station for warm air church heating in a church, in particular for carrying out the sanitation method according to claims 1 to 4, wherein the heat exchanger station has a carrier for a heat exchanger which is acted upon by a liquid heat transfer medium and is provided with means for equalizing the heating air flow , characterized in that the carrier ( 15 ; 15 ′) is tubular or box-shaped and is connected to the heat exchanger ( 11 ) at its end facing the air duct ( 1 ) and is provided with fastening means ( 16 ) at its other end. 6. Heat exchanger station according to claim 5, characterized in that the fastening means ( 16 ) are formed by an at least partially circumferential collar which covers the cross section of the air duct ( 1 ) in the transition to the hot air outlet opening ( 2 ). 7. Heat exchanger station according to claim 5 or 6, characterized in that the carrier ( 15 ; 15 ') seen in the flow direction of the air behind the heat exchanger ( 11 ) is connected to a filter ( 18 ). 8. Heat exchanger station according to one of claims 5 to 7, characterized in that in the air duct ( 1 ) protruding extension of the carrier ( 15 ') is provided, which is provided with a damper element covering the channel cross section ( 20 ).