DE3836843A1 - BURNER-HEATED UNIT, IN PARTICULAR WATER HEATER - Google Patents

Abstract

In a burner-heated apparatus with a heat exchanger (3) which is arranged in the waste gas guide (2) of the burner (1), which leads to a chimney (5) or similar waste gas take-off, and is flowed through by the waste gases of this burner (1), a portion, which can be selected as required, of the waste gases from the combustion chamber (8) is conducted directly into the chimney (5) or similar waste gas installation, in order that the temperature there is not allowed to fall below the dew point and as a result the formation of condensate is prevented. The size of this waste gas portion to be conducted off directly into the chimney (5) or similar can be defined from case to case taking the respective local conditions into consideration. The supply of uncooled waste gases can take place via a bypass guide (9) or the heat absorption capacity of the heat exchanger (3) can be reduced selectively. <IMAGE>

Description

The invention relates to a burner-heated device, in particular another a water heater, with one in the to a fireplace or. Like exhaust gas discharge leading exhaust burner arranged, through which the exhaust gases of the burner flow exchanger.

The object of the invention is to prevent a consequence Falling below the dew point condensation in the fireplace. Such condensation creates an all gradual sooting of the chimney, which covers the chimney wall destroyed and their costly renovation forced.

The invention is based on the knowledge that to prevent This condensate formation depends on the local area Texture of the fireplace the temperature of the exhaust gases is required, provided that Fireplace, e.g. in old buildings, not optimal quality has and therefore with comparatively low exhaust gas temperatures tends to soot.

In the case of devices operated with a blower, the condensate Avoidance in the exhaust fume hood avoided or at least largely be reduced.

According to the invention, such is locally individual adjustable increase in the temperature of the fireplace or the like. Exhaust gas exhaust is a selectable if necessary Share of these exhaust gases from the combustion chamber directly into the Fireplace or the like conductive.

The size of this portion is therefore arbitrary and one  adjustable so that the temperature of the fireplace or the like. Exhaust gas exhaust gases flowing through the local conditions accordingly to one above the dew point Optimal value can be set, on the one hand, none Condensation is to be feared, but on the other hand no excessive heat energy losses occur.

The heat exchangers of devices of the aforementioned Genera are known with the device in which they are series are moderately installed, supplied and are independent of the opening location dimensioned uniformly. Thanks to the invention Solution can now reduce the exhaust gas temperature of such devices according to the time and effort required at the installation site of the device individually to the respective local nature of the Chimneys can be set so that the exhaust gas temperature inside half of the fireplace does not fall below the dew point and in as a result, no condensate is produced.

To the exhaust gas temperature in the area of the fireplace to such a Sufficient temperature to prevent condensation only needs to be lifted directly to the fireplace guided portion of the exhaust gases can be increased in a targeted manner.

After an advantageous and particularly easy to use Embodiment of the subject of the invention is this select share of the exhaust gases from below the heat exchanger located combustion chamber of the device in a directly in bypassing the chimney, bypassing the heat exchanger branchable.

To make the device compact and spacious with this bypass guide Bypassing to make it more economical  point essentially parallel to that of the heat exchanger containing exhaust duct arranged.

This subsequently opens up the advantageous possibility speed, this bypass in addition to that of the heat exchanger containing exhaust gas routing from the combustion chamber to a common to lead the exhaust gas collector from which the exhaust gas outlet or the chimney connection goes out.

The bypass can easily be within the scope of the invention the components of the heat exchanger, e.g. the limbs of one Link kettles, are formed, but you can do this order walking tour also separately and at a distance from the Exhaust gas routing containing heat exchanger from the combustion chamber the burner directly into the flue gas collection chamber.

By means of an adjustment arranged in the bypass guide clear regulatory body, e.g. a slider, a throttle flap or the like, is the immediately the exhaust and the Part of the uncooled flue gas to be fed comfortably and easily adjustable to its optimal size.

According to other embodiments of a Ge according to the invention can solve the problem defined at the outset Capacity of the initially uniformly dimensioned heat exchanger purposeful considering the respective local Conditions and the nature of the fireplace changed and be optimally adjusted.

In this regard, various are within the scope of the invention with such constructive possibilities, with their help can be achieved that a determinable in size Share of exhaust gases from the combustion chamber of the device without  Cooling through the heat exchanger directly to the exhaust manifold and the like in the fireplace. reaches the condensate to prevent education and sooting.

In the case of one usually with a coulter with slats The existing heat exchanger tubes is with this goal according to the invention provided that of the entire surface of the heat exchanger to be flowed through by the exhaust gases a partial surface area can be selected as required is free or at least lamellar design, to thereby within this range uncooled exhaust gases in one allowable amount to get into the fireplace.

For example, in this partial surface area Part of the slats for the required heat measurement absorption capacity of the heat exchanger with the ones carrying it Pipes can be detachably connected. Then the exhaust gas temperature in the chimney to prevent condensation Increasing sufficient height only needs a variable type number of such removable slats are removed or it can be in a slat-free area from the outset Pipes are only used as many detachable fins each that the exhaust gases are not in this partial area essential, at least not cool down to below the dew point.

According to a preferred embodiment, the slats are open the pipes attachable and by frictional engagement with the Pipes releasably connected.

To prevent such detachable slats from being too tight be classified, what locally too high temperatures and a would cause poor heat transfer, a dissolve  bare slat between two or more stationary Slats can be used.

Another way of realizing the invention idea is to get between adjacent pipes Extending walls of the slats removable in some areas to design, so that their heat transfer as needed Reduce area and the temperature of the heat exchanger leaving exhaust gases.

In this case, no additional, releasable fixing slats needed, but only need it the existing, stationary slats slightly to be edited.

To facilitate the removal of removable wall parts the slats can be punched out in these slats be seen, preferably ver in pairs at an angle to each other ongoing punchings for separation such as triangular or trapezoidal wall parts.

To facilitate the handling of the wall to be separated parts it is recommended to arrange a transverse Punch in the removable wall part.

It is also advantageous for the function of the heat exchanger the slats with the removable wall parts in one limited, preferably central partial area of the To arrange heat exchanger.

According to other embodiments of the subject matter of the invention can be used to increase the number of chimneys Temperature of the flow of exhaust gases through part of the Heat exchanger can be throttled.  

With this objective, for example, after a wide Ren embodiment in a device whose heat exchanger attached at least one water-carrying heat exchange tube, has fins parallel to the exhaust gas flow, can be provided, that at least one of adjacent slats turned on closed space if necessary by one on a free The outer edge of at least one of these slats, crosswise at least partially to the level of these slats extending wall is limited.

With this measure, any part of the otherwise the exhaust gases flowed between the fins block formed spaces, one at a time The extent that a sufficiently high temperature of the Exhaust gases leaving the heat exchanger.

The desired extent of this blockage ent speaking this wall can cover only a part of the formed between adjacent slats Extend distance or over the full distance. lm in the latter case, the wall can also span several Extend distances formed between adjacent slats. The extent of the blockage of the heat exchanger is therefore in Extraordinary framework of the invention with very simple measures can be finely regulated to keep the flue gas temperature in the fireplace to achieve, which prevents its sooting, but on the other hand does not result in excessive energy losses.

Carries the inner edge facing the heat exchange tube Fins one flat against the pipe wall th collar, then it is advisable to put on the outer edge of this  Lamella-attaching wall against this collar to let the overlying side point.

The heat exchanger consists of a block of heat exchange pipes that penetrate fins, it is advantageous the walls in the edge area of this block to the slats start.

In general, it is recommended that these walls in Strö direction of the exhaust gases mainly downstream, i.e. at the the side of the fins facing away from the combustion chamber.

After another, on a targeted ring tion of the heat exchangeability of the heat exchanger agreed embodiment of the subject matter of the invention part of the throughput area is flat across the cross section of the exhaust gas duct, e.g. from a bevy of finned tubes existing heat exchanger if necessary coverable.

For this purpose - according to a particularly simple form of cash and easy to be realized embodiment - on the heat exchanger, a plate, for example a heat-resistant metal plate may be arranged which extends over part of the surface of the heat exchanger.

The one to be covered with such a plate, from case to case each optimal area share, on the one hand a Falling below the dew point in the fireplace or the like. is avoided on the other hand, the losses in exhaust gas heat are still acceptable are either predetermined from the outset for the locally determined conditions or by a fixed installation the cover plate can be fixed, or one can  plate preventing the throughput of the exhaust gases in some areas Arrange to arrange them optimally when needed selectable throttle position. Anyway is such a cover plate always after can be attached to an existing heat exchanger.

The arrangement of such cover plates on the heat exchanger is in Basically any scope of the invention, you can thus extend over edge areas of the heat exchanger, e.g. on the side, front and / or rear of the heat exchanger be arranged, such as in adjacent borders areas.

However, in order to distribute the To reduce the throughput, it is recommended such plates symmetrical with respect to the area of heat exchangers, for example in pairs for each other overlying edge areas of the surface of the heat exchanger or to arrange over a central area.

Are the plates used to regulate the extent of the Throttling adjustable, it is recommended to join them simplification of their handling can be pivoted about a horizontal axis to store.

In practice, it is advantageous to use gas-fired devices first deliver with a heat exchanger, its effects grad or the like the optimal condition of the existing fireplace. Exhaust gas discharge corresponds, and then at the installation site of the Device this efficiency by setting or Reduce the dimensioning of the cover plate (s) so far that thus falling below the dew point in the chimney  is casually prevented. In the event of a later renovation the flue gas temperature can then be within the Exhaust fume hood adapted to its new condition at all times, namely be reduced.

According to a further feature of the invention, at least one Edge area of the heat exchanger by at least one its underside arranged in the upper part of the combustion chamber Be covered. Such use can be advantageous will contribute to the insulation of the combustion chamber and thereby reducing the heat loss in this area as well increase the temperature of the exhaust gases.

To cover a selectable proportion of the heat exchanger, can on the preferably cooled and / or insulated wall the insert fastened against the combustion chamber the edge of the heat enlarging the heat exchanger have exchanging covering width.

To further ensure that as little heat as possible the environment of the device is released, rather in the for Flue gases flowing remain and increase the Exhaust gas temperature in the chimney and thus to a reduction or Avoidance of condensation contributes, according to further features of the invention on the top of the heat exchanger preferably baffles within an exhaust manifold arranges by their surface as well as shape and installation position a radiation of the recorded and a reflection of the allow incident heat in the exhaust gas flow and thereby increase the exhaust gas temperature.

Directed diagonally upwards against the inlet of the exhaust gas flue  Baffles and / or a distance from the inlet of the exhaust gas deducted arranged, transverse to its axis Leit sheet metal allows a flow within the exhaust manifold that started absorbing the radiant heat Stigt and also a uniform flow of the pre switched heat exchanger guaranteed.

Furthermore, the exhaust manifold can be used to reduce the Temperature of its outside advantageously isolated the easiest way is that his hood up to Exhaust fume cupboard is designed to double reduce radiation and high exhaust gas inlet temperature guarantee in the exhaust fume hood. The inner shell can then be designed constructively in such a way that the Function of the above baffles fully takes over.

All of these measures bear through their sensible application contribute to the fact that in the exhaust gases after flowing through the heat remaining heat is not lost and still high when the exhaust gases enter the chimney Exhaust gas temperature is available, which is a shortfall of the dew point in the chimney prevented.

Finally, it is advantageous in the context of the invention, a divided into lamellas that can be used in the exhaust system, preferably retractable, heat absorption and radiation serving plate or one made of lamellas Frame existing plate to be provided, which after each nominal heat output a correction of the exhaust gas temperature enables, by reducing or enlarging the free exhaust gas flow cross-section and thus the heat  transfer surface of the heat exchanger.

According to a preferred embodiment, two are in slats articulated plates provided, of which at least one slidable with respect to the other within the exhaust duct is stored in order to dimension the flow cross-section in a targeted manner to be able to.

With the help of such a device, it is also possible to carry out a pressure loss-dependent control of the exhaust gas flow from the combustion chamber directly into the exhaust gas collector. For this purpose - according to a further feature of the invention - a bypass is provided on the side of the heat exchanger and the above-mentioned plates in the exhaust gas duct for a part of the exhaust gases flowing through the exhaust gas duct, through which this part reaches the chimney without flowing through the heat exchanger.

The following are the subject matter of Aus guidance examples shown in the drawings, explained. Show in detail

Fig. 1 shows a first embodiment of a device according to the invention in a schematic vertical section and

Fig. 2 shows a modified embodiment of this device.

Fig. 3 shows the heat exchanger of a second embodiment form and diagram

Fig. 4 shows an associated detail in a view.

Fig. 5 shows a modified embodiment of this heat exchanger also graphically and

Fig. 6 shows a detail on a larger scale.

Fig. 7 is a plan view of a heat exchanger, for example, arranged in a vertical exhaust gas duct of a device, and FIGS . 8 to 10 show vertical sections through part of a heat exchange tube of such heat exchangers in various variants.

FIGS. 11 and 12 show heat exchangers where the Drosse lung of the exhaust flow will find use cover plates.

Fig. 13 shows the upper part of a combustion chamber with flue-gas discharge and with disposed in the exhaust system heat exchanger in a vertical section represents

Fig. 14 shows the upper part of a combustion chamber with the subsequent flue-gas discharge, also in a vertical section.

FIG. 15 is a top view of a sheet metal that can be inserted into an exhaust gas duct and divided into lamellae

Fig. 16 shows the cross-section according to XVI-XVI of Fig. 15.

Fig. 17 shows an embodiment of such a plate in a bottom view and

Fig. 18 is a section along XVIII-XVIII of Fig. 17th

Fig. 19 is partly a section according to XIX-XIX of Fig. 20 through a heat exchanger equipped with such plates, partly its side view and

Fig. 20 is a Waagschnitt according to XX-XX of Fig. 19.

A water heater shown in FIGS . 1 and 2, for example, consists essentially of the burner 1 , for example a gas burner, and a heat exchanger 3 arranged in its exhaust duct 2 , which, for example, consists of a family of ribs, needles or the like. pipes, plates or the like which favor the exchange of organs. water-bearing members can exist, the outer sides of which are flushed by the exhaust gases.

These exhaust gases flow to a hood-shaped exhaust manifold 4 with an exhaust gas outlet opening into a chimney 5 . The forward and return flow of the heat exchanger 3 belonging to a heating circuit is designated 6 and 7 , respectively.

In order not to let the temperature of the exhaust gases in the chimney 5 drop below the dew point and thereby prevent the formation of condensate in the chimney 5 , a selectable proportion of the hot exhaust gases generated by the burner 1 in the combustion chamber 8 of the device is necessary via a bypass guide 9 the combustion chamber 8 directly, ie bypassing the heat exchanger 3 , in the exhaust manifold 4 conductive.

According to FIG. 1, a regulating member 10, for example designed as a slide, is provided at the outlet of the bypass guide 9 , according to FIG. 2, however, there is an adjustable throttle valve as a regulating member 10 in the bypass guide 9 .

The setting of such control elements 10 can be carried out in the context of the invention on the installation of the device depending on the nature of the locally existing fireplace, but it could also, if necessary automatically controlled, depending on the temperature of the exhaust gases in the fireplace, operational and / or can be controlled as a function of time or as a function of other physical parameters.

The bypass guide 9 can be designed as desired within the scope of the invention. For example, according to FIG. 1, it can be formed from components of the heat exchanger, for example from the members of a sectional boiler, and can consist of castings of such members.

However, as shown in FIG. 2, this bypass guide 9 can also be guided separately and at a distance from the exhaust gas guide 2 containing the heat exchanger 3 from the combustion chamber 8 of the burner 1 into the exhaust gas collection chamber 4 .

The task defined at the beginning of a need-based increase the exhaust gas temperature in the fireplace can be within the Invention also through a targeted reduction in heat Loosen the heat exchanger's absorption capacity.

In detail, FIG. 3 shows a heat exchanger 3 with a group of parallel water-carrying pipes 11 , which are covered with fins 12 . At the opposite ends of these tubes 11 there is on the one hand a distributor 13 and on the other hand a collector 14 to which the return 7 or the flow 6 of a heating circuit connect. The exhaust gas of the burner-heated device flows through this heat exchanger 3 upwards in the direction indicated by an arrow to the exhaust manifold and the chimney.

A partial surface area 15 of the total area of the heat exchanger 3 is designed to be lamella-free and in this area 15 , as required, plug-in fins 16 according to FIG. 4 can be plugged onto the tubes 11 in any desired number.

Because these fins 16 are only plugged on, they do not serve fully, but only partially for heat exchange. Above all, however, they reduce the free cross-section for the throughput of the exhaust gases.

The heat exchange capacity of the heat exchanger 3 is thereby or the like on the respective local nature of the fireplace. Exhaust fume cupboard can be adjusted so sensitively that during normal operation of the device the dew point in the chimney is not undershot and therefore the chimney is not dampened. The heat of the like in the fireplace. Exhaust gases is influenced by the size of the lamella-free area 15 , which flows through a part of the exhaust gas largely uncooled to the exhaust manifold and which is reduced to any size by inserting the detachable fins 16 or by removing existing detachable fins 16 big can be enlarged

Seen according to the Fig. 5 and 6 are in an area 17 of the heat exchanger 3 extending between adjacent tubes 11 wall portions 18 of the fins 12, if required, removable, whereby to facilitate the severing of such approximately triangular wall parts 18 paarwcise angle to one another extending outs 19 of the blades 12 prior are. A further, transverse punching 20 serves to facilitate the handling of the wall parts 18 .

According to FIG. 7, water-carrying heat exchange tubes 11 are equipped with fins 12 which are aligned parallel to the flow of the exhaust gas flowing from a combustion chamber of a burner-heated device into a chimney in an exhaust gas duct 2 . In the area of the pipe passages, the lamellae 12 have collars 21 with which they are fastened flat against the pipe wall.

In the illustrated embodiment, the exhaust gas runs flow vertically upwards, it could - with a fan operated burner, but also vertically downwards or run horizontally.

The fins 12 have - in the direction of the exhaust gas flow downstream - edges 22 and - in the direction of the exhaust gas flow upstream - edges 23 which face the combustion chamber. In the exemplary embodiment shown, the edges 22 are accordingly at the top and the edges 23 at the bottom.

The fins 12 are made of copper or stainless steel in the same way as the tubes 11 . Each lamella 12 is penetrated by a plurality of tubes 11 which are parallel to one another. In this way, the fins 12 of the heat exchanger 3 form a block, which is delimited on the long sides by a frame 24 .

Individual, in particular in the edge region of this frame 24 to ordered slats 12 now carry a wall 25 extending transversely to their plane, starting at one of their free edges, which at least partially delimits the space 26 enclosed by two adjacent slats 12 from the outside.

These walls 25 accordingly block the exhaust gas flow through these spaces 26 locally and in this way reduce the efficiency of the heat exchanger 3 as required and thereby increase the temperature of the exhaust gases flowing into the chimney.

These walls 25 can be formed in the simplest way by flanges attached to the edge of the lamellae 12 . These flanges can be arranged both on the edge 22 facing the combustion chamber, ie upstream of the exhaust gas flow, according to FIG. 7, and on the edge 23 facing away from the combustion chamber, i.e. downstream of the exhaust gas flow, according to FIGS. 8 to 10.

If the lamellae are secured 12 at its inner edge, so the edge of the penetrated by the tubes 11 openings by means of collars 21 on the walls of the tubes 11, then tackling the problem at its outer edge wall 25 should after this collar 21 opposite side have to thereby strengthening the stability of the lamella 12 .

While FIGS. 7 to 9 represent embodiments in which the walls 25 extend only over part of the distance between adjacent slats 12 , these walls 25 according to FIG. 10 extend over the full distance and over several slats 12 , so that they completely close some spaces 26 formed between these lamellae 12 and block them for the exhaust gas flow. These walls 25 thus may extend over several lamella 12 in accordance with FIG. 10.

The respectively desirable extent of the increase in the temperature of the exhaust gases entering the chimney must be matched to the local nature of the chimney from case to case by selecting the number and arrangement of the walls 25 .

The fin block of FIG. 7 water to be heated is supplied via the return line 7 of a heating circuit, this passes via the manifold 13 into the heat exchange tubes 11, flows through these tubes 11, the exhaust duct 2 and passes via the manifold 14 into the flow 6 of the heat exchanger 3.

The spaces 26 to be blocked by means of the walls 25 can be located within the scope of the invention of the frame 24 which is laterally delimiting in the vicinity of the heat exchanger 3 ( FIGS. 8 and 9) or in the middle of the exhaust gas duct 2 , as shown in FIG. 10 shows.

In accordance with Fig. 11 will exchanger on top of a flat heat 3 is a cover plate placed 27 that covers in a required, selectable surface extent of the four edge regions and inhibits characterized ranges the flow rate of the exhaust gases in this edge, therefore the heat capacity of the heat exchanger and the cooling of the exhaust gases decreased.

The dimensions of this cover plate 27 are to be chosen from case to case in such a way that the exhaust gas temperature above the heat exchanger 3 increases only to such an extent that the dew point in the chimney or the like is undershot. and consequently the formation of condensate is reliably prevented there.

According to the embodiment according to FIG. 12, two abutting, adjacent edge regions of the heat exchanger 3 can be covered by adjustable cover plates 28 , which are pivotably mounted about a horizontal axis 29 and can be adjusted in a throttle position as required by means of (not shown) adjustable design elements .

In addition, however, there are numerous other outages leadership forms of such throttling part covers of  Heat exchanger conceivable.

For example, above the central area of the heat exchanger a cover plate running vertically be arranged and by means of an adjusting member, e.g. by means of an outside screw, one Adjustment rod or the like., Adjustable to the throughput through the central area of the heat exchanger if necessary to throttle.

FIG. 13 shows the upper part of a combustion chamber 8 of a water heater, in the exhaust gas duct 2 of which a heat exchanger 3 is arranged, to which the water to be heated flows in circulation via the collector 13 .

The wall 30 of this combustion chamber 8 and the flue gas duct 2 is encased with an insulation 31 in order to prevent heat losses in this area and to allow the heat gained thereby to prevent the accumulation of condensate in the chimney and to increase the temperature of the flue gases flowing into the flue gas extractor and chimney . On the underside of the heat exchanger 3 , that is to say in the upper part of the combustion chamber 8, there is now an insert 32 which covers certain, selectable or adjustable surface area of the heat exchanger 3 from the combustion chamber side by enlarging an upwards towards the heat exchanger 3 , has an edge area of this heat exchanger 3 covering width. This insert 32 can be flat on the inside of the wall 30 of the exhaust gas duct 2 BEFE Stigt; It consists of a refractory insulating material and thus also contributes to the avoidance of heat loss of the exhaust gases. In addition, the wall 30 of the exhaust gas duct 2 can be cooled in this area with a water jacket 33 which is connected via a line 34 to the water circulation of the water to be heated which is conducted via the heat exchanger 3 .

This cover could be structurally such that movably mounted ceramic molded parts cover a variable area of the heat exchanger 3 via an externally accessible adjusting device and, if necessary, reduce the heat-transferring surface of this heat exchanger, thereby causing an increase in the exhaust gas temperature in the chimney.

According to the embodiment of the exhaust manifold 4 according to FIG. 14, baffles 35 and 36 are arranged therein, which by their design and arrangement ensure a radiation of the heat absorbed by them and a reflection of the heat incident on them and thereby increase the exhaust gas temperature.

The baffles 35 extend obliquely upwards against the inlet of the exhaust gas extractor 5 , the baffle plate 36 is arranged at a distance from the inlet of the exhaust gas extractor 5 and extends transversely to its axis.

These baffles 35 and 36 achieve a flow within the exhaust gas collector, which favors the absorption of the radiant heat and also ensures a uniform flow through the upstream heat exchanger.

To reduce the temperature of the outside of the exhaust gas collector 4 , the hood is covered up to the inlet of the exhaust fume hood with an outer shell 37 , that is designed with two shells to reduce radiation losses and to ensure high temperatures of the exhaust gas entering the exhaust fume hood. The inner shell can be designed so that it takes over the function of the above-mentioned guide plates 35 .

The-demand increasing the exhaust gas temperature is also shown in FIGS. 15 and 16 lamellar grid, that is a step-fin plate 38, in such a divided targeted and between the exhaust manifold 4 and the heat exchanger 3 is used, may at best be also incorporated subsequently.

Another such structured plate, which consists of a frame 41 and lamella 42 , is shown in FIGS. 17 and 18.

A construction consisting of such plates 38 and 41 is illustrated in FIGS . 19 and 20 and consists of a slidably mounted plate 38 and a stationary plate 41 . The upper, slidable plate 38 carries an upstanding flange 40 . By covering the fins 39 and 42 to a greater or lesser extent, the exhaust gas flow cross section can be regulated and there are 3 areas within the heat exchanger which have good or poor flow. In this way, the active surface of the heat exchanger can be reduced, the heat transfer deteriorated and the exhaust gas temperature increased as necessary to adapt it to the respectively set or desired nominal heat load.

In addition, by means of such a device, a pressure loss-dependent control of the exhaust gas flow from the combustion chamber 8 can be carried out directly into the exhaust manifold 4 by a bypass path 43 of selectable flow cross-section for a measurable proportion by the side of the heat exchanger 3 and the plates 38 and 41 in the exhaust duct 2 the exhaust gases coming into the exhaust gas outlet is provided, through which this portion reaches the chimney without flowing through the heat exchanger 3 . As a result, the pressure loss caused by the articulated plates 38 and 41 is reduced and adaptation to the nominal heat output to be set at the desired exhaust gas temperature in the exhaust gas outlet is made possible.

Claims (40)

1. Burner-heated device, in particular water heater, with an arranged in the leading to a chimney flue of the burner, the exhaust gases of this burner by flowing heat exchanger, characterized in that a selectable proportion of the exhaust gases from the combustion chamber ( 8 ) directly into the fireplace ( 5 ) or the like is conductive. 2. Apparatus according to claim 1, characterized in that the selectable proportion of the exhaust gases from the heat exchanger ( 3 ) located under the combustion chamber ( 8 ) in a direct bar in the chimney ( 5 ) opening, the heat exchanger ( 3 ) to bypass ( 9 ) can be branched ( Fig. 1, 2). 3. Device according to claim 2, characterized in that the bypass guide (9) is guided substantially parallel to the said heat exchanger (3) containing combustion gas passage (2) (Fig. 1, 2). 4. Apparatus according to claim 3, characterized in that the bypass duct ( 9 ) in addition to the heat exchanger ( 3 ) containing the exhaust duct ( 2 ) from the combustion chamber ( 8 ) to a common exhaust manifold ( 4 ), from which the chimney ( 5 ) or the like Exhaust fume goes out ( Fig. 1, 2). 5. Apparatus according to claim 4, characterized in that the bypass guide ( 9 ) from the components of the heat exchanger ( 3 ), for example the members of a sectional boiler, is formed ( Fig. 1). 6. Apparatus according to claim 4, characterized in that the bypass guide ( 9 ) separately and at a distance from the heat exchanger ( 3 ) containing exhaust gas guide ( 2 ) from the combustion chamber ( 8 ) of the burner ( 1 ) in the exhaust gas collection chamber ( 4 ) is performed ( Fig. 2). 7. Device according to one of the claims 2 to 6, marked net by an in the bypass ( 9 ) arranged, the size of the throughput regulating, adjustable control organ ( 10 ), for example a slide, a throttle valve or the like, for dimensioning the Size of the portion of the exhaust gases to be fed directly to the chimney ( 5 ) ( FIGS. 1, 2). 8. Apparatus according to claim 1, with a heat exchanger consisting of a flock of fins with tubes, characterized in that of the entire area to be flowed through by the exhaust gases of the heat exchanger, a partial surface area ( 15 or 17 ) lamellae selectable size if necessary can be designed freely or lamellar ( Fig. 3 to 6). 9. Apparatus according to claim 8, characterized in that for the purpose of dimensioning the size of the partial area ( 15 ) or the lamella density within this area ( 15 ) at least part ( 16 ) of the lamellae ( 12 ) with the tubes ( 11 ) detachable is connected ( Fig. 3,4). 10. Apparatus according to claim 9, characterized in that these releasably connectable to the tubes ( 11 ) slats ( 16 ) on the tubes ( 11 ) can be plugged and connected by friction with these tubes ( 11 ) ( Fig. 3, 4). 11. Apparatus according to claim 9 or 10, characterized in that releasable slats ( 16 ) can be used between fixedly arranged slats ( 12 ) ( Fig. 3, 4). 12. Apparatus according to claim 8, characterized in that extending between mutually adjacent tubes ( 11 ) de wall parts ( 18 ) of the fins ( 12 ) in some areas can be removed ( Fig. 5, 6). 13. Apparatus according to claim 12, characterized in that to facilitate the separation of the removable wall parts ( 18 ) punchings ( 19 , 20 ) in the slats ( 12 ) are seen before ( Fig. 5, 6). 14. Apparatus according to claim 13, characterized in that the punched-out portions ( 19 ) are arranged in pairs at an angle to one another in order to separate approximately triangular or trapezoidal wall parts ( 18 ) ( FIG. 5, 6). 15. Device according to claim 14, characterized by a transverse punching ( 20 ) in the removable wall part ( 18 ) to facilitate its handling ( Fig. 4). 16. Device according to one of the claims 12 to 15, characterized in that the slats ( 12 ) with the removable wall parts ( 18 ) in a limited, preferably in a central partial surface area ( 17 ) of the heat exchanger ( 3 ) are arranged ( Fig. 5). 17. Apparatus according to claim 1, characterized in that the throughput of the exhaust gases through part of the heat exchanger ( 3 ) can be throttled if necessary ( Fig. 8-12). 18. Apparatus according to claim 17, with a heat exchanger consisting of a group of fins with fins tubes, characterized in that at least one of such mutually adjacent fins ( 12 ) enclosed space ( 26 ) by at least one of these fins ( 12 ) on the free outer edge starting wall ( 25 ) extending transversely to the plane of this lamella ( 12 ) can be at least partially limited ( FIGS. 8-10). 19. Apparatus according to claim 18, characterized in that this wall ( 25 ) extends over the full distance formed between adjacent slats ( 12 ) ( Fig. 10). 20. Apparatus according to claim 18, characterized in that this wall ( 25 ) extends only over part of the distance formed between adjacent slats ( 12 ) ( Fig. 8, 9). 21. Apparatus according to claim 18, characterized in that this wall ( 25 ) extends over a plurality of spacings formed between adjacent slats ( 12 ) ( Fig. 10). 22. Apparatus according to one of the claims 18 to 20 with fins, the edge of which faces the heat exchange tube and carries a collar ( 21 ) which lies flat against the tube wall, characterized in that the wall ( 25 ) attached to the outer edge of these fins ( 12 ) the side opposite this collar ( 21 ) has ( Fig. 8, 9). 23. Device according to one of the claims 18 to 22, consisting of a block of heat exchange tubes ( 11 ) penetrated fins ( 12 ), characterized in that the walls ( 25 ) in the edge areas of this block to the fins ( 12 ) ( Fig. 7). 24. Device according to one of the claims 18 to 23, characterized in that the walls ( 25 ) downstream in the flow direction of the exhaust gases on the combustion chamber ( 8 ) facing away from the edge ( 22 ) of the fins ( 12 ) ( Fig. 9). 25. Apparatus according to claim 17, characterized in that part of the throughput area of the heat exchanger ( 3 ) which extends across the cross section of the exhaust gas duct ( 2 ) can be covered if necessary (FIGS . 11, 12). 26. Apparatus according to claim 25, characterized by at least one on the heat exchanger ( 3 ) arranged cover plate, preferably a sheet metal plate ( 27 or 28 ), which extends over part of the surface of the heat exchanger ( 3 ) ( Fig. 11, 12) . 27. Apparatus according to claim 26, characterized by cover plates ( 27 , 28 ) which extend over edge regions of the surface of the heat exchanger ( 3 ) ( Fig. 11, 12). 28. Apparatus according to claim 27, characterized in that at least one plate ( 27 ) extends over opposite edge regions of the surface of the heat exchanger ( 3 ) ( Fig. 11). 29. Device according to claim 27, characterized by one located in the central area of the heat exchanger Plate. 30. Device according to one of the claims 26 to 29, characterized in that at least one cover plate ( 28 ) is adjustable in a throttle position selectable as needed ( Fig. 12). 31. Apparatus according to claim 30, characterized in that at least one plate ( 28 ) for controlling the extent of the throttling about an axis ( 29 ) parallel to the plane of the heat exchanger ( 3 ) is pivotally mounted ( Fig. 12). 32. Apparatus according to claim 25, characterized in that at least one edge region of the heat exchanger ( 3 ) is covered by at least one insert ( 32 ) arranged on its underside in the upper region of the combustion chamber ( 8 ) ( FIG. 13). 33. Apparatus according to claim 33, characterized in that the on the, preferably cooled and / or insulated, wall ( 30 ) of the combustion chamber ( 8 ) attached insert ( 32 ) an upward against the heat exchanger ( 3 ) enlarging, an edge area of Has heat exchanger ( 3 ) covering width ( Fig. 13). 34. Apparatus according to claim 1, characterized in that on the top of the heat exchanger ( 3 ) within an exhaust manifold ( 4 ) baffles ( 35,36 ) are arranged, which serve to emit radiation and the reflection of incident heat in the exhaust gas flow ( Fig. 14). 35. Apparatus according to claim 34, characterized by baffles ( 35 ) directed obliquely upwards against the inlet of the exhaust gas exhaust ( 5 ) ( Fig. 14). 36. Apparatus according to claim 34 or 35, characterized by a spaced from the inlet of the exhaust fume hood ( 5 ), to its axis transverse guide plate ( 36 ) ( Fig. 14). 37. Apparatus according to one of the claims 34 to 36, characterized by an outer shell ( 37 ) arranged above the exhaust gas collector ( 4 ) at a distance from its outer wall to reduce the heat radiation of the exhaust gas collector ( 4 ). 38. Apparatus according to claim 1, characterized by a plate ( 37 ) which is divided into fins ( 39 ) and can be inserted into the exhaust gas duct ( 2 ), preferably insertable, and determines the exhaust gas throughput through the heat exchanger ( 3 ) and / or has a plate ( 42) ) equipped frame ( 41 ) ( Fig. 15 to 18). 39. Apparatus according to claim 38, characterized by two mutually associated articulated plates ( 37 and 41 ) of which at least one ( 38 ) with respect to the other ( 41 ) within the exhaust duct ( 2 ) is slidably mounted GE ( Fig. 19, 20th ). 40. Apparatus according to claim 38 or 39, characterized in that a bypass path ( 43 ) is provided for a selectable portion of the exhaust gases flowing through the exhaust gas duct to the side of the plates ( 37 and 41 ) which can be inserted into the exhaust gas duct ( 2 ) and determine the exhaust gas flow rate through which this portion is led directly into the chimney.