DE202015105156U1 - heating system - Google Patents

Abstract

Heating installation, comprising a first heat generator (1) with a first exhaust pipe (1.1) and a second heat generator (2) with a second exhaust pipe (2.1), wherein the two exhaust pipes (1.1, 2.1) are openly opening into an exhaust pipe connector (3) , characterized in that one of the two exhaust pipes (2.1) for forming a Kondensatabfuhranschlusses at a lowest point (3.4) in the exhaust pipe connecting piece (3) is formed opening.

Description

The invention relates to a heating system according to the preamble of patent claim 1.

A heating system of the type mentioned is according to the patent document DE 10 2005 050 212 A1 known. This consists of a first heat generator with a first exhaust pipe and a second heat generator with a second exhaust pipe, wherein the exhaust pipes are formed opening into a Abgasleitungsverbindungsstück. This solution serves to avoid the entry of exhaust gas of an operating heat generator in a standstill heat generator. This is achieved by injectors provided on both exhaust pipes, wherein a condensate discharge connection is arranged at a lowest point of the exhaust pipe connection piece. Condensate is formed by condensing out of the exhaust gas.

The invention has for its object to improve a heating system of the type mentioned. In particular, a heating system of the type mentioned should be further simplified.

This object is achieved with a heating system of the type mentioned by the features listed in the characterizing part of the protection claim 1.

According to the invention, it is thus provided that one of the two exhaust pipes is designed to open at the lowest point in the exhaust pipe connecting piece for forming a condensate discharge connection.

In other words, the solution according to the invention is characterized by the fact that it is possible completely to dispense with the condensate discharge connection present in the aforementioned prior art by using one of the two exhaust gas pipes as such. This is possible in particular if the exhaust pipe used as condensate discharge port is connected to a boiler, which in turn has a Kondensatabfuhranschluss, which is the case regularly.

The proviso with respect to the junction of the exhaust pipe at a lowest point of the exhaust pipe connection means that the exhaust pipe is arranged on the exhaust pipe connector that automatically flows from the other exhaust gas condensate exiting gravity to this lowest point and from there into the designed as Kondensatabfuhranschluss exhaust pipe.

Other advantageous developments of the heating system according to the invention will become apparent from the dependent claims.

For the sake of completeness, the remainder of the solution according to the patent document will be referred to DE 102 40 990 A1 pointed. However, this solution differs in particular from the solution according to the invention in that there the two exhaust pipes are not openly formed in an exhaust pipe connecting piece, but that there is an exhaust pipe is guided only concentrically in the other. A merger of the two exhaust gas streams takes place only after the so-called exhaust manifold outside the building.

The heating system according to the invention including its advantageous developments will be explained in more detail with reference to the drawing of a preferred embodiment.

It shows

1 partially cut a heating system with the exhaust pipe connection piece according to the invention.

In 1 a preferred embodiment of the heating system according to the invention is shown. This consists initially in a known manner from a first heat generator 1 with a first exhaust pipe 1.1 and a second heat generator 2 with a second exhaust pipe 2.1 , Here are the two exhaust pipes 1.1 . 2.1 in an exhaust pipe connector 3 Openly formed.

Essential for the heating system according to the invention is now that one of the two exhaust pipes 2.1 for forming a Kondensatabfuhranschlusses at a lowest point 3.4 into the exhaust pipe connector 3 , which preferably consists of plastic, is formed einmündend.

The proviso that the exhaust pipe 2.1 at a lowest point 3.4 into the exhaust pipe connector 3 formed einmündend, this means in addition to the above explanations also that the exhaust pipe connector 3 possibly even has a deeper lying dead water, but that there condensate from a certain level in Totwassergebiet by overflow practically alone or by gravity flows to the condensate discharge port forming exhaust pipe.

How out 1 it is particularly preferred that the one with the lowest point 3.4 connected exhaust pipe 2.1 until the heat generator 2 vertically extending trained and / or the lowest point 3.4 above the heat generator 1 . 2 is arranged.

Furthermore, it is provided that the first heat generator 1 , which is preferably designed as a fuel cell heater, to cover a base load and the second heat generator 2 , which is preferably designed as a boiler operated with oil, gas or wood, designed to cover a peak load.

It is the one with the lowest point 3.4 connected exhaust pipe 2.1 with the second heat generator designed as a boiler 2 connected trained. In addition, one of the heat generators points 1 . 2 , here according to the second heat generator 2 , a building-side Kondensatabfuhranschluss on (not shown separately, because known and readily imaginable).

To optimize the pressure conditions within the exhaust pipe connector 3 which will be discussed again in detail below, it is further preferably provided that a flow cross-section of an exhaust pipe 1.1 in the junction area of the exhaust pipe connector 3 for generating a pressure reduction in this exhaust pipe 1.1 is formed tapered. In other words, it is provided that a in the exhaust pipe connection piece 3 opening end of an exhaust pipe 1.1 is designed as a nozzle-shaped injector. Considered even more specific, it is envisaged that a in the exhaust pipe connector 3 opening end of the exhaust pipe 1.1 seen in the exhaust gas flow direction first from a nozzle-shaped portion 1.1.1 followed by a cylindrical section 1.1.2 is formed.

So that at the open end of the cylindrical section 1.1.2 accumulating condensate directly into the exhaust pipe 2.1 can reach or drain, is further preferably provided that a in the exhaust pipe connection piece 3 opening, open end of an exhaust pipe 1.1 vertically above the other exhaust pipe 2.1 is arranged. How to continue 1 Obviously, these requirements also lead to the fact that once from the exhaust pipe 1.1 escaped condensate no longer in this exhaust pipe 1.1 can go back, as a free end of the exhaust pipe 1.1 , in particular the nozzle-shaped injectors, always at a distance, particularly preferably concentrically, to walls of the preferably designed as a T-shaped piece of pipe exhaust pipe connecting piece 3 is arranged.

Further, with reference to 1 to optimize the pressure conditions in the exhaust pipe connector 3 provided that a flow cross-section of an exhaust pipe 2.1 in the junction area of the exhaust pipe connector 3 for generating a pressure increase in this exhaust pipe 2.1 is formed extended. In other words, it is provided that a in the exhaust pipe connection piece 3 opening end of an exhaust pipe 2.1 is designed as a diffuser.

Furthermore, it is preferably provided that the exhaust pipe 1.1 of a heat generator 1 unparallel or not parallel, preferably perpendicular, to the exhaust pipe 2.1 of the other heat generator 2 into the exhaust pipe connector 3 is formed einmündend.

Further, the exhaust pipe connector has 3 a first exhaust port 3.1 for the first exhaust pipe 1.1 , a second exhaust port 3.2 for the second exhaust pipe 2.1 and a third exhaust port 3.3 to a common exhaust gas discharge line 5 on. In this case, preferably connecting surfaces of two exhaust ports 3.1 . 3.3 parallel to each other and a connection surface of the further exhaust port 3.2 unparallel or not parallel, preferably perpendicular, arranged to the other two pads.

It is also confusing when connecting the heat generator 1 . 2 to the exhaust pipe connector 3 to avoid, provided that the exhaust port 3.1 for the one exhaust pipe 1.1 another size, in particular a different diameter, than the exhaust port 3.2 for the other exhaust pipe 2.1 having.

Finally, the exhaust pipe connector 3 for a room air-independent operation of the heat generator 1 . 2 with a three air connections 4.1 having the exhaust pipe connector 3 preferably jacket-shaped enclosing air duct 4 Mistake. At least one, in the present case all, of the exhaust ports 3.1 . 3.2 . 3.3 are each concentric within the air connections 4.1 arranged.

The heating system according to the invention works as follows:
The heat generator 1 , in this case a fuel cell heater, serves to satisfy a given base load. About the exhaust pipe 1.1 Gets exhaust from the heat generator 1 to the exhaust pipe connector 3 , where the heat generator 1 preferably simultaneously via the air connection 4.1 is supplied with fresh air. Due to the taper or the nozzle-shaped section 1.1.1 At the junction area, the flow rate of the exhaust gas increases at this point. At the same time, the rejuvenation due to the Bernoulli effect (see also http://de.wikipedia.org/w/ index.php? title = Str% C3% of Bernoulli and Venturi & oldid = 127053410) to a pressure drop, ie at the open end is a comparatively low pressure.

The heat generator 2 , in this case, for example, a gas fired boiler, serves to satisfy peak loads. About the exhaust pipe 2.1 Gets exhaust from the heat generator 2 to the exhaust pipe connector 3 , where the heat generator 2 preferably simultaneously via the air connection 4.1 is supplied with fresh air. Due to the in 1 shown extension or the aforementioned diffuser at the junction region, the flow rate of the exhaust gas drops at this point. This simultaneously leads to a pressure increase at this point.

As a result, these described and deliberately induced pressure conditions advantageously lead to the second, preferably modulating, heat generator 2 at low power not from the exhaust of the first heat generator 1 impaired or even blown out at worst, since the pressure of the exhaust gas at the outlet of the exhaust pipe 2.1 is higher than at the outlet of the exhaust pipe 1.1 ,

LIST OF REFERENCE NUMBERS

1

first heat generator

1.1

first exhaust pipe

1.1.1

nozzle-shaped section

1.1.2

cylindrical section

2

second heat generator

2.1

second exhaust pipe

3

Exhaust pipe connector

3.1

first exhaust connection

3.2

second exhaust connection

3.3

third exhaust connection

3.4

lowest point

4

air duct

4.1

air connections

5

Flue tube

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102005050212 A1 [0002]
• DE 10240990 A1 [0009]

Cited non-patent literature

• Bernoulli effect (see also http://de.wikipedia.org/w/index.php?title= Str% C3% B6mung Bernoulli and Venturi & oldid = 127053410) [0026]

Claims (10)

Heating installation, comprising a first heat generator ( 1 ) with a first exhaust pipe ( 1.1 ) and a second heat generator ( 2 ) with a second exhaust pipe ( 2.1 ), whereby the two exhaust pipes ( 1.1 . 2.1 ) in an exhaust pipe connector ( 3 ) are openly opening, characterized in that one of the two exhaust pipes ( 2.1 ) for forming a Kondensatabfuhranschlusses at a lowest point ( 3.4 ) in the exhaust pipe connector ( 3 ) is formed einmündend. Heating installation according to claim 1, characterized in that a flow cross-section of an exhaust pipe ( 1.1 ) in the junction area of the exhaust pipe connector ( 3 ) for generating a pressure reduction in this exhaust pipe ( 1.1 ) is tapered. Heating installation according to claim 1 or 2, characterized in that a in the exhaust pipe connection piece ( 3 ) opening end of an exhaust pipe ( 1.1 ) is designed as a nozzle-shaped injector. Heating installation according to one of claims 1 to 3, characterized in that a flow cross-section of an exhaust pipe ( 2.1 ) in the junction region of the exhaust pipe connector ( 3 ) for generating a pressure increase in this exhaust pipe ( 2.1 ) is formed extended. Heating installation according to one of claims 1 to 4, characterized in that the exhaust pipe ( 1.1 ) of a heat generator ( 1 ) unparallel to the exhaust pipe ( 2.1 ) of the other heat generator ( 2 ) in the exhaust pipe connector ( 3 ) is formed einmündend. Heating installation according to one of claims 1 to 5, characterized in that the exhaust pipe connection piece ( 3 ) a first exhaust port ( 3.1 ) for the first exhaust pipe ( 1.1 ), a second exhaust port ( 3.2 ) for the second exhaust pipe ( 2.1 ) and a third exhaust connection ( 3.3 ) to a common exhaust gas discharge line ( 5 ) having. Heating installation according to claim 6, characterized in that connection surfaces of two exhaust connections ( 3.1 . 3.3 ) parallel to each other and a pad of the further exhaust port ( 3.2 ) are arranged unparallel to the other two pads. Heating system according to claim 6 or 7, characterized in that the exhaust connection ( 3.1 ) for the one exhaust pipe ( 1.1 ) another size, in particular a different diameter, than the exhaust port ( 3.2 ) for the other exhaust pipe ( 2.1 ) having. Heating installation according to one of claims 1 to 8, characterized in that the exhaust pipe connection piece ( 3 ) for a room air-independent operation of the heat generator ( 1 . 2 ) with a three air connections ( 4.1 ) having air duct ( 4 ) is provided. Heating installation according to claim 9, characterized in that the exhaust connection ( 3.1 . 3.2 . 3.3 ) concentrically within the air connection ( 4.1 ) is arranged.

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