DE102009056097B4 - Plant for supplementing a heating system - Google Patents

Abstract

Plant for supplementing a heating system (6) for a building (8) for using the sensitive and the latent residual heat energy of a flue gas line (1) guided flue gas (10) of a burner (60) of the heating system (6), wherein the system with a the flue gas line (1) coupled cooling system (3) for the flue gas (10) having at least a first flue gas cooler (31) through which the flue gas (10) removed residual heat energy via a fluid to a hydraulic circuit (50) of the flue gas cooler (31 ) and wherein an air conditioning device (2) with a first heat exchanger (21) is provided and at least the first flue gas cooler (31) is hydraulically coupled via the circuit (50) to the first heat exchanger (21), wherein the first heat exchanger (21 ) is acted upon by a first fresh air duct (20) with outside air (80), characterized in that the air conditioner (2) has a recirculation duct (25) for building air circulation (81) and a n further fresh air duct (26) for the outside air (80), wherein the two fresh air ducts (20, 26) open via opposing flaps (28) in a common outlet channel (27) and the recirculating air duct (25) and the common outlet channel (27) each separately for external or circulating air can be controlled.

Description

The invention relates to a system for supplementing a heating system for a building to use the sensitive and the latent residual heat energy of a guided over a flue gas pipe flue gas of a burner of the heating system. The system has a coupled to the flue gas line cooling system for the flue gas with at least a first flue gas cooler. Through the flue gas cooler, the residual heat energy removed from the flue gas can be discharged via a fluid to a hydraulic circuit of the flue gas cooler. There is provided an air conditioning device with a first heat exchanger, which is hydraulically coupled to the first flue gas cooler via the circuit, wherein the first heat exchanger is acted upon via a first fresh air duct with outside air.

Every building or every building envelope has a specific, unavoidable leaks. This leakage causes an uncontrolled inflow of untreated outside air or an uncontrolled outflow of heated room air between the building and the surroundings. This process is called infiltration. In accordance with DIN 1946 Part 6, May 2009, additional measures to supplement the building-specific infiltration are described to cover the ventilation requirements of a building. These additional measures can be designed as so-called "free ventilation" by means of windows as defined building openings or by machine as so-called "fan-assisted ventilation".

The fan-assisted ventilation systems have the energetic advantage that the air exchange in the building can be made by utilizing the thermal potential of the exhaust air through appropriate heat recovery. Such ventilation systems for so-called "controlled ventilation" have therefore prevailed in the market.

In the DE 35 18 143 A1 a method and a device for energy-saving heating, ventilation and exhaust air purification of industrial halls with a high air quality in the occupied zone of the workers and a high quality exhaust air purification of discharged from the hall exhaust air is described. For this purpose, the supply air is sucked in Zulufttürmen over the roof with a fan and heated by one or more heat exchangers, which are hydraulically coupled to a flue gas heat exchanger.

In the US 4 122 834 A describes a heat recovery system for kitchen hoods, which is integrated in a heating system.

In the DE 10 2008 039 010 A1 a system wall is described, via which solar thermal energy is also released indirectly via intermediate storage to the room air.

After DE 298 10 120 U1 is a system for the use of waste heat for small combustion plants known, after the two heat exchangers and a high-temperature heat transfer medium and a low-temperature heat transfer medium are used.

According to the description of DE 198 26 625 A1 a heat-insulating foundation is heated by an air / water heat exchanger with solar heat energy.

In the DE 41 21 953 A1 a method for heating a mixture of exhaust air and outside air by exhaust heat is described in which a storage container is designed as a layer storage. The regulation of the power of the heat generator takes place as a function of the buffer temperatures. For exhaust heat utilization, a second fresh air heat exchanger is used downstream.

The invention has the object of providing the ventilation of living spaces in such a way that prevents uncontrolled influx of outside air and at the same time a very low temperature level of the heat sources can be used.

The object is achieved according to the invention by the features of claim 1.

The present invention differs from the prior art in that it does not act additively to natural building infiltration, but substitutively, i. H. it reduces by appropriate supply of outside air the corresponding part of the freely flowing, untreated outside air. The targeted mechanical supply of outside air makes it possible to use heat sources with a relatively low temperature level with this partly very cold outside air.

As heat sources, the invention uses the calorific energy contained in flue gases and the low-temperature heat output of a thermal solar system. The invention can be usefully used in various ways in addition to boiler systems of older design, modern condensing boilers and all thermal solar systems and fan-assisted ventilation systems for the heating of buildings.

It is also advantageous, alternatively or in combination, that the air conditioning unit has a second heat exchanger designed as a solar heat exchanger and the solar heat exchanger has a hydraulic circuit with a solar thermal system is coupled, wherein the solar heat exchanger can be acted on the air side into the building incoming outside air and / or circulating air. Both by the residual flue gas and by a low heat potential of the solar system, the advantage of a targeted leakage compensation according to the invention can be achieved.

For this purpose, it is advantageous for the first heat exchanger and the solar heat exchanger to be arranged in a fresh air duct receiving the feed device in the air conditioning device for outside air and / or for circulating air and the solar heat exchanger is positioned upstream or downstream of the first heat exchanger in the flow direction S of the outside air and / or circulating air. It is thereby achieved that, depending on the heat supply of the two residual heat sources, the heat can be supplied individually to the waste air or recirculated air.

Depending on the operation of the condensing boiler of the heating system, it may be advantageous that a second flue gas cooler is provided in the cooling system, which is arranged in the flow direction S of the flue gas in front of the first flue gas cooler, and by the second flue gas cooler, the heat energy removed from the flue gas via a fluid in a hydraulic circuit the flue gas cooler can be discharged and the heating system can be fed. In a condensing boiler with relatively high exhaust gas temperatures can be cooled by the second flue gas cooler, the exhaust gas to about 60 ° C, before the first flue gas cooler is acted upon by the cooled flue gas.

Further advantageous embodiments for the heat exchange are described in the claims.

Further advantages and details of the invention are explained in the patent claims and in the description and illustrated in the figures. Show it:

1 a schematic diagram of a system in a building comprising a Luftkonditioniergerät for the benefit of residual heat from a heating system and a solar system;

2 a subarea A of the system according to 1 in which a second flue gas cooler is provided in addition to the first flue gas cooler;

3 an alternative portion B of the system according to 1 in which the air conditioner has a cross heat exchanger and double-sided, opposing louvers;

4 a further alternative to section B of the system according to 1 in which the air conditioning unit has only one heat exchanger and double-sided, opposing louvers.

In 1 is a plant to supplement a heating system 6 for a building 8th shown schematically. Such a system is connected to an existing heating system 6 consisting of a burner 60 with combustion chamber 61 , a primary heat exchanger 66 as well as radiators 67 and a heat exchanger 65 connected to service water. The combustion chamber 61 is via a flue gas line 1 to a fireplace 12 connected.

The plant essentially has a cooling system 3 for flue gas 10 and one to the cooling system 3 hydraulically connected air conditioner 2 on. The air conditioner 2 is also via a second heat exchanger 22 hydraulically with a thermal solar system 4 coupled. For clarity, the air flows are like outside air 80 , Circulating air 81 , Supply air 82 and exhaust air 83 marked with the same reference numerals as the corresponding lines. The respective flow directions S of the air flows are shown by an arrow.

The flue gas 10 is in a first flue gas cooler 31 cooled to about 10 ° C above the outside temperature and the sensible and the latent heat through a hydraulic circuit 50 to a first heat exchanger 21 in the air conditioner 2 transfer.

The heat of the solar thermal system 4 can be at a low temperature level via a hydraulic circuit 40 and the second heat exchanger 22 the air conditioner 2 be supplied. As soon as more heat is available at high solar radiation, the heat is directly or at least partially in the heat exchanger 65 guided.

For a needs-based use, the system is in a boiler room 84 inside the building 8th Installed. The air conditioner 2 is over a line 80 supplied with outside air. The administration 80 is at a corresponding building opening 800 connected. In addition, the air conditioner 2 via a corresponding line with circulating air 81 provided. The circulating air 81 is over a building opening 810 from a building use area 85 , the so-called living room, vacuumed.

The two air streams 80 . 81 are mixed in variable proportions and through the first heat exchanger 21 and through the second heat exchanger 22 guided and heated, the variable ratio between outside air 80 and circulating air 81 via a double-sided, counter-acting Luftregulierklappe 28 adjusted as needed and the required supply air volume 82 via a variable speed fan 29 is realized. The heated total air flow is as supply air 82 over a building opening 820 and a corresponding line the living room 85 fed. The amount of outside air or the outside air mass flow is due to the leakage of the building 8th adapted so that no outside air enters the building uncontrolled. Over a building opening 80a is provided for a pressure equalization while ensuring the supply of combustion air.

The in 1 Subarea A shown surrounded by a dashed line can be replaced by a second flue gas cooler 32 be supplemented. This alternative embodiment is in 2 shown. The second flue gas cooler 32 is in the flow direction S of the flue gas 10 in front of the first flue gas cooler 31 arranged and via a hydraulic circuit 320 with the heating system 6 coupled. In a condensing boiler with relatively high exhaust gas temperatures can through the second flue gas cooler 32 The exhaust gas must be cooled to approximately 60 ° C before the first flue gas cooler 31 with the cooled flue gas 10 is charged.

The further in 1 Partial area B, shown surrounded by a dashed line, can be replaced by a more extensive air conditioning unit 2 be replaced. This alternative embodiment is in 3 shown. In this case, the air conditioner 2 two fresh air channels 20 . 26 for outside air 80 and a recirculating air duct 25 for circulating air 81 on. The fresh air duct 26 and the recirculation channel 25 be via a cross-flow heat exchanger 23 guided and exchange each other heat, so that the heated outside air 80 over the fresh air channel 26 in an exhaust duct 27 to be led. In the fresh air channel 20 is the outside air 80 as per 1 explains, however, without a proportion of recirculated air 81 through the two heat exchangers 21 . 22 heated and also in the exhaust duct 27 guided. The ratio of the two outside air flows 80 in the two channels 20 . 26 is provided by a double-sided, counter-acting air regulating flap 28 adjusted as needed and the required total amount of air 82 via the variable speed fan 29 regulated. The from the crossflow heat exchanger 23 Exiting recirculating air flow is via a fan 29a regulated. This proportion of recirculated air 81 is as exhaust air from the building 8th led out. A conditioning of this recirculating air flow 81 through one with the heating system 6 hydraulically coupled heat exchanger 62 can be provided.

One over the embodiment according to 1 simplified alternative for subarea B is in 4 shown. Thereafter, only the thermal solar system 4 with the air conditioner 2 hydraulically for heating outside air 80 and circulating air 81 coupled. The two air streams 80 . 81 are mixed in variable proportions and through the second heat exchanger 22 the solar thermal system 4 guided and heated, the variable ratio between outside air 80 and circulating air 81 via the double-sided, counter-acting air regulating flap 28 adjusted as needed and the required total amount of air 82 via a variable speed fan 29 is realized. The heated total air flow is as supply air 82 over the building opening 820 and the corresponding line 82 the living room 85 fed. Again, the amount of outside air 80 or the external air mass flow to the leakage of the building 8th adapted so that no outside air 80 enters the building in an uncontrolled manner.

The system allows extremely efficient use of heat. Basically, the flue gas 10 in the first flue gas cooler 31 cooled to about 10 ° C above the outside temperature and over the fireplace 12 be fed to the atmosphere. The condensate of the flue gas 10 is in a condensate tank 33 collected and then neutralized by a medium that via a dosing 7 is supplied.

The condensate can in an embodiment not shown on the first flue gas cooler 31 be sprayed to thermally utilize the heat energy contained in the condensate.

The condensate storage 33 can serve as a buffer memory in another embodiment, not shown. Through the buffer memory 33 the period of a burner standstill can be bridged, whereby a continuous flow of heated outside air 80 to the building 8th is possible. The cache 33 is correspondingly hydraulically to a heat exchanger in the air conditioner 2 coupled.

The condensate is used to clean a flue gas filter 15 used and then via a drain line 30 as wastewater. To prevent equipment contamination, the fast components of combustion are mostly through the flue gas filter 15 caught in the flue gas pipe 1 is provided. The flue gas filter 15 has a filter body for this purpose 150 on, through which the flue gas 10 flows through it. The filter body 150 is cleaned discontinuously. For this purpose, the filter body 150 through a cleaning device 151 with cooling water 30 sprayed.

Claims (4)

Plant for supplementing a heating system ( 6 ) for a building ( 8th ) to use the sensitive and the latent residual heat energy of a via a flue gas line ( 1 ) guided flue gas ( 10 ) of a burner ( 60 ) of the heating system ( 6 ), with the system connected to the flue gas line ( 1 ) coupled cooling system ( 3 ) for the flue gas ( 10 ) with at least one first flue gas cooler ( 31 ), through which the flue gas ( 10 ) removed residual heat energy via a fluid to a hydraulic circuit ( 50 ) of the flue gas cooler ( 31 ) and wherein an air conditioner ( 2 ) with a first heat exchanger ( 21 ) is provided and at least the first flue gas cooler ( 31 ) hydraulically via the circuit ( 50 ) with the first heat exchanger ( 21 ), wherein the first heat exchanger ( 21 ) via a first fresh air channel ( 20 ) with outside air ( 80 ), characterized in that the air conditioning device ( 2 ) a recirculating air channel ( 25 ) for building air ( 81 ) and another fresh air channel ( 26 ) for the outside air ( 80 ), wherein the two fresh air channels ( 20 . 26 ) via opposing flaps ( 28 ) in a common outlet channel ( 27 ) and the recirculating air duct ( 25 ) and the common outlet channel ( 27 ) each separately for external or circulating air can be controlled. Plant according to claim 1, characterized in that the air conditioner ( 2 ) a second designed as a solar heat exchanger heat exchanger ( 22 ) and the solar heat exchanger ( 22 ) via a hydraulic circuit ( 40 ) with a thermal solar system ( 4 ), wherein the solar heat exchanger ( 22 ) on the air side into the building ( 8th ) incoming outside air ( 80 ) can be applied. Plant according to claim 2, characterized in that the first heat exchanger ( 21 ) and the solar heat exchanger ( 22 ) in a fresh air duct receiving a feeder ( 20 ) in the air conditioner ( 2 ) for outside air ( 80 ) and the solar heat exchanger ( 22 ) in the flow direction S of the outside air ( 80 ) and / or circulating air ( 81 ) in front of or behind the first heat exchanger ( 21 ) is positioned. Installation according to one of the preceding claims, characterized in that a second flue gas cooler ( 32 ) in the cooling system ( 3 ) is provided which in the flow direction S of the flue gas ( 10 ) in front of the first flue gas cooler ( 31 ) is arranged, and by the second flue gas cooler ( 32 ) the flue gas ( 10 ) extracted heat energy via a fluid in a hydraulic circuit ( 320 ) of the flue gas cooler ( 32 ) and the heating system ( 6 ) can be fed.

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