DE2811586A1 - Heating system with heat pump - passes mixt. of fresh air and flue gases through heat pump secondary circuit heat exchanger - Google Patents

Abstract

The heating system uses a stove or boiler which may be gas or oil heated with a hot water circuit connected to a heat pump. The flue gases (27) are passed through a heat exchanger (12) with a heat exchange coil (9) forming part of the secondary hot water circuit (7, 8) also connected to the heat pump. This heat exchanger (12) can be mounted on an outside wall (20) so that fresh air can be mixed with the flue gases before they are passed through the heat exchange coil (9) and out again to atmosphere. The ratio of flue gas to fresh air is at least 1:2 and preferably 1:10 or more. The mixture is driven through the coil (19) by a fan (18) preceding it, which has its rotor enclosed by a ring (29) which produces a suction effect on the flue gases.

Description

heating system

The invention relates to a heating system in the preamble of claim 1 specified ArtO To improve the overall efficiency and thus to save heating costs, heating systems are equipped with heat pumps, which couple two primary heat circuits with a secondary heat circuit. Of the a primary heat cycle is driven by an oil or gas burner, whereas the other primary heat circuit is driven by a heat exchanger, which extracts heat from the outside air below the correspondingly thermally insulated building roof. The secondary circuit includes the building's radiators.

In such heating systems are in the same way as with conventional Heating systems and furnace heating due to the aggressive and corrosive components attacked the chimneys in the exhaust gas of the oil or gas burner or coal stove and decomposed. Furthermore, a not inconsiderable amount arises from the exhaust gas immission Odor nuisance and pollution in the form of condensing, heavy and medium-volatile exhaust gas components, which on the building roofs and exterior walls get knocked down.

In contrast, the object of the invention is to provide a heating system the to improve the aforementioned type to the effect that the exhaust gas effects mentioned are significantly weakened and at the same time the overall efficiency of the system is increased.

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

Advantageous refinements and developments of the heating system according to Claim 1 results from the subclaims.

The solution according to the invention is based on the consideration with which anyway Existing heat exchanger of a heating system equipped with a heat pump to the exhaust gas of the oil or gas burner or coal stove on the one hand to extract heat and on the other hand Mix in fresh air, which makes the exhaust gas flowing into the atmosphere very strong is diluted and cooled, and additional useful heat is added to the heat cycle will. The exhaust gas can be diluted so much that there is no need for a chimney can be.

The burner is expediently used together with the heat exchanger mounted on the outside of the building in a common housing that is soundproof can be carried out, which nuisance noise from the burner and the Fan of the heat exchanger both for the building occupants and for the environment be avoided. It is also possible to use the one on the outside of the building Combine the heat exchanger with an air conditioning system, thereby increasing the suction power of the Heat exchanger enlarged or a simple air supply to the inside of the building is made possible.

The invention is explained in more detail with reference to the drawings. It shows: 1 shows a block diagram of a heating system according to the invention and FIGS. 2 to 4 are schematic Vertical sections through three different embodiments of the heat exchanger (a. 2 and 4) or the heat exchanger and the heater of the invention Heating system according to Fig. 1o The heating system shown schematically in Fig. 1 is up to on the exhaust-gas connection between the heater 27 and the heat exchanger 9 and should therefore be included in. The following are only explained in outline.

A heat pump is an essential part of the heating system shown 3, which has a first primary heat circuit 1 and a second primary heat circuit 2 couples with a secondary heat circuit 16. The first primary heat cycle 1 comprises the heater 27, which is connected to the heat pump via heat transport lines 4 and 5 3 is connected. The heat transfer line 4 conveys hot water from the heater 27 to the heat pump 3, whereas the heat transport line 5 cold water from the Heat pump 3 conveyed to the heater 27. The heater 27 is a gas or oil burner, which is fed with gas or oil from a combustion medium line 6. Preferably if these burners are forced draft burners or pulsating burners, which have a strong exhaust gas development In addition, the exhaust gas has one pulsating burner has a high level of humidity during the start-up phase in the form of drops of condensation or with appropriate humidity and low outside temperatures as visible fog or condensation streaks.

The second primary heat circuit 2 comprises the heat exchanger 9, the is connected to the heat pump 3 via heat transfer lines 7 and 8. The heat transfer pipe 8 conveys cold water from the heat pump 3 to the heat exchanger 9, where it is heated and is fed back to the heat pump as hot water via line 7.

The heat pump 3 consists in a known manner from ein.Verdampfer, an absorber and a condenser. The heating circuit leads via line 31 to the heating elements of the building, not shown, where the water gives off thermal energy and flows back to the heat pump 3 via the line 90.

According to the invention, the exhaust gas from the heater 27 is either immediately or via an exhaust pipe 10 to the heat exchanger 9 on its supply air side and fed there mixed with fresh intake air. The diluted exhaust gas is in the Heat exchanger 9 from heat to the second primary heat circuit 2 and occurs from there into the atmosphere. The dilution of the exhaust gas can e.g. be 1:10 and more, so that the diluted exhaust gas is practically harmless after exiting the heat exchanger 9 and is neither damp nor foggy. The diluted exhaust gas can therefore optionally be discharged into the atmosphere without the use of a chimney.

The kinetic energy present in the exhaust gas is also partially Drive of a fan 17 or 17 'connected upstream or downstream of the heat exchanger 9 (a. 2 to 4) are used. This fan can be designed so that it simultaneously as a suction fan for the heater 27 is used. In the case of a forced draft burner As a heating device, the fan 17 or 17 'conveys combustion air or combustion mixture in the combustion chamber of the heater 27, while in the case of a pulsating burner as a heater 27 ventilates the combustion chamber during the starting phase. For the fan burner the omission of a separate burner fan results in an essential one Cost savings, while with the pulsating burner, which is usually not a separate one Start fan has the aforementioned formation of condensate droplets or Condensation streaks are avoided during the start-up phase. Opposite pulsating Burners with a separate start blower result from the omission of the start blower the same cost savings as with forced draft burners.

Increased by the extraction of residual heat from the exhaust gas of the heater 27 the temperature gradient in the second primary heat circuit 2 and thus the overall efficiency the heating system. When the system is only in operation, i.e. when it is switched off Heat pump 3, it can be advantageous if the exhaust gas does not pass through the heat exchanger 9 is directed. For this purpose, in the embodiment according to FIG. 4, a direct Pipe section 10b of the exhaust pipe 10 leading into the open air and a switchable flow switch 28 available.

The heat exchanger shown schematically in FIG. 1 only as a block 9 is part of a heat exchanger unit 12 shown in FIG. 2, the housing of which 11 is fastened in a corresponding opening of a housing outer wall 20. Included conclude that Housing 11 flush with the outside of wall 20. The attachment of the housing 11 can in a manner not shown with an intermediate layer of heat and sound insulation layers. Perner can go inside the building protruding portion of the housing 11 with heat and / or sound insulation layers be provided. Inside the housing 11 is the schematically indicated heat exchanger 9 attached so that it together with the housing 11 has an annular air inlet opening 13, which is flush with the outside of the housing outer wall 20.

The annular air inlet opening is set in a cylindrical one Supply air duct 15 continues, which in turn of the housing 11 and the jacket 19 of a Fan 17, which adjoins the heat exchanger 9, is limited. The drive motor 18 of the fan 17 is located in the axial extension of the exhaust pipe 10, which from the heater 27 he iommend through the housing 11 in its axis of symmetry gas-tight is passed through. The through the annular inlet opening 13 from the fan 17 intake air initially flows in the channel 15 against the direction of flow of the exhaust gas in the pipe 10 and is - seen in their flow direction - behind the Fan 17 deflected while being swirled with the exhaust gas. That way with fresher Inlet air, diluted exhaust gas then flows through the heat exchanger 9, where it is Gives off residual heat and escapes into the open air. The heat exchanger 9 is with the lines 7 and 8, coming from the same side as the exhaust pipe 10 into the Housing 11 are introduced in a thermally insulated manner parallel to its axis of symmetry.

Since the exit of the diluted exhaust gas directly into the price leads, must the cross sections of the exhaust pipe 10 and the air inlet opening 13 and des Supply air duct 15 are dimensioned so that a very strong dilution of the exhaust gas takes place, the fan designed as a radial fan in the example shown 17 is partly also driven by the exhaust gas and generated via the exhaust pipe 10 a suction effect in the combustion chamber of the heater 27 (Fig. 1), resulting in the above already mentioned reduction of condensation droplets and plumes during the This effect is caused by the dilution the exhaust gas is increased with fresh air to such an extent that the exiting diluted exhaust gas also no visible condensation products under unfavorable weather conditions owns more.

In the embodiment according to Pig0 3, the heat exchanger 9 and the upstream fan 17 'together with the heater 27 and the exhaust pipe 10 in a common housing 11 ′ attached to the outside of the housing outer wall 20 The housing 11 'is in a manner not shown both opposite the building outer wall 20 as well as heat and sound insulated from the surrounding atmosphere. The fan 17 'is designed as an axial fan in the example shown, the blades of which directly opposite the mouth of the exhaust pipe 10 In this way, the kinetic energy of the exhaust gas is used solely to drive the fan 17, so that a separate fan motor is unnecessary. The fresh air to mix with the exhaust gas is on the top of the housing 11 via housing openings, not shown in evenly distributed over the entire cross section of the fan 17 sucked away. The fan 17 'mixes the sucked in Prischluft with the exhaust gas, which is diluted in Porm flows past the heat exchanger 9 and not through the underside of the housing openings shown exits through. The prischluft- and exhaust flows are indicated in Fig. 3 with arrows.

The axial fan 17i also generates a suction effect via the pipe 10 within the combustion chamber of the heater 27, its oil or. Gas supply through a Valve 21 is adjustable by hand.

Since this suction depends on the length of the exhaust pipe 10, this is guided in a meander shape within the housing 11 '.

This loop-shaped design of the exhaust pipe 10 has the. like teren The advantage is that the fresh air flowing past is preheated on the surface of the tube 10 is, whereby the operation of the heat exchanger 9 is supported. The attachment the heater it 27 and the heat exchanger 9 on the outside of the building offers next a very compact, space-saving design has the advantage that the burner and Noise from the fan inside the building is unacceptable. Lines 4, 5 and 7, 8 lead through the housing 11 'and the housing outer wall 20 into the interior of the housing, where the remaining parts of the heating system shown in Fig. 1 are housed. It goes without saying that the wall bushings of the lines 5, 4 and 7, 8 also can be designed to be heat-insulated and sound-insulated. The one at the bottom of the case 11 ', the diluted exhaust gas escaping directly into the open has a correspondingly high degree of dilution, so having a harmful environmental impact Security is avoided.

Due to the already mentioned suction effect of the fan 17 'on the combustion chamber of the heater 27 is the formation in connection with the high exhaust gas dilution of condensation droplets or plumes of condensation even in bad weather certainly avoided.

In Fig. 4, an embodiment of the heat exchanger unit 12 is shown, which is attached to the outside "of the building outer wall 20 and with an air mixing unit 22 is combined on the inside of the building outer wall 20. For this is located on the top of the heat exchanger housing 112f a number of air flaps 29 and in a breakthrough in the wall 20 on the back of the mixing unit 22 a number of air flaps 25. The air flaps are in the operating position shown 29 open and the air flaps 25 closed, so that when the fan is switched on 17 fresh air is sucked in through the openings 24 between the air flaps 29 and with the exhaust gas emerging from the pipe 10 is mixed. With the fan switched off 17 and open air flaps 25, the mixing unit 22 can blow air through the openings 24 suck in and convey into the interior of the building. With air flaps closed 29 and open air flaps 25, the fan 17 sucks room air from inside the building the mixing unit 22 and the open air flaps 25, which instead of the Prischluft is mixed with the exhaust gas. The exhaust pipe 10 led from the inside of the building is forked in the manner shown into two pipe sections 10a and 10b, of which the pipe section 10a perpendicular to the fresh air flow shown inside the housing 11 ″ into the interior of the housing and connected to the heat exchanger 9 opposite side is provided with gas outlet openings. The pipe section 10b, on the other hand, is parallel to the pipe section 10a through the housing 11 ″ Out into the surrounding atmosphere and is not in contact with the interior of the housing. At the fork point of the exhaust pipe 10 is a flow switch 28, shown in FIG Example trap a flap, attached to the exhaust gas optionally through the pipe section lOb directly into the open air or through the pipe section lOa into the interior of the housing to steer. An immediate introduction of the undiluted exhaust gas into the surrounding area The atmosphere comes through the pipe section 10b, as already mentioned above was then taken into account when the heat pump 3 (Fig. 1) is switched off and that Heater 27 operates in pure heating mode.

Otherwise, as in the exemplary embodiments according to FIGS. 2 and 3 introduced into the interior of the housing via the pipe section 10a, namely via the entire cross section of the fan 17 distributed away. The fan 17 is shown in FIG Example case designed as a radial fan with a fan motor 18, which - in the direction of flow of the exhaust gas - is arranged behind the heat exchanger 9. This attachment has the purpose of a good swirling of the exhaust gas with the fresh air as a result of the to achieve turbulence forming in front of the heat exchanger 9. That on the open Underside of the housing 11 ″ exiting, diluted exhaust gas is shown in FIG Way deflected by baffles 23 and 26 by about 900.

L e r s e i t e

Claims (12)

Claims heating system, with a first and second primary heat circuit, a heat pump and a secondary heat circuit, the first primary heat circuit from a combustion heat source and the second primary heat circuit from one tuft heat exchanger is driven that the combustion heat source (27) on the exhaust gas side with the heat exchanger (12) in such a way connected or connectable is that the exhaust gas with the supply air of the heat exchanger (12) is mixed. 2. Heating system according to claim 1, d a d u r c h g e k e n n -z e i c n e t s that the dissolution ratio between exhaust gas and supply air is at least 1: 2, is preferably 1:10 or greater. 3. Heating system according to claim 1 or 2, with a heat exchanger, the a fan is connected upstream or downstream, which is not shown t that the fan (17, 17 ') equally as a suction fan for the combustion chamber of the designed as a fan burner combustion heat source (27) is provided, which Combustion air or combustion mixture promotes into the combustion chamber. 4. Heating system according to claim 1 or 2, with a heat exchanger, to the a fan is connected upstream or downstream, which is not shown t that the fan (17, 17 ') at the same time as a suction fan for the combustion chamber of the combustion heat source (27) designed as a pulsating burner is provided, which ventilates the combustion chamber when the pulsating burner starts. 5. Heating system according to one of claims 1 to 4, with a heat exchanger, which is preceded by a centrifugal fan, d u r c h g e k e n n n z e i c h n e t that the exhaust gas is supplied in the area of the fan axis and that the supply air initially concentric to the fan jacket (19) against the direction of flow of the exhaust gas guided and then deflected while being swirled with the exhaust gas (Fig. 2). 6. Heating system according to one of claims 1 to 4, with a heat exchanger, which is preceded by an axial fan, d u r c h g e k e n n z e i c h n e t that the exhaust gas at a point near the fan blades and the supply air is supplied distributed over the entire fan cross-section (Big. 3). 7. Heating system according to claim 6, d a d u r c h g e k e n n -z e i c h n e t that the combustion heat source (27) wholly or partially with the heat exchanger (12) and the fan (17!) Is arranged in a common housing (11 '). 8. Heating system according to claim 7, d a d u r c h g e k e n n -z e i c h n e t that the housing (11 ') is soundproofed on the outside of an outer wall of the building (20) is attached. 9. Heating system according to one of claims 1 to 4, with a heat exchanger, which is followed by a radial fan, d u r c h g e k e n n n z e i c h n e t that the supply air and the exhaust gas are distributed over the entire fan cross-section are supplied (Fig. 4). 10. Heating system according to claim 9, d a d u r c h g e k e n n -z e i n h n e t that the heat exchanger (12) and the fan (17) in a common housing (11 ") are attached to the outside of a building outer wall (20) that an exhaust pipe (10) the combustion heat source (27) immediately before the heat exchanger (12) in the essentially perpendicular to the direction of flow of the supply air into the housing (in ") is inserted and that in the housing (11 ") located pipe section (10a) of the Exhaust pipe (10) is provided with outlet openings, which the heat exchanger (12) facing0 11. Heating system according to claim 10, d a d u r c-h g e k e n n -z e i c h n e t that a further pipe section (lOb) of the exhaust pipe (iOj essentially passed through the housing (11 ") parallel to the first pipe section (10a) is and that in the exhaust pipe (10) or in one of its pipe sections (10a, lOb) a flow diverter (28) for optionally shutting off one of the two pipe sections (10a, lOb) is arranged. 12. Heating system according to claim 9 or 10, d a d u r c h g ek e n n z e i c h n e t that an air mixer on the inside of the building outer wall (20) (22) is attached, its suction side optionally with the air supply side of the housing (11 ") or can be connected to the surrounding room air and its The outlet side either with the surrounding room or with the supply air side of the housing (11 ") can be connected.