NL1006891C2 - Heating plant with burner - Google Patents

Abstract

The outer surface provided with apertures (4) is accessible from the burner body (3) for ambient air. A heat exchanger (7,8) is flowed through by at least a first heat transport medium and is positioned at a short distance from the apertures. During the operation of the burner the heat exchanger is in direct contact with the flames emitted by the burner (2). On the side of the first heat exchanger turned away from the burner is located a second heat exchanger through which flows a second heat transport medium. The first heat transport medium can be water or another fluid, air or another gas. The two heat exchangers are accommodated in a common housing.

Description

HEATING DEVICE

A known heating device comprises a burner with an internal cavity provided with a burner body with a number of openings each opening on the one side on the cavity and on the other side on the outer surface, to which cavity 5 a supply for non-solid fuel connects, the apertured outer surface of the burner body is accessible to ambient air.

The heat released by the burner in the form of combustion gases is passed along a heat exchanger 10, which is flowed through a heat transport medium. Due to the contact between the aforementioned exhaust gases and the heat transport medium flowing through the heat exchanger, heating of that medium takes place and heat can be transported to a desired place and in accordance with a set goal.

It is a known drawback of such devices that the flue gases, even after passing through the heat exchanger, contain a considerable proportion of nitrogen oxides (ΝΟχ). It is known that such gases promote the formation of acid rain.

It is therefore an object of the invention to design a heating device such that the emission is reduced from ΝΟχ to greatly reduced proportions.

It is a further object of the invention to further improve the efficiency with which the energy delivered by the burner is transferred to the or each heat transport medium.

In connection with the above objects, the invention provides a heating device, comprising: a burner with a burner body to be provided with an internal roller, with a number of openings each opening on the one hand on the cavity and on the other on the outer surface, on which cavity a non-solid fuel supply 5, wherein the apertured outer surface of the burner body is accessible to ambient air, and a distance of such apertures positioned at such a short distance from those apertures that flows through at least one first heat transport medium such that these are exchanged during operation of the burner is in direct contact with the flames emitted by the burner.

It is essential for the invention that during operation of the burner the flames released thereby are in direct cooling contact with the heat exchanger. The cooling effect of this arrangement on the flames suppresses the formation of ΝΟχ to a considerable extent, while furthermore, due to the intense thermal contact between the flames and the heat exchanger, the thermal transfer efficiency can be very high.

In a specific embodiment the heating device according to the invention has the feature that on the side of the first heat exchanger facing away from the burner there is a second heat exchanger which can flow through at least one second heat transport medium.

This second heat exchanger is placed downstream of the first heat exchanger in the gas stream 30 and is therefore subject to a lower temperature. Depending on the dimensioning of the two heat exchangers, it is nevertheless quite possible that the second heat exchanger extracts a greater amount of heat from the flue gases than is taken up from the flames by the first heat exchanger.

These heat flows partly depend on the effective heat-exchanging surface and various physical parameters with regard to the relevant 1006891.

3 heat transfer media. A specific embodiment has a special feature that the first heat transport medium is water or another liquid. The liquid generally has a better ability to transport heat. This is an essential property, in particular for the first heat exchanger, which after all has to cool the flames emitted by the burner to an essential degree. By the use of liquid, a large cooling capacity can be realized with a relatively low flow rate, which can only be achieved with high flow rates when gas is used.

Since the second heat exchanger is a less critical component with respect to the heat transfer, it may very suitably be designed such that the first heat transfer medium is air or other gas.

For example, the first heat exchanger can thus serve for heating heat transfer medium for a central heating installation or hot tap water, while the second heat exchanger can for instance serve for space heating with air.

Preference is given to an embodiment in which the burner and the first heat exchanger are housed in a common house. As a result, a natural thermal coupling is realized, while, moreover, the flames released by the burner are bounded by the housing.

The described embodiment with both a first and a second heat exchanger preferably has the special feature that the burner, the first heat exchanger 30 and the second heat exchanger are accommodated in a common housing.

In order to make the operation of the burner and the thermal transfer as controllable as possible, use is preferably made of an embodiment in which the housing comprises fan means for forcing a flow of ambient air to the burner.

A specific embodiment has the special feature that the first heat exchanger comprises more than one circuit that can be flowed through for the first 1006891 4 heat transfer medium. By selectively adjusting each of the flow rates of the first heat transfer media, the respective temperatures and heat transfers are also controllable within wide limits.

In principle, the same applies to an embodiment in which the second heat exchanger comprises more than one circuit that can be flowed through for a second heat transfer medium.

A preferred embodiment is characterized in that the first heat exchanger comprises at least one conduit for transporting the first heat transfer medium, which conduit consists of heat-conducting material, for example metal, such as copper, on the outer surface of which surface-enlarging means, such as fins or wires, of heat-conducting material, around which surface-enlarging means are placed guide plates, which conduct the flames emitted by the burner along those surface-increasing means. This achieves the greatest possible efficacy and associated yield.

A very simple variant has the feature that the conduit is straight. The surface-enlarging means may be arranged on the peripheral surface, such as the aforementioned slats, wires or the like. The advantage of a straight pipe is that the manufacture of the heat exchanger in question can be very simple.

As is known, a straight pipe has the drawback of a relatively short length and limited turbulence in the heat transfer medium flowing through. As a result, the thermal transfer can leave something to be desired. To cope with this inconvenience, turbulence-promoting provisions may be present in the conduit, for example an inlaid helical structure, screw thread, increased surface roughness, or the like.

Yet another embodiment has the special feature that the second heat exchanger is of the cross flow type.

ï υ 0 6891 5

The invention will now be elucidated with reference to the annexed drawing of an exemplary embodiment. It will be clear that the drawing is not limited to this, however.

5 In the drawing shows:

Fig. 1 is a partly broken away perspective view of a heating device according to the invention; and

Fig. 2 is a highly schematic longitudinal sectional view of the heating device of FIG. 1.

Figures 1 and 2 show respective heating devices 1,20 according to the invention.

The heating device 1 comprises a burner 2 with a burner body 3 provided with an internal cavity (not shown) with a number of openings or nozzles 4, each of which opens on the one hand on the cavity and on the other side on the outer surface of the burner body 3. A supply 5 for gaseous fuel connects to the cavity. The openings 4 are accessible on their outside for ambient air, which is indicated by 6 in Fig. 2.

A heat exchanger unit 7,8 is placed at a short distance above the nozzles or openings 4. This comprises two straight copper tubes, 9,10 respectively on the outer surface of which copper or aluminum fins 11,12 are arranged. As Fig. 1 clearly shows, the slats 11,12 are placed at such a small height above the openings 4 that the flames 13 emitted thereby are in direct contact with the slats 11,12, which has a considerable cooling effect on these flames . Due to this cooling effect, the Ν0χ emissions are greatly limited. The straight tubes 9,10 are flowed through water in two separate circuits.

Arrows 13,14 respectively indicate the respective currents. The water flows 13, 14 can be used for transporting heat in a central heating installation. One circuit can supply power for convectors, while the other - - cd © i 6, for example, feeds for preheating or another part of the convectors.

A second heat exchanger 13 is placed above the heat exchanger unit 7,8. This comprises a bundle 5 of vertical, heat-conducting tubes 14, through which the still hot combustion gases 15 flow. The heat exchanger 13 is of the cross-flow type and is flowed through by air 16, for example, cold outside air which is heated by thermal contact with the hot tubes 14, so that heated air can be supplied to a space to be heated.

In the embodiment according to Fig. 1, the burner 2 is arranged substantially freely. Ambient air can freely reach openings 4. Around the first heat exchangers 7,8 and the second heat exchanger 13 a jacket 17 is placed, which serves to conduct the flames 18 and the flue gases 15 in such a way that they are kept in intensive contact with the heat exchangers. The jacket 17 thus increases the thermal transfer of the heat supplied by the burner 2 to the water flows 13, 14 and the air flow 16. At the top, the jacket 17 connects to a flue gas outlet 19. This can be connected to a chimney or the like .

The device 20 according to Fig. 2 comprises a housing 21 in which the burner 2, the heat exchangers 7,8 and the heat exchanger 13 are accommodated.

In this embodiment, the intake of ambient air 6 takes place by means of a fan 22. This fan 22 draws in ambient air and transports it 30 with some pressure to the interior of the housing 21 for supplying burner 2 with oxygen. Alternatively, the The fan may also be included in the exhaust 19, in which case it draws in the flue gases and draws in the ambient air through one or more openings in house 21. In the latter case, the burner is subject to heating by the combustion gases. In general, the latter embodiment may have the advantage that there is no risk that in the case of small leaks r i ',' () £ I:, · 1 '·. '/; For example, 7 of the house 21, semi-burned gases are released into the environment.

Fig. 2 schematically shows pumping means 23, 24, respectively, which serve to pump the heat transport media 13, 14 and 16.

Fig. 1 shows that the device 1 has a very flat construction. This has been achieved through the use of straight pipes 9,10. The device can hereby occupy a very small floor space, which is favorable for certain applications.

The drawing does not show the drawing of ignition means for starting the ignition and control means for regulating the supply of gas 25 to the burner 2. In Fig. 1, furthermore, the drawing of an optionally used exhaust fan in exhaust is shown. 19.

The described flat structure is very simply realized in the embodiment according to Fig. 1 by giving the module of pipe bundles 14 a shape corresponding to the desired shape. A pipe module is very flexible in this regard. The pipes connect to perforated end plates 26, 27 which are coupled to jacket 17. The space thus enclosed connects to an inlet pipe stub 28 and a discharge pipe stub 29.

It is not shown that the tubes 9, 10 in the region of the burner can be provided with turbulence-increasing provisions, for instance a helically twisted metal strip or the like.

It will be clear that the slats 11, 12 must be able to withstand the high temperatures of the flames 18 occurring, while in addition they must be so firmly connected to the tubes 9, 10 that an excellent heat transfer of the flames via the slats and the walls of the tubes 9,10 to the water flows 13,14 are ensured.

***** io 68 91

Claims (12)

Heating device, comprising: a burner with a burner body to be provided with an internal roller, with a number of openings each opening on the one hand on the cavity and on the other on the outer surface, to which cavity a supply for non-solid fuel connects, wherein the Outer surface of the burner body provided with openings is accessible to ambient air, and a heat exchanger positioned at such a small distance from those openings 10, which can flow through at least one first heat transport medium, is in direct contact with the flames released by the burner during operation of the burner . 2. Heating device as claimed in claim 1, wherein a second heat exchanger which can flow through at least one second heat transport medium is located on the side of the first heat exchanger facing away from the burner. A heating device according to claim 1, wherein the first heat transport medium is water or another liquid. A heating device according to claim 1, wherein the first heat transport medium is air or another gas. A heating device according to claim 1, wherein the burner and the first heat exchanger are housed in a common housing. 6. Heating device according to claim 2, wherein the burner, the first heat exchanger and the second heat exchanger are housed in a common housing. : 1 Heating device according to claim 5 or 6, wherein the housing comprises fan means for forcing a flow of ambient air to the burner. The heating device of claim 1, wherein the first heat exchanger comprises more than one circuit flowable for first heat transfer medium. 9. Heater as claimed in claim 2, wherein the second heat exchanger comprises more than one circuit that can be flowed through for second heat transfer medium. 10. Heater as claimed in claim 1, wherein the first heat exchanger comprises at least one conduit for transporting the first heat transfer medium, said conduit consisting of a heat-conducting material, for example metal, such as copper, on the outer surface of which surface-enlarging means, such as fins or wires, of heat-conducting material, around which surface-enlarging means are placed guide plates, which conduct the flames released by the burner 20 along those surface-increasing means. A heating device according to claim 10, wherein the conduit is straight. A heating device according to claim 2, wherein the second heat exchanger is of the cross flow type. ***** 1006891