EP0356690B1 - Fuel-fired heat producer - Google Patents

Abstract

A heat producer has, in addition to a main pipe (21) which guides a fuel/air mixture of controlled composition, a secondary pipe (22), which can be switched on and off alternatively, with an associated fuel pipe (23). The variation range from minimum to maximum heating output, which is limited by the performance in service of the burner, is to be increased. The outlet pipe (5) and the inlet pipe (2) of the heat producer are interconnected by means of a return pipe (71) which is provided with a valve (72) and via which a flow of exhaust gas, which decreases with an increase in the size of the flow of fuel/air mixture which is supplied to the burner (1), can be added to the latter flow. As a result of this, the minimum output of the burner (1) is greatly reduced because by adding the exhaust air the outflow rate at the burner is increased and at the same time the ignition rate of the fuel/air mixture is reduced, so that stable relationships are maintained at the burner even with a very small flame. <IMAGE>

Description

The invention relates to a fuel-fired heat generator with a burner, which has an inlet line for supplying a fuel / air mixture and an outlet line for discharging the exhaust gases, with a main line connected to the inlet line, in which a flow sensor is arranged, with a first fuel line, introduces a fixed-size fuel flow that determines the minimum heating output into the area of the main and inlet lines between the flow sensor and the burner, with at least one secondary line that supplies an air flow that is proportional to its cross-section to the inlet line, with a second fuel line that surrounds the inlet line Area a second fuel flow introduces, which is in the same ratio to the fuel flow of fixed size as the cross section of the branch line to the cross section of the main line, with a fan determining the size of the air flow flowing through the lines and with a delivery rate of the fan depending on the output signal of the main line arranged flow sensor controlling control device.

Such a heat generator is known from DE-A-37 00 084. It enables the burner to be operated in a very simple manner with flows of the fuel / air mixture of very different strengths while maintaining the optimum fuel / air ratio. Nevertheless, the controllability of such a heat generator is subject to strict limits because the outflow speed of the fuel / air mixture does not allow for a large variation. If the outflow rate exceeds the ignition rate of the fuel / air mixture, the flame breaks off. If, on the other hand, the outflow speed becomes too low, the flame moves too close to the burner and the burner is inadmissibly overheated due to the reduced cooling capacity due to the reduced flow speed.

In contrast, the invention has for its object to develop a fuel-fired heat generator of the type described in such a way that the heating output can be varied to a much greater extent than in the known heat generators.

This object is achieved according to the invention in that the outlet line and the inlet line are connected to one another by a return line provided with a valve, via which a flow of the exhaust gas that decreases with increasing size can be mixed with the fuel / air mixture flow.

By adding exhaust gases, the volume of the fuel / air mixture is increased and thereby the outflow speed is increased without the fuel portion of the mixture and thus its heat content being increased or the ratio of fuel to air volume, which is important for optimal combustion, being changed. At the same time, the ignition speed of the mixture is reduced by the addition of exhaust gases, so that a reduction in the throughput compared to conventionally operated burners is also possible. The double effect of increasing the throughput with a constant calorific value and reducing the ignition speed makes it possible to operate conventional burners far below the minimum power required previously, thereby considerably expanding their control range.
A particular advantage of this measure is that it does not require any complicated measures to regulate the composition of the fuel / Lusft mixture or the burner behavior, but the advantages of the known heat generator are retained in full.

In the German patent application DE-A-37 08 573, the content of which is considered to be prior art, a valve arrangement is described which enables the heat generator according to DE-A-37 00 084 to be designed in a particularly simple manner. A similar arrangement can also be used successfully with the heat generator designed according to the invention. Accordingly, a preferred embodiment of the invention provides that the secondary line, the second fuel line and the return line open side by side in the inlet line and the mouths of the three lines a common slide is assigned, which can optionally be brought into a position which simultaneously releases or covers the two mouths of the secondary line and the second fuel line, in which it covers or releases the mouth of the return line in the reverse manner.

When using such a valve arrangement, there is no need to install separate valves in the return line, the secondary line and the second fuel line and, if necessary, to connect them to a common drive. In addition, special fittings such as T-pieces or the like need not be provided in order to bring the various lines together, since the valve arrangement according to the invention fulfills both the functions of the shut-off valves and the line mergers. Therefore, such a valve arrangement significantly simplifies the structure and reduces the space requirement of fuel-fired heat generators of the type described.

The use of such a valve arrangement is particularly advantageous if not only a sudden increase in heating power by completely switching on the secondary line and the second fuel line with a corresponding complete blocking of the return line is desired, but a more or less constant change in the heating power because it is the Valve arrangement enables that in a further embodiment of the invention the orifices of the secondary line, the fuel line and also the return line have cross sections which are proportional to one another and the slide can be able to be brought into intermediate positions in which it releases or covers corresponding portions of the orifice cross sections. Do the outlets of the secondary line and the return line have a rectangular Cross-section, the throughputs of the secondary line and the return line are exactly proportional to the travel of the slide or inversely proportional. In this case, either the mouth of the associated fuel line can also have a rectangular cross section, or all holes can have the same diameter when using holes.

For the mechanical construction of the valve arrangement of such a heat generator, it is particularly advantageous if the main line, the secondary line and the return line open into the inlet line in the region of a chamber having an arcuate wall section and the slide is designed as a rotary slide valve. Rotary slide valve arrangements are particularly easy to manufacture and allow simple storage and also particularly simple drive of the slide valve. The chamber can be formed in a particularly simple manner completely by a cylindrical pot open at one end, in the jacket of which, in addition to the secondary line, the return line also opens, while the inlet line leading to the burner of the heat generator connects to the open end of the pot. In this embodiment of the invention, the bottom of the chamber also permits the bearing of a shaft which is sealed off from the bottom and to which the slide is fastened inside the chamber and whose end penetrating the bottom is connected to a drive motor.

Fig. 1

eine schematische Darstellung eines Wärmeerzeugers nach der Erfindung in schematischer Darstellung,

Fig. 2

einen Schnitt längs der Linie II-II durch eine Ausführungsform der in Fig. 1 nur schematisch dargestellte Ventilanordnung des Wärmeerzeugers und

Fig. 3

einen Schnitt längs der Linie III-III durch die Ventilanordnung nach Fig. 2.

The invention is described and explained in more detail below with reference to the embodiment shown in the drawing. The features to be gathered from the description and the drawing can be used in other embodiments of the invention individually or in combination in any combination. Show it

Fig. 1

1 shows a schematic illustration of a heat generator according to the invention,

Fig. 2

a section along the line II-II through an embodiment of the valve arrangement of the heat generator shown only schematically in Fig. 1 and

Fig. 3

a section along the line III-III through the valve assembly of FIG. 2nd

The heat generator shown in the drawing has a burner 1, to which a gas / air mixture is supplied via an inlet line 2. The burner 1 is located within a boiler housing 3, which also encloses the heat exchanger 4 of a heating system. The boiler housing 3 is provided with an outlet line 5 for the exhaust gases, in which there is a fan 7 driven by a motor 6.

The inlet line 2 connects the burner 1 to a main line 21, which leads to an air inlet opening 8. A temperature sensor 9 and a flow sensor 10 also protrude into the main line 21. The output signals of these sensors 9, 10 are fed to a control device 11. In the area between the sensors 9, 10 and the burner 1, a first fuel line 13 opens into the main line 21 and supplies gas to the main line as fuel. A gas pressure regulator 14 is located in the fuel line 13 in the flow direction of the gas, so that the main line 21 is supplied with the gas at a predetermined pressure and therefore also as a current of a predetermined strength. In order to have optimal combustion conditions, a precisely defined one belongs to the given gas flow Airflow. The supply of the correct air flow is monitored by the flow sensor 10, the output signal of which is characteristic of the flow speed of the air in the main line 21. The control device 11 controls depending on the output signals of the temperature sensor 9 and the flow sensor 10, the speed of the motor 6 used to drive the blower 7 in such a way that the flow rate required for supplying the correct amount of air prevails in the main line 21. This ensures in a very simple way that optimal combustion conditions are present for the gas supplied to the burner 1.

The main line 21 is connected in parallel to a secondary line 22 which, like the main line 21, opens into the inlet line 2. Similar to the main line 21, the secondary line 22 also has an open end serving as an air inlet opening, and a second fuel line 23 is assigned to it, which branches off from the first fuel line 13 opening into the main line 21. A shut-off valve 24 is located in this second fuel line 23. A shut-off valve 25 is also located in the secondary line 21. The shut-off valves 24 and 25 are connected to a common servomotor 26 which, if necessary, causes the shut-off valves 24, 25 to open and close together .

As can be seen from FIGS. 2 and 3 in more detail, the check valves 24, 25, schematically shown in FIG. 1, for the secondary line 21 and the associated fuel line 23 are integrated into a valve arrangement which has a cylindrical pot 31, in the jacket 32 of which the Air inlet opening 8 leading section 2 of the main line and the secondary line 21 open. As can be seen, both lines have the same rectangular cross-section in the exemplary embodiment shown and are arranged parallel to one another in such a way that they abut one side 27 and 28, respectively. The leading to the burner 1 section 2 'of the main line connects to the open end of the pot 31.

The section 2 'of the main line opposite end of the pot 31 is provided with a bottom 33 into which an annular channel 34 is incorporated. For this purpose, the bottom 33 consists of two disk-shaped parts 35, 36, of which the upper part 36 has a groove forming the annular channel 34 on its side facing the lower part 35. The lower disc-shaped part 35 is provided with a screw connection for the gas line 13, so that the gas line 13 opens into the annular channel 34. This ring channel 34 communicates with the interior of the pot 31 via bores 37 and 38, of which the bore 37 is arranged in front of the mouth of section 2 of the main line and has a diameter such that the amount of gas entering the pot via this bore 37 corresponds to the minimum output of the burner, to which the amount of air flowing through the main line 2, 2 'is set by means of the sensors 9, 10.

The bores 38 are arranged within the sector 39 delimited by dash-dotted lines in FIG. 2, which is defined by the mouth 40 of the secondary line 21 in the jacket 32 of the pot 31, and next to one another on a circular arc 41, likewise indicated by dash-dotted lines. The bores 38 in their entirety form the fuel line 23 assigned to the secondary line 21. The overall cross section of these bores 38 is so dimensioned that the amount of gas supplied through these holes to the pot 31 to the amount of air supplied via the secondary line 21 is in the same ratio as the amount of gas supplied via the bore 37 to the amount of air supplied through section 2 of the main line. The amount of gas supplied over the entirety of the bores 38 and the amount of air supplied via the secondary line 21 can be dimensioned such that the maximum output of the burner 1 is achieved together with the fuel / air mixture always carried by the main line 2, 2 ' . In the illustrated embodiment, the section 2 of the main line and the secondary line 21 leading to the air inlet opening 8 have the same cross section, so that the entirety of the bores 38 has the same cross section as the bore 37 and the heating power of the burner 1 is doubled by switching on the secondary line 21 can be.

In the illustrated embodiment of the valve arrangement, a rotary slide valve 51 serves as shut-off valves 24, 25 for the secondary line 21 and the associated gas line 23, which is fastened on the inner end of a shaft 52 which is rotatably mounted in the base 33 and is sealed against the base in a manner not shown is. This rotary slide valve has at its end a plate 53 which is circular in cross-section and which, in a first end position shown, covers the mouth 40 of the secondary line 21 and thus blocks the secondary line 21. In its section connecting the plate 53 to the shaft 52, the rotary slide 51 has a bore 54 perpendicular to the bottom 33 of the pot, in which a stamp-like insert 55 is mounted displaceably and is loaded by a helical compression spring 56 arranged in the bore 54, so that the latter Insert with the outer surface of his head 57 abuts the bottom 33. The diameter The head 57 is dimensioned such that it completely covers the holes 38 arranged on the circular arc 41 when the plate 53 covers the mouth 40 of the secondary line 21. By pivoting the rotary valve 51 by an angle which is substantially equal to the angle of the sector 39 defined by the mouth 40 of the secondary line 21, the rotary valve 51 can be brought into a second end position, not shown in the drawing, in which the plate 53 the mouth 40 and also the head 57 of the insert 55 clear all the bores 38. If the rotary slide valve occupies a position lying between these two end positions, the mouth 40 of the secondary line 21 is only partially released. The use of tubes with a rectangular cross section has the result that the mouth 40 of the secondary line also has a rectangular cross section and the released section of the secondary line is exactly proportional to the swivel angle of the rotary valve. Likewise, the use of a number of bores 38 as the mouth of the fuel line assigned to the secondary line 21 ensures that the amount of gas supplied is proportional to the number of bores released and thus in turn to the swivel angle of the rotary valve. It is advisable to gradually adjust the rotary valve so that one additional hole is completely released or covered. If a completely constant change in the heating output is desired, the row of holes could be replaced by a corresponding slot. It would also be possible to partially cover a larger bore similar to the mouth of the secondary line, in which case such a bore would correspond to a circular mouth of the secondary line. With regard to a linear dependency of the power change on the angle of rotation, however, the described embodiment preferred with a rectangular mouth of the secondary line and a correspondingly designed mouth of the associated fuel line.

The particular advantage of the invention is that by using a common slide to release or shut off the secondary line and the associated fuel line there are no problems for the motor drive of the valve arrangement. In the illustrated embodiment, the drive motor 26 for the rotary valve 51, which corresponds to the two shut-off valves 24, 25 according to FIG. 1, is fastened to the base 33 of the pot 31 by means of a holder 61 such that the output shaft 62 of the motor with the rotary valve 51 supporting shaft 52 is aligned and can be connected to this shaft by a plug-in coupling 63. The motor 26 can be a stepping motor, but it can also be a continuously running motor with appropriate control, which preferably has a strong reduction, since the rotary valve 51 may only be adjusted at a relatively low speed. Since the air throughput is determined by the delivery capacity of the blower 7, the change in the line cross sections and thus the fuel supply must not take place faster than the speed at which the blower 7 can react to the changed air requirement.

It goes without saying that the invention is not restricted to the exemplary embodiment shown, but deviations from it are possible without leaving the scope of the invention. For example, it is readily apparent that the cylindrical shape of the pot is only important for the pivoting range of the rotary valve, so that even when using a rotary valve, the chamber formed by the pot is also different Can have a cross-sectional shape as long as only the secondary line opens into a cylindrical wall section and there is sufficient space for the rotary valve to pivot away. Furthermore, it can be seen that instead of a rotary slide valve, a linearly movable slide valve can also be used and that it is possible to provide the mouths of the air and gas lines in the same wall section. There is the possibility of arranging these orifices one behind the other at a sufficient distance in the direction of movement of the slide and also on the same wall perpendicular to the direction of movement of the slide. It should also be mentioned that in the case of heat generators which have such a valve arrangement, the fan could be arranged at an air inlet common to the main line and the secondary line. In view of all these many possibilities, however, the embodiment of the valve arrangement shown is regarded as the optimal implementation of the invention because of its particularly simple and compact design.

Claims (6)

1. Fuel-fed heat producer with a burner (1) having an inlet duct (2) for the supply of a fuel/air mixture and an outlet duct (5) for the discharge of the burnt gases, with a main duct (21) for air which is connected to the inlet duct and in which a flow sensor is arranged, with a first fuel duct (13) which feeds into the area of the main duct and the inlet duct between the flow sensor and the burner a fuel flow of a fixed value determining the minimal heating power, with at least one side duct (22) for air which supplies the inlet duct with an air flow proportional to its cross-section, with a second fuel duct (23) which feeds into an area comprising the inlet duct a second fuel flow which has the same ratio to the fuel flow of the fixed value as the cross-section of the side duct to the cross-section of the main duct, with a fan (7) determining the value of the air flow flowing through the ducts and with a control unit (11) regulating the capacity of the fan dependent on the output signal of the flow sensor arranged in the main duct,
   characterized in that
   the outlet duct (5) and the inlet duct (2) are connected with one another by a return duct (71) provided with a valve (72), via said return duct a flow of the burnt gases decreasing as the fuel/air mixture flow increases can be mixed into the fuel/air mixture.
2. Heat producer according to claim 1, characterized in that the side duct (22), the second fuel duct (23) and the return duct (71) end side-by-side into the inlet duct (2) and the muzzles (40, 38, 73) of the three ducts are related to a common slide valve (51) which can selectably be brought into a position which simultaneously releases or covers the two muzzles (40, 38) of the side duct (22) and of the second fuel duct (23), in said position it covers or releases the muzzle (73) of the return duct (71) in the reverse way.
3. Heat producer according to claim 2, characterized in that the muzzles (46, 73) of the side duct (21) and of the return duct (71) have rectangular cross-section.
4. Heat producer according to claim 2 or 3, characterized in that the main duct (21), the side duct (22) and the return duct (71) end into the inlet duct (2) in the area of a chamber (31) having a circular wall section (32) and the slide valve (51) is provided as a rotary slide.
5. Heat producer according to claim 4, characterized in that the chamber (31) is formed by a cylindrical pot open on one end, in the shell (32) of said pot the return duct (71), apart from the side duct (21) also ends, whereas the inlet duct (2) leading to the burner (1) of the heat producer adjoins the open end of the pot.
6. Heat producer according to claim 5, characterized in that the slide valve (51) is fastened to a shaft (52) which is supported in the bottom (33) of the chamber (31) and is sealed against the bottom, said shaft is linked with a driving motor (26) at the outside of the bottom (33).

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