DE102006057349B4 - Supply air control of a biomass furnace - Google Patents

Abstract

Method for controlling the air supply for biomass firing, comprising:
Measuring the amount of air taken from a space in which the biomass furnace is located, the amount of air taken being supplied to combustion in the biomass furnace;
- measuring an amount of fresh air supplied to the room via the biomass furnace; and
- Controlling the amount of fresh air supplied as a function of the air removed from the room.

Description

Field of the invention

The The present invention relates to a control of the air supply of a Biomass firing, and in particular a control or regulation considering from supplied and used air.

Background of the invention

It Various types of biomass furnaces are known, such as Biomass furnaces for the most diverse requirements with regard to the Performance, for example large-scale plants, medium or even residential installations.

modern Biomass combustion, as used in private households often take air from the room in which they are placed for the Combustion in biomass firing. The air taken from the room Biomass combustion is supplied either as primary and / or as secondary air. For example have modern stoves, which have a transparent panel in the kiln door, a secondary air duct on at the secondary air over the Clear window led is to keep them free from combustion residues. Other kilns, on the other hand even take air from the room as primary air and as secondary air for the Combustion. But also in biomass combustion, which is an external air supply exhibit, will - like above for example for the Stove described - secondary air to the room, in which the biomass firing is set up, taken for combustion.

Spaces that are substantially airtight, as is the case for example with low energy houses Consequently, they are not readily suitable for generating biomass in it to operate. The same applies to Facilities, their air, for example, by an air conditioner or another ventilation system is exchanged. In the former case, the use of a biomass furnace in a more or less airtight room cause the oxygen content decreases in the room air.

in the second case, the operation of a biomass furnace due to the for the Combustion of extracted room air, to disturbances in the forced ventilation or to disturbances in the operation of other ventilation systems, such as air conditioning, lead.

From the DE 100 12 485 B4 It is known to supply outside air to a single fire place in a low energy house. The outside air supply can be controlled in dependence on a combustion chamber temperature of the individual fire place.

The DE 298 20 785 U1 discloses a heater with a gas burner. The air supply and the gas supply are controlled based on a predetermined characteristic in response to a requested load.

A combination of heating and venting device with a heat source is off CH 665 270 A5 known. An exhaust duct for the fuel-fired heat source has a blower and a vent port located upstream of the blower. During downtimes of the fuel-fired heat source can be made via the vent port and the fan venting a room in which the heat source is placed.

task The invention is an improved method for controlling or Provide control of biomass firing.

Summary of the invention

One The first aspect of the present invention relates to a method for controlling the air supply for a Biomass firing, comprising: measuring, taken from a room Air quantity in which the biomass firing is arranged, the taken amount of air is supplied to a combustion in the biomass furnace; Measuring a room over the biomass firing amount of fresh air supplied; Controlling the supplied Fresh air quantity depending on from the amount of air taken from the room.

One second aspect of the present invention relates to a control or regulating device for controlling the air supply for a biomass combustion, comprising: a microprocessor; a memory; a first air quantity measuring device, which is set up, one from a room in which the biomass firing is arranged to determine the amount of air removed and a first measurement output, the amount of air taken from a combustion in fed to the biomass combustion becomes; a second air flow meter, which is set up, an amount of fresh air supplied to the room via the biomass firing to determine and output a second measured value; the Microprocessor stores the first and second measured value in the memory and based on a comparison of the first and second measured values outputs a control signal to an actuator for the fresh air supply in dependence of the first measured value to control.

A third aspect of the present invention relates to the use of a control device according to the second aspect of the present invention for controlling the air supply for biomass firing.

Further Aspects and features of the invention will become apparent from the dependent claims, the attached Drawing and the following description of preferred embodiments.

Brief description of the drawing

embodiments The invention will now be described by way of example with reference to the accompanying drawings described in the:

1 a schematic sectional view of an embodiment of a biomass combustion in a room in accordance with the invention illustrated;

2 a schematic sectional view of a second embodiment of a biomass furnace in a room in accordance with the invention;

3 an embodiment of a control sequence in accordance with the invention;

4 an embodiment of a control device in accordance with the invention explained.

Description of the preferred embodiments

In 1 FIG. 2 illustrates a first embodiment of a biomass furnace in a room with a fresh air control device in accordance with the present invention. Before a detailed description first follows general explanations to the embodiments and their advantages.

To the embodiments are there biomass furnaces for different types of biomass that serve as fuel. With Biomass furnaces are, for example, kilns for burning biomass, like logs, shredded material, Pellets, agricultural fuels (eg cereals, Straw), reeds, sewage sludge, Textile fibers, etc. meant. The biomass furnaces in the embodiments not only differ in terms of their fuel used (biomass), but also in terms of their construction and their purpose. Uses include, for example, the use as a small room fire, such as for example, as a stove, over a complete home central heating, which also produces hot water, up to the middle plant, as for example for larger halls or for heating stables and other residential / commercial buildings For example, be used in agriculture.

In the embodiments is the air supply for the biomass firing different. In some embodiments will the for Combustion in biomass firing needed air completely taken from the room in which the biomass firing is located. In other embodiments however, the air supply is split. For example, primary air is from outside the Room in which the biomass firing is located, while secondary air, out taken from the room. In some embodiments, the secondary air is additionally as window cleaning a transparent pane of a furnace door used. In others again embodiments will the primary and secondary air from outside the Room supplied and an additional one Air flow removed from the room and thus passed over the disk so rinse. In again other embodiments is also the disc cleaning air from outside supplied to the room. It is in the embodiments consequently realizes all possibilities: Primary-, secondary and / or disc purging air each supplied separately or in combination from outside the room or taken from the room. The division between primary and secondary air (and - depending on Embodiment - also the Window flushing) takes place in the embodiments in different ways. In some embodiments, this will a slider is used, while in others an electronic control device, around the air supply between primary and secondary air (and ever according to embodiment - the disc purging air) accordingly to control.

The Air supply is thus divided in some embodiments by a part of the air from outside supplied to the room will, while another part of the air is taken from the room in which the biomass firing stands. The outside supplied Air is in the embodiments partly called fresh air. This is meant to express be that these Air just is not taken from the room in which the Biomass combustion is located. The fresh air must therefore in the embodiments not necessarily from for example outside fed to a house become. The fresh air differs accordingly from the room air in that they comes from another "air reservoir".

The space in which the biomass furnace is located, in some embodiments as a closed volume of air auffaßbar. Completed here is not a completely closed air volume referred to, but the seclusion of the room or the air volume is such that the amount of air that is fed to the biomass combustion during combustion, is greater or at least of the same magnitude tion is how the amount of air that is supplied by space leaks in the "closed air volume".

In other embodiments on the other hand biomass firing is located in a room where certain amounts of air to or removed become. This happens, for example, due to a ventilation system or an air conditioning system for heating / cooling or indoor climate improvement Exchange indoor air to a certain extent.

As from the above becomes clear, the operation of a biomass firing in one closed room or in a room equipped with a ventilation or air conditioning system, cause a certain negative pressure arises. This negative pressure in the room can arise because the biomass firing for the combustion draws air from the room. In "dense" rooms is Accordingly, the air consumption by biomass firing greater than the amount of air supplied by the leaks in the room. At air-conditioned clear or rooms, the to a ventilation system Although this negative pressure may be due to the air conditioning or the ventilation system compensated by an appropriate regulation or control become. However, this may cause the air conditioning or ventilation system no longer in the desired Way is operated.

In some embodiments will create a negative pressure in a closed space or a fault of ventilation systems or air conditioning systems by those taken from the biomass firing Air is prevented. This is achieved in some embodiments in that the of the quantity of air taken from biomass firing by the same amount on supplied fresh air is compensated. As stated above, the fresh air is a Air reservoir taken outside the room in which the biomass firing is set up.

In some embodiments will be the supplied Fresh air quantity by means of an air quantity sensor, for example a mass flow sensor, measured in a supply air line, which the Biomass firing supplied with fresh air. The used air, So the air that is taken from the room, flows in some embodiments past another air flow sensor. This second air flow sensor is located, for example, in an air supply line, the room air leads to combustion in biomass combustion.

In some embodiments will be the supplied Fresh air is passed through the biomass firing, so that they have a certain amount of heat receives. In some embodiments is therefore the fresh air to, for example, room temperature heated before she led into the room becomes.

By the determination of the amount of fresh air supplied and the amount of air taken from the room for combustion, it is in some embodiments possible, an actuator for the fresh air supply in dependence to adjust the amount of air taken from the room, for example such that the supplied Fresh air amount of the volume of combustion air taken from the room corresponds.

The Determination of the amount of air relates in some embodiments on the volume of air while it is in other embodiments refers to the mass of air. That is, in some embodiments is the density of the supplied Air or the used air determined. With supplied air Here again the fresh air is meant, while with spent air the Air is meant to come from the room for combustion in biomass firing was removed.

Of the Balancing between supplied Fresh air and used room air is not in all embodiments absolutely complete. In some embodiments For example, more fresh air is supplied than by biomass combustion for combustion is consumed. In other embodiments however, the amount of fresh air supplied is lower than that for the combustion consumed room air.

In some embodiments includes the Biomass firing a control or regulation by means of which the Fresh air supply is controlled or regulated. In some embodiments comprises such a controller or a microprocessor, the corresponding data analyzed. To do this, the microprocessor receives data which the supplied Represent fresh air quantity and data representing the amount of indoor air consumed, and places them for example in a memory for further processing from. The microprocessor then compares the two air quantity data, So the data for the amount of fresh air supplied and those for the amount of indoor air consumed, and outputs a corresponding control signal for one Control of fresh air supply off. This control process or Control sequence is determined in some controls or regulations in certain Time intervals repeated. These time intervals can be arbitrary be set as is for the Professional is obvious.

In some embodiments, the biomass firing or the control or regulation of the biomass firing corresponding Stell For example, to control or regulate the supply of fresh air, the exhausted room air, the division between primary and secondary air and the deduction of the resulting flue gas during combustion. These actuators can each be operated individually or in combination with each other in the embodiments. In some embodiments, at least one actuator is realized. The actuators are different depending on the embodiment and include, for example, blower, slide, plates or similar actuators. In some embodiments, not all actuators are electrically operable, but are, for example, mechanically operable.

Coming back to 1 , this shows a room 1 with a biomass firing 5 , as it can be used in the embodiments. The space 1 is with a wall 3 surrounded in the 1 is shown as dense. This is, of course, an idealized representation and a dense space is understood here to mean a space in which the amount of air supplied due to leaks is so low that the consumption of ambient air during combustion causes a vacuum in the space 1 can arise. The biomass firing 5 has an internal structure, not shown 6 on. Furthermore, the biomass firing 5 an air supply line 21 on, through the fresh air 13 into biomass firing 5 arrives. The amount of fresh air supplied 13 is by means of a Luftmengenmeßmittels, here for example a mass flow sensor 11 , certainly. On the opposite side is a fresh air exhaust pipe 27 from which the supplied fresh air 13 as fresh air 8th the room 1 is supplied. The mass flow sensor 11 , located in other embodiments at a different position. For example, the mass flow sensor is located 11 within the structure 6 biomass firing 5 , In some embodiments, not the completely supplied fresh air 13 again to the outside as fresh air 8th in the room 1 but it is part of the fresh air supplied 13 as primary air and / or as secondary air for combustion in biomass firing 5 used. That is, in some embodiments, the mass flow sensor is used 11 not the complete amount of fresh air supplied 13 measured, but only the amount of fresh air, as fresh air 8th in the room 1 to be led. In other embodiments, in turn, although the complete amount of fresh air 13 certainly, that of biomass firing 5 is supplied. However, in some embodiments, within the structure 6 biomass firing 5 a corresponding control, which is set up, a more precisely determinable part of the supplied fresh air quantity 13 as fresh air quantity 8th for the room 1 is intended to dissipate.

In the 1 shown biomass firing 5 also has a flue gas outlet 19 on, out of the flue gas 23 from biomass firing 5 Will get removed. The flue gas 23 occurs during combustion within the structure 6 biomass firing 5 , Furthermore, in 1 a flue gas fan 17 shown the deduction of the flue gas 23 from biomass firing 5 can control.

The biomass firing 5 also has a room air duct 25 on, through which room air 7 into biomass firing 5 arrives. The room air 7 is used for combustion in biomass firing 5 expires, needed. The crowd coming out of the room 1 discharged room air 7 , Is by means of a Luftmengenmeßmittels, here a mass flow sensor 9 , certainly. In this way, therefore, with the mass flow sensor 11 the amount of fresh air supplied 13 determined and with the mass flow sensor 9 coming from the room 1 discharged room air volume 7 ,

A controller that works in 1 is not shown, controls based on that of the mass flow sensor 11 supplied fresh air quantity and the mass flow sensor 11 supplied air volume a fresh air actuator. The fresh air actuator includes, for example, a fresh air blower 15 , by means of which the amount of fresh air supplied 13 can be controlled precisely. By comparing that of the mass flow sensor 11 and the mass flow sensor 7 supplied measured data and based thereon control of the fresh air blower 15 , So it is possible, the amount of fresh air supplied 13 exactly the discharged air volume 7 adapt. As a result, the volume of air in the room remains 1 constant and it arises in the room 1 no underpressure or overpressure.

In some embodiments, the fresh air blower becomes 15 but so operated that in the room 1 sets a certain overpressure. This is definitely a sufficient fresh air supply of the room 1 guaranteed.

In 2 is a second embodiment of a biomass furnace 35 in a room 31 shown. The space 31 has a limit 33 that by symbolized fresh air supply breakthroughs 59 is interrupted. There is still space 31 over a line 65 connected to a ventilation system, not shown. management 65 is still a fan 63 shown what air 61 out of the room 31 can deduct. Of course, the blower 63 be operated so that air to the room 31 is supplied. The fan 63 symbolizes therefore only that the space 31 not "tight". The same applies to the breakthroughs 59 that indicate that room 31 not hermetically sealed. By combining the breakthroughs 59 with the fan 63 , it is accordingly possible, a constant exchange of air in the room 31 adjust. Such a constant air exchange is necessary, for example, to air conditioning or appropriate ventilation or heating of the room 31 to ensure.

Furthermore, in the room 31 a biomass firing 35 arranged, which has a heat exchanger area 67 has and a combustion chamber 66 , Both rooms are shown only symbolically. In the combustion chamber 66 finds a combustion in biomass firing 35 instead of. Flue gas that burns in the combustion chamber 66 is created by a flue gas outlet 49 as a flue gas 53 dissipated. To adjust the flue gas outlet, includes the biomass furnace 35 a smoke glass blower 47 , Furthermore, the biomass firing includes 35 a room air duct 55 , through the room air 37 in the combustion chamber 66 biomass firing 35 arrives. The amount of air supplied 37 is by means of a Luftmengenmeßmittels 39 , For example, a mass flow sensor determined. Furthermore, the biomass firing includes 35 a fresh air supply line 51 in which a fresh air actuator, namely a fresh air blower 43 , is arranged. The amount of fresh air supplied 43 is by means of a Luftmengenmeßmittels, here a mass flow sensor 41 , certainly. The supplied fresh air quantity passes through the fresh air supply line 51 in the heat exchanger area 67 biomass firing 35 , In the heat exchanger area 67 gets the fresh air 43 heated, for example, to room temperature, and further than fresh air 38 in the room 31 issued. A not-shown Frischluftsteuer- or regulation now controls or regulates based on the amount of fresh air supplied 43 and the discharged room air 37 the fresh air actuator 45 such that the amount of fresh air 38 in the room 31 is discharged, the discharged air volume 37 equivalent. This will cause the airflow passing through the blower 63 and the openings 59 is established, not disturbed.

In some embodiments, which are not shown, as described above, the supplied fresh air 43 not completely as fresh air 38 in the room 31 issued. In some embodiments, part of the fresh air becomes 43 for combustion in biomass combustion 35 used. The air distribution of the fresh air supplied 43 within the biomass 35 may be arbitrary in some embodiments. In some embodiments, the split between fresh air is that of combustion in the biomass furnace 35 fed, and the fresh air 38 in the room 31 is fed, controllable.

3 shows an embodiment of a process flow, as for example in a biomass combustion or in a control and / or a regulation of such biomass combustion, as for example in connection with the 1 and 2 described is used. at 100 the amount of air consumed in combustion is measured. This may be, for example, the amount of air that is taken from a room, such as, for example, above in connection with the 1 respectively. 2 has been described. At one step 102 the supplied fresh air quantity is determined. The amount of fresh air supplied is, as stated above, the amount that is supplied from outside the combustion chamber or the biomass combustion, in which the combustion takes place. Accordingly, two quantities of air are determined. Once the amount of air that is taken from a room to be burned. And on the other hand, the amount of air that is ultimately returned to the room from outside. The externally supplied fresh air is not passed through the Biomassefeuerung in all embodiments. There are also exemplary embodiments in which the supplied fresh air is introduced into the room independently of the biomass firing.

at 104 Finally, the supplied amount of fresh air is controlled depending on the amount of air consumed. That is, for example, that the supplied fresh air amount is adapted to the amount of air consumed that the amount of fresh air supplied and the amount of air consumed are substantially equal. Substantially equal here is also to be understood as a scenario in which the amount of fresh air supplied is increased compared to the amount of air consumed. In an increased fresh air quantity supply, ie, in a supply in which the fresh air amount is higher than the amount of air consumed, it is ensured in any case that in the room no negative pressure. On the other hand, in some embodiments, the process will occur so that the amount of fresh air supplied is slightly below the amount of air consumed. In yet other embodiments, the amount of fresh air supplied within the measurement accuracy of the amount of air consumed by the corresponding control is the same.

The connection 105 between the control step and the measuring step for the amount of air consumed symbolizes a loop-like repetition of the method steps. This loop-like repetition of the process steps ensures that during combustion, the supplied fresh air quantity is regularly adapted to the amount of air consumed. The repetition rate of the method steps is different in the exemplary embodiments. In addition, the repetition rate can also depend on other parameters. For example, in some embodiments at a combustion start, the amount of fresh air supplied more frequently adjusted, since at an incipient Ver combustion, the amount of air consumed changes faster than with a uniform burnup. Furthermore, in some embodiments, the repetition rate of the process steps is adapted to the fuel itself. In pellet stoves, for example, a more stable burning behavior and concomitantly a stable consumption of the air quantity is to be expected, so that there are fewer repetition steps in a certain time interval necessary, as for example in a stove. In wood-burning stoves, which are operated, for example, with firewood, due to the fuel used (such as logs) a less constant burning behavior and concomitantly a greater variation in the air consumption is expected.

4 shows an embodiment of a control device 120 , The control device 120 comes for example in a biomass firing, as related to 1 respectively. 2 described is used. Furthermore, in some embodiments, the control device 120 suitable, a procedure, as for example in connection with 3 has been described.

The control device 120 includes a microprocessor 128 and a memory 130 , The microprocessor 128 receives signals from a Luftmengenmeßmittel 122 and an air flow meter 124 , The Luftmengenmeßmittel 122 measures the amount of fresh air supplied and outputs a corresponding data signal to the microprocessor 128 is transmitted. Similarly, the Luftmengenmeßmittel determined 124 the amount of air consumed in a combustion and outputs a corresponding data signal to the microprocessor 128 from. The microprocessor gives both measured data, for example, in the memory 130 , The memory 130 is in some embodiments in the microprocessor 128 self-integrated. Furthermore evaluates the microprocessor 128 the measurement data that he received from the Luftmengenmeßmitteln 122 and 124 had received. Thereafter, the microprocessor outputs a corresponding control signal to the actuator 126 for the fresh air supply. The control signal generated by the microprocessor 128 to the actuator for the fresh air supply 126 is discharged causes the actuator 126 , to be adjusted so that the supplied fresh air amount is substantially equal to the amount of air consumed.

The amount of fresh air supplied or the amount of air consumed is to be understood as described above in connection with the description of 1 to 3 has been described.

In some embodiments, the control device comprises 120 much more control lines or signal line than they are here in 4 are illustrated. In some embodiments, therefore, the in 4 shown control or regulating device is only a small section.

Furthermore, in some embodiments, further data is supplied to the processing of the microprocessor, based on which the microprocessor adjusts the actuator for the fresh air supply. In some embodiments, the control device controls 120 additional actuators. Such actuators are in some embodiments, for example, actuators for a flue gas blower, for an actuator which divides the primary and secondary air, an actuator which divides the fresh air supply to both the combustion and the space in which the biomass furnace is to feed , an actuator for the amount of air that is supplied from the room of combustion, etc.

In some embodiments is next to the supplied Fresh air quantity and the amount of air consumed controlled. there Therefore, not only an actuator for the supply of fresh air, but also an actuator for controlled the amount of air consumed. In yet other embodiments on the other hand, instead of the supplied fresh air quantity, only the used amount of air controlled.

It it is obvious that the above explained embodiments individually or in combination are realized. Furthermore, above explained embodiments combined with known methods or control or regulating operations become. Continue to lead some combinations of embodiments and known state of the art processes to that the supplied Amount of fresh air not only depending on the amount of air consumed is controlled. For example, in some embodiments the control of the fresh air supply with the control of a ventilation or air conditioning for the Room where biomass heating is located, combined. Farther it is obvious that the above embodiments can be used in any biomass furnaces, but also biomass furnaces for the "home use", such as pellet, Log stove, stoves or corresponding combinations thereof.

Claims (12)

A method for controlling the air supply for a biomass combustion, comprising: - measuring the amount of air taken from a space in which the biomass combustion is arranged, wherein the amount of air taken from a Burn tion in biomass firing; - measuring an amount of fresh air supplied to the room via the biomass furnace; and - controlling the amount of fresh air supplied as a function of the amount of air taken from the room. The method of claim 1, wherein the amount of fresh air supplied is controlled so that the supplied to the room Amount of fresh air essentially the amount of air taken from the room equivalent. The method of claim 2, wherein the supplied fresh air is heated by means of biomass firing. The method of claim 3, wherein the heating with Help of a heat exchanger he follows. Method according to one of claims 1 to 4, in which air from the room in addition via an air conditioner is exchanged. Control device for controlling the air supply for a biomass combustion, comprising: - a microprocessor ( 128 ); - a memory ( 130 ); A first air quantity measuring device ( 124 ) arranged to determine a quantity of air taken from a space in which the biomass furnace is located and to output a first measured value, the amount of air taken being sent to combustion in the biomass furnace; A second air quantity measuring device ( 122 ) arranged to determine an amount of fresh air supplied to the room via the biomass furnace and to output a second measured value; wherein the microprocessor stores the first and second measured values in the memory and, on the basis of a comparison of the first and second measured values, outputs a control signal in order to control an actuator for the supply of fresh air in dependence on the first measured value. Control device according to claim 6, wherein the Control signal for the fresh air supply is controlled so that the air taken from the space and the supplied Fresh air quantity are substantially equal. Control device according to claim 7, wherein the supplied Fresh air is heated by means of biomass combustion. Control device according to claim 8, wherein the warming done with the help of a heat exchanger. Control device according to one of claims 6 to 9, in which air from the room additionally replaced by an air conditioner becomes. Use of a control device according to claim 6 for controlling the air supply for a biomass firing. Use of the control device according to claim 11, the biomass firing additionally a heat exchangers comprises, by means of which the supplied fresh air is heated.