WO2023041599A1 - Burning apparatus having bulk material layer to reduce particulate matter - Google Patents

Abstract

The present invention relates to a device for, in particular low-emission, combustion of (solid) fuels, in particular with visible fire, preferably to a fireplace and/or stove and/or stove fireplace, comprising a portion for receiving a bulk material, preferably an air turbulence chamber, which is designed to guide an air mass flow in at least one direction through the bulk material and to receive the bulk material so that the air mass flow experiences turbulence through the bulk material, which turbulence decelerates the air mass flow in the at least one direction and makes the air mass flow decelerated in this way available for combustion of the (solid) fuel, in particular so that the combustion produces little particulate matter.

Description

Combustion device with layer of bulk material to reduce fine dust

The present invention relates to a device for, in particular, low-emission burning of (solid) fuels, preferably a chimney and/or oven and/or oven chimney.

Fireplaces, stoves, stove chimneys and the like are small to medium-sized combustion appliances, particularly for domestic use, and are well known.

The devices generate heat and visible fire, in particular by means of controlled combustion of (solid) fuels.

This controlled burning of the (solid) fuel leads to emissions, e.g. in the form of soot and/or other fine dust.

A disadvantage of previously known chimneys, stoves, furnace chimneys and the like is the high level of emissions produced when (solid) fuels burn, particularly fine dust.

The object of the present invention is therefore to address at least one of the problems mentioned above. In particular, a device for the low-emission burning of (solid) fuels is to be provided, in particular for domestic use.

According to the invention, a device for, in particular, low-emission burning of (solid) fuels is proposed, in particular with visible fire, comprising a section for accommodating a bulk material, preferably an air turbulence chamber, which is set up to cause an air mass flow in at least one direction through the bulk material to pass through and receive the bulk material in such a way that the air mass flow is subjected to turbulence through the bulk material, which decelerates the air mass flow along at least one direction, and makes the air mass flow decelerated in this way available for combustion of the (solid) fuel, in particular in such a way, that the combustion takes place with little particulate matter. In particular, a chimney and/or stove and/or stove chimney or the like with low-emission combustion is therefore proposed.

The device is therefore designed in particular as a chimney or stove or stove chimney or the like and in particular for domestic use.

The device is preferably set up to generate heat and light, in particular in the form of a decorative fire, by burning or pyrolyzing a (solid) fuel.

The (solid) fuel is, for example, solid, liquid, gaseous or gel-like. The (solid) fuel is, for example, fossil or biogenic. The (solid) fuel is preferably based on wood, for example deciduous or softwood, in the form of lumpy firewood, such as logs, wood pellets, wood chips or the like.

The device is used in particular for domestic use, and in particular not for industrial use, such as for example for power generation or for waste incineration. The device thus has in particular a nominal heat output which is less than 100 kW, preferably less than 50 kW, more preferably less than 20 kW, in particular less than 10 kW, for example 4 to 8 kW.

For burning the (solid) fuel, the device comprises in particular a section for receiving a bulk material. This section is also referred to below as the air turbulence chamber.

The section for accommodating the bulk material is preferably designed as a space or chamber or the like, in particular for accommodating and/or storing the bulk material.

The section for receiving the bulk material is, for example, made of a heat-resistant material, for example stainless steel, in the shape of a cube, shaft or tube.

The section for receiving the bulk material is preferably arranged within the device and equipped with a bulk material in such a way that at least one air mass flow can be guided through the bulk material in at least one direction. The bulk material is therefore selected in such a way that the air mass flow can be swirled within the bulk material, as a result of which the air mass flow is slowed down.

The section for receiving the bulk material therefore has the task of receiving a bulk material in such a way that the air mass flow guided through the bulk material is swirled.

The section for receiving the bulk material can therefore also be referred to as an air turbulence or air turbulence chamber.

The bulk material is preferably lumpy and/or heat-resistant (>1000° C.), for example balls, chunks of rock or expanded clay or heat-resistant metal.

The bulk material is also preferably such that, in particular when storing bulk material, it can swirl an air mass flow flowing through the bulk material, in particular as described below.

For example, the section for receiving a bulk material is arranged below the combustion chamber and the combustion chamber is supplied with oxygen via a central draft from below through the bulk material. The bulk material then swirls this central draft. This turbulence slows down the central draft and/or smoothes it out and/or flattens it out, resulting in a more even burning of the fuel inside the combustion chamber, which in turn reduces the emissions, in particular the fine dust, of the burning.

Preferably, the device also includes a section for setting up, in particular the device, preferably a stand, which is preferably arranged below the section for receiving the bulk material.

The device thus also includes in particular at least one section for setting up the device. This section is also referred to below as the base.

The section for setting up is preferably arranged below the section for receiving the bulk material. The section for setting up can in particular also be referred to as a base or is designed as a base.

The section for setting up is, for example, made of a heat-resistant material, for example stainless steel, in the shape of a cube, a shaft or a tube.

The section for setting up is preferably made of the same material as the section for receiving the bulk material.

More preferably, the section for setting up and the section for receiving the bulk material are connected to one another, in particular via a material connection, preferably airtight, for example by a circumferential weld seam.

Particularly preferably, the section for setting up has a larger cross section than the section for receiving the bulk material.

Preferably, the device also includes a section for receiving a solid fuel, preferably a combustion chamber, which is preferably arranged above the section for receiving the bulk material.

The device thus also includes in particular at least one section for accommodating a (solid) fuel.

In the section for receiving the (solid) fuel, the (solid) fuel in particular is stored and/or burned off in a controlled manner.

The section for receiving the (solid) fuel can also be referred to as the combustion chamber. Optionally, the combustion chamber also has a burner that is set up to ignite and/or ignite the (solid) fuel.

The section for accommodating the (solid) fuel is designed, for example, in the shape of a cube, shaft or tube from a heat-resistant material, for example stainless steel.

In addition, the section for receiving the (solid) fuel has at least one opening for introducing the (solid) fuel and/or one opening for discharging the fire or the combustion gases associated therewith. The section for accommodating the (solid) fuel is preferably arranged above or on the section for accommodating the bulk material.

Furthermore, the section for accommodating the (solid) fuel is in particular made of the same material as the section for accommodating the bulk material.

The section for accommodating the (solid) fuel and the section for accommodating the bulk material are more preferably connected to one another, in particular via a material connection, preferably airtight, for example by a circumferential weld seam.

Particularly preferably, the section for accommodating the (solid) fuel has a cross section that is larger than the cross section of the section for accommodating the bulk material.

The device preferably also includes a section for light emission, in particular a sight glass, preferably a sight glass surrounding the visible fire, preferably above the section for receiving the bulk material and/or above the section for receiving a (solid) fuel.

The visible fire is therefore preferably behind a sight glass.

The sight glass can, for example, be embedded in the combustion chamber or arranged on the combustion chamber.

The sight glass is made of glass, for example, in particular fireproof glass, preferably between 2 and 8 mm thick and in particular heat-resistant.

The sight glass is preferably arranged on the combustion chamber and the combustion chamber has an opening at an upper end, in particular in the middle, in particular in such a way that the fire erupts upwards from the combustion chamber and can be seen through the sight glass.

The section for emitting light particularly preferably has essentially the same cross section as the section for receiving the (solid) fuel. Preferably, the device also includes a device for catching ash, in particular an ash drawer, which is preferably arranged within the section for setting up and/or can be moved horizontally and, in particular, can be removed.

The device for catching ash can also be referred to as an ash drawer.

The device for catching ash is preferably arranged within a or the section for setting up or the base of the device.

The means for catching ash is preferably formed from a heat-resistant material, preferably from the same material as the mounting portion.

Preferably, the device also comprises a grid, in particular made of bars (vibrating bars), which separates the section for receiving the bulk material from the section for receiving the (solid) fuel and/or within the section for setting up and/or the section for receiving the Bulk material is arranged in such a way that the bulk material can be arranged on the grid and/or essentially within the section for receiving the bulk material.

It is therefore particularly proposed to store the bulk material on a grid.

The grid is preferably arranged below the section for accommodating the (solid) fuel, in particular in such a way that the bulk material is arranged below the (solid) fuel.

The lattice is preferably formed from a plurality of essentially parallel rods, which are arranged horizontally, for example, within the device.

The distances between the bars are chosen in such a way and depending on the bulk material that the bulk material can be stored on the grid.

The grid or the bars are preferably made of stainless steel.

The grating preferably has at least one handle with which the grating can be moved at least partially and/or in sections, preferably horizontally, and/or which is connected to a vibrating rod, in particular in such a way that it causes a movement when actuated and/or vibration of the bulk material occurs, preferably in such a way that ash within the bulk material reaches the device for catching ash.

The device therefore has at least one handle, by means of which the grid can be moved and/or shaken.

The device preferably has at least one vibrating rod, preferably two vibrating rods, which are connected to the grating and/or arranged in the grating in such a way that the grating can be shaken, in particular in such a way that ash within the bulk material falls into the catching device reached by ash.

The device preferably also has at least one opening, in particular for generating the (primary) air mass flow, which is preferably arranged below the section for receiving the (solid) fuel, in particular in the section for mounting.

The device thus preferably comprises at least one opening for generating an, in particular central, air mass flow, which preferably runs vertically (from bottom to top) through the device.

The opening is preferably arranged in a lower end of the device, in particular below the combustion chamber, ie the fire.

The opening serves in particular to supply the fire with oxygen within the section for accommodating the (solid) fuel, ie for example the combustion chamber.

The opening can preferably be regulated by means of an adjustment unit, in particular in order to influence the (primary) air mass flow.

For this purpose, for example, a flap is arranged in front of the opening, by means of which the opening can be closed or partially opened or opened by a desired amount.

In particular, the active surface of the opening can thus be influenced or freely adjusted by means of the adjustment unit, for example with a displaceable or rotatable flap in front of the opening. The device preferably also comprises the bulk material described above or below.

The present invention is explained in more detail below and with reference to the accompanying figures, the same reference numbers being used for identical or similar assemblies.

Fig. 1 shows a device for low-emission burning of solid fuels, especially wood.

FIG. 2 shows a plan view of a device for low-emission burning of solid fuels.

1 shows a device 100 for the low-emission burning of solid fuels, in particular wood.

The device 100 is arranged on a floor B and comprises a section 110 for setting up, a section 120 for receiving a bulk material, a section 130 for receiving a (solid) fuel and a section 140 for light emission.

The section 110 for setting up is arranged on the floor B and is designed as a base for the device 100 .

The section 110 for setting up comprises a device for catching ashes A, for example a drawer, which is arranged essentially horizontally and can be moved, in particular horizontally.

The section 110 for setting up also includes a substantially horizontally arranged grid 114 on which the bulk material 200 is stored. The grid 114 is particularly described in FIG. The drawer 112 is preferably arranged below the grid 114.

The section 110 for setting up also includes an opening 116 for generating a (primary) air mass flow L, which runs essentially vertically through the device 100 and is used to supply the fire F with oxygen. The section 120 for receiving the bulk material 200 is arranged above and on the section 110 for setting up, in particular in such a way that the bulk material 200 can be stored on the grid 114 .

The section 120 for receiving the bulk material 200 is therefore set up to receive the bulk material.

The bulk material is, for example, spherical expanded clay or another fireproof and/or heat-resistant material.

The section 130 for receiving the (solid) fuel H is arranged above and on the section 120 for receiving the bulk material 200 .

The section 130 for holding the (solid) fuel H is therefore set up to hold the fuel H. For example, the fuel H, wood pellets, is arranged directly on the bulk material 200 or on another grid, which is arranged above the bulk material 200.

The section 130 for accommodating the (solid) fuel H also preferably has a height that is lower than the fire F generated by the fuel H, in particular so that the fire F extends beyond the section 130 for accommodating the (solid) )fuel H blows out.

The section for light emission 140 is made of glass, for example, and is arranged above the section 130 for receiving the (solid) fuel H, in particular in such a way that the fire F is guided vertically and is visible in sections.

To operate the device 100, the device 100 is first equipped with a bulk material 200 and then with a fuel H. In this case, the fuel H is preferably arranged on the bulk material 200 .

After being loaded, the fuel H is set on fire, for example by a burner or an igniter ore arranged in the combustion chamber. B. Fidibus, waxed wood rasp or the like.

The burning of the fuel H then creates a fire F or flames that erupt upward from the device 100 . The fire F is supplied with oxygen by means of the air mass flow L.

The air mass flow L pulls through the opening 116 into the device 100 and from there due to the convection through the fire F essentially vertically upwards, namely essentially vertically through the bulk material 200.

The bulk material 200 then creates turbulence in the air mass flow L, which leads to a slowing down (vL2<vL1) or equalization of the air mass flow L.

This equalization leads to an improved, in particular more uniform, combustion of the fuel H, which minimizes the emissions and in particular the fine dust from the combustion.

In the area of the transition of sections 130 and 140, it is also possible to form openings (holes) in the side walls, so that air, e.g. B. as a secondary air flow from the outside into the interior in the direction of the impinging flame. Such a further air flow can improve the formation of flames, in particular the burning off, in order to further reduce the fine dust content and in particular also to maintain the flame F in the center of section 140, which increases the attractiveness of the flame pattern.

FIG. 2 shows a plan view of a device 100 for the low-emission burning of solid fuels, in particular as shown in FIG. 1 .

The grid 114 is positioned between the erecting section 110 and the bulk material receiving section 120, particularly as shown in FIG.

The grid 114 is essentially formed from a plurality of parallel rods 114' which are arranged essentially horizontally in the device 100.

In addition, the grid 114 has at least two handles 114''.

The handles 114'" are each arranged on a vibrating rod 114", with which the bulk material 200 can be set in motion or shaken in such a way that ash resulting from the combustion of the fuel can fall through the bulk material 200. The vibrating rods 114″ are formed, for example, from a tube and a rod 114′ located therein and preferably resemble the other rods 114′ from the outside. The rod 114' located in the tube can be moved back and forth by means of the handle 114''', in particular in order to set the bulk material 200 in motion or to shake it.

Finally, Fig. 3 and Fig. 4 show a further development of the invention according to Figs. 1 and 2.

FIG. 3 shows an alternative arrangement as in FIG. 1, with an alternative essentially being in the manner of movement of the vibrating rods 114''. These vibrating rods 114" lie individually on both sides in a vertically aligned movement groove, so that they have a limited vertical movement range 115. The individual vibrating rod 114" can only be moved and/or rotated in this movement range 115.

At least one moving member 117 is arranged below the vibrating rods 114″; in the exemplary embodiment according to FIG. 3, there are two moving members 117 arranged next to one another for the vertical movement of the vibrating rods. When these moving members 117 move, they each push up the vibrating rods 114'' located above them. The moving members 117 are each connected via a toothed rack 118 to a motor-driven pinion 119 . This pinion 119 itself can be connected to an electric motor 121 or a manual drive. FIG. 4 shows an electric motor 121, but, as mentioned, a manual drive via a hand crank would be just as possible.

Instead of the motorized drive 121 of the movement members 117 shown in Fig. 3 and 4, it is also possible - not shown - to connect a movement member 117 simply to a longitudinally guided rod, this rod then being displaceable in its longitudinal direction between two end positions and thus the Moving member 117 moves transversely to the vibrating bars 114" to then successively push up the vibrating bars. In such a case, the rod on which the moving member 117 is arranged has a handle as shown in FIG move or shake.

In Figs. 3 and 4, the moving member 119 is designed as a sphere, but it can also have a different geometry, for example it can be designed as a hemisphere or as a tetrahedron or the like, it only has to be in the back-and-forth Movement to be able to move the overhead vibrating bars 114” vertically. With the motor drive 121, the toothed rack 118 and thus the moving element 117 fused with it can be moved back and forth between two end positions, so that the vibrating rods 1 14" are gradually pushed up and then fall down again due to gravity, which then also causes the bulk material 200 (the bulk layer), ie the heat-resistant balls are moved in the air vortex chamber and the components lying on it, e.g. B. coal components, are then also taken up by the movement of the bulk material 200 of this bulk material 200 and ground small, so that the finely ground material can then fall into the device for collecting the ash, in particular the ash drawer 112.

The bulk material 200 thus consists of heat-resistant balls, e.g. B. made of expanded clay and can thus also be used as a grinder for the completely degassed solid fuels, i.e. coal, by actuating or moving the vibrating rods 1 14" and if the device 100 has the electric motor drive 121, which drives the racks 118 and thus moving the moving members 117 back and forth between their end positions, the grinding function of the grinder can also be realized by an automatic control 122.

One or more temperature sensors (not shown) in the area of section 120 and/or in the area of section 130 and/or 140 can also be used to precisely determine whether the degassing process of the fuel H has already been completed and, if this is the case, this will be done measured accordingly by the respective temperature sensor and when its value is fed to and processed by the controller 122 and a predetermined threshold value is present, the motor 121 is then automatically started and the gear wheel and rack 118 is moved accordingly.

The over the bulk 200, so the heat resistant s balls from z. B. Expanded clay, lying coal is shaken out of the balls by the ball layer and crushed (ground) on the balls themselves to fine coal crystals Z components.

These charcoal crystals (or charcoal powder) then trickle into the collecting container 112 arranged underneath. B. as biochar in horticulture, landscaping, or in agriculture or the like.

A burner with a rectangular or square cross section is shown in the figures. The invention also readily permits a cylindrical burner device in which the fuel H or the bulk material 200 is located in a chamber that is circular or oval in cross section.

In the example shown, the balls in the drawing each have the same diameter, but it is also preferable to use first and second balls with different diameters and also to use first and second balls that have different weights.

It is particularly preferred that the larger (first) spheres are preferably lighter than the smaller (second) spheres.

This can be done with the material itself, e.g. B. by the smaller balls are made of metal and the larger balls made of a heat-resistant material such. B. expanded clay.

This then leads to the so-called "Brazil nut effect", which means that the larger balls always tend to move on top and the smaller balls stay on the bottom. This has the advantage that the grinding operation is improved and the passage of air can be controlled in a more targeted manner.

In the example shown, the distance between the rods 114' is preferably in the range of 1 to 10 mm, preferably 2 to 7 mm, and the ball diameter of the ball used is in the range of 10 to 50 mm, preferably between 15 and 40 mm.

In the present invention, it is possible for primary air (VL1, VL2), which is introduced from below, to be completely independent of secondary air, which is introduced, controlled and regulated into the combustion device from above. The primary air flows past the balls, i.e. the layer of bulk material 200 or between the gaps between them, and the customer (operator) can ultimately set the air mass flow L for the primary air individually through opening 116, in particular he can over it set how long or how fast and how intensive the combustion should take place, the customer or the operator of the device 100 according to the invention can therefore control the air access of the primary air (VL2, VL1), which has the advantage that the efficiency of the burner can be improved. The secondary air reaches the flame or fire F either from the side in the area of sections 130/140 and/or from above. Devices for introducing this secondary air are not shown in the exemplary embodiment, but are known as such.

In tests, it was possible to use the device 100 according to the invention to enable quasi-fine dust-free combustion, which produces a very attractive flame pattern, with the height of the flame also being individually adjustable by the customer/operator by adjusting the primary air and after pyrolose combustion ( Gas combustion) by the vibrating movement of the bulk material 200, the combustible material burned to coal is ground in order to collect it as fine coal particles or coal dust of a predetermined grain size in the collecting container 112 and use this biochar thus obtained for a desired purpose, e.g. B. improvement / addition to the garden and potting soil or as a charcoal to use.

Reference List

100 device, especially fireplace

110 Section for setting up, in particular base 112 Device for catching ash, in particular ash drawer

114 grid, in particular for supporting the bulk material

114' rod, especially of the lattice

114" vibrating rod, especially the grid

114'' Handle, especially of the vibrating stick 115 Vertical range of motion of a vibrating stick

116 opening, in particular for receiving the air mass flow

117 moving link for vertical movement of vibrating bars

118 rack

119 pinion for the rack and pinion drive 120 section for receiving a bulk material, in particular a turbulence chamber

121 engine

122 control

130 Section for receiving a (solid) fuel, in particular combustion chamber

140 Light emission section, especially sight glass 200 bulk goods, especially expanded clay

B Ground, e.g. floor

F fire

H (solid) fuel L air mass flow v velocity

Claims

Expectations 1. Device (100) for, in particular low-emission, burning of (solid fuels (300), in particular with visible fire (400), preferably a chimney and/or oven and/or oven chimney, comprising: a section (120) for receiving a bulk material ( 200), preferably an air turbulence chamber, which is set up to: guide an air mass flow in at least one direction through the bulk material (200); and receive the bulk material (200) in such a way that the air mass flow undergoes turbulence through the bulk material (200), which decelerates the air mass flow along the at least one direction, and makes the air mass flow decelerated in this way available for combustion of the solid fuel (300), in particular in such a way that the combustion takes place with little fine dust. 2. Device (100) according to claim 1, further comprising: a section (110) for setting up, in particular the device, preferably a base, which is preferably arranged below the section (120) for receiving the bulk material (200). 3. Device (100) according to Claim 1 or 2, further comprising: a section (130) for accommodating a (solid) fuel (300), preferably a combustion chamber, which is preferably located above the section (120) for accommodating the bulk material (200 ) is arranged. 4. Device (100) according to at least one of the preceding claims, further comprising: a section (140) for light emission, in particular a sight glass, preferably a sight glass surrounding the visible fire, preferably above the section (120) arranged for receiving the bulk material (200) and/or above the section (130) for receiving a (solid) fuel (300). 5. Device (100) according to at least one of the preceding claims, further comprising: a device (112) for catching ash, in particular an ash drawer, which is preferably arranged within the section (110) for setting up and/or can be moved horizontally, and in particular removable. 6. Device (100) according to at least one of the preceding claims, further comprising: a grid (114), in particular made of bars (1 14'), which separates the section (120) for receiving the bulk material (200) from the section for receiving the (Solid fuels (300) separates and/or is arranged within the section (110) for setting up and/or the section (120) for receiving the bulk material (200) in such a way that the bulk material (200) is on the grid (114) and/or or can be arranged essentially within the section (120) for receiving the bulk material (200). 7. Device (100) according to at least one of the preceding claims, wherein the grid (114) has at least one handle (114''): with which the grid (114) can be moved at least partially and/or in sections, preferably horizontally, and /or which is connected to a vibrating rod (114"), in particular in such a way that the bulk material (200) is shaken when it is actuated, preferably in such a way that ash within the bulk material reaches the device (112) for catching ash. 8. Device (100) according to at least one of the preceding claims, further comprising: - 19 - an opening (116), in particular for generating the air mass flow, which is preferably arranged below the section (120) for receiving the (solid) fuel (300), in particular in the section (110) for installation. 9. Device (100) according to at least one of the preceding claims, comprising a number of vibrating bars (114"), which lie substantially parallel to one another and which are vertically movable by a predetermined amount, the extent being defined by a groove in which the vibrating bars (114") lie with their ends and at least one moving member (117) is formed below the vibrating bars (114"), which is movable transversely to the longitudinal direction of the vibrating bars (1 14) in order to move the vibrating bars (114) vertically , e.g. B. up and down. 10. Device (100) according to claim 9, characterized in that the moving member (117) with a rack (1 18) is connected by the drive of a pinion (119) which engages in the rack (118), back and forth can be moved forward along the vibrating bars (114"). 11. Device (100) according to one of the preceding claims, characterized in that the bulk material (200) on it is moved by the movement of the grid (114) or by the movement of the vibrating bars (114") and by the movement of the bulk material (200) the fuel on it, especially if it has been burned to coal by pyrolysis combustion, is ground and the ground coal is allowed to fall into the device (112) for catching the ash. Device (100) according to any of the preceding claims, characterized in that the bulk material (200) consists of a first number of a first bulk material of a first diameter and a first weight and a second number of a second bulk material of a different diameter and another Weight. 13. Device (100) according to any one of the preceding claims, characterized in that in the section (120) for receiving the bulk material and / or in the section (130) for receiving the fuel (300) one or more temperature sensors are formed, the temperature record and the temperature sensor(s) is/are connected to a controller (112), which determines the measured temperature value and processes it depending on the measured temperature, whether - 20 - the degassing process (pyrolysis combustion) is completed and the controller (112) is designed to control the motor (121) in order to trigger a reciprocating movement of the moving member (117).