DE102012203641A1 - Particle filter device for a firing device - Google Patents

Abstract

The present invention relates to a particulate filter device (5) for removing particles from exhaust gas of a firing device (1) with a filter structure (11) which is arranged in an exhaust gas flow path (10) and can be flowed through by the exhaust gas, wherein in the exhaust entrained particles at the Attach filter structure (11). A simplified construction results with the aid of a filter housing (6) which has an exhaust gas inlet (7), an exhaust gas outlet (8) and an interior space (9), in which the exhaust gas path (10) runs from the exhaust gas inlet (7) to the exhaust gas outlet (8) and in which the filter structure (11) is arranged.

Description

The present invention relates to a particulate filter device for removing particles from exhaust gas of a firing device, having the features of the preamble of claim 1. The invention also relates to a firing device, in particular a domestic firing device, preferably a wood firing device, which is equipped with such a particulate filter device.

From the EP 2 332 628 A1 a particulate filter device for removing particles from exhaust gas of a firing device is known, which is equipped with a filter structure which is arranged in an exhaust gas flow path and which can be flowed through by the exhaust gas, wherein particles entrained in the exhaust gas accumulate on the filter structure. In the known particulate filter device, the filter structure is formed by a plurality of retaining elements which are movable relative to each other and may be formed for example by bristles or by fins or by shaking. In the known particulate filter device, the filter structure with the aid of a corresponding holder is mounted directly in a chimney of the firing device, which dissipates the resulting during combustion exhaust gas from a combustion chamber of the firing device during operation of the firing device. The known particulate filter device thus in particular simplifies retrofitting of existing firing devices with the particulate filter device so as to reduce the particulate emissions of the respective firing device. The installation of the filter structure in the chimney of the firing device is comparatively complex.

The present invention addresses the problem of providing for such a particulate filter device or for such a firing device an improved embodiment, which is characterized in particular by a simplified assembly. In addition, an improved filtration effect is desired.

This problem is solved according to the invention by the subject matter of the independent claim. Advantageous embodiments are the subject of the dependent claims.

The invention is based on the general idea of associating the particle filter device with its own filter housing, in which the filter structure can be arranged in a particularly simple manner. Such a filter housing comprises an exhaust gas inlet and an exhaust gas outlet, whereby the filter housing can be installed particularly easily in a chimney of a firing device or between the chimney and a housing of the firing device. The use of a separate filter housing for the particulate filter device also makes it possible to choose the dimensions of the filter housing and thus also the dimensioning of the filter structure largely independent of the dimensions of the fireplace. In particular, this makes it possible to provide a flow-through cross-section within the filter housing which is larger than a cross-section through which the chimney can flow. As a result, the filter structure for the larger cross-section of the filter housing can be designed, whereby higher separation efficiency can be realized with reduced flow resistance.

A combustion device according to the invention thus comprises a combustion chamber, a chimney and a particle filter device with filter housing and filter structure of the type described above.

The filter structure preferably consists of a plurality of fibrous or thread-like or cord-shaped or wire-shaped elements, which may in particular have a corrugated structure and which are preferably substantially uniformly oriented with respect to their longitudinal direction, so that they are arranged side by side transversely to their longitudinal direction. These structural elements are elastic and movable relative to each other. The structural elements are preferably made of a metallic material. At least at one longitudinal end, the structural elements by means of a holding device can be fixed relative to each other, so that the respective holding device allows positioning of the filter structure within the filter housing. Between their longitudinal ends, the individual structural elements preferably lie loosely against one another. The filtration effect of the filter structure is determined by the packing density of the structural elements within the filter structure. The higher the packing density, that is, the greater the number of structural elements per unit area or volume unit, the greater the filtration effect.

In firing devices that work with a fireplace, the drive of the exhaust gas is preferably carried out exclusively via the chimney effect, so on the withdrawal power of the chimney. This extraction capacity, which is also referred to below as the chimney draft, depends strongly on the temperature of the exhaust gas or on the temperature of the combustion chamber or the chimney. When starting the firing device, the exhaust gas temperature is relatively low, so that the chimney draft is correspondingly small. If, in contrast, the firing device in the area of the combustion chamber is heated, high exhaust gas temperatures and a correspondingly enlarged flue draft result.

In such passive firing devices, the use of Particle filter devices problematic, since they have a certain flow resistance. While at high exhaust gas temperatures of the large chimney draft is usually sufficient to pull the exhaust gas through the filter structure, at low exhaust gas temperatures, so preferably when starting the firing device, the chimney draft may be too small to pull enough exhaust gas through the filter structure. The result is a strong smoke in the combustion chamber. Likewise, the fire can go out again.

According to a particularly advantageous embodiment, a compression device can now be provided which is designed such that it compresses the filter structure depending on the temperature of the exhaust gas. In this case, this compression device is expediently designed so that it generates the lowest possible compression of the filter structure at low exhaust gas temperature, so that there is only a very small packing density within the filter structure. With increasing exhaust gas temperature, the compression device increases the compression of the filter structure, so that at a high exhaust gas temperature, a correspondingly high packing density is present within the filter structure. However, the packing density of the filter structure correlates with the flow resistance of the filter structure. This means that it is possible with the help of the compression device to set a low flow resistance for low exhaust gas temperatures, which in particular can be made so small that even a small chimney draft is sufficient to pull the exhaust gas through the filter structure. In doing so, a reduced cleaning effect associated with the reduced packing density is quite accepted. As the exhaust gas temperature increases and as the flue draft increases, the compression of the filter structure leads to an increasing packing density, which improves the filtration effect. The simultaneously increasing flow resistance is compensated by the increasing chimney draft, so that always sufficient exhaust gas can be withdrawn through the filter structure.

For example, the compression device may include at least one actuator that can compress the filter structure for compression. Such an actuating element can be formed, for example, by a bimetallic component or by a component made of a shape memory alloy, so that it deforms reversibly correspondingly to temperature. Thus, the compression device operates preferably passive or de-energized, which reduces energy consumption and installation costs.

The structural elements of the filter structure are as mentioned above, preferably arranged oblong and transversely to their longitudinal direction next to one another and oriented substantially uniformly in their longitudinal direction. The compression of the filter structure is now carried out with the aid of the compression device, preferably transversely to the orientation of the structural elements, so that therefore the distances of adjacent structural elements are reduced during compression.

In the compression device, preferably in the respective control element may be integrated according to an advantageous development of a cracking mechanism that triggers a sudden compressing on reaching a predetermined temperature during heating and / or a sudden decompression when cooling. This sudden or stepped compression or decompression leads to a rapid movement of the structural elements relative to each other, resulting in an efficient cleaning of deposited on the filter structure particles. In this way, a self-cleaning function for the filter structure can thus be integrated into the compression device.

Alternatively, the compression device can also be designed so that it performs the compression or decompression of the filter structure continuously and largely proportional to the exhaust gas temperature.

A large part of the particles carried in the exhaust gas consists of soot, ie unburned carbon. Especially at low temperatures, comparatively much soot can form, as a result of which a filter structure which is designed for a high separation efficiency is added comparatively rapidly. Therefore, there is also a need for a solution that enables regeneration of the filter structure during operation of the firing device.

This problem is solved in another advantageous embodiment in that the filter structure is equipped with a catalytically active coating. Such a catalytically active coating leads to a reduction of the self-ignition temperature of the particle loading of the filter structure. In particular, with the aid of the catalytically active coating, this autoignition temperature can be reduced to such an extent that, in normal operation of the combustion device, this autoignition temperature is generally exceeded. Consequently, when the firing device is sufficiently heated, spontaneous combustion occurs and the particle loading of the filter structure burns off. The filter structure is characterized largely regenerated.

The filter housing may expediently be cylindrical and have an internal cross section, which is greater than an inlet cross section of the exhaust gas inlet and transverse to its longitudinal central axis is greater than an outlet cross section of the exhaust outlet. The exhaust gas inlet and the exhaust gas outlet can now be aligned with one another axially with respect to the longitudinal center axis of the filter housing, preferably one above the other, preferably in the installed state of the particulate filter device, on the filter housing. In such a structure of the filter housing, the filter structure preferably has an annular and conical jacket body, which is arranged coaxially to the longitudinal central axis of the filter housing in the filter housing and thereby tapers in a funnel shape towards the exhaust gas inlet. Such an embodiment results in a mechanical cleaning of the filter structure, for example, by knocking or shaking or hitting the filter structure, a large proportion of the particles dissolving along the funnel-shaped filter structure falls by gravity in the direction of the inlet opening or trickles. Thus, the cleaned particles ultimately pass through the inlet opening into the combustion chamber, which in the case of a wood-burning device is in any case equipped with a corresponding catching device for combustion residues, eg an ash container.

In this case, a combination with a compression device, in particular of the type described above, is particularly expedient. For this purpose, the compression device is arranged on the inflow-side end region of the filter structure in order to be able to compress or decompress it in a temperature-dependent manner concentrically with respect to the longitudinal central axis. Particularly advantageous is now an embodiment in which the compression device and the filter structure are matched to one another so that forms a central opening in the decompressed state, ie at low temperature in the filter structure in the upstream end, within which the packing density of the filter structure is very low , In particular, this central opening can be at best free of structural elements of the filter structure, so that the filter structure surrounds the central opening in an annular manner. For firing the firing device thus a central through-hole is created, which passes the exhaust path through the central opening, without the exhaust gas in this case must flow through the filter structure. The central opening thus represents a bypass for bypassing the filter structure. The compression device now causes the central opening closes with increasing exhaust gas temperature. This can - as already mentioned above - be stepless or stepped or abruptly. While the upstream axial end region of the filter structure is adjustable or compressible with the aid of the compression device, the downstream axial end region can expediently be fixedly arranged on the filter housing, for example with a suitable retaining device already mentioned above.

The upstream end of the conical filter structure has transversely to the longitudinal central axis expediently a cross section which is smaller than or at most equal to the size of an opening cross section of the exhaust gas inlet. In contrast, the downstream end of the filter structure expediently has a cross section transverse to the longitudinal center axis which is larger than an opening cross section of the exhaust gas outlet. In this case, an embodiment in which the opening cross-sections of the exhaust gas inlet and the exhaust gas outlet have the same size is particularly advantageous.

According to another advantageous embodiment, in which the exhaust gas inlet and the exhaust gas outlet with respect to the longitudinal center axis of the filter housing to the cylindrical filter housing axially aligned, and in particular in the installed state of the particulate filter device are arranged one above the other, the filter structure according to an advantageous embodiment, an annular jacket body having coaxial is arranged to the longitudinal central axis of the filter housing in the filter housing, wherein a density of the filter structure decreases within the jacket body in the direction of the exhaust gas inlet. If the filter structure consists of a multiplicity of individual, elongate structural elements, their packing density in the direction of flow of the filter housing thus increases. This means that the filter structure in a section arranged proximally to the exhaust gas inlet has a lower cleaning effect than in a section arranged distally to the exhaust gas inlet. It has been found that such a configuration hardly has a disadvantageous effect with regard to the overall cleaning effect achievable with the filter structure. However, this shaping results in a significantly improved cleaning action for the filter structure in mechanical cleaning operations, such as e.g. Knocking or hitting or shaking the filter structure. Such a shape within the filter structure can be achieved particularly easily with elongate structural elements in that the structural elements are fixed to a holding device only at one axial end of the filter structure, while they are essentially free-standing at the opposite axial end, at least relative to one another.

According to another advantageous embodiment, the device according to the invention can be equipped with a cleaning device, with the aid of which the particles deposited on the filter structure can be cleaned off. With the help of such a cleaning device, an arbitrary cleaning of the filter structure is preferably possible. Suitably, the particulate filter device can now also be equipped with a vacuum cleaner connection, via which a suction pipe of a vacuum cleaner can be connected. This makes it possible for the arbitrary Purify the filter structure to suck dissolved particles with a vacuum cleaner via the vacuum cleaner port, especially before the cleaned particles fall into the combustion chamber of the firing device. In this way, an additional contamination of the combustion chamber or a housing containing the combustion chamber of the combustion device when cleaning the particulate filter device can be avoided.

The vacuum cleaner connection is expediently arranged on the raw side or inlet side of the filter structure. In the installed state, the vacuum cleaner connection is expediently located below the filter structure and preferably below the exhaust gas inlet. For example, the vacuum cleaner connection can be arranged directly on the filter housing. Likewise, the filter housing may be equipped on its outer side with an inlet connection piece, which encloses the exhaust gas inlet. The vacuum cleaner connection can now also be arranged on this inlet connecting piece.

The cleaning device preferably operates normally, so that it can be actuated manually. It may include a mechanism that causes knocking or hitting or shaking of the filter structure. Particularly useful is an embodiment in which the cleaning device can be actuated or triggered by means of negative pressure, which can be generated by means of the vacuum cleaner, which is connected to the vacuum cleaner port. In this case, the cleaning device is thus automatically actuated precisely when, with the aid of the vacuum cleaner connected to the vacuum cleaner connection, there is a vacuum required for the extraction of the particles.

According to another advantageous embodiment, the particulate filter device may be equipped with an uncontrolled bypass for the exhaust gas bypassing the filter structure. The uncontrolled bypass is characterized by a flow-through cross-section, which is always largely independent of the respective exhaust gas temperature and is maintained in particular even at high exhaust gas temperatures. The uncontrolled bypass allows undisturbed operation of the firing device even in the event that the filter structure clogged during operation of the firing device so far that the chimney draft is no longer sufficient to pull exhaust gas through the filter structure. The suction effect of the chimney draft then amplifies correspondingly at the uncontrolled bypass, so that in this case sufficient exhaust gas can be withdrawn through the uncontrolled bypass.

The uncontrolled bypass is characterized by a flow-through bypass cross section, which is small in comparison to the flow-through cross sections of the exhaust gas inlet and the exhaust gas outlet. For example. the bypass cross-section of the uncontrolled bypass is at most 25% of the flow-through cross-section of the exhaust gas inlet or the exhaust gas outlet. Suitably, the uncontrolled bypass is arranged on the inflow-side end region of the filter structure. In particular, the uncontrolled bypass may be arranged annularly between the filter housing and the annular filter structure.

Advantageously may be formed on the filter housing in the interior projecting annular collar on which the filter structure is axially supported. The annular collar can now be formed completely or at least in a region adjoining the filter housing by a perforated plate or by a grid. The free cross sections of the perforated plate or of the grid now form the uncontrolled bypass, which passes radially between filter housing and filter structure on the filter structure. Particularly expediently, a cleaning device can now be provided for the uncontrolled bypass, which ensures that impurities accumulating at the uncontrolled bypass, in particular particles, are again cleaned off. In this way, the uncontrolled bypass can be protected from clogging by attaching particles. Such a cleaning device may comprise a mechanism for stripping or knocking or shaking or hitting. Particularly advantageous is an embodiment in which the annular collar is completely or at least in the adjoining the filter housing area equipped with two perforated plates or with two gratings, the. With respect to the longitudinal center axis axially to each other and are arranged to be movable relative to each other. For example. a perforated plate or a grid may be rotatably mounted on the other perforated plate or on the other grid about the longitudinal center axis of the filter housing. By means of a corresponding drive, a relative adjustment between the two perforated plates or between the two gratings can be effected, which leads to a sufficient cleaning action for cleaning off the particles accumulating on the perforated plates or on the grids. Such a drive can be realized by means of a bimetallic component or by means of a component made of a shape memory alloy, so that the corresponding drive operates without current and temperature-dependent.

According to another advantageous embodiment, the particulate filter device may have a controlled bypass, which allows an exhaust gas bypassing the filter structure, wherein the controlled bypass is associated with a control, with the aid of a flow-through cross-section of the bypass can be controlled temperature-dependent. Such a controlled bypass may be beneficial to the firing of the firing device. When starting the exhaust gas temperature is relatively low, so that the chimney draft is correspondingly small. Depending on the design of the filter structure, the chimney draft during firing is not sufficient to pull sufficient exhaust gas through the filter structure. Due to the controlled bypass, a bypass of the filter structure can be made possible for the starting, so that the high flow resistance of the filter structure does not come into play. At higher temperatures, where the chimney draft is sufficient to pull the exhaust gas through the filter structure, the controlled bypass can be closed accordingly, so that as a result of the exhaust gas flow through the filter structure and is cleaned.

The controlled bypass is characterized by a bypass cross-section through which, compared to the flow-through cross sections of the exhaust gas inlet and the exhaust gas outlet, in the opened state is substantially equal or similar. For example. the bypass cross-section of the controlled bypass in the open state is at least 50% of the flow-through cross-section of the exhaust gas inlet or the exhaust gas outlet.

According to a variant in which an annular filter structure is used, the controlled bypass can be formed on an axial end region, preferably on the outlet side, within the particle filter device. In this case, the controlled bypass is arranged concentrically in the filter structure, i. the filter structure encloses the controlled bypass ring. In such an embodiment, the controlled bypass may expediently have a flap, preferably a butterfly flap, in order to be able to control the cross-section through which the bypass can flow. To rotate the flap, a shaft may be provided, on which a drive for actuating the flap can attack. For example. can be used to drive the shaft, a bimetallic component or a component of a shape memory alloy, which causes a temperature-dependent rotation of the shaft or the flap. In addition, the shaft may be led out of the filter housing and carry on the outside of the filter housing a handle through which a manual actuation of the flap is possible.

According to another variant of the particulate filter device in which an annular filter structure is used, the controlled bypass may be arranged at an axial end region of the filter structure, preferably upstream, annularly between the filter structure and the filter housing. In this case, the controlled bypass can be suitably designed so that its flow-through cross-section is not completely closed, so that therefore always an uncontrolled bypass component remains open. In this way, the function of the uncontrolled bypass already described above can be integrated into the controlled bypass presented here.

According to an advantageous development, the filter structure can cooperate at its respective end region for forming the controlled bypass with a seat structure. Filter structure and seat structure are now axially adjustable relative to each other. A corresponding actuator can be realized, for example, by means of a bimetallic component or by means of a component made of a shape memory alloy. Suitably drives the respective actuator, the filter structure relative to the seat structure, which is fixedly arranged in this case on the housing. Alternatively, the actuator drives the seat structure relative to the filter structure, which in this case is fixed to the filter housing.

The respective actuator is suitably designed so that it sets a maximum flow-through cross-section in the controlled bypass at low exhaust gas temperature, whereby the firing of the firing device is facilitated. With increasing temperature of the actuator adjusts the filter structure relative to the seat structure such that the flow-through cross-section decreases. The adjustment can be made stepless or stepped. Suitably, the actuator is designed so that it does not fall below a predetermined minimum flow-through cross-section.

Additionally or alternatively, a stop in the adjustment path of the seat structure or the filter structure can be arranged, which ensures that a minimum predetermined flow-through cross-section is maintained even at high exhaust gas temperatures.

In another advantageous embodiment, the particulate filter device can also be equipped with a cleaning device, with the aid of which particles deposited on the filter structure can be cleaned off. The cleaning device is equipped with a movement device for introducing a movement into the filter structure relative to the filter housing, with an actuating device for actuating the movement device and with a coupling device for mechanically coupling the actuating device with the movement device. Advantageously, the actuating device is now arranged outside of the filter housing, whereby it is particularly easy to operate from outside the arranged in the interior of the filter housing movement means.

In this case, an embodiment in which the actuating device is arranged on a housing of the firing device that contains the combustion chamber is particularly advantageous. By this measure, the accessibility of the Actuator can be significantly improved. For example. is a commercially available, stove can be set up in the household already readily on the housing side two meters high, with the fireplace can connect up. Even if the filter device is arranged between the housing of the firing device and the chimney, an actuating device arranged on the filter housing would be difficult to access.

In the simplest case, the actuating device is a handle which is arranged on the housing of the firing device and is coupled via the coupling device to the movement device arranged in the filter housing.

Particularly advantageous is now an embodiment in which the coupling device is coupled to a flap or door of the combustion chamber containing housing of the firing device, such that by pivoting the flap or door on the coupling means, the moving means for cleaning the filter structure is actuated. In other words, in this case, the actuating device is formed by a flap or door of the housing of the firing device.

Alternatively, it is also conceivable to arrange a grate, which serves in the combustion chamber for laying firewood, movable in the housing and to couple via the coupling device with the movement device. As a result, loading the grate and burning off the combustible material via the coupling device results in actuation of the movement device for cleaning the filter structure. In other words, the grate movably arranged in the housing forms the actuating device of the cleaning device.

According to an advantageous embodiment, the movement device can be designed so that it generates a sudden movement of the filter structure. This can be realized, for example, by means of a spring structure or by means of a clicking mechanism.

Other important features and advantages of the invention will become apparent from the dependent claims, from the drawings and from the associated figure description with reference to the drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be described in more detail in the following description, wherein like reference numerals refer to the same or similar or functionally identical components.

Show, in each case schematically,

1 an isometric view of a firing device,

2 a simplified side view of a firing device,

3 and 4 in each case a greatly simplified sectional view of a particle filter device in the region of a filter structure in two different states,

5 a highly simplified sectional view of a particulate filter device,

6 and 7 each a highly simplified sectional view of a particulate filter device at different states,

8th also a simplified sectional view of a particulate filter device in another embodiment,

9 to 11 Views of a detail IX of the particulate filter device 8th in the area of an uncontrolled bypass,

12 u. 13 each a highly simplified sectional view of a particulate filter device in various embodiments

14 u. 15 in each case a greatly simplified schematic view of a firing device in various embodiments

According to the 1 . 2 . 14 and 15 includes a firing device 1 in a housing 2 a combustion chamber 3 , In addition, the firing device 1 with a fireplace 4 for removing exhaust gas from the combustion chamber 3 and with a particulate filter device 5 equipped to remove particles from the exhaust. At the firing device 1 in particular, it is a domestic heating device, which can therefore be installed in a building. Particularly advantageous is the firing device 1 to a wood-burning device, so can be burned with the so in particular in a living room wood and the like.

The particulate filter device 5 has a filter housing 6 , the appropriate inlet side in the fireplace 4 or between housings 2 and fireplace 4 is installed.

According to the 5 to 8th . 12 and 13 owns the filter housing 6 an exhaust inlet 7 , an exhaust outlet 8th and an interior 9 in which an exhaust path partially indicated by arrows 10 from the exhaust inlet 7 to the exhaust outlet 8th leads. The particulate filter device 5 also has a filter structure 11 on the inside of the filter housing 6 , namely in the interior 9 is arranged, such that the filter structure 11 also in the flow path 10 is located and can flow through the exhaust. The filter structure 11 is designed so that it filters out entrained particles in the exhaust, whereby the deposited particles on the filter structure 11 attach.

According to the 3 to 5 may the particulate filter device 5 with a compression device 12 be equipped with their help the filter structure 11 is compressible depending on the temperature of the exhaust gas. For example, shows. 3 a compressed state, which occurs at comparatively high exhaust gas temperatures, while the 4 and 5 show a decompressed state that sets at low exhaust gas temperatures.

The filter structure 11 expediently comprises a multiplicity of elongate structural elements which run largely parallel to one another or are oriented largely identically with respect to their longitudinal direction. Thus, the structural elements are juxtaposed transversely to their longitudinal direction. The compression by means of the compression device 12 , in the 3 by a double arrow 13 is indicated, is transverse to the longitudinal direction of the structural elements of the filter structure 13 oriented.

The filter structure 11 can be provided with a catalytic coating, not shown here, to a sufficient exhaust gas temperature regeneration of the filter structure 11 to be able to initiate by combustion of the particle loading.

In the embodiments shown here, the filter housing 6 cylindrical and has according to 5 transverse to its longitudinal central axis 14 an inner cross section 15 which is larger than an inlet cross-section 16 the exhaust inlet 7 and larger than an outlet section 17 the exhaust outlet 8th , Furthermore, expedient exhaust gas inlet 7 and exhaust outlet 8th with respect to the longitudinal central axis 14 axially aligned with one another on the filter housing 6 arranged. In the assembled state or in the installed state within the firing device 1 is the exhaust outlet 8th vertically above the exhaust inlet 7 , In the 5 to 8th is for this state of installation, the orientation of gravity by an arrow 18 indicated.

According to the in 5 shown preferred embodiment has the filter structure 11 an annular conical jacket body 19 coaxial with the longitudinal center axis 14 of the filter housing 6 in the filter housing 6 is located and to the exhaust inlet 7 rejuvenated. In this embodiment is also a compression device 12 provided here on the upstream end of the filter structure 11 is arranged. In this case, the compression device 12 so on the filter structure 11 matched that in the decompressed state on the upstream side of the filter structure 11 a central passage opening 20 arises. As the temperature increases, the upstream end region of the filter structure becomes 11 through the compression device 12 concentric to the longitudinal central axis 14 compressed, causing the opening 20 is closed.

The particulate filter device 5 can according to the 1 . 2 . 5 . 6 . 13 to 15 with a cleaning device 21 be equipped with the filter structure 11 clean off any particles that have accumulated. Further, the particulate filter device 5 convenient with a vacuum cleaner connection 22 equipped, to which a suction pipe of a vacuum cleaner can be connected, in order to be able to suck off particles, which occur when cleaning the filter structure 11 have solved. In the embodiments shown here is the vacuum cleaner port 22 to an inlet connection piece 23 attached, the outside of the filter housing 6 is arranged and the exhaust inlet 7 encloses.

According to the 6 and 7 may the particulate filter device 5 a controlled bypass 24 have the filter structure 11 on the exhaust side bypasses and a control 25 is assigned, with the help of a flow-through cross-section of the bypass 24 can be controlled depending on the temperature. In the example of 6 and 7 is the filter structure 11 again ring-shaped, so that the controlled bypass 24 centric in the filter structure 11 can be arranged at the outlet-side axial end portion. The control 25 includes a flap 26 using a wave 27 is rotatable. A bimetal component 28 or a corresponding component 28 From a shape memory alloy can now depending on the temperature in the exhaust, the wave 27 for twisting the flap 26 drive. In addition, one outside the case 6 arranged handle 29 be provided with the help of the flap 26 can be adjusted manually. 6 now shows the state when starting the firing device 1 , The flap 26 is in its open position, so that the exhaust gas corresponding to an arrow 30 through the controlled open bypass 24 bypassing the filter structure 11 through the filter housing 6 can flow. If the firing device has reached its operating temperature, can according to 7 the controlled bypass 24 using the flap 26 be closed, so that the exhaust gas flow is now forced through the filter structure 11 pass.

According to the 6 to 8th also has an uncontrolled bypass 31 be provided, which also has an exhaust-side bypass of the filter structure 11 allows. In the examples shown the 6 and 8th is the uncontrolled bypass 31 at the upstream axial end portion of the filter structure 11 arranged, wherein it is annular between the filter housing 6 and the filter structure 11 extends.

In detail, according to the 8th to 11 the filter structure 11 on the housing side on a ring collar 32 axially supported on the inside of the filter housing 6 is arranged. Appropriately, the ring collar 32 through a perforated plate 33 or through a grid 33 educated. According to 11 can the ring collar 32 through two perforated sheets 33 or by two grids 33 be formed, which lie on each other and are movable relative to each other. Using an actuator 34 , For example, in the form of a bimetallic component and / or in the form of a component of a shape memory alloy, it is possible, the two perforated plates 33 or the grid 33 Temperature dependent relative to each other to adjust.

Alternatively, according to the 9 and 10 also the use of a vibrating device or the use of a stripping conceivable.

The 12 and 13 now show embodiments in which the functionalities of the controlled bypass 24 and the uncontrolled bypass 31 are integrated into each other. This is the controlled bypass 24 configured so that it is not completely closed, so that even at high operating temperatures, a predetermined flow-through cross-section remains open, then the uncontrolled bypass 31 forms. For this purpose, for example, be provided, the filter structure 11 at its upstream end with a seat structure 35 to interact, with filter structure 11 and seat structure 35 relative to each other axially with respect to the longitudinal center axis 14 are adjustable to each other. An adjusting device 36 , which can be produced for example by means of a bimetallic component or by means of a component made of a shape memory alloy, can now, depending on the temperature, the relative position between the filter structure 11 and seat structure 35 change.

In the examples of 12 and 13 is the seat structure 35 firmly on the filter housing 6 attached, so that the adjusting device 36 expedient the filter structure 11 in the filter housing 6 stroke-displaced. It is clear that a reverse arrangement is possible.

13 now also shows a particular embodiment in which the density of the filter structure 11 within the shell body 19 towards the exhaust inlet 7 decreases. This is achieved by a packing density of the individual structural elements of the filter structure 11 towards the exhaust inlet 7 decreases. For example. This can be achieved by the fact that the elongated structural elements exclusively at their exhaust outlet 8th facing end by means of a holding device 45 attached to each other while at the opposite, the exhaust inlet 7 facing longitudinal end are not attached to each other. In addition, the individual structural elements are not axially attached to each other between their axial ends.

In the embodiments of the 14 and 15 includes the cleaning device 21 , with the help of which the filter structure 11 be cleaned of particles deposited thereon, a movement device 37 for introducing a movement into the filter structure 11 relative to the filter housing 6 , an actuating device 38 for actuating the movement device 37 and a coupling device 39 for mechanically coupling the actuator 38 with the movement device 37 , By the use of such a coupling device 39 can be the actuator 38 comparatively far away from the movement device 37 Arrange. Preferred is an arrangement outside the filter housing 6 , namely preferably on or in the housing 2 the firing device 1 , At the in 14 the embodiment shown is the actuating device 38 through a flap 40 of the housing 2 formed by the combustion chamber 3 is accessible. Accordingly, the coupling device 39 to the flap 40 connected, such that opening and / or closing the flap 40 via the coupling device 39 an actuation of the movement device 37 generated, which helps to clean the filter structure 11 leads.

At the in 15 the embodiment shown is the actuating device 38 through a rust 41 formed in the combustion chamber 3 for laying on firewood 42 serves. The rust 41 is, for example, in the housing 2 pivoted. For example. is at 43 provided a pivot bearing and spaced from a spring 44 , By loading the grate 41 can be a pivoting of the grate 41 be effected. Likewise, the burning of the fuel leads 42 to a pivoting of the grate 41 , In any case, the pivoting movement of the grate 41 via the coupling device 31 for actuating the movement device 37 used to filter the structure 11 clean off.

The movement device 37 Appropriately has a knock, or shaking or percussion.

In addition to these integrated cleaning facilities 21 can also be in the 1 . 2 . 5 and 6 indicated, manually operable cleaning devices 21 be provided.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2332628 A1 [0002]

Claims (10)

Particulate filter device for removing particles from exhaust gas of a firing device ( 1 ) with a filter structure ( 11 ) located in an exhaust gas flow path ( 10 ) is arranged and can be flowed through by the exhaust gas, wherein in the exhaust entrained particles on the filter structure ( 11 ), characterized by a filter housing ( 6 ), which has an exhaust gas inlet ( 7 ), an exhaust outlet ( 8th ) and an interior ( 9 ), in which the exhaust path ( 10 ) from the exhaust inlet ( 7 ) to the exhaust outlet ( 8th ) and in which the filter structure ( 11 ) is arranged. Firing device, in particular house-firing device, preferably wood-burning device, with a combustion chamber ( 3 ), with a fireplace ( 4 ) and with a particle filter device ( 5 ) according to claim 1. Apparatus according to claim 1 or 2, characterized by a compression device ( 12 ) for compressing the filter structure ( 11 ) depending on the temperature of the exhaust gas. Device according to one of claims 1 to 3, characterized by a catalytically active coating of the filter structure ( 11 ). Device according to one of claims 1 to 4, characterized in that - the filter housing ( 6 ) is cylindrical and transversely to its longitudinal central axis ( 14 ) an inner cross-section ( 15 ) which is larger than an inlet cross-section ( 16 ) of the exhaust gas inlet ( 7 ) and larger than an outlet cross-section ( 17 ) of the exhaust outlet ( 8th ), - that the exhaust gas inlet ( 7 ) and the exhaust outlet ( 8th ) with respect to the longitudinal central axis ( 8th ) of the filter housing ( 6 ) axially aligned with each other on the filter housing ( 6 ), that the filter structure ( 11 ) an annular and conical jacket body ( 19 ) coaxial with the longitudinal central axis ( 14 ) of the filter housing ( 6 ) in the filter housing ( 6 ) and to the exhaust inlet ( 7 ) rejuvenated. Device according to one of claims 1 to 5, characterized in that - on the cylindrical filter housing ( 6 ) the exhaust inlet ( 7 ) and the exhaust outlet ( 8th ) with respect to the longitudinal central axis ( 14 ) of the filter housing ( 6 ) are arranged axially aligned with each other, - that the filter structure ( 11 ) an annular jacket body ( 19 ) coaxial with the longitudinal central axis ( 14 ) of the filter housing ( 6 ) in the filter housing ( 6 ), that the density of the filter structure ( 11 ) within the jacket body ( 19 ) towards the exhaust inlet ( 7 ) decreases. Device according to one of claims 1 to 6, characterized by - a cleaning device ( 21 ) for cleaning the at the filter structure ( 11 ) deposited particles and - a vacuum cleaner connection ( 22 ) for connecting a suction pipe of a vacuum cleaner. Device according to one of claims 1 to 7, characterized by an uncontrolled bypass ( 31 ) for the exhaust gas bypassing of the filter structure ( 11 ). Device according to one of claims 1 to 8, characterized by a controlled bypass ( 24 ) for the exhaust gas bypassing of the filter structure ( 11 ) to which a control ( 25 ) for temperature-dependent control of the flow-through cross section of the bypass ( 24 ) assigned. Device according to one of claims 1 to 9, characterized by a cleaning device ( 21 ) for cleaning on the filter structure ( 11 ) attached particles, a movement device ( 37 ) for introducing a movement into the filter structure ( 11 ) relative to the filter housing ( 6 ), an actuating device ( 38 ) for actuating the movement device ( 37 ) and a coupling device ( 39 ) for mechanically coupling the actuating device ( 38 ) with the movement device ( 37 ), wherein the actuating device ( 38 ) outside the filter housing ( 6 ) is arranged.

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