DE102011102678A1 - Dosing device for variable quantity metering of bulk material e.g. wood fuel pellet, has metering gap which is variable and/or movable using dosing unit, so that loose portions of bulk material retained or fall through by metering gap - Google Patents

Abstract

The dosing device (8) has a bulk material container (1) which comprises container wall (5) and a downward limiting base element (6). The base element with respect to the container wall has a circumferential metering gap (7) through which the bulk material is dosed and provided into the discharge opening. The metering gap and/or closest vicinity of the metering gap is variable and/or movable using the dosing unit (9), so that the loose portions of the bulk material are retained or fall through by the metering gap. An independent claim is included for method for variable quantity metering of bulk material.

Description

The invention relates to a metering device for variable-volume metering of bulk material according to the preamble of claim 1 and a method for variable-volume metering of bulk material according to the preamble of claim 12.

Generic metering devices find their application, for example, for dosing (dimensioning) of wood fuel pellets in biomass heating, with which hot water for the heating of buildings or drinking water supply is prepared.

As with many other applications, there is also the need to vary the size of the throughput (metered bulk material), that is in the example of Biomasseheizanlage a firing performance (heating capacity) of a pellet burning burner between a minimum power and a maximum power corresponding to different sized heat requirements to vary. The throughput variation must be very precise, especially the fulfillment of the minimum performance makes high demands on the metering device, as an in / out of the pellet burner is to be avoided. For the supply of dwellings or single-family dwellings, for example, the heating power must be able to be regulated down to 1 kW, which corresponds to a pellet throughput of about 3 g or 3 ... 4 pieces per minute

Wood fuel pellets consist entirely or predominantly of wood or sawing by-products (sawdust). They are a standardized renewable fuel whose properties, including diameter, length, calorific value, water content and ash content, for Europe by the European Standard EN 14961-2 be managed. This ensures uniform quality from pellet production to delivery to the end customer. As a result of these efforts, biomass heating plants and pellet burners can be optimally designed for the fuel and the fuel can be burned with stable combustion and low pollutant emissions.

There are various known principles for the promotion and special dosage of wood pellets. The US 5 151 000 A discloses a linear displacement slider operating in the bottom region of a pellet container and advancing (conveying) pellets out of the container and into a sampling slot, from which they then slide onto a burning plate and burn there. The return stroke is used to prepare the mechanism for the next delivery stroke and slipping of the pellets to be delivered. The stroke frequency of the linear slide determines the size of the throughput and the firing capacity.

The US 5,357,877 A shows a working according to the displacement principle rotary slide, which is also arranged in the bottom region of a pellet container. At each angular movement of a turntable slide elements arranged obliquely slide the pellets to be conveyed in front of them and push them outwards into a removal shaft, from which they in turn slide onto a burning plate. A return stroke as with the linear slide is not required. The rotational frequency of the rotary valve determines the size of the throughput and the firing rate.

The DE 10 2009 020 344 B3 Replaces the slider by a rotating about a horizontal axis, also working on the displacement principle rotary valve, which is below a pellet container arranged in each cell from above receives pellets and releases down. After that, the pellets fall over a chute on the bread plate. In the DE 10 2008 050 239 A1 The pellets fall on an air-permeable and refractory conveyor belt, which transports the pellets into the combustion chamber, where they are burned on the conveyor belt. The rotational frequency of the rotary valve and the feed speed of the conveyor belt determine the size of the firing capacity.

In addition, there are numerous disclosures on the use of horizontally, vertically or obliquely arranged augers that can vary the metering capacity (throughput) by means of a clocking or speed modulating auger operation.

All these dosing devices have in common that with them a precise fuel design, in particular a very small pellet throughput, but also an adjustment of the minimum and maximum flow rate to the requirements of an individual heating system are not readily possible.

The invention has for its object to provide a dosing device for bulk material and a method for their operation, which overcome the disadvantages of the prior art and in particular provide an improved dosage with variable dosing and adjustable minimum and maximum performance limits.

This is achieved by the objects with the features of claim 1 and of claim 12 according to the invention. Advantageous developments can be found in the dependent claims.

The metering device according to the invention for variable-volume metering of bulk material, in particular of wood fuel pellets, from a bulk material container into a removal opening, the bulk material container comprising at least one container wall and at least one bottom element bounding the bulk goods container bottom, is characterized in that the bottom element relative to the container wall has a circumferential open Forming metering gap through which the bulk material is metered through and which opens into the removal opening, wherein the metering and / or a nearby environment of the metering be changed using at least one switchable and / or movable metering, so loose parts of the bulk material due to their gravity through the Dosing fall through and jammed parts of the bulk material are retained. This invention is based on the finding that bulk material, such as wood fuel pellets, then jams in front of passages or gaps when the dimensions of the openings in relation to the dimensions of the bulk material particles are relatively small; The opening dimensions may well be larger than the particle dimensions and may actually be large enough for the particles to fall through the opening. However, the bulk solids over the dosing or in the immediate vicinity of the dosing approximately in the manner of a bow or a vault from each other, hinder each other, form a jam or a blockage, and remain so dammed over the gap in the bulk material. If the passage opening or the gap or its nearest surroundings is changed, the bulk material jam is at least partially dissolved by at least some particles leaching out of the jam. These can then fall through the gap under the influence of their gravity. The change of the passage opening or of the gap or its nearest surrounding takes place with a dosing agent. If the change is completed or reduced back to an initial value, then again forms a new stable particulate matter over the dosing and the dosage stagnates. By repeated or different kind of change of the gap or its nearest environment, the amount of the falling bulk material can be influenced.

Another dosing device according to the invention is characterized in that the bulk material with the aid of at least one switchable and / or movable dosing agent is partially loosened, so that the loose bulk material falls through the dosing, while not loose loose material remains in the stowage and remains above the gap in the bulk material container.

A suitable embodiment of the metering device according to the invention is characterized in that the metering gap and / or the nearest surrounding of the metering gap are geometrically changeable. This can include a change in a gap width, a gap length and / or a gap angle, including changes in an effective gap width, an effective gap length and / or an effective gap angle, which can actually be used during the metering process of the bulk material.

Another suitable embodiment of the metering device is characterized in that the metering agent extends into the metering gap and / or into the immediate vicinity of the metering gap. Thus, for example, the dosing agent can extend permanently into the dosing gap and / or into the closest surroundings of the dosing gap and be moved therein. Or the dosing may temporarily extend into the metering and / or in the nearest vicinity of the dosing. This means that the dosing agent can at least partially dissolve the bulk material accumulations in a targeted and controlled manner at the site of formation. It is useful if the dosing agent comprises at least one loosening agent for local loosening of the bulk material. The loosening agent comprises, for example, mechanical arms or drivers which extend into the metering gap and / or into the closest surroundings of the metering gap; These can break up the bulk material accumulation locally.

Particularly suitable is a metering device in which the dosing agent consists essentially of the bottom element. This bottom element is switchable and movable and changes the metering gap formed between the bottom element and the container wall or its closest surroundings by means of a movement. For example, the gap edges can be moved and / or the gap can be broadened and / or narrowed. As a result, bulk material accumulation can be selectively and locally dissolved in a controlled manner. It is useful if the gap-limiting components (container wall and bottom element) perform a relative movement to each other. For example, the bottom element or generally the dosing means may be rotational, translatory, tumbling and / or swinging or vibratory. A round, for example, circular or elliptical shaped bottom element can move in rotation between circularly formed container walls. There are also translational movements, for example, a swinging or vibrating the bottom element between the container walls possible. The movements can take place in the plane of the (flat) floor element and / or perpendicular to the plane of the floor element. On the other hand, a relative movement of the container wall and bottom element, in which the bottom element to a vertical axis of rotation rotatable and the bulk goods container with the container wall in the direction of the axis of rotation of the bottom element up and / or moved away, offer advantages. Thus, for example, an engine driving the floor element can be set up in a stationary manner, while less frequent upward and downward movements are effected independently of this by a height-variable suspension of the container.

An advantageous embodiment of the metering device is characterized in that the metering gap in the region of a tapered contour of the bulk material container arranged and the dosing into the taper into movable and / or out of the taper is movable, so that the metering gap closable and / or variable in width is. For example, a circular bottom element is arranged in a funnel-shaped container section; the dosing gap can then be reduced or closed by a movement of the bottom element into the funnel and enlarged or opened by a movement of the bottom element out of the funnel.

A suitable embodiment of the metering device is characterized in that a metering section of the bulk material container - that is that cross section or region of the bulk material container in which the metering gap is arranged - has a main and / or longitudinal axis, and that the bottom element has an offset, eccentric main - and / or axis of rotation. As a result, the dosing gap is given different width dimensions over its length. At one area, the bottom element may almost abut against the container wall, at a region opposite a wider point of the metering gap is formed. Dosing is then primarily at this wider site. A conceivable jamming of bulk material particles in the metering gap that narrows again in the circumferential direction can be avoided if the edge of the bottom element bordering the gap is sharp-edged and thus possibly shears off particles which are drawn into the narrowing gap.

Another suitable embodiment of the metering device is characterized in that the main and / or rotational axis of the bottom element relative to the main and / or longitudinal axis of the metering section of the bulk goods container, in which the metering or the bottom element are arranged, has a movable position and moved on a cylindrical surface or conical surface about the main and / or longitudinal axis of the metering. This leads to an eccentric arrangement of the bottom element in the metering section of the bulk goods container with an annular metering gap of varying width; a narrow gap section faces a wide gap section. The axis of rotation of the bottom element travels around the longitudinal axis of the bulk material container, so that the bottom element carries out, in addition to its own rotation about its own axis of rotation, another, tumbling, rotary motion about the longitudinal axis of the bulk material container. If the axis of rotation of the bottom element moves on a cylindrical surface, then the orientation of the axis of rotation does not change, but moves from one position to a parallel position, the angle of inclination of the bottom element remains unchanged. On the other hand, if the axis of rotation moves on a conical surface, the orientation of the axis of rotation and thus the angle of inclination of the base element changes in the course of this movement. Due to the changing angle of inclination slippage of the jammed bulk material particles in the direction of the gap is favored. The dosing then again takes place primarily at the broader cleavage site. A conceivable jamming of bulk material particles in the metering gap narrowing in the circumferential direction can also be avoided here if the edge of the bottom element delimiting the gap is sharp-edged and thus possibly shears off particles which are drawn into the gap.

The inventive method for variable-volume metering of bulk material, in particular wood fuel pellets, from a bulk material container into a removal opening by means of a metering device according to one of the device claims is characterized in that bulk material that accumulates in a dormant state of the metering in the range of a metering gap by arc-like or forms dome-like blockages, is at least partially relaxed in a deviating from the dormant state of a switchable and / or movable dosing, so that the loose bulk material falls under the action of gravity through the dosing into the removal opening. The jam can be resolved by a change in the gap, for example a broadening and / or a relative movement of the gap edges and / or a relative movement of a dosing agent projecting into the gap and / or into the closest gap environment. As a result, the vault-like structures responsible for the jam break at least locally and allow parts of the bulk material to fall through the dosing gap. The amount of dosed bulk material can be adjusted by means of the gap width and the type of gap change.

When the metering gap is unchanged in a position corresponding to the size of the bulk material particles, that is to say, for example, when each movement of the metering agent is stopped, the metering comes to a standstill. In addition, it is advantageous to close the metering gap when switching off a downstream process, for example, when switching off a pellet furnace, and so every possibility to prevent unwanted further dosing. This can also be advantageous when filling (refilling) the bulk goods container, in order to avoid accidental collapse or dissolution of the bulk material jam at the metering gap under the suddenly higher load. At the beginning of a metering operation, the metering gap is then reopened from a closed position. The closing and opening can take place, for example, by a linear movement of the bottom element in the direction of its axis of rotation into a funnel-shaped metering section of the bulk goods container or out of the hopper. This movement may be superimposed by a rotational movement of the bottom element or in general of the dosing agent.

The size of a quantity of conveyed bulk material per unit of time also means the metering capacity of the metering device. In the case of pellet heating systems, this corresponds to the fuel delivery rate and the firing rate. It can be adjusted by means of a variable speed of the relative movement of the gap limiting components container wall and floor element. In general, there is an influence on the metering performance by means of a changed intervention of the metering agent, for example based on a changed speed of the relative movement of the metering agent.

With the metering device according to the invention, bulk material can be dimensioned precisely and with variable quantities. The setting of a maximum and minimum dosing is done by adjusting the device by adjusting and / or limiting the dosing. Metering performance can be monitored and controlled by counting or weighing the amount of bulk material being dosed, or by observing and evaluating the impact of bulk material on the downstream process.

The drawings illustrate several embodiments of the invention and show in the figures:

1 Longitudinal section through a bulk material container with a metering device according to the invention,

2 Longitudinal section through a bulk material container with a metering device according to the invention,

3 Side view and top view of differently shaped floor elements,

4 Longitudinal section through a bulk material container with a metering device according to the invention,

5 Longitudinal section through a bulk material container with a metering device according to the invention,

6 Longitudinal section through a bulk material container with a metering device according to the invention, and

7 Longitudinal section through a bulk material container with a metering device according to the invention.

1 and 2 each show a longitudinal section through a bulk material container 1 with a feed opening 2 for filling the bulk goods container 1 with bulk material 3 (Recognizable here at the illustrated interface of the bulk material 3 to a surrounding medium (air)), a discharge opening 4 for removing the metered bulk material 3 , a container wall 5 and a floor element 6 , The floor element 6 forms opposite the container wall 5 a horizontal metering gap, in the figures together with its closest environment (dashed circle) with the common reference numerals 7 is marked. In the bulk material container 1 is a metering device according to the invention 8th with a dosing agent 9 for dosing bulk material 3 arranged. The figures show a dosing agent 9 Essentially from the floor element 6 consists; this is the bottom element 6 a common component of both the bulk material container 1 and the dosing agent 9 , The floor element 6 and the metering gap 7 are in a funnel-shaped metering section 10 of the bulk goods container 1 arranged, it is both the bottom element 6 as well as the metering section 10 circular, as can be seen particularly well from the cross-sectional views (below). The dosing agent 9 further includes an axis 11 with which the floor element 6 is rotatably mounted. For turning the axle 11 and the floor element 6 Furthermore, a storage and a drive (motor) are required, which are not shown here; Suspension, storage and drive can, as shown here, from below, but also from above or from the side to the dosing 9 come close. The metering gap 7 is here by a rotation of the floor element 6 changeable by the dosing gap 7 limiting components, the bottom element 6 and the container wall 5 , move relative to each other. This change releases a build-up of particulate matter overlying the soil element 6 forms, at least partially, whereby parts of the bulk material 3 under the influence of gravity through the metering gap 7 fall through and be dosed. By the type and size of the movement of the dosing agent 9 The metered quantity of bulk material (number of particles) can be varied. In addition to a rotation, the dosing agent 9 or the floor element 6 be moved linearly in the direction of the axis of rotation; so that the gap width is varied, creating a minimal and a maximum dosing of the metering device are adjustable. 1 shows a centric arrangement of the dosing 9 in the dosing section 10 of the bulk goods container 1 ; that's the gap 7 , as seen from the cross-sectional view, along the entire gap length consistently wide. 2 on the other hand shows an eccentric arrangement of the dosing 9 in the dosing section 10 ; this indicates the gap 7 as can be seen from the cross-sectional view, a gap width changing along the gap length.

3 shows the side view and top view of several differently shaped floor elements 6 , floor elements 6 can, as in 1 and 2 shown, more or less conical be formed with a feed of the bulk material to the dosing favoring tendency. You can deviate also be completely flat as a plate or disc. In the three left variants of 3 are flat floor elements 6 presented the different loosening agents 12 exhibit. The loosening agents 12 are fixed to the floor element here 6 connected. These looseners 12 can have the form of pins, wedges, wings, and so on. They reach into the dosing gap 7 and / or in the immediate vicinity of the dosing 7 into it, loosen the bulk material 3 and thus promote the dosage. The right variant in 3 shows a corrugated floor element 6 , The wave shape also changes the metering gap, during a rotational movement it raises and lowers the bulk material particles and thus releases the jam in front of the metering gap.

4 and 5 each show a longitudinal section through a bulk material container 1 , In addition to the versions according to the 1 here are looseners 12 shown, with which the bulk material 3 can be relaxed. The dosing agent 9 consists essentially of the floor element 6 and the loosening agent 12 , where they can move and determine independently. So they can move synchronously, in different directions and / or with different speeds. It is also possible to use the floor element 6 or the loosening agent 12 opposite the bulk material container 1 or the container wall 5 rigid form. The dosing agent 9 is designed so that the bottom element 6 and / or the loosening agent 12 can be adjusted in the direction of their coaxial axes of rotation. This axial adjustment can be done independently, causing the loosening agent 12 deeper into the metering into and out of the gap is moved out. A combination with rigid with the floor element 6 associated loosening means in accordance with 3 is also possible in principle. A so-adjusting shear movement between the loosening agents can serve to crush oversized bulk particles. 4 shows a loosening agent 12 coming from the filling side of the bulk goods container 1 (from above) into the dosing gap 7 or in the immediate vicinity of the dosing 7 extends. In 5 protrudes the loosening agent 12 from the unloading side (from below) into the gap 7 heinein; while a rotational movement of the loosening agent is significantly less inhibited by the bulk material, as in an embodiment according to 4 ,

6 shows a longitudinal section through a bulk material container 1 , In addition to the versions according to the 1 Here is a main or rotary axis 11 of the dosing agent 9 or of the floor element 6 opposite the longitudinal axis 13 of the bulk goods container 1 or the metering section 10 inclined. This is the arrangement of the floor element 6 in the bulk material container 1 eccentric. The floor element axis 11 moves on a conical surface around the container axis 13 This causes the floor element to wobble or sway 6 circular around the tank axis 13 , The widest cleavage site thus migrates along the gap length on the container wall 5 around. The dosing agent 9 or the floor element 6 can swing around only in the container as described above (without rotation about axis 11 ); It is also possible that this pivoting is a rotation of the dosing 9 or of the floor element 6 around its own axis 11 superimposed.

7 shows a longitudinal section through a bulk material container 1 , The dosing agent 9 is not here between the container walls 5 but arranged below, whereby the metering gap is oriented vertically. The metering function is nevertheless the same as in the embodiments described above: By changing the metering gap 7 or its nearest environment, for example a relative movement between the floor element 6 and container wall 5 , a bulk material jam is dissolved and individual, loose loose particles 3 fall so metered into the removal opening 4 , In contrast to the figures described above, the removal opening 4 led out to the side. The floor element 6 is elliptical in this embodiment, this results despite the centric arrangement of the floor element 6 in the dosing section 10 of the bulk goods container 1 a metering gap 7 with varying width along the gap length. This results in a different metering characteristic than in a circular bottom element: bulk material jams dissolve upon movement of the dosing 9 over the wide part of the metering gap easier than over the narrow places.

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

• US 5151000 A [0005]
• US 5357877 A [0006]
• DE 102009020344 B3 [0007]
• DE 102008050239 A1 [0007]

Cited non-patent literature

• Standard EN 14961-2 [0004]

Claims (14)

Dosing device ( 8th ) for variable-volume dosing of bulk material ( 3 ), in particular of wood fuel pellets, from a bulk material container ( 1 ) into a removal opening ( 4 ), wherein the bulk material container ( 1 ) at least one container wall ( 5 ) and at least one floor element ( 6 ), characterized in that the floor element ( 6 ) opposite the container wall ( 5 ) a circumferential metering gap ( 7 ), through which the bulk material ( 3 ) is metered through and into the removal opening ( 4 ), wherein the metering gap ( 7 ) and / or a nearest environment of the metering gap ( 7 ) by means of at least one switchable and / or movable dosing agent ( 9 ) are changeable, so that parts of the bulk material ( 3 ) through the metering gap ( 7 ) fall through or are retained. Dosing device ( 8th ) for variable-volume dosing of bulk material ( 3 ), in particular of wood fuel pellets, from a bulk material container ( 1 ) into a removal opening ( 4 ), wherein the bulk material container ( 1 ) at least one container wall ( 5 ) and at least one floor element ( 6 ), characterized in that the floor element ( 6 ) opposite the container wall ( 5 ) a circumferential metering gap ( 7 ), through which the bulk material ( 3 ) is metered through and into the removal opening ( 4 ), the bulk material ( 3 ) by means of at least one switchable and / or movable dosing agent ( 9 ) is partially loosely so that the loose bulk material ( 9 ) through the metering gap ( 7 ) falls through. Dosing device ( 8th ) according to one of the preceding claims, characterized in that the metering gap ( 7 ) and / or the nearest surroundings of the metering gap ( 7 ) are geometrically changeable. Dosing device ( 8th ) according to one of the preceding claims, characterized in that the dosing agent ( 9 ) into the metering gap ( 7 ) and / or in the immediate vicinity of the metering gap ( 7 ). Dosing device ( 8th ) according to one of the preceding claims, characterized in that the dosing agent ( 9 ) the floor element ( 6 ). Dosing device ( 8th ) according to one of the preceding claims, characterized in that the dosing agent ( 9 ) at least one loosening agent ( 12 ) for loosening the bulk material ( 3 ). Dosing device ( 8th ) according to one of the preceding claims, characterized in that the change in the metering gap ( 7 ) and / or the nearest surroundings of the metering gap ( 7 ) in a relative movement of the gap limiting components container wall ( 5 ) and floor element ( 6 ) consists. Dosing device ( 8th ) according to one of the preceding claims, characterized in that the dosing agent ( 9 ) is rotationally and / or translationally and / or tumbling movable. Dosing device ( 8th ) according to one of the preceding claims, characterized in that the metering gap ( 7 ) in the region of a tapered contour of the bulk goods container ( 1 ) and the dosing agent ( 9 ) is movable into the taper and / or is movable out of the taper so that the metering gap ( 7 ) is closable and / or changeable in width. Dosing device ( 8th ) according to one of the preceding claims, characterized in that a metering section ( 10 ) of the bulk goods container ( 1 ), in which the metering gap ( 7 ) is arranged, a main and / or longitudinal axis ( 13 ) and the bottom element ( 6 ) a staggered, eccentric main and / or rotational axis ( 11 ), whereby the metering gap ( 7 ) has different width dimensions over its length. Dosing device ( 8th ) according to claim 10, characterized in that the main and / or rotational axis ( 11 ) of the floor element ( 6 ) with respect to the main and / or longitudinal axis ( 13 ) of the metering section ( 10 ) has a location that can be moved and is located on a cylindrical surface or conical surface around the main and / or longitudinal axis ( 13 ) of the metering section ( 10 ) emotional. Method for variable-volume dosing of bulk material ( 3 ), in particular of wood fuel pellets, from a bulk material container ( 1 ) into a removal opening ( 4 ) by means of a metering device ( 8th ) according to one of claims 1 to 11, characterized in that bulk material ( 3 ), which in an idle state of the dosing device ( 8th ) in the region of a metering gap ( 7 ) accumulates in a dosing state deviating from the idle state from a switchable and / or movable dosing agent ( 9 ) is at least partially relaxed, so that the loose bulk material ( 3 ) under the action of gravity through the metering gap ( 7 ) through into the removal opening ( 4 ) falls. Method according to claim 12, characterized in that the metering gap ( 7 ) is opened at the beginning of a metering operation from a closed position and at the end of the metering operation and / or before filling the bulk goods container ( 1 ) is closed. A method according to claim 12 or 13, characterized in that a dosing by means of a variable speed of the relative movement of the dosing ( 7 ) delimiting components container wall ( 5 ) and floor element ( 6 ) is changed.

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