EP2444569A1 - Method and device for conveying bulk material - Google Patents

Abstract

The device (1) has a container (2) receiving bulk material, and a transition (44) over which the bulk material in a pneumatic conveying line is transferred. A vertical agitator (4) is arranged in the container. The agitator comprises an agitation unit (5) and another agitation unit (6) coaxially aligned to the former agitation unit. The agitation units stay in effective connection with each other such that the latter agitation unit executes a relative rotational movement with respect to the former agitation unit. The agitation units are rotated at a common rotation axis (R). An independent claim is also included for a method for conveying bulk material and blowing blow-in insulation material.

Description

The invention relates to a device and a method for conveying bulk material. The inventive device are particularly suitable for blowing Einblasdämpfstoff, especially cellulose, for example, in cavities of walls, ceilings or floors of buildings. Another field of application relates to the so-called "open-inflation", in which, for example, roof floors are coated with damping material for energetic renovation by blowing.

Genetically comparable devices are for example from the US 5,511,730 and US 7,568,642 known. The devices have arranged in the container agitators with a vertical axis of rotation. At the axis of rotation radial stirring arms or other stirring means for loosening the Einblasdämmstoffes are firmly fixed. In practice, it has been shown that only insufficient dissolution results can be achieved with such agitators. If the dissolution is incomplete, lumps remain in the insulating material, whereby the insulation product created by blowing has worse insulation values. Furthermore, it can also lead to blockages before or in the pneumatic delivery line. Another disadvantage is that conventional agitators are operated at relatively high speeds or angular speeds.

It is therefore an object of the present invention to avoid the disadvantages of the known and in particular to provide a device and a method in which the bulk material is dissolved or loosened in an advantageous manner with the agitator. In particular, the final product, ie, for example, created by blowing insulation products, high demands for homogeneity and thus thermal insulation properties suffice. The device should continue to be energetically efficient operable.

These objects are achieved according to the invention with an apparatus and a method having the features of the independent claims.

The device has a container for receiving bulk material and a preferably vertical agitator in the operating position for dissolving or loosening the bulk material. Preferably, in the region of the bottom of the container, a transition is arranged, via which the bulk material can be transferred and conveyed into a preferably pneumatic conveying line. Depending on the field of application, a nozzle or a discharge nozzle can be arranged at the user end of the delivery line. The agitator has at least two coaxial stirring units, which are in operative connection with each other so that they are movable relative to each other. This can achieve significant benefits. One advantage, for example, is that the stirring units can be operated at a comparatively low rotational or angular speed. Experiments with prototypes have shown that the degree of loosening significantly improved and results in a nearly homogeneous two-phase flow in the pneumatic conveying of the material in the delivery line.

In a first embodiment, the first stirring unit can be fixed and the second stirring unit can be rotatably arranged in the container. The device may also have two rotatable stirring units. In this case, the first stirring unit and the second stirring unit may be connected to one another in terms of gear in such a way that the stirring units are rotatable about different axes of rotation and / or angular speeds about a common axis of rotation. The transmission may, for example, a reduction gear be, whereby the stirring units can rotate at different speeds. The transmission may also comprise coupling means via which the stirring units can be coupled automatically (eg with a centrifugal clutch) or by means of control means or by control to a drive unit for driving the stirring units.

It may be particularly advantageous if the device has a gearbox with the aid of which the first stirring unit and the second stirring unit are rotatable in opposite directions. With such an arrangement, particularly good dissolution results can be achieved even at comparatively low speeds.

The first stirring unit may have or be connected to a drive shaft, and the second stirring unit may have or be connected to a hollow shaft, wherein the drive shaft is received in the hollow shaft.

Particularly advantageously, the device has a planetary gear, via which the first stirring unit and the second stirring unit are connected to each other in terms of gear. Planetary gears have the advantage that they allow different modes of operation and in particular also opposing rotational movements of the stirring units. Another advantage is that by using a planetary gear compact devices are created with comparatively small external dimensions.

The planetary gear may have a ring gear which is rigidly connected to the first stirring unit or connectable by means of coupling means.

The stirring arms of the first stirring unit can be rigidly connected to the ring gear, in particular by welding or in another way.

The first stirring unit and / or the second stirring unit may each comprise at least one, preferably at least two, and more preferably at least three, and typically six, stirring arms extending from the inside to the outside and in particular in the radial direction. In a vertical stirrer in operating position, the stirring arms are preferably each on horizontal planes. The stirring arms can also be inclined.

At the Rührarmen can be arranged by these projecting and preferably approximately axially parallel additional Rührabschnitte or extensions. These additional stirring sections can thus form vertical stirring means for vertical agitators, whereby the dissolution or loosening of the bulk material can be carried out more efficiently depending on the material properties.

The first stirring unit and the second stirring unit may each comprise at least one stirring arm provided with projecting stirring portions or extensions, wherein the additional stirring portions of the two stirring units are preferably aligned with each other or wherein the additional stirring portions of the two stirring units also extend in the same direction could be.

At the respective stirring arms, a plurality of stirring portions may be arranged to form a comb-like configuration. The comb-like configuration is characterized by a plurality of successively arranged and aligned in the same direction Rührabschnitte or extensions, for example in the form of prongs from. The additional stirring portions of the stirring units can be aligned with one another and arranged (of course without touching each other) intermeshing and meshing with each other.

At the outer end at least one stirring arm and preferably at the outer ends of each stirring arm, a stirring blade section projecting away from the stirring arm can be attached to at least one of the stirring units. The stirring units can be designed, for example, as stirring stirrers.

The apparatus may include means for scraping off soil remaining material. Such scraping means may be scraping segments attached or formed on at least one lower stirring arm. The scraper segments can be formed by obliquely directed towards the ground profile parts. Alternatively, the scraping means can also be formed by profile sections which connect in radial section to a stirring section. Such a profile section may be an end section having a free end.

At the stirring blade section can connect an inwardly directed end portion. The end portion may be arranged in the region of the inside of a bottom of the container for scrapping or detachment of bulk material at the bottom. Furthermore, it may be advantageous if the mixing arm with the associated stirring blade section and the end section produce a U-shaped configuration in radial section. Overall, it may be advantageous if one of the stirring units in the radial section has an approximately U-shaped or V-shaped configuration and is designed such that it surrounds the other stirring unit.

At least one agitating tine can be arranged on the respective stirring arms. Preferably, a plurality of approximately axially parallel stirring tines are arranged on the respective stirring arms. These stirring prongs can be formed by the previously mentioned additional stirring sections or extensions.

The stirring prongs may have screw portions which are screwed or screwed into complementary screw holes in the stirring arm. In this way, the field of application can be extended. Depending on requirements, stirring tines can be removed, inserted or replaced by tines of other dimensions or shapes.

The device may comprise a drive unit for driving the agitator. The drive unit may be, for example, a commercially available electric motor. For mobile applications in which no power connections are available, the device may also be equipped with a combustion and in particular with a diesel engine as a drive unit.

The device may have a metering unit in the form of a rotary valve for the metered feeding of bulk material into a delivery line and a blower unit for generating a compressed air flow for the pneumatic conveying of the bulk material of the delivery line. The delivery line may preferably be a flexible tube, allowing the user to easily place the free end of the tube and fill or top up the material at the desired location.

The blower unit may be, for example, a blower in axial or radial design. Also conceivable are positive displacement blowers. Other types of fans, blowers or compressors are also possible.

The apparatus may comprise a drive unit with which the stirring units and the fan unit and optionally (i.e., if present) a metering unit are jointly operable or drivable.

Another aspect of the invention relates to a method for conveying bulk material and in particular for blowing Einblasdämmstoff, preferably using the device described above. The method comprises a working step in which the bulk material received in a container is dissolved or loosened with a preferably vertical agitator, comprising a first and at least one second stirring unit coaxially aligned with the first stirring unit. During the dissolution process, the second stirring unit performs relative rotational movement with respect to the first stirring unit. The method then further comprises the step that the bulk material thus dissolved is transferred from the container into a preferred pneumatic conveying line. During transfer, the bulk material can pass through a rotary valve or another metering device.

Figur 1:

Eine schematisierte Darstellung einer erfindungsgemässen Vorrichtung zum Fördern von Schüttgut,

Figur 2:

eine schematische Darstellung eines Rührwerks mit einem Planetengetriebe für die Vorrichtung gemäss Figur 1,

Figur 3:

eine Seitenansicht einer erfindungsgemässen Vorrichtung in einer vereinfachten Darstellung,

Figur 4:

eine vergrösserte und vereinfachte Darstellung eines Rührwerks für die Vorrichtung gemäss einem weiteren Ausführungsbeispiel,

Figur 5:

eine Seitenansicht einer weiteren Vorrichtung mit geöffnetem Deckel,

Figur 6

eine perspektivische Aussenansicht der Vorrichtung aus Figur 5 (Deckel geschlossen),

Figur 7

eine perspektivische Darstellung eines Rührwerks für die Vorrichtung,

Figur 8a

eine Draufsicht des Rührwerks aus Figur 7,

Figur 8b

eine Seitenansicht des Rührwerks aus Figur 7,

Figur 8c

eine weitere Seitenansicht des Rührwerks aus Figur 7,

Figur 9

eine perspektivische Darstellung eines weiteren Rührwerks für die Vorrichtung,

Figur 10

eine perspektivische Darstellung eines weiteren Rührwerks für die Vorrichtung,

Figur 11

eine alternative Ausführungsform der Vorrichtung gemäss Figur 6, und

Figur 12

eine alternative Vorrichtung in einer Seitenansicht.

Further individual features and advantages of the invention will become apparent from the following description of exemplary embodiments and from the drawings. Show it:

FIG. 1:

A schematic representation of an inventive device for conveying bulk material,

FIG. 2:

a schematic representation of an agitator with a planetary gear for the device according to FIG. 1 .

FIG. 3:

a side view of an inventive device in a simplified representation,

FIG. 4:

an enlarged and simplified representation of an agitator for the device according to a further embodiment,

FIG. 5:

a side view of another device with the lid open,

FIG. 6

an external perspective view of the device FIG. 5 (Lid closed),

FIG. 7

a perspective view of an agitator for the device,

FIG. 8a

a plan view of the agitator FIG. 7 .

FIG. 8b

a side view of the agitator FIG. 7 .

FIG. 8c

another side view of the agitator FIG. 7 .

FIG. 9

a perspective view of another agitator for the device,

FIG. 10

a perspective view of another agitator for the device,

FIG. 11

an alternative embodiment of the device according to FIG. 6 , and

FIG. 12

an alternative device in a side view.

FIG. 1 shows a generally designated 1 device with which Einblasdämmstoff, such as cellulosic fiber materials can be injected to a desired location. The apparatus 1 comprises a container 2 with a container wall 18, into which bulk materials loosely stored in bags, such as insulating fibers or fibrous flakes or insulating material present in bales, are introduced. In the container above the bottom 19 is a stirrer 4 for dissolving or loosening the introduced material. The material thus dissolved is then transferred to a pneumatic conveying line 3 and conveyed to the outlet of the line 3. Denoted by 10 is a blower unit for generating a compressed air flow for the pneumatic conveying in the delivery line. The indicated with a dotted line material flow at the end of the feed line 3 is blown into cavities or open shots for thermal insulation of newly built buildings or building renovation. Instead of cellulose or cellulose-containing materials, other materials for insulation, such as mineral fibers, sheep's wool, wood fiber insulation, glass wool, rock wool, wood chips, etc., can also be inflated or inflated with the device. It would also be conceivable to process and convey other bulk materials such as road salt, gravel or lime meal with this device.

In the embodiment according to FIG. 1 (As well as in the following embodiments), the agitator 4 is vertically aligned in the operating position. Of course, the axis of rotation denoted by R could also be inclined or aligned. The agitator 4 comprises a lower stirring unit 5 and an upper stirring unit 6. The two stirring units 5 and 6 are aligned coaxially with one another and connected to one another in a gearbox manner. The agitator is connected via a drive shaft 11 with a Drive unit 8, for example, an electric motor, operated. A gear 7 is designed such that the two stirring units 5 and 6 are movable relative to each other. The transmission 7 (for example, a planetary gear with a ring gear 13, they also subsequent Fig. 2 ) allows, for example, opposing rotational movements of the two Rühreinheiten 5 and 6. The Rühreinheiten can rotate at different angular velocities in the same or opposite directions.

The respective stirring units have radially outwardly directed stirring arms 16, 17. The respective stirring arms 16, 17 are arranged horizontally and lie on approximately plane-parallel to the container bottom 19 extending planes. At the outer ends of the arms 16, 17 close approximately at an angle projecting Rührblattabschnitte 22, 23, which are directed towards each other. However, it would also be conceivable that a stirring unit can be stationary relative to the bottom of the device.

FIG. 2 shows a possible embodiment of a stirrer 4 with a schematic diagram of the transmission 7. The transmission 7 is designed as a planetary gear and has a sun gear 14, three sitting on a planet carrier 20 planet gears 15 and a ring gear 13. Denoted at 11 is a drive shaft directly or indirectly connected to the motor, to which the stirring arms 17 of the upper stirring unit 6 are attached. The stirring arms 16 of the lower stirring unit 5 are fixedly connected to the ring gear 13. The transmission module 7 has controllable couplings 27 and 28, whereby various modes are possible. The planet carrier 20 as a driver is selectively connectable via the shiftable clutch 28 with the ring gear 13. With the aid of a switchable coupling 29, the sun gear 14 can be rotatably connected to the drive shaft. Depending on the intended use can of course also on individual or all of the aforementioned couplings (27, 28, 29) be waived. The respective clutches could also be designed as automatic clutches. Theoretically, transmission modules with multi-stage planetary gears would also be conceivable. In the embodiment according to FIG. 2 the planetary gears 15 are configured only in one stage.

How out FIG. 3 As can be seen, the two stirring units 5 and 6 have aligned, vertically extending additional stirring sections or extensions (see also FIGS Fig. 4 ). The planetary gear is located directly below the container bottom 19. The planetary gear is in FIG. 3 not shown in detail and therefore only indicated by 7.

In the bottom 19 is located as a transition to the delivery line, an outlet 44, via which the material enters the delivery line. To transfer the material into the delivery line, the device 1 has a rotary valve 9, which is connected upstream of the pneumatic delivery line. The transition 44 could basically - be arranged in the bottom area of the side wall 18 of the container - instead of on the ground.

With a drive unit 8 (in Fig. 3 in the background), which serves to drive the agitator 4, at the same time the rotary valve 9 can be operated. The respective machine components 4 and 9 are connected via a transmission 21 (in Fig. 3 also in the background) geared to the unit 8 connected. The drive unit 8 and the gear 21 are formed as a motor / gear unit. The gear 21 may have a reduction gear or be configured as such, whereby the cell wheel of the dosing unit 9 and the drive shaft associated with the agitator 4 are operated at different speeds. A blower 10 serves to generate a conveying air flow.

In FIG. 4 is the planetary gear 7, via which the two Rühreinheiten 5 and 6 are connected to the drive unit. shown greatly simplified. The first stirring unit 5 is connected to a drive shaft 11 and the second stirring unit 6 has a hollow shaft 12. The drive shaft 11 is received in the hollow shaft 12. The ring gear 13 is connected to transmit power to the hollow shaft 13 of the planetary gear 7. The sun gear is rotatably mounted on the drive shaft 11. The rotational movements are shown with arrows for angular velocities ω ₁ and ω ₂ . The respective stirring units 5 and 6 of the agitator 4 are similar to the embodiment according to FIG. 3 designed like a comb. The respective stirring portions 24 and 25 of the stirring units 5 and 6 are aligned with each other and interlockingly arranged without disturbing each other. In addition to the stirring portions 25 extending towards the bottom, the upper stirring unit additionally has axially parallel, upwardly protruding tear-off portions 40 and 40 'of different lengths and a scraper 26 directed to the container side wall 18. The tear-off portions 40, 40' are used for tearing off material a bottom of a bale of insulating material. By the tear-off sections are not formed the same length, the bale is applied irregularly. This avoids turning the bale in the container without tearing off any material.

As the embodiment according to FIG. 5 shows, the agitator 4 and the rotary valve can be connected in terms of gear on the drive unit 8. The motor shaft of the drive unit 8 is aligned coaxially with the rotor of the rotary valve 9. With the aid of a bevel gear 31 and a planetary gear 7 (see also FIGS. 7 and 8 ) is also the agitator 4 driven by the drive unit 8. To reduce the speed is provided with the drive unit as a unit formed gear 21. Furthermore, in FIG. 5 and the perspective external view of the injection device 1 according to FIG. 6 an outlet 32 recognizable, to which the delivery line for conveying the insulation materials can be connected. The support line is in FIG. 5 indicated by dashed lines. On the opposite side of the outlet nozzle 32 is an inlet nozzle 37 to which the blower 10 is connected. The mechanical components for operating the agitator and for conveying the bulk material are located in the self-standing stable designated 41, which adjoins the container bottom 19 and is connected to this example by means of screws. All components are attached to a common plate, which forms a force node. The base 19 has an enclosure, whereby about engine and fan noise and noise of the rotary valve 9 can be reduced. By a sound insulation, the per se occurring noise can be insulated so that it no longer bothers. Particularly advantageous housing is equipped with sound-absorbing means, which allows use of the device in residential areas. For the sound insulation, the side walls of the substructure 41 can be clad on the inside with sound insulation mats.

How out FIG. 6 As can be seen, the containers of the devices need not necessarily be cylindrical. The container is present octagonal in plan view. Of course, other container shapes are conceivable. Moreover, the containers need not be evenly configured in the axial direction. The container could have a funnel-shaped container section on the bottom side. With the exception of the stirring units, the movable machine components (eg planetary gear 7, drive unit 8, rotary valve 9, Blower) housed in the base 41 and dust and / or soundproof included. The substructure has a support structure with which the device can be stably placed on the ground. In FIG. 6 Furthermore, a latticed intake filter is shown.

FIG. 11 shows a device with about the same base 41 as in FIG. 6 However, it is also conceivable to arrange the various components in a frame and to arrange the frame in the interior of the container at the bottom thereof. This container 2 has an approximately quadrangular shape in plan view and consists essentially of plastic. In the present embodiment, a commercial container for compostable waste was used as container 2. Such containers are inexpensive and available in different sizes. Such containers are generally known and used in Germany under the name "green waste bin" (GMT). A GMT only has to be adapted in the area of the floor by means of cutting and drilling operations for the attachment or for the connection to the substructure or if the components are used for material and air inlets and outlets. This device is also very easy to transport and is particularly well suited as a small appliance for craftsmen or for home improvement. Depending on the size, the device can be provided with carrying handles or in the case of larger and heavier devices with wheels, as they are already present in a GMT.

The FIGS. 7 and 8a / b / c show a further alternative variant for an agitator 4 of the device according to the invention. The agitator 4 in turn has two stirring units 5 and 6. The stirring units have, in contrast to the other embodiments stirring blade sections 22 and 23 extending in the same direction. In particular FIG. 8a shows that the respective stirring arms do not necessarily have the same length and can have different Rührarmlängen. The agitator further comprises a transverse bridge member 35, which connects two mutually opposite Rührblattabschnitte the upper Rühreinheit 6 together.

Next, the embodiment is characterized according to the FIGS. 7 and 8 by a comparatively simple planetary gear 7. The planetary gear has only one planetary gear 15 which is rotatably mounted on a fixed axis 33 on the planet carrier 20. The planet carrier 20 is designed frame-shaped in plan view. On the frame adjoins an inwardly extending, in plan view about triangular holding section on the inner tip of the planet gear 15 is mounted (see esp. Fig. 8a ). The two Rühreinheiten 5 and 6 are detachably connected to the Antiebsmitteln. The free end of the drive shaft 11 is designed flattened and forms a form-fitting portion 43 for attachment of the upper stirring unit 6 by means of positive engagement. For this purpose, a corresponding hole is provided centrally in the stirring unit 6. At the outer edge of the ring gear, a plurality of connecting parts 36 are arranged, which are connected in a force-transmitting manner with the stirring arms 16 of the lower stirring unit for the rotational movement. In the present exemplary embodiment, the connecting parts 36 have recesses complementary to the stirring arms, into which the respective stirring arms can be accommodated approximately accurately. Instead of such a releasable interface between the lower stirring unit and planetary gear mechanism, it would of course also be conceivable to rigidly connect, for example, a welded connection between the stirring unit and the ring gear.

How out FIG. 8b shows, the bridge member 35 is arranged obliquely in the agitator and inclined at an angle of about 15 ° to the horizontal. The bridge member serves to tear off material from the underside of a bale. The bridge member 35 is detachably connected to the upper stirring unit 6 and can optionally be easily assembled or disassembled.

How the particular Figures 8b and 8c show, the respective stirring arms 16 and 17 of the two stirring units are close to each other. The distance between the stirring arms can be a few centimeters (eg A = 2cm). One of the stirring arms 16 has a stripping segment 34 directed obliquely against the bottom 19, with which material remaining on the inner bottom wall can be returned to the loosening process. This additional element 34 can be fastened by means of screw connections to the corresponding stirring unit.

In FIG. 9 Another variant for a stirrer 4 is shown. The agitator 4 has a lower stirring unit 5 with six stirring arms 16. By contrast, the upper stirring unit 6 has only four stirring arms 17. The stirring arms are provided with rectangular and round holes, in which, as required, extending in the axial direction Rührabschnitte with rectangular or even round cross section can be inserted. In FIG. 9 the additional stirring sections or prongs are formed by flat profiles 22 or 25. Out FIG. 9 goes on to say that the respective stirring arms can be equipped differently with tines. Thus, for example, the stirring arm denoted by 16 'merely has an agitating tine 22' arranged approximately centrally. The adjoining mixing arm 16 has an external tine 22 and a tine lying in the region of the drive shaft 11. The opposite rotational movement of the two stirring units 5 and 6 are indicated by the arrows ω ₁ and ω ₂ .

The agitator 4 according FIG. 10 has Rühreinheiten 5 and 6, which are equipped with a variety of attachments. The upper stirring unit 6 has two mutually opposite stirring arms 17 with axially aligned stirring blade sections 23, at the ends of which inwardly directed end sections 34 join. These end portions 34 form bottom-side scraper segments, which are evidently formed by inclined flat profiles. As a result, upon rotation in the ω ₂ direction, material remaining on the bottom of the container (not shown) can be easily removed or scraped off or simply scraped off. The agitator arms 17 with the associated Rührblattabschnitten 23 and end portions 34 result in a radial section about an U-shaped configuration surrounding the other stirring unit 5, whereby the Rühreinheiten are in an opposite rotational movement past each other. The stirring tines 24 and 25 of the two stirring units have transverse bars 38 and 39 running transversely to the tines and extending horizontally. The cross bars can also comb each other. Such cross bars could also in corresponding openings on the Rührblattabschnitten or tines 22, 23, 24, 25 according to FIG. 3 or 7 be arranged. In addition, at the upper Rührarmen 17 upwardly in the axial direction extending Abreisssabschnitte 40 are screwed.

The embodiment according to FIG. 12 is characterized inter alia by the fact that only one stirring unit 6 is rotatably arranged in the container 2; the other stirring unit 5, however, is arranged fixed in the container 2. At the outer end of the upper horizontal stirring arms 17 close from this approximately perpendicular projecting Rührblattabschnitte 23 at. In turn, inwardly directed end portions 34 adjoin the stirring blade sections 23, whereby mixing arm 17, stirring blade section 23 and end section 34 define a U-shape in radial section. The respective ones Sections 17, 23 and 34 are integrally connected to each other and can by bending processes in the in FIG. 12 shown form brought. The tines 24 and 25 of the respective stirring units are designed as screws, each having a screw portion and a screw head. Furthermore, the upper stirring unit 6 has prongs which extend both downwards and upwards in the vertical or axial direction. The upper stirring section of this tine is designated 40. To screw in the respective stirring arms corresponding threaded holes. The drive unit 8 is aligned coaxially with the stirring or rotation axis R. In addition to the agitator 4, the drive unit 8 also drives the blower 10. Other than according to Fig. 5 the blower is designed as a blow-through fan, which sucks in and conveys material and air. The fan unit is designed as a radial fan and has a rotatable about the axis R, filled with blades impeller. The device 1 further comprises a reduction gear 21. This gear 21 ensures that the stirring unit 6 rotates at a considerably lower speed than the impeller 42. Of course, such a blower can also be combined with a device of the type previously described equipped with a planetary gear.

Claims (18)

Device (1) for conveying bulk material and in particular for blowing in blown insulating material, in particular cellulose, with a container (2) for receiving the bulk material, a transition (44) via which the bulk material can be transferred into a preferably pneumatic conveying line (3), and at least one preferably vertical agitator (4) arranged in the container, characterized in that the agitator (4) has a first agitating unit (5) and at least one second agitating unit (6) coaxially aligned with the first agitating unit and thus operatively connected to each other in that a relative rotational movement with respect to the first stirring unit (5) can be carried out with the second stirring unit (6). Apparatus according to claim 1, characterized in that the first stirring unit (5) fixed and the second stirring unit (6) are rotatably arranged in the container (2). Apparatus according to claim 1, characterized in that the first stirring unit (5) and the second stirring unit (6) are connected to each other in gear such that the stirring units (5, 6) with different directions of rotation and / or angular velocities about a common axis of rotation (R) are rotatable and that in particular the device comprises a gear (7), by means of which the first stirring unit (5) and the second stirring unit (6) are rotatable in opposite directions. Device according to one of claims 1 to 3, characterized in that the first stirring unit (5) has a drive shaft (11) and the second stirring unit (6) have a hollow shaft (12), wherein the drive shaft (11) is received in the hollow shaft (12). Device according to one of claims 1 or 3 to 4, characterized in that the device comprises a planetary gear (7) via which the first stirring unit (5) and the second stirring unit (6) are connected to each other in terms of gear. Apparatus according to claim 5, characterized in that the planetary gear (7) has a ring gear (13) which is rigidly connected to the first stirring unit (5) or connectable. Device according to one of claims 1 to 6, characterized in that the first stirring unit (5) and / or the second stirring unit (6) each at least one, preferably at least two and more preferably three from the inside out and in particular in the radial direction extending Stirring arms (16, 17). Apparatus according to claim 5 and claim 6, characterized in that the stirring arms (16) of the first stirring unit (5) are connected to the ring gear (13) in particular by welding. Apparatus according to claim 7 or 8, characterized in that the stirring arms (17, 17) of these projecting and preferably approximately axially parallel extending additional stirring sections are arranged. Device according to one of claims 7 to 9, characterized in that the first stirring unit (5) and the second stirring unit (6) each have at least one stirring arm (16, 17) provided with projecting stirring portions (22, 23, 24, 25), wherein the additional stirring portions (22, 23, 24, 25) of the stirring units are aligned with each other or aligned in the same direction. Device according to one of claims 7 to 10, characterized in that a plurality of additional stirring portions for forming a comb-like configuration are arranged on the respective stirring arms (16, 17). Device according to one of claims 9 to 11, characterized in that the additional Rührabschnitte (22, 23, 24, 25) of the stirring units (5, 6) aligned with each other and interlocking. Device according to one of claims 7 to 12, characterized in that at the outer end at least one Rührarms (16, 17) and preferably at the outer ends of each Rührarm (16, 17) at least one of the Rühreinheiten (5, 6) one of the Rührarm Wegragender stirring blade section (22, 23) adjoins. Apparatus according to claim 13, characterized in that on the stirring blade section (22, 23) an inwardly directed end portion (34) adjoins. Apparatus according to claim 14, characterized in that the end portion (34) in the region of the inside of a bottom (19) of the container (2) for bottom scraping of Bulk material is arranged. Apparatus according to claim 14 or 15, characterized in that stirring arm (17) with associated stirring blade section (23) and end section (34) in the radial section give an approximately U-shaped form. Device according to one of claims 1 to 16, characterized in that one of the stirring units (6) in radial section has an approximately U- or V-shaped configuration and is designed such that it surrounds the other stirring unit (5). Method for conveying bulk material and in particular for blowing in blown insulation, in particular using the device (1) according to one of claims 1 to 17, characterized by the following steps: Dissolving the bulk material received in a container (2) with a preferably vertical agitator (4) comprising a first stirring unit (5) and at least one second stirring unit (6) coaxial with the first stirring unit, the second stirring unit (6) providing a relative stirring Performs rotational movement with respect to the first stirring unit (5), and - Transferring the bulk material from the container in a preferably pneumatic conveying line (3).

Images