The invention relates to an agitator device as per the preamble of claim 1.
Agitator bodies having a hub and having carrier struts welded to the hub, to which carrier strut in each case one agitator blade is fastened, are known from the prior art. Here, the hub is drive shaft of an agitator. Furthermore, agitating elements are known in the case of which agitator blades are welded directly to a hub.
It is the object of the invention in particular to provide a generic agitator device with improved characteristics with regard to a design. The object is achieved according to the invention by means of the features of patent claims 1, 2 and 15, whereas advantageous embodiments and refinements of the invention can be gathered from the subclaims.
The invention proceeds from an agitator device having at least one carrier unit, which has at least one connection element for a connection to a drive shaft and at least one beam element for the fastening of at least one agitator blade.
It is proposed that the beam element and the connection element are connected to one another in a one-part implementation.
Alternatively or advantageously in addition, it is proposed that the beam element has at least one portion with an at least substantially quadrilateral cross section.
By means of the embodiment according to the invention, an advantageous design can be achieved. Furthermore, an agitator device which is inexpensive and/or easy to manufacture can be provided. Furthermore, an agitator device can be provided which can be cut out of a sheet, wherein, in particular, the number of required welding processes can be reduced and/or strength can be increased. In particular, a hub and struts of an agitator device can be manufactured from a common workpiece, wherein the agitator device is advantageously of seamless form. Furthermore, high flexibility can be achieved with regard to a connection of an agitator blade. In particular, an agitator blade can be easily attached to a carrier strut. It is advantageously possible to at least almost completely dispense with milling machining during a production process. Furthermore, a strut can be provided which has an advantageous geometry, in particular with regard to simple production and/or a flexible and/or simple connection of an agitator blade.
An “agitator device” is to be understood in particular to mean an in particular functional constituent part, in particular a structural and/or functional component, of an agitator appliance, for example of a mixer and/or of an agitator mechanism, in particular for a fluid, in particular with a maximum rotational speed of 500 rpm, advantageously of 200 rpm, particularly advantageously of 100 rpm, preferably of 50 rpm. In particular, the agitator device may also comprise the entire agitator appliance. The agitator device is advantageously a constituent part of an agitator body or implemented as an agitator body. The agitator device is particularly advantageously provided for being rotated about an axis of rotation, in particular during an agitation process. The agitator device is preferably of point-symmetrical form, in particular with respect to a central point of the connection element. It is particularly preferable if, in an installed state of the agitator device, the axis of rotation of the agitator device runs through the central point of the connection element. It is advantageously the case that, in an installed state, the axis of rotation runs parallel to the vertical direction, in particular in a normal operating state of the agitator appliance, wherein the vertical direction runs preferably perpendicular to an underlying surface.
The carrier unit is preferably embodied in a one-part implementation. The carrier unit is particularly preferably realized at least predominantly and in particular completely from a metal, for example from steel and/or high-grade steel and/or from an alloy and/or from any other desired metal such as for example aluminum and/or titanium. It is however also conceivable for the agitator unit to be manufactured at least predominantly from a plastic. It is furthermore conceivable for the agitator unit to have an, in particular additional, at least partial coating, for example with a metal oxide and/or an in particular corrosion-resistant polymer, and/or to be of rubber-lined form. Here, the expression “at least predominantly” is to be understood in particular to mean at least 55%, advantageously at least 65%, preferably at least 75%, particularly preferably at least 85% and particularly advantageously at least 95%.
The connection element, or all of the connection elements of the carrier unit, and the beam element, or all of the beam elements of the carrier unit, preferably form the carrier unit.
The connection element advantageously forms a part, in particular an upper part, of a hub. The connection element is particularly advantageously implemented at least predominantly, in particular entirely, from a metal, for example from steel and/or from high-grade steel, and/or from the same material as the carrier unit. It is conceivable for the carrier unit to have multiple connection elements, in particular with corresponding cross sections, which are advantageously arranged one above the other, and which together form the hub.
The beam element is advantageously implemented at least predominantly, in particular entirely, from a metal, for example from steel and/or from high-grade steel, and/or from the same material as the carrier unit. In particular, the beam element is of elongate form. The beam element is preferably of straight form. The beam element is particularly advantageously of rod-like form. In particular, the beam element, in particular a longitudinal direction of the beam element, extends, proceeding from a central point of the connection element, in particular in a straight manner in a radial direction of the agitator device. The beam element preferably runs in a plane, in particular in a plane perpendicular to the axis of rotation. In particular, the beam element has a longitudinal extent which corresponds to at least 5%, advantageously at least 10%, particularly advantageously at least 20% and preferably at least 30% of a maximum extent, in particular of a diameter, of the agitator device. It is also conceivable for the beam element to be of bent form, wherein the beam element may be realized so as to be curved within the plane and/or out of the plane. The beam element advantageously has at least one connection region for the agitator blade, wherein the connection region is particularly advantageously provided for welding to and/or screwing to and/or riveting to, and/or for a connection in a one-part implementation and/or for some other connection, to the agitator blade. The beam element preferably forms a strut to which an agitator blade is attachable or attached. In particular, the strut corresponds to the beam element. It is also conceivable for the carrier unit to have a multiplicity of beam elements which are advantageously arranged one above the other, in particular with corresponding cross sections, which beam elements together form a strut. Here, the carrier unit may have a multiplicity of struts which are in particular each implemented by multiple beam elements, which are preferably arranged one above the other. “Configured” is in particular to mean specifically designed and/or equipped. A statement that an object is configured for a particular function is to be understood in particular to mean that the object performs and/or carries out this particular function in at least one usage and/or operating state.
“In a one-part implementation” is in particular to mean formed in one piece. Said one piece is preferably produced from a single workpiece and/or from a single blank and/or one mass and/or one casting, or in an injection molding process, in particular in a single-component and/or multi-component injection molding process. It is for example conceivable for the carrier unit to be implemented such that it can be manufactured as a single forged part. It is also conceivable for the carrier unit to be formed as a cast part.
An “at least substantially quadrilateral/rectangular cross section” of an object is to be understood here in particular to mean that, for at least 60%, advantageously for at least 70%, particularly advantageously for at least 80% preferably for at least 90% of all cross sections of the object along at least one direction, an area of a differential area of the cross section and of a smallest, advantageously non-crossed quadrilateral/rectangle which surrounds the cross section amounts to at most 30%, advantageously at most 20%, particularly advantageously at most 10%, preferably at most 5% and particularly advantageously at most 3% of the area of the quadrilateral/rectangle.
The portion is preferably of cuboidal form. The portion particularly preferably comprises at least a predominant part of the beam element and in particular the entire beam element. The beam element is advantageously rectangular. Here, “rectangular” is basically also intended to encompass geometrical shapes which correspond to rectangles with rounded and/or beveled corners. The beam element is particularly advantageously of cuboidal form, wherein, in particular, rounded and/or beveled edges are likewise conceivable. By means of a rounding or a corresponding bevel, it is possible in particular for a notch effect to be reduced.
The beam element may also have a cross section which differs from a rectangle. In particular, the cross section may be a quadrilateral which differs from a rectangle, such as for example a parallelogram with internal angles that differ from 90°, or a trapezoid or any desired, advantageously non-crossed quadrilateral.
In one advantageous embodiment of the invention, it is proposed that the beam element and the connection element have an at least substantially identical material thickness in a common connection region, in particular in a view perpendicular to the axis of rotation. In particular, in the connection region, material thickness of the beam element corresponds to the material thickness of the connection element. The beam element and the connection element advantageously have an at least substantially identical extent along the axis of rotation in the connection region. The connection element advantageously transitions seamlessly into the beam element. The connection element particularly advantageously has an at least substantially constant material thickness, in particular in a view perpendicular to the axis of rotation. The material thickness of the connection element roughly corresponds to the material thickness of that portion of the beam element which has an at least substantially quadrilateral cross section. In this context, “at least substantially” to be understood in particular to mean that a deviation from a predefined value corresponds in particular to less than 15%, preferably less than 10% and particularly preferably less than 5% of the predefined value. In this way, a geometry can be provided which is easy to manufacture. Furthermore, in this way, it is possible to realize a high load capacity, in particular of a connection between a hub and a strut.
In a particular advantageous embodiment of the invention, it is proposed that the connection element and the beam element are produced from a common plate-like workpiece, in particular from a sheet or a plate, advantageously a metal sheet or a metal plate. The plate-like workpiece has in particular the same material as the carrier unit, and may for example be implemented at least partially, in particular entirely, of a plastic or a composite material. It is advantageous for the entire carrier unit to be produced from the plate-like workpiece. The beam element and the connection element, advantageously the entire carrier unit or at least the corresponding blank, are advantageously realized as a common flat part, for example as a cut flat part or as a punched flat part. In this way, it is advantageously possible to realize inexpensive producibility. Furthermore, in this way, high flexibility can be achieved with regard to usable production methods and/or usable materials.
In a further refinement of the invention, it is proposed that the connection element forms at least one connection flange which is configured for an in particular detachable connection to a shaft flange, in particular a shaft flange of the drive shaft. The connection flange is advantageously configured for being screwed to a shaft flange. The connection element advantageously has an in particular cylindrical recess which advantageously surrounds the connection flange. It is particularly advantageous if, in an installed state, the axis of rotation runs through the recess. In this way, it is possible to realize advantageous characteristics with regard to an installation capability and/or easy maintenance and/or the possibility of flexible conversion.
It is conceivable for a connection between the connection element and the drive shaft to comprise at least one force screw and/or at least one parallel key connection. It is also conceivable for the connection element to be configured for being connected by means of a clamping connection to the drive shaft. Alternatively or in addition, it is conceivable for the connection element to be adhesively bonded to the drive shaft. Further connection variants that would appear suitable to a person skilled in the art are self-evidently also conceivable.
In a preferred embodiment of the invention, it is proposed that the beam element has, in at least one direction, a tapering cross section. In particular, the cross section of the beam element tapers in an advantageously radially running direction away from the connection element. The beam element advantageously has at least one first portion with a constant, in particular at least substantially rectangular, cross section, which particularly advantageously adjoins the connection element. The beam element particularly advantageously has at least one second portion with in particular at least substantially rectangular, tapering cross section. It is conceivable for the first portion and the second portion to join one another. The beam element preferably has at least one third portion with in particular at the substantially rectangular, constant cross section, which is smaller than a cross section of the first portion. It is conceivable for the second portion and the third portion to join one another. In this way, it is advantageously possible for a geometry to be adapted to a load. In particular, in this way, it is possible to provide a geometry which can be flexibly adapted to a corresponding demand.
It is furthermore proposed that the beam element is realized so as to be twisted at least section-wise, for example by an angle of at least 5° or of at least 10° or of at least 15° or of at least 20° or of at least 30° or of at least 45° or of at least 60° or of at least 75 or by a greater angle. In particular, the beam element has an inherent twist at least section-wise. The beam element advantageously has at least one first portion which is oriented in a straight manner with respect to the connection element. The beam element particularly advantageously has at least one second portion which is arranged so as to be tilted with respect to the second connection element. It is preferable for the second, tilted portion to be configured for the fastening of the agitator blade, such that said agitator blade is advantageously inclined relative to an agitating direction during an agitation process. A further beam element, arranged opposite the beam element, of the carrier unit is particularly preferably realized so as to be twisted in an opposite direction, in particular the same angle. The strut is preferably implemented such that it can be produced by cutting out/punching out of the plate-like workpiece and subsequent testing. In this way, it is advantageously possible for an angle of inclination of an agitator blade to be adapted in a simple and/or inexpensive and/or variable manner.
It is furthermore proposed that the agitator device comprises at least one agitator blade which is connected to the beam element. The carrier unit particularly preferably comprises at least one second beam element which is in particular arranged opposite the beam element. The agitator device advantageously comprises at least one further agitator blade, which is fastened to the second beam element. The agitator device preferably comprises, at least one, advantageously exactly one, agitator blade per beam element, which agitator blade is fastened to the corresponding beam element. It is particularly preferable for the carrier unit to comprise exactly two beam elements and for the agitator device to comprise exactly two agitator blades, which are advantageously fastened in each case to one of the beam elements. It is conceivable for the agitator device to have a multiplicity of carrier units, which are in particular arranged one above the other. Agitator device with a total number of N agitator blades may in this case advantageously comprise a number of N/2 carrier units with in each case two agitator blades, which are particularly advantageously arranged at uniform angles with respect to one another, for example at angles of 720°/N, wherein the agitator blades are in particular in this case arranged preferably at regular intervals in a circle in a view parallel to the axis of rotation. In particular in the case of a stack of multiple carrier units, lower carrier units are realized such that, in a central region, in particular in a region of their respective connection element, they are fastened and/or fastenable to a carrier unit arranged respectively thereabove, and/or to the drive shaft. It is however also conceivable for the carrier unit to comprise three or four or five or six or more beam elements, and advantageously a corresponding number of agitator blades. In this way, it is possible to provide a geometry which is easy to manufacture. Furthermore, in this way, characteristics relating to an agitation process can be adapted to the requirements.
In one advantageous embodiment of the invention, it is proposed that the agitator blade is connected to the beam element along a longitudinal side of said beam element. In particular, the agitator blade is connected along its front longitudinal side to the beam element. The agitator element may be welded and/or screwed and/or adhesively bonded and/or connected in some other way to the beam element. The agitator blade preferably has at least one in particular L-shaped outer contour, in the region of which said agitator blade is connected to the beam element. Here, it is in particular conceivable for the outer contour to be of L-like form, wherein limbs of the imaginary “L” includes an angle which differs from 90°, for example an in particular considerably smaller angle, such as for example 75° or 60° or 45°, or an in particular considerably greater angle, such as for example 105° or 120° or 150°. It is particularly advantageous that a relatively long portion of the outer contour runs at least substantially parallel to a main direction of extent of the beam element. In particular, the relatively long portion of the outer contour bears, preferably over its entire length, against the longitudinal side of the beam element. Here, “at least substantially parallel” is to be understood in particular to mean an orientation of a direction relative to a reference direction, in particular in a plane, wherein the direction has a deviation of in particular less than 8°, advantageously less than 5° and particularly advantageously less than 2° relative to the reference direction. A “main direction of extent” of an object is to be understood here in particular to mean a direction which runs parallel to a longest edge of a smallest imaginary cuboid which just completely encloses the object. In this way, it is advantageously possible to achieve a high load-bearing capacity of an agitator blade connection.
In a particularly advantageous embodiment of the invention, it is proposed that a leading edge of the agitator blade terminates flush, at least section-wise, with at least one edge of the beam element. The leading edge preferably extends from a front side of the beam element in a direction facing away from the connection element and in particular parallel to a main direction extent of the beam element. The leading edge of the agitator blade particularly preferably forms an elongation of the edge of the beam element. The leading edge is advantageously configured for being arranged at the front in an agitating direction during an agitation process. In this way, expedient agitation characteristics can advantageously be achieved.
In a preferred embodiment of the invention, it is proposed that the agitator blade and the beam element are connected to one another on a front side of the beam element. In particular, the agitator blade bears with a relatively short portion of the in particular L-shaped outer contour, preferably over its entire length, against the front side of the beam element. The agitator blade is preferably connected along the outer contour to the beam element. The agitator blade is particularly preferably welded along its outer contour to the beam element, in particular along the entire length of the outer contour. In this way, it is advantageously possible to achieve a high bending stiffness of an agitator blade connection.
Alternatively or in addition, it is proposed that the beam element and the agitator blade are connected to one another in a one-part implementation. In particular, the beam element and the agitator blade are manufactured from a common, preferably plate-like workpiece, wherein the agitator blade is advantageously realized so as to be bent out of a plane relative to the beam element. The material thickness of the agitator blade advantageously corresponds at least substantially to the material thickness of the beam element. It is conceivable for the carrier element to have, above and/or below the beam element, advantageously plate-like and/or flat reinforcement elements, which are in particular arranged parallel to a main direction of extent of the beam element and/or are connected to said beam element. It is furthermore conceivable for the entire agitator device to be manufactured from a single plate-like workpiece, from which in particular the connection element, the beam element and the agitator blade, or all of the beam elements and all of the agitator blades, of the agitator device are cut out or punched out. In this way, it is advantageously possible to realize simple and/or fast and/or cost-efficient producibility.
It is furthermore proposed that at least a part of the carrier unit, in particular the entire carrier unit, is implemented by a layered structure with at least two sheets. For example, multiple sheets may be arranged so as to lie one on top of the other and in particular so as to be connected to one another, and may in particular form the entire carrier unit. For example, the carrier unit may comprise a central sheet which forms the beam element and the connection element. Furthermore, the carrier unit may comprise at least one reinforcement sheet which reinforces the central sheet, preferably in a region of the connection element and/or in a region of the beam element, and which in particular lies flat on the central region and/or is arranged above and/or below said central region. Multiple central sheets and/or multiple reinforcement sheets are basically also conceivable. For example, it is conceivable for the carrier unit to be constructed in the manner of a plywood panel from a multiplicity of sheets arranged in parallel. Here, edges that form may be rounded or beveled. Furthermore, oblique surfaces may be implemented by multiple sheets, in particular with beveled edges, arranged obliquely one above the other. In this way, it is advantageously possible to achieve high flexibility with regard to a design. Furthermore, in this way, it is possible to use simple and/or inexpensive production methods for producing an agitator device.
Advantageous characteristics with regard to a design and in particular inexpensive producibility can be achieved with an agitator appliance having at least one agitator device according to the invention.
Furthermore, the invention proceeds from a method for producing an agitator device, having at least one carrier unit which is at least one connection element for a connection to a drive shaft and at least one beam element for the fastening of at least one agitator blade.
It is proposed that the connection element and the beam element are produced from a common plate-like workpiece.
By means of a method according to the invention, it is possible to achieve advantageous characteristics with regard to production which is expedient from a manufacturing aspect. Furthermore, an agitator device which is inexpensive and/or easy to manufacture can be provided. Furthermore, an agitator device can be provided which can be cut out of a sheet, wherein, in particular, the number of required welding processes can be reduced and/or strength can be increased. In particular, a hub and struts of an agitator device can be manufactured from a common workpiece, wherein the agitator device is advantageously of seamless form. Furthermore, high flexibility can be achieved with regard to a connection of an agitator blade. In particular, an agitator blade can be easily attached to a carrier strut. It is advantageously possible to at least almost completely dispense with milling machining during a production process. Furthermore, a strut can be provided which has an advantageous geometry, in particular with regard to simple production and/or a flexible and/or simple connection of an agitator blade.
It is preferable for the entire carrier unit to be produced from the plate-like workpiece. It is particularly preferable for a carrier unit blank to be cut out or punched out of the plate-like workpiece and advantageously subsequently machined, for example by virtue of edges being beveled and/or rounded. Furthermore, for example, the recess in the region of the connection flange of the connection element is cut out or punched out. Cutting-out is advantageously performed by flame cutting, whereby in particular a need for edge machining and/or a need for milling machining is at least partially and advantageously completely eliminated. Any agitator blades of the agitator device are advantageously subsequently welded to the corresponding beam elements. It is also conceivable for at least one central sheet to be cut out or punched out, which central sheet forms a blank for the connection element, the beam element and the agitator blade and in particular for the entire carrier unit and all agitator blades. The central sheet is advantageously bent in certain regions in order to form the agitator blades. It is conceivable for reinforcement sheets to subsequently be cut out and/or punched out and connected to the central sheet and/or to one another.
In particular, the method according to the invention may comprise special method steps in which in each case at least one of the above-described features of the agitator device according to the invention and/or of the agitator appliance according to the invention is generated and/or added and/or implemented, in particular by means of a suitable manufacturing method.
Here, the agitator device according to the invention and the method according to the invention are not intended to be restricted to the uses and embodiments described above. In particular, the agitator device according to the invention and the method according to the invention may, in order to perform a function described herein, have a number of individual elements and/or components and/or units and/or method steps which differs from a number stated herein.
Furthermore, in the case of the value ranges stated in this disclosure, it is also intended that values lying within the stated limits are disclosed and usable as desired.
Further advantages will emerge from the following description of the drawings. The drawings illustrate five exemplary embodiments of the invention. The drawings, the description and the claims contain numerous features in combination. A person skilled in the art will expediently also consider the features individually and combine these to form further meaningful combinations.
In the drawings:
Furthermore, the carrier unit 12a comprises a beam element 18a for the fastening of at least one agitator blade 20a. The beam element 18a forms a strut for the agitator blade 20a. The beam element 18a and the connection element 14a are connected to one another in a one-part implementation. In the present case, the carrier unit 12a is formed as a single piece. Furthermore, the carrier unit 12a is implemented from high-grade steel. Other materials and/or material combinations are however also conceivable.
The beam element 18a has a portion 22a with an at least substantially quadrilateral cross section. In the present case, the portion 22a has a rectangular cross section. Furthermore, in the present case, the entire beam element 18a has a substantially quadrilateral, in particular rectangular, cross section. The edges of the beam element 18a are beveled at least section-wise.
In the present case, the carrier unit 12a comprises a further beam element 50a. The further beam element 50a is of point-symmetrical design relative to the beam element 18a about the central point 48a of the agitator device 10a. The first agitator device 10a has the agitator blade 20a. The agitator blade 20a. is fastened. to the beam element 18a. Furthermore, in the present case, the first agitator device 10a has a further agitator blade 52a. The further agitator blade 52a is fastened to the further beam element 50a. The further agitator blade 52a is of point-symmetrical design relative to the agitator blade 20a about the central point 48a of the first agitator device 10a. The beam element 18a, the further beam element 50a and the connection element 14a together form the carrier unit 12a. The carrier unit 12a, the agitator blade 20a and the further agitator blade 52a together form the agitator device 10a.
In the present case, the first agitator device 10a has a longitudinal extent of approximately 4 m. The longitudinal extent corresponds to a diameter of the agitator device 10a. Other dimensions of an agitator device are however also conceivable, in particular different ratios of a length, a width and a height. For example, a longitudinal extent of an agitator device may amount to 0.1 m or 0.5 m or 1 m or 2 m or 3 m or 5 m or 6 m or even more. Furthermore, in the present case, the beam element 18a has a longitudinal extent of approximately 1 m. Other longitudinal extents of a beam element are however also conceivable, in particular in a similar length ratio relative to the longitudinal extent of the agitator device 10a as in the present case, or else in some other length ratio.
The connection element 14a and the beam element 18a are produced from a common plate-like workpiece. In the present case, the common workpiece is a high-grade steel plate. Other suitable materials are self-evidently also conceivable. A thickness of the workpiece furthermore amounts in the present case to approximately 7 cm. Other thicknesses are however also conceivable, such as for example 0.1 cm or 1 cm or 2 cm or 4 cm or 6 cm or 8 cm or 10 cm or 15 cm or more or less or any thicknesses lying between the stated values. In the present case, the further beam element 50a is additionally produced from the common plate-like workpiece. The carrier unit 12a is produced from the common plate-like workpiece, in particular by being cut out or punched out.
The beam element 18a and the connection element 14a have an at least substantially identical material thickness and a common connection region 24a. In the present case, the material thickness amounts to approximately 7 cm. The material thickness corresponds at least substantially to a thickness of the common plate-like workpiece. The connection element 14a transitions into the beam element 18a in the connection region 24a. Furthermore, the connection element 14a and the beam element 18a have an at least substantially identical width in the connection region 24a. Furthermore, the connection element 14a and the beam element 18a have an at least substantially identical cross section in the connecting region 24a.
The connection element 14a forms an connection flange 26a, which is configured for a connection to the shaft flange 28a. In an installed state, the connection flange 26a is screwed to the shaft flange 28a.
The beam element 18a has, in at least one direction 54a, a tapering cross section. In the present case, the direction 54a corresponds to a radial direction with respect to the axis of rotation 46a. Furthermore, the beam element 18a has, in the present case, a first portion 56a with a constant rectangular cross section and, joining this, a second portion 58a with a tapering rectangular cross section.
The agitator blade 20a is connected to the beam element 18a along a longitudinal side 30a of said beam element. The agitator blade 20a is welded to the beam element 18a. Other connection types are however also conceivable, as described above. The agitator blade 20a has an L-shaped outer contour 60a, which is connected to the beam element 18a. The L-shaped outer contour 60a is adapted to an outer contour of the beam element 18a. A long limb portion of the outer contour 60a lies against the longitudinal side 30a of the beam element 18a.
The agitator blade 20a and the beam element 18a are connected to one another on a front side 36a of the beam element 18a. In the present case, the agitator blade 20a is welded to the front side 36a of the beam element 18a. A short limb portion of the outer contour 60a of the agitator blade 20a lies against the front side 36a of the beam element 18a. Alternatively or in addition, it is conceivable for a beam element to form, in particular on a front side, a slit into which at least a part of the agitator blade is inserted. The agitator blade may then be clamped and/or welded to the beam element.
A leading edge 32a of the agitator blade 20a terminates flush, at least section-wise, with an edge 34a of the beam element 18a. The edge 34a is a leading edge of the beam element 18a. In the present case, the leading edge 32a of the agitator blade 20a forms an elongation of the edge 34a of the beam element 18a.
The beam element 18b has a portion 22b with an at least substantially quadrilateral cross section. In the present case, the portion 22b has a rectangular cross section. Furthermore, in the present case, the entire beam element 18b has a substantially quadrilateral, in particular rectangular, cross section. The edges of the beam element 18b are beveled at least section-wise.
In the present case, the agitator blade 20b has a rubber coating. The agitator blade 20b is basically designed, and fastened to the beam element 18b, analogously to the agitator blade 20a from the exemplary embodiment of
The beam element 18c has a portion 22c with an at least substantially quadrilateral cross section. In the present case, the portion 22c has a rectangular cross section. Furthermore, in the present case, the entire beam element 18c has a substantially quadrilateral, in particular rectangular, cross section. The edges of the beam element 18c are beveled at least section-wise.
In the present case, the beam element 18c is of cuboidal form. A cross section of the beam element 18c is constant. The cross section of the beam element 18c is invariant along a longitudinal direction 64c of the beam element 18c. The longitudinal direction 64c of the beam element 18c corresponds to a radial direction. Such an embodiment is particularly easy to produce. In particular, the carrier unit 12c may be cut out or punched out of a plate-like workpiece, advantageously without the need to form bevels at certain locations.
The beam element 18d has a portion 22d with an at least substantially quadrilateral cross section. In the present case, the portion 22d has a rectangular cross section. Furthermore, in the present case, the entire beam element 18d has a substantially quadrilateral, in particular rectangular, cross section. The edges of the beam element 18d are beveled at least section-wise.
At least a portion of the carrier unit 12d is realized by a layered structure 38d with at least two sheets 40d, 42d, 43d. In the present case, the entire carrier unit 12d is realized by the layered structure 38d. Furthermore, in the present case, the layered structure 38d comprises a first sheet 40d, a second sheet 42d and a third sheet 43d. The sheets 40d, 42d, 43d are implemented from high-grade steel. The second sheet 42d is in the present case realized as a central sheet. The second sheet 42b has the connection element 14d and the beam element 18d.
The first sheet 40d is realized as an upper reinforcement sheet. The third sheet 43d is realized as a lower reinforcement sheet. The first sheet 40d and the third sheet 43d each have further beam elements 66d, 68d and further connection elements 70d, 72d. The beam elements 18b, 66d, 68d together form a strut 74d of the carrier unit 12d. The connection elements 14d, 70d, 72d together form a shaft connection unit 76d of the carrier unit 12d for a connection to the drive shaft. The carrier unit 12d is constructed in the manner of a plywood panel from the sheets 40d, 42d, 43d.
The beam element 18d and the agitator blade 20d are connected to one another in a one-part implementation. The agitator blade 20d is part of the second sheet 42d. During production of the fourth agitator device 10d, the first sheet 40d, the second sheet 42d and the third sheet 43d are cut out or punched out from a starting sheet. Corners may be rounded or beveled if required. The sheets 40d, 42d, 43d are subsequently arranged one above the other and adhesively bonded and/or welded and/or screwed and/or riveted to one another. The second sheet 42d is deformed in targeted fashion in order to form the agitator blade 20d. The agitator blade 20d is curved out of a plane of the beam element 18d and of the connection element 14d.
The beam element 18e has a portion 22e with an at least substantially quadrilateral cross section. In the present case, the portion 22e has a rectangular cross section.
The beam element 18e is of twisted form at least section-wise. In the present case, the beam element 18e is of twisted form in a connection region 78e to the connection element 14e. The connection region 78e corresponds to a torsion region. A straight region 80e of the beam element 18e adjoins the connection region 78e. The straight region 80e of the beam element 18e is tested through approximately 20° relative to the connection element 14e. As indicated above, other angles are however also conceivable. An attached agitator blade is inclined during an agitation process owing to the torsion region of the carrier unit 12e. The inclination of an agitator blade can be performed easily through adaptation of the angle of twist. The carrier unit 12e may for example be produced by cutting or punching of a blank out of a plate-like workpiece and subsequent targeted twisting of parts of the blank.
10 Agitator device
12 Carrier unit
14 Connection element
16 Drive shaft
18 Beam element
20 Agitator blade
22 Portion
24 Connection region
26 Connection flange
28 Shaft flange
30 Longitudinal side
32 Leading edge
34 Edge
36 Front side
38 Layered structure
40 Sheet
42 Sheet
43 Sheet
44 Agitator appliance
46 Axis of rotation
48 Central point
50 Beam element
52 Agitator blade
54 Direction
56 Portion
58 Portion
60 Outer contour
62 Rubber coating
64 Longitudinal direction
66 Beam element
68 Beam element
70 Connection element
72 Connection element
74 Beam
76 Shaft connection unit
78 Connection region
80 Region
82 Method step
84 Method step
86 Method step
Number | Date | Country | Kind |
---|---|---|---|
10 2016 115 046.0 | Aug 2016 | DE | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2017/070404 | 8/11/2017 | WO | 00 |