CZ201862A3 - Cuff attachment system for a rotary bulk material feeder rotor blade - Google Patents

Abstract

The base of the fastening system is a bar (6) to which a collar (3) is attached outside the stator (1) of the rotary feeder to seal the blade (4) of the rotor (2) with respect to the stator (1). The assembled assembly of the bar (6) and the sleeve (3) is inserted into a groove (5) made in the blade (4). This assembly is then fastened to the blade (4) by means of pressure screws (7). The sleeve (3) may be made of a rigid belt (31), in particular of steel, or of a flexible belt (32), in particular of a rubber-textile fabric, ducked on the outside with a rigid ruler (38).

Description

Technical field

BACKGROUND OF THE INVENTION The present invention relates to a system for attaching a collar to a rotor blade of a rotary bulk material feeder, the collar comprising one element selected from the group consisting of a rigid strip of abrasion-resistant material and a resilient strip of nonabrasive material.

BACKGROUND OF THE INVENTION

The sleeves of the rotary feeders suffer considerable wear, particularly when conveying abrasive materials. This necessitates frequent replacement. For this purpose, mounting holes are provided in the stator faces of the rotary feeder, which are covered during operation and whose dimensions are so large that the hand with the tools can be inserted into them and the cuff released and subsequently removed. Reverse the procedure to fit a new cuff.

Known systems for securing the cuff to the blade are known based on the cuff being bolted by means of pressure screws. The assembly procedure consists in inserting a new sleeve into the inner space of the rotary feeder through one of the mounting holes, and then the thrust screws are threaded through its mounting holes, which are screwed into the anchor holes made in the blade.

This work is inconvenient because it is done in a confined space. The disadvantage of this known fastening system is that the exact alignment of the cuff with respect to the stator is inaccurate and depends on the feel and manual skill of the installer. The inaccuracy is due to the fact that the collar is guided only by the clamping screws during its alignment, between which the necessary clearance must be left between the collar alignment holes.

In an improved version of this fastening system, the cuff is centered by means of pins and subsequently secured by pressure screws. In this version, the alignment accuracy of the cuff will increase, but the inconvenience of replacing work remains.

SUMMARY OF THE INVENTION

These disadvantages are substantially reduced by the system of fastening the cuff to the rotor blade of the rotary bulk material feeder of the invention. The cuff comprises one element of the group comprising both a rigid strip of abrasion-resistant material and a flexible strip of non-abrasive material to which a rigid ruler is pressed in the direction of the blade. The cuff fastened to the blade has a sealing edge provided above the back of the blade. SUMMARY OF THE INVENTION The invention is based on the fact that a groove of concave cross-section is formed in the wall of the blade below the back of the blade, which is parallel to the rotor axis. A slide is inserted into the groove. The shape of the molding on the front is essentially identical to the shape of the groove. The back of the bar is provided with a contact surface on which the contact surface of the sleeve is supported. On the sides of the groove, at least two anchor holes are provided in the vane adapted to fasten the thrust screws. Through-holes are provided in the bar, which are fully concentric with the anchor holes when the bar is fully inserted into the groove. Through the collar are formed through alignment holes with the same spacing as the anchor and through holes. On the side opposite to the contact surface, the locating holes are provided with a conical recess with the same conicity as the conical heads of the thrust screws. When the sleeve bar is inserted into the groove and the pressure screws are tightened, the sleeve and the blade are rigid.

- 1 GB 2018 - 62 A3

An advantage of said arrangement is that the sleeve can be conveniently slid into the blade via a groove and then screwed to the blade. Another advantage is the accuracy of the seating of the sleeve in the blade, and thus the precise positioning of the sleeve relative to the stator.

In a preferred embodiment, the groove is in the form of a dovetail comprising an inclined lower surface in the radial direction from the rotor axis up to the blade spine, facing downwardly from the blade wall. The lower normal surface is connected to the inclined bottom surface at least to the level below the anchor holes. Above the anchoring holes, an inclined upper surface is formed with a slope opposite to that of the inclined lower surface. An oblique upper surface is connected at an acute angle to the upper normal surface, which is parallel to the lower normal surface.

In the groove so formed, the load from the cuff to the blade is transmitted by the groove, so that only two pressure screws are sufficient to secure the cuff to the blade, one at each end of the cuff. This makes assembly of the sleeve much easier.

To simplify the production of the groove blade, a modification in which the lower normal surface of the groove coincides with the upper normal surface contributes.

Depending on the properties of the bulk material, forces are transferred from the cuff to the blade, which in some cases could result in deformation when fastened with only two pressure screws. In order to increase the stiffness of the sleeve, threaded holes for fixing screws are provided in the bar. In the sleeve, mounting holes are provided for these fastening screws provided with a conical recess with the same conicity as the conical tapered heads of the fastening screws. The length of the fastening screws is less than the sum of the thickness of the cuff and the bar. In addition to participating in the transmission of force from the cuff to the blade, this has the advantage that the sleeve and the bar can be conveniently formed outside the interior of the rotary feeder to form a single piece which is attached to the blade as described above.

If the sleeve is formed by a rigid belt, an adjustment may be used to position it precisely with respect to the bar, in which the sleeve is provided with a nose in the radial direction from the rotor axis, the bearing surface of which bears against the rotor axis.

In order to press the sleeve against the bar and the bar to the respective groove surfaces, the distance of the tapered recess axis from the bearing surface is less than the distance of the through hole axis from the tangent surface by a first eccentricity of 5-15% of the pressure screw diameter.

A similar effect can be achieved by mounting the rigid belt cuff to the bar, separate from the interior of the rotary feeder. For this purpose, the distance between the axis of the conical recess and the bearing surface is less than the distance of the axis of the threaded hole from the tangent surface, by a second eccentricity of 5 to 15% of the diameter of the fastening screw.

In order to increase the effect of the latter adjustments, the dimensions of the conical recess are identical to the dimensions of the conical recess, as are the conical dimensions of the pressure screw conical heads with the conical tapered heads of the fastening screws. At the same time, the first eccentricity, given by the distance of the axis of the conical recess from the bearing surface, is identical with the second eccentricity, given by the distance of the axis of the conical recess from the bearing surface.

The fastening system according to the invention, both in the basic embodiment and in the framework of the improved modifications, significantly improves the exchange of the sleeves of the rotary feeders of bulk material.

Clarification of drawings

1 is a diagrammatic view of a system for securing a collar to a rotor blade of a rotary feeder according to the invention, wherein FIG. 1 is an axonometric view of a rotary feeder;

Fig. 2 is an enlarged perspective view of a rigid belt and bar cuff; Fig. 3 is the same scale as in Fig. 2 an axonometric view of a flexible belt with a rigid ruler and bar; FIG. 2 is an enlarged scale of FIG. 2, FIG. 5 is an enlarged view of FIG. 2, section BB of FIG. 2, FIG. 6 is an exploded view of the individual components of FIG. Fig. 3 is a sectional view CC of Fig. 3, Fig. 8 on an enlarged scale compared to Fig. 3, a section DD of Fig. 3, Fig. 9 of the individual components of Fig. 8 in an exploded state;

DETAILED DESCRIPTION OF THE INVENTION

The rotary feeder (FIG. 1) consists of a stator 1 in which a rotor 2 provided with a drive mechanism (not shown) is rotatably mounted. The rotor 2 comprises vanes 4 which, when rotated, carry loose material from the inlet opening 11 to the outlet opening 12. The rotor 2 is sealed with respect to the stator 1 by cuffs 3 which are attached to the outer edges of the vanes 4 so that the cuff 3 fastened to the vane 4 a sealing edge 35 provided above the spine 41 of the blade 4. On the faces of the stator 1, insertion holes 14 are provided which serve to replace the collar 3. In operation of the rotary feeder, the insertion holes 14 are covered by the lids 13.

The collar 3 is formed by one element of the group comprising, on the one hand, a rigid strip 31 of abrasion-resistant material and, on the other hand, a flexible strip 32 of non-abrasive material. For abrasive bulk materials, it is suitable to use wear-resistant steel for the manufacture of the rigid belt 31. For softer bulk materials, a flexible web 32, e.g. of rubber-textile, may be used. For reasons of sufficient rigidity, a rigid ruler 38 is pressed against the flexible belt 32 in a manner that will be explained below.

A concave cross-section groove 5 is formed in the wall 42 of the vane 4 below its ridge 41 and is parallel to the axis 21 of the rotor 2. In a preferred embodiment (FIGS. 6, 9), the groove 5 has a dovetail shape. The dovetail comprises a sloping lower surface 51 facing away from the wall 42 of the vane 4 at an incline downwardly from the axis 21 of the rotor 2 upwards to the spine 41 of the vane 4. A lower normal surface 52 is attached to the inclined bottom surface 51 at least to a level below the anchor holes 43. Above the anchor holes 43 a sloping top surface 54 is formed with a slope opposite to the sloping bottom surface 51. The sloping top surface 54 is at an acute angle 6 and 9, the lower normal surface 52 coincides with the upper normal surface 53. In this way, a pocket 55 is formed in the groove 5. In a not shown alternative, the lower normal surface 52 is formed. the normal surface 52 may be bonded to the inclined top surface 54 so that the pocket 55 is not formed.

Within the fastening system, a groove 6 is slidably inserted into the groove 5, the shape of which on the face 61 is substantially identical to that of the groove 5. The rear side of the groove 6 is provided with a contact surface 62 on which the contact surface 34 of the sleeve 3 is supported.

On the sides of the groove 5, at least two anchor holes 43 are formed in the vane 4 adapted to secure the thrust screws 7 (Figs. 5, 8). The fastening of the clamping screws 7 can best be realized in that the anchor holes 43 are threaded. Another possibility of fastening is the use of nuts.

In the bar 6 are provided through holes 63 which, when the bar 6 is fully inserted into the groove 5, are concentric with the anchor holes 43. The cuff 3, whether it is a rigid belt 31 or a flexible belt 32 and a rigid ruler 38, is provided with through constitutional holes 36 with the same layout as the anchor and through holes 43, 63.

On the side opposite to the contact surface 34, the alignment holes 36 are provided with a conical recess 361 with the same conicity as the conical heads 71 of the thrust screws 7 (FIGS. 6, 9).

CZ 2018-62 A3

Thread bar holes 64 for fastening screws 8 are further provided in the bar 6, for which mounting holes 37 are provided in the collar 3 having a tapered recess 371. The tapered recess 371 has the same taper as the tapered heads 81 of the fastening screws 8. Length m of the fastening screws 8 is less than the sum of the thickness h of the sleeve 3 and the bar 6 (FIGS. 4, 7).

The embodiment described so far relates to both the rigid belt collar 3 and the collar 3 comprising the compliant belt 32. In case the collar 3 is formed by the rigid belt 31, in the preferred embodiment shown in Figures 4, 5 and 6, it is in a radial The bearing surface 39 is supported in the direction of the axis 21 of the rotor 2 by a tangential surface 65 formed on the bar 6.

When applying the collar 3 comprising the compliant belt 32, the axis 431 of the anchor hole 43 coincides with the axis 362 of the tapered recess 361 and the axis 631 of the through hole 63 (FIG. 9). When applying the rigid belt sleeve 3, the same embodiment may be used, but it is preferable that (Fig. 6) this identity of the axes is violated such that the distance g of the tapered recess 361 from the abutment surface 39 is less than the distance b axis 631 of the through hole 63 from a tangent surface 65 of a first eccentricity eo of 5 to 15% of the diameter D of the pressure screw 7.

Similarly, the collar 3 is fastened to the strip 6. When using the collar 3 with a flexible belt 32, the axis 641 of the threaded bore 64 is identical to the axis 372 of the tapered recess 371 (FIG. 7). If a rigid belt sleeve 3 is used which is supported by its nose 33 on the tangent surface 65 of the blade 4, it is preferable that the distance n of the axis 372 of the tapered recess 371 from the bearing surface 39 is less than the distance c of the threaded axis 641. hole 64 from the tangent surface 65 by a second eccentricity f0 of 5 to 15% of the diameter d of the fastening screw 8 (FIG. 4).

For the transmission of forces it is suitable if both the dimensions of the conical recess 361 with the conical recess 371 and the conical head 71 of the thrust screws 7 with the conical tapered heads 81 of the fastening screws 8 are identical. In this case the first eccentric e coincides .

When changing the sleeve 3, the lids are first removed from the stator 1 and the blade 4 is rotated to the insertion hole 14. Then the pressure screws 7 are loosened and removed and the sleeve 3 and the bar 6 are slid out of the groove 5. screws 8.

When assembling the new sleeve 3, a rigid assembly is first formed consisting of a bar 6 and either a rigid strip 31 or a flexible strip 32 folded with a rigid ruler 38. To form said rigid assembly, the fastening screws 8 (Figs. 2, 3) are threaded through the assembly. If the sleeve 3 is formed by a rigid belt 31 with a nose 33 and if it has a conical recess 371 offset by a second eccentricity f relative to the axis 641 of the threaded hole 64 (FIG. 4), after tightening of the fastening screws 8, the bearing surface 39 of the nose 33 is pressed against the tangent surface 65 of the bar 6.

If the rigid belt sleeve 3 is not provided with an eccentric displacement of the conical recess 371 of the mounting hole 37, or in the case of the flexible belt sleeve 3 and the rigid ruler 38, the self-adjusting effects are limited to pressing against the bar 6 from tightened fastening screws 8.

After the rigid assembly has been assembled, the sleeve 3 with the bar 6 is inserted through the insertion hole 14 into the groove 5 in the blade 4 of the rotor 2. Through the alignment holes 36 in the sleeve 3 and the through holes 63 in the bar 6, push bolts 7 are screwed into the anchor holes 43 If a conical recess 361 offset by the first eccentricity e is provided in the collar 3 formed by the rigid belt 31, the tightening of the clamping screws 7 already strengthens the connection between the collar 3 and the bar 6 and on the other This configuration is important both for ensuring the exact position of the sleeve 3 and for reliable transmission of forces during operation in both directions of rotation of the rotor 2.

-4GB 2018 - 62 A3

If the sleeve 3 does not have an eccentrically displaced conical recess 361, the force effects are similar to the absence of displacement of the conical recess 371 of the mounting hole 37.

After mounting the cuffs 3, the lids 13 are attached to the stator 1 and the rotary feeder is ready to work.

Industrial applicability

The system of fastening the cuff 3 to the blade 4 of the rotor 2 finds application particularly in rotary feeders of bulk material. After technical adjustments, it could be used with other rotary machines such as planers.

PATENT CLAIMS

Claims (8)

A system for attaching a collar (3) to a blade (4) of a rotor (2) of a rotary bulk material feeder, said collar (3) comprising one element selected from the group consisting of a rigid belt (31) of abrasion-resistant material and a flexible belt (32). ) of a non-abrasive material to which a rigid ruler (38) is pressed in the direction of the blade (4), the collar (3) attached to the blade (4) having a sealing edge (35) provided above the back (41) of the blade (4); characterized in that a groove (5) of concave cross-section, parallel to the axis (21) of the rotor (2), is formed in the wall (42) of the vane (4) beneath the ridge (41) and is slidable into the groove (5) a molding (6) having a shape on the front side (61) substantially identical to the shape of the groove (5) and having a contact surface (62) on the back of which the contact surface (34) of the sleeve (3) is supported, and at least two anchor holes (43) are formed in the vane (4) at the sides of the groove (5) For fastening the clamping screws (7), in the bar (6), through holes (63) which, when the bar (6) is fully inserted into the groove (5) are concentric with the anchor holes (43), and through the collar (3) holes (36) with the same spacing as the anchoring and push-through holes (43, 63), and on the side opposite to the contact surface (34) the alignment holes (36) are provided with a conical recess (361) with the same conicity as conical heads (71) of the thrust screws (7), wherein when the bar (6) with the sleeve (3) is inserted into the groove (5) and the thrust screws (7) are tightened, the sleeve (3) and the blade (4) form a rigid unit. System according to claim 1, characterized in that the groove (5) is in the form of a dovetail comprising a sloping lower surface (51) in the radial direction from the axis (21) of the rotor (2) upwards to the back (41) of the vane (4). from the wall (42) of the vane (4) obliquely downwardly, wherein the lower normal surface (52) is connected to the inclined lower surface (51) at least to a level below the anchor holes (43), and an inclined upper surface is formed above the anchor holes (54) with an inclination opposite to that of the inclined lower surface (51), the inclined upper surface (54) being angled at an acute angle to the upper normal surface (53), which is parallel to the lower normal surface (52). The system of claim 2, wherein the lower normal surface (52) is coincident with the upper normal surface (53). System according to claim 1, characterized in that threaded holes (64) for fastening screws (8) are provided in the bar (6), for which mounting holes (37) provided with a conical recess (371) are provided in the sleeve (3). ) with the same taper as the tapered heads (81) of the fastening screws (8), the length (m) of the fastening screws (8) being less than the sum (h) of the thickness of the sleeve (3) and the bar (6). System according to claim 1, characterized in that in the radial direction from the axis (21) of the rotor (2) the sleeve (3) formed by the rigid belt (31) is provided with a nose (33) whose bearing surface (39) is in the direction to the axis (21) of the rotor (2) supported on a tangent surface (65) formed on the bar (6). -5 EN 2018 - 62 A3 System according to claim 5, characterized in that the distance (g) of the tapered recess axis (362) from the bearing surface (39) is smaller than the distance (b) of the through hole (63) axis from the tangent a first eccentricity (e) of 5 to 15% of the diameter (D) of the pressure screw (7). System according to claims 4 and 5, characterized in that the distance (n) of the axis (372) of the conical recess (371) from the bearing surface (39) is smaller than the distance (c) of the axis (641) of the threaded bore (64). a second eccentricity (f) of 5 to 15% of the diameter (d) of the fastening screw (8). System according to claims 6 and 7, characterized in that the dimensions of the conical recess (361) correspond to the conical recess (371), the dimensions of the conical heads (71) of the thrust screws (7) with the conical tapered heads (81) of the fastening screws (7). 8) and at the same time the first eccentric (e) is identical to the second eccentric (f).