This invention is directed to vertical shaft impact (VSI) crushers and in particular to components of the drive assembly of a VSI crusher that are locked in rotational alignment for providing a secure and robust connection between the rotating drive shaft and the impeller of the crusher.
VSI-type crushers operate as high-speed “rock pumps.” The receipt, acceleration and discharge of rock feed introduced to this type of rock crusher passes through a rotating impeller. Broadly speaking, impellers are referred to in the art as either “open” or “enclosed.” Enclosed impellers include a floor, a perimeter wall, and a disk-like ceiling, and are frequently described as a rock-lined rotor. An open impeller, commonly referred to as a shoe table, does not have a ceiling but has a number of anvils on the floor of the device for impacting and pulverizing materials introduced into the device. The nature of the drive system connecting the drive shaft to the impeller is equally applicable to both open and closed impellers.
The impeller is supported in the machine by a drive shaft 12 which is held by and turns in a bearing cartridge assembly 14, as shown in
A popular method of affixing the impeller 44 to the shaft 12 is by the use of a taper lock type of arrangement in which a tapered outer surface 16 of a taper lock 18 and a cooperating tapered inner surface 20 of an impeller boss 22 are drawn together using a top plate 24 and several bolts 26, 28. See
A conventional key system acts as a backup to minimize or eliminate any rotational slipping between the parts, ensuring that all the components rotate as one. The taper lock 18 is keyed to the shaft 12 using a longitudinal keyway 32 in the shaft 12 into which is fitted a key 34. There is a mating keyway 36 in the bore 38 of the taper lock 18 which matches and slides over key 34. This forms a positive mechanical connection between the shaft 12 and the impeller 44. See
While the conventional taper lock-and-keyway design is effective and generally reliable, it is not ideal for application in a VSI-type crusher where extensive vibrational forces and unpredictable shock loadings routinely occur. Due to manufacturing tolerances and variances, weaknesses can develop that undermine the system. Minute differences between the exterior surface of the shaft and the interior surface of the taper lock lead to “fretting,” the microscopic movement of material under high pressure. Poorly machined surfaces can lead to “notches” in the shaft, along the shaft keyway, or in the taper lock bore. As the shaft is typically a hardened steel alloy, it is vulnerable to the phenomena of “notch sensitivity.” This works similarly to the etching of glass wherein a small imperfection in the material may become the focal point for cracking and part failure. Extended use can result in pitting and poor surface conditions. Finally, experience has shown that a high proportion of shaft failures occur in that portion of the shaft adjacent the bottom of the taper lock where a bending moment is formed by the collective weight of the taper lock 18, impeller boss 22, and impeller 44 resting on the shaft 12. In concert, these irregularities can cause unique loading conditions and stress concentrations which may result in shaft failure.
In the normal operation of a VSI-type crusher, the impeller is routinely removed and re-installed for purposes of maintenance. In some instances, multiple impellers may be applied to the same shaft and taper lock. All of this removal and re-installation distresses the parts of the taper lock assembly, especially the main shaft, with the result that, as the VSI crusher ages, the main shaft becomes more vulnerable.
A need therefore exists for a robust joint between the drive shaft and the impeller that reduces failures due to notch sensitivity, reduces the propensity for shaft failure at the bottom of the taper joint, and that speeds and facilitates removal and reinstallation of the impeller for maintenance purposes.
A rotationally locked drive assembly for a VSI crusher provides an assembly that effectively transfers torque from the drive shaft to the impeller, protects the main shaft from the types of distress discussed above that can lead to premature failure, and is fast and simple to disassemble and reassemble for maintenance purposes.
The impeller boss 22 and taper lock 18 of a conventional drive assembly are replaced with a flywheel having a tapered center opening. A tapered upper end portion of the shaft is removably received in the correspondingly tapered center opening of the flywheel to form a robust taper joint between the drive shaft and the flywheel. A locking key having a plurality of extensions radiating from a central body is secured in a key receptor formed on the top surface of the flywheel to hold the drive shaft in rotational alignment with the flywheel. The locking key is held in place by fasteners engaged with the upper end portion of the drive shaft. Tightening of the fasteners (a) attaches the locking key to the upper end portion of the drive shaft, (b) secures the locking key in the key receptor and (c) compresses the flywheel onto the tapered upper end portion of the shaft thus fortifying the taper joint. The assembly eliminates the longitudinal keyway 32 in the shaft 12 present in the conventional key system, thereby removing opportunities for fretting and notching as discussed above. The same type of taper joint used in the conventional system locks the improved drive assembly together as one, but the back up system to ensure against rotational slipping has been changed from the key and keyway in the shaft to the locking key which is secured in the key receptor formed in the top of the flywheel and attached to the upper end portion of the drive shaft. The locking key mates to the drive shaft by fitting a square center opening in its central body over a square pilot key on the top face of the drive shaft. Locking to the flywheel is achieved by four outwardly-radiating extensions of the locking key engaging four cooperating slots formed in the key receptor. The new drive assembly rotationally aligns all components securely, does not interfere with the ability to loosen the assembly's grip on the drive shaft quickly by axial movement of the flywheel such as when using the conventional key design, and simplifies and reduces the number of components in the drive assembly thereby facilitating maintenance and reducing the opportunities for component failures.
A rotationally locked drive assembly for a VSI crusher 50 is now described with reference to
Referring now to
Locking key 56 comprises a plurality of extensions 82 radiating from a central body 84. See
The drive assembly 10 is assembled by positioning flywheel 54 on drive shaft 52 such that the drive shaft 52 is tightly received in the central opening 72 of the flywheel 54 thereby forming a robust taper joint between flywheel 54 and drive shaft 52. Thereupon locking key 56 is set in key receptor 81 with the central body 84 thereof disposed between rampart walls 74 and seated on the annular receiving surface 80 of the flywheel 54, with extensions 82 removably received in and seated on the bottom surfaces 79 of slots 78, and oriented such that the pilot key 66 on the top face 64 of the drive shaft 52 is removably received in the locking key's center opening 86. It should be noted that at this stage of assembly locking key 56 can easily be removed from key receptor 81. Assembly is completed by insertion of fasteners 58 through fastener receiving holes 88 and into threaded apertures 70 in the upper end portion 62 of shaft 52. Tightening of fasteners 58 firmly attaches locking key 56 to the upper end portion 62 of drive shaft 52, secures locking key 56 in key receptor 81, presses flywheel 54 onto drive shaft 52 thereby fortifying the taper joint between the flywheel 54 and drive shaft 52, and locks drive shaft 52, flywheel 54 (and attached impeller) and locking key 56 in rotational alignment, as shown in
In one embodiment of the invention, the rampart walls 74 can be moved inwardly so that their inner faces 98 are not inset from center opening 72. This eliminates annular receiving surface 80 so that when locking key 56 is seated in key receptor 81, only extensions 82 are resting on the bottom surfaces 79 of slots 78.
In another embodiment of the invention, the pilot key 66 on the top face 64 of the drive shaft 62 and the center opening 86 of the locking key 56 are eliminated.
There have thus been described certain preferred embodiments of a rotationally locked drive assembly for a VSI crusher. While preferred embodiments have been described and disclosed in some detail, it will be recognized by those with skill in the art that modifications are within the true spirit and scope of the invention. The appended claims are intended to cover all such modifications.
This application is a continuation-in-part of application Ser. No. 11/823,532, filed Jun. 27, 2007.
Number | Name | Date | Kind |
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1472565 | Manning | Oct 1923 | A |
3920089 | Mitchell | Nov 1975 | A |
3993147 | Mitchell | Nov 1976 | A |
6786671 | Eckendorff | Sep 2004 | B1 |
7267502 | Sawai | Sep 2007 | B2 |
Number | Date | Country | |
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20100266335 A1 | Oct 2010 | US |
Number | Date | Country | |
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Parent | 11823532 | Jun 2007 | US |
Child | 12825966 | US |