The present invention refers, in a general way, to mechanical vibrators mounted inside closed or semi-closed casings, usually used in pairs and individually installed on the sides of vibrating equipment which utilizes linear, circular or elliptical motions, either for screening, classification, transportation, dosing, feeding or simply vibration.
In a more specific way, the invention refers to a vibrator of the type that includes a bearing housing provided with one or more end flanges for fixing the vibrator to the side of the equipment and supporting, through a pair of bearings, a determined portion of a shaft carrying eccentric counterweights and being connectable to a motor unit, directly or by means of other mechanical vibrator.
One of the known solutions to move the vibrating screens with circular motion includes the provision of a mechanical vibrator V basically comprising, as illustrated in
The assembling illustrated in
In a compact vibrator of the type cited above, the load distribution on two roller bearings 20 instead of one, as it occurs with the known long shaft arrangements, permits to reduce the diameters of the roller bearings 20 and thereby to operate in higher rotation speeds.
However, despite presenting several advantages over the long shaft arrangements, the compact arrangement with short shaft 30) cited above introduced some limitations that did not exist in the classic arrangement of long transversal shaft and which include:
1—The occupation of an undesirable internal space in the screen (or other equipment) resulting from great radii of eccentricity equally utilized for the eccentric counterweights internal and external to the side wall 2 of the equipment 1. This arrangement also conducts to an undesirable increase in the distance between the classifying floors of a screen.
2—The setting of the eccentric mass has to be effected also inside the equipment, since the eccentric counterweights 41 (of adjustment) are located on both sides of the respective side wall 2 of the equipment 1. The difficult access usually conducts to setting errors, unbalancing the loads on the bearings 20 of each bearing housing 10.
3—The setting of the internal eccentric counterweights requires the removal of the protective casing 60 which surrounds them in the interior of the equipment 1 and which is difficult to seal in the reassemblies, facilitating the penetration of dust in the inner ambient of the vibrator V and shortening the lifetime of the bearings 20.
The ideal would be to use prior art compact vibrators, as illustrated in
It should be noticed that, on the balanced situation illustrated in
The removal of a second eccentric counterweight 41 (of adjustment) from one side only, that is, from the external side, creates an unbalanced situation, making a bending moment appear on the side wall 2 of the equipment 1, as well as reaction forces F1 and F2 on the bearings 20, which forces, instead of being equally distributed, as in the case of the compact vibrator V of
Patent BR PI 9005855 (U.S. Pat. No. 5,220,846) proposes a constructive solution, according to which each vibrator has a short shaft mounted in a pair of roller bearings contained in a bearing housing affixed to a respective side wall of the equipment, said short shaft carrying an assembly defined by a first counterweight (main) and an adjusting counterweight on its end external to the equipment and only one first counterweight (fixed) on the end of the short shaft internal to the equipment.
According to this prior proposal, the first counterweight (fixed), internal to the equipment, presents reduced mass and radial dimension and a relatively large axial distance from the center of the bearing housing. On the other hand, the first counterweight (main), external to the equipment, presents larger eccentric mass and radial dimensioning, but a smaller axial distance from the center of the bearing housing.
The eccentric mass, the axial distance from the center of the bearing housing and also the radial dimensioning of the first external counterweight are variable, to guarantee the production of the eccentric force required by the equipment, maintaining the bending moment on the hearing housing equal to that produced by the rotation of the first internal counterweight (fixed). Such variation of the characteristics of the first counterweight is obtained by affixing it in two possible axial distances in relation to the center of the bearing housing and determining different predetermined mounting positions of the adjusting counterweight in the first counterweight. The mass of the adjusting counterweight can also vary in predetermined values.
Despite actually transferring, to the exterior of the equipment, the settings of the eccentric force to be produced by the vibrator, this prior art solution still presents limitations regarding the variation of the axial distance of the eccentric mass of the main counterweight in relation to the center of the bearing housing, allowing only two basic positions for mounting the adjusting counterweight to the first counterweight. Besides, the radial dimensioning variations are also limited as a function of the possible variations in mounting the adjusting counterweight to the first external counterweight.
The present invention has as object to provide a mechanical vibrator for vibrating screens and other equipment, which presents a short and low weight shaft, requiring a pair of bearings of reduced dimensions, to be operated in high rotation speed; which can be mounted on a side wall of the equipment, in a way to present counterweight adjustment only externally to this side wall; and which allows obtaining a balanced distribution of forces on the bearings and absence of bending moment on the side walls of the equipment.
As mentioned before, the invention applies for a mechanical vibrator of the type which comprises: a bearing housing to be affixed to a side wall of the equipment and internally carrying, symmetrically to a center line, a pair of bearings; a shaft supported by the pair of bearings and having an inner end portion and an outer end portion, projecting outwardly from the bearing housing.
According to the present invention, the inner end portion and the outer end portion of the shaft respectively affix a first and a second counterweight having respective first and second eccentric masses of different values and presenting respective first and second radial extensions and first and second distances to the center line of the bearing housing which are dimensioned so that said first and second counterweights generate equal loads on the bearings and equilibrium of moments on the side wall of the equipment, said second counterweight selectively and removably affixing a third counterweight presenting a third eccentric mass, which is maintained aligned with the center line of the bearing housing, so as to provide a respective variation of the total eccentric mass of the vibrator, without changing the balance of the distribution of loads on the bearings.
The new constructive arrangement cited above allows obtaining a compact vibrator, provided with shaft and inner counterweight of reduced dimensions, and which permits the setting of the eccentric mass, from a basic project value, only on the outside of the equipment, maintaining, however, the equalization of the loads on the bearings of the bearing housing and the desirable null or reduced bending moments on the side walls of the equipment.
The fact that the first radial extension of the first counterweight internal to the equipment is reduced allows constructing a protecting casing and an elongated protection (if the connecting shaft exists) of reduced dimensions, and which conducts to a smaller vertical distance between the classifying floors in an equipment in the form of a screen.
The invention will be described below, with reference to the enclosed drawings, given by way of example of a possible embodiment of the invention and in which:
As described above and illustrated in
As best illustrated in
The bearing housing 10 internally carries two bearings which, in the illustrated construction, take the form of sliding bearings defined by bushings adequately retained in the interior of the bearing housing 10 and having their mutually adjacent edges disposed in the region of the bearing housing 10 in which is provided the inner radial recess 12. The two bearings 20 are axially spaced from each other by a spacing ring 21 and dimensioned to support the median region of a short shaft 30, having an inner end portion 31 and outer end portion 32 projecting respectively inwardly of and outwardly from the bearing housing 10.
In its end internal to the side wall 2, the bearing housing 10 secures, by means of axial eccentric bolts 15, a small peripheral end flange 20a of the adjacent bearing 20, the corresponding inner end portion 31 of the shaft 30 being provided with a circumferential rib to be axially seated against a thrust ring 34 which, on its turn, is axially seated against the external end of the adjacent bearing 20. On its other end, external to the side wall 2 of the equipment 1, the bearing housing 10 is configured to carry, by means of bolts 16 or another adequate fastening means, a retaining means 25 which actuates on the adjacent cylindrical surface of the shaft 30 and also on the external end of the adjacent bearing 20.
As seen in the figures of the drawings, the two bearings 20 of each vibrator V are symmetrically positioned in relation to a center line CL of the bearing housing 10, disposed in a plane transversal to the latter.
As already described with respect to the prior art (see
On the other hand, the outer end portion 32 of the shaft 30 affixes a second counterweight 80 having a second eccentric mass M2 larger than the first eccentric mass M1 of the first counterweight 70, a second radial extension R2 larger than the first radial extension R1 of the first eccentric mass M1 of the first counterweight 70 and a second distance L2 from the center line CL of the bearing housing 10 smaller than the first distance L1 of the first eccentric mass M1.
The second eccentric mass M2 should represent another fixed and complementary amount of the minimum nominal eccentric mass to be produced by the vibrator V under operation. Since the same limitations of radial extension of the counterweight are not found in the exterior of the equipment 1, the second counterweight 80 can have a second eccentric mass M2 and a second radial extension R2 larger than the first eccentric mass M1 and the first radial extension. R1, as long as the second distance L2 to the center line of the bearing housing 10 conducts to a respective second load P2 equal to the first P1, maintaining balanced loads on the bearings 20.
The balance condition of the reaction forces F1, F2 generated in the bearings 20, as a function of the loads P1, P2 relative to the first and to the second eccentric mass M1, M2 in the operations of the vibrator V, is schematically illustrated in
Also according to the invention, the setting of the total eccentric mass of the vibrator V is made by means of a third counterweight 90 having a third predetermined eccentric mass M3 to be removably coupled to the second counterweight 80, preferably to an eccentric portion 86 of the second counterweight 80, to maintain the third eccentric mass M3 aligned with the center line of the bearing housing 10.
The constructive arrangement cited above permits increasing the second mass M2 of the second counterweight 80 by adding the third mass M3, without affecting the balance of the reaction forces F1, F2 generated on the bearings 20, as schematically illustrated in
a=distance between the reaction forces F1 and F2 and the center line CL of the bearing housing.
Preferably, the third counterweight 90 is configured to maintain unaltered the second radial extension R2 of the eccentric mass (M2+M3) carried by the outer end portion 32 of the shaft 30, the value of the third eccentric mass M3 being selected as a function of the setting of the total eccentric mass to be moved by the vibrator.
Thus, the provision of the third counterweight 90 alters only the value of the total eccentric mass of the vibrator V, without causing any alteration over the balance of the reaction forces F1, F2 generated in the bearings 20.
In the illustrated construction, the second counterweight 80 is defined by an annular hub 81 attached around the outer end portion 32 of the shaft 30 and incorporating an axial projection 82 projecting towards the center line CL of the bearing housing 10, radially externally to the latter. In the illustrated construction, the axial projection 82 takes the form o a tubular skirt concentric to the shaft 30 and surrounding, with a certain radial gap, an extension of the bearing housing 10 externally to the center line LC.
The annular hub 81 can be attached to the shaft 30 in different ways such as, for example, by means of a key 83 and of an end locking plate 84, affixed to the shaft 30 by bolts 85, only one of which being illustrated in
In the illustrated construction in
The second counterweight 80, likewise the first counterweight 70, is made of any adequate material, such as steel or cast iron. Preferably, the second counterweight 80 further incorporates, in its tubular skirt 82, an eccentric portion 86 disposed axially externally to and slightly spaced from the center line CL of the bearing housing 10, said eccentric portion 86 defining the second eccentric mass M2 of the second counterweight 80.
The eccentric portion 86 presents an axial end face 86a turned to the center line CL of the bearing housing 10 and maintaining a predetermined distance “d” therefrom, as best illustrated in
The eccentric, portion 86 of the second counterweight 80 is preferably configured in the annular form, extending along an angle which varies as a function of the vibrator project, and it may present, for example, a circumferential extension of up to about 180°, the axial end face 86a of said eccentric portion being configured to allow to selectively and removably affix weight portions 90a of a third counterweight 90 thereon.
As illustrated and already mentioned, the third counterweight 90 is designed so that its third eccentric mass M3 maintains the same radial extension R2 of the eccentric portion 86 of the second counterweight 80 and being maintained aligned with the center line CL of the bearing housing 10 when the third counterweight 90 is attached to the axial end face 86a of the eccentric portion 86 of the second counterweight 80, so that the third eccentric mass M3 of the third counterweight 90 causes no unbalance whatsoever in the reaction forces F1 and F2 generated in the bearings 20. The fixation of the third counterweight 90 can be made by bolts 87, of which only one is illustrated in
As illustrated in
In the illustrated construction in
However, the setting of the total eccentric masses of the vibrator V can be made by modifying the radial extension of the weight portions 90a of the third counterweight 90, dividing the weight portions 90a in multiple layers that are mutually seated in the axial direction of the vibrator and which can be spaced from the eccentric portion 86 of the second counterweight 80, by one or more spacers of reduced mass.
As illustrated in
As a function of the reduced radial extension R1 of the first counterweight 70, it is possible to protect the inner region of the vibrators V and, if existing, the connecting shaft 100, through a single protective casing 60 in the form of a tube having the opposite ends hermetically attached to the opposite side walls 2 of the equipment.
While only one constructive form for setting the eccentric mass of the vibrator has been illustrated herein, it should be understood that modifications can be made in the form and arrangement of the different component parts, provided that they fall within the inventive concept defined in the claims that accompany the present specification.
Number | Date | Country | Kind |
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PI0602961-2 | Jul 2006 | BR | national |
Number | Date | Country | |
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Parent | 12303992 | Dec 2008 | US |
Child | 13332795 | US |