US3722381A

US3722381A - Dual amplitude vibration generator

Info

Publication number: US3722381A
Application number: US00121036A
Authority: US
Inventors: E Tuneblom
Original assignee: Dynapac AB
Current assignee: Dynapac AB
Priority date: 1971-04-03
Filing date: 1971-03-04
Publication date: 1973-03-27
Anticipated expiration: 1990-03-27
Also published as: GB1327002A

Abstract

A dual amplitude vibratory mechanism has a pair of eccentric weights mounted on a shaft in such a way that a different amplitude of vibration can be had simply by reversing rotation of the shaft. One of the weights is attached to the shaft and rotatable with it, while the other weight is mounted on the shaft but freely rotatable relative to it. Each weight has a pair of contact surfaces that cooperate with similar surfaces on the other weight, so that when the shaft rotates one of the surfaces on the fixed weight engages the cooperating surface on the free weight, which results in both weights revolving as a single composite eccentric weight, thereby causing the shaft to vibrate. When the shaft rotation is reversed, the other surface on the fixed weight engages its cooperating surface on the free weight, and the weights revolve in that direction as a single composite eccentric weight. The weights are shaped and dimensioned such that they have a combined center of gravity relative to the shaft when one set of surfaces engage each other that is different from the center of gravity when the other surfaces are in engagement, thereby resulting in a different amplitude of vibration when rotation of the shaft is reversed.

Description

United States Patent [191 Tuneblom Mar. 27, 1973 DUAL AMPLITUDE VIBRATION GENERATOR [75] Inventor: Eskil Tuneblom, Mount Arlington,

[21] Appl. No.: 121,036

[52] US. Cl ..404/1l7, 74/87, 209/3665 [51] lnt.Cl.... ..E01c19/28 [58] Field of Search ..74/87, 61; 94/50 V, 48; 209/3665, 367; 259/DIG. 42

[56] References Cited UNITED STATES PATENTS Engelhard ..94/50 V 3 ,097,5 37

Peterson 3,267,825 8/1966 Owen et al.... 3,608,388 9/1971 Huber ..'.....74/87 OTHER PUBLICATIONS German Utility Model, ABG, Werke, May, 1966.

Primary Examiner-Milton Kaufman Attorney-Brumbaugh, Graves, Donohue & Raymond ABSTRACT A dual amplitude vibratory mechanism has a pair of eccentric weights mounted on a shaft in such a way that a difierentamplitude of vibration can be had simply by reversing rotation of the shaft. One of the weights is attached to the shaft and rotatablewith it, while the other weight is mounted on the shaft but freely rotatable relative to it. Each weight has a pair of contact surfaces that cooperate with similar surfaces on the other weight, so that when the shaft rotates one of the surfaces on the fixed weight engages the cooperating surface on the free weight, which results in both weights revolving as a single composite eccentric weight, thereby causing the shaft to vibrate. When the shaft rotation is reversed, the other surface on the fixed weight engages its cooperating surface on the free weight, and the weights revolve in that direction as a single composite eccentric weight. The weights are shaped and dimensioned such'that they have a combined center of gravity relative to the shaft when one set of surfaces engage each other that is different from the center of gravity when the other surfaces are in engagement, thereby resulting in a different amplitude of vibration when rotation of the shaft is reversed.

2 Claims, 4 Drawing Figures PATENTEUHARZ'HGYE! ,722,3 1

SHEET 10F 2 INVENTOR. ESKIL TUNEBLOM his ATTORNEYS PATENTEDHARNIHYS 3,722,381

sum 2 [IF 2 INVENTOR. ESKIL TUNEBLOM his ATTORNEYS 1 DUAL AMPLITUDE VIBRATION GENERATOR BACKGROUND OF THE INVENTION Thisinvention relates to a mechanism that generates a vibratory motion through rotation of a shaft, and more particularly to a vibratory mechanism that is capable of producing vibrations of more than one amplitude. I

There are many types of machines that utilize a vibratory motion to perform their basic operations. These machines include, among many others, soil and stone compactors for road construction, grinding mills for mineral comminution and shaker screens for separating and sizing particles. It is well known that the use of an eccentric weight in conjunction with a rotating shaft mounted in such a machine will provide the vibratory motion that is needed to enable the machine to function effectively.

However, in most of these machines the vibratory motion is normally limited to a single amplitude. This is disadvantageous in that the conditions under which the machines must operate often change, and a machine that has vibratory motion limited to one amplitude many times cannot perform in the most effective manner and can only be used under one set of operat: ing conditions. I

Road construction is one area in which it is economically important to use machines that are capable of vibrating at more than one amplitude. Compactors with rollers producing high amplitude vibrations have been used on earth and granular base materials, the so-called thick lift materials. It is also advantageous to use vibrat' ing rollers to compact bituminous paving mixtures and other thin lift materials to provide substantial savings in construction costs and a road surface of a higher quality, when compared to static rollers which do not vibrate.

However, when working on the thin lift materials, vibrations of a relatively low amplitude produced at a high rotational frequency are needed to avoid a bounce back effect, which causes ripples to form on the surface of bituminous materials such as asphalt and a high degree of surface dispersion in materials such as soil cement. For the thick lift materials, though, a higher amplitude is needed so that the pressure waves caused by the roller will penetrate the material and effectively compact it to the proper density. Thus, ideally a compactor for road construction should have a roller that is capable of vibrating at different amplitudes, so that a single machine is provided with the versatility to compact both the thin lift and thick lift materials. This type of compactor would result in significant economic savings by eliminating the need for a separate machine for each operation.

In known machines, the amplitude of the vibratory motion produced by an eccentric weight can be changed, but this normally requires dismantling at least a portion of the machine and replacing the existing weight withanother one having a different center of gravity. In one road roller machine known to the art, an eccentric weight has a number of cavities in which weights can be inserted or removed for changing the center of gravity of the eccentric weight, thereby varying the amplitude of vibration. However, although that machine did not have to be dismantled to change the amplitude of vibration, a mechanical adjustment did have to be made which is time consuming, especially when operating under less than ideal weather conditions.

SUMMARY or THE INVENTION There is provided, in accordance with the invention, a mechanism which transmits a vibratory motion through a shaft to a machine, with the mechanism being capable of producing a vibration having a different amplitude, simply by reversing the rotation of the shaft. The mechanism has special applicability with regard to road compacting machines and will be described in conjunction with one, but the mechanism can be effectively used in other vibrating machines.

More specifically, the dual amplitude vibratory mechanism has a shaft on which is mounted a pair of eccentric weights. One of the weights is attached to the shaft and, therefore, rotatable with it. The other weight is mounted on the shaft, for example by means of a pair of rings through which the shaft is passed, so that the weight is freely rotatable relative to it.

Each weight has a pair of contact surfaces, located on opposite sides of the weight relative to its rotational path, that cooperate with similarly placed surfaces on the other weight. The cooperating surfaces are located relative to each other in such a way that when the shaft rotates, the fixed weight revolves and one of its surfaces engages one of the cooperating surfaces on the free weight, thereby causing both weights to revolve as a single composite eccentric weight. When rotation of the shaft is reversed, the fixed weight rotates with the shaft causing the contact surfaces mentioned above to move out of engagement, the fixed weight revolving independently of the free weight through part of a revolution until the other contact surface engages its cooperating surface on the free weight which, in turn, causes the weights to revolve with the shaft as a single composite eccentric weight in the reverse direction.

The weights are shaped and dimensioned such that when one pair of contact surfaces engage each other, the composite eccentric weight formed by the weights has a center of gravity relative to the shaft that is different from the center of gravity of the weights when the other pair of contact surfaces engage each other. Thus, when the shaft rotates in one direction, the revolving eccentric weights generate vibrations that have an amplitude that is different from the vibration amplitude generated when the weights revolve in the reverse direction.

Each end of the shaft is journaled in a machine, such as, for example, a road compactor, and the vibrations are transmitted through the shaft to the machine. A reversible motor attached to the shaft enables its rotation in either direction for selectively changing the amplitude of vibration.

Thus, there is provided in accordance with the invention a dual amplitude'vibratory mechanism which is advantageous because the amplitude. of vibration of a machine can be changed. without having to dismantle the machine and replace an eccentric weight, and even without the need to make a mechanical adjustment on the machine. The change in amplitude can be accomplished simply by reversing the direction of rotation of the shaft on which the eccentric weights are mounted, which is an essential characteristic in affording a machine such as a road compactor great versatility. A machine in which the inventive mechanism has been installed can be used to perform operations that heretofore could only be done economically by more than one machine, thereby eliminating the need to purchase an extra machine.

DESCRIPTION OF THE DRAWINGS For a better understanding of the invention, reference may be had to the following description of the preferred embodiment, taken in conjunction with the accompanying drawings, in which:

FIG. 1 is a front elevational view of a pair of eccentric weights mounted on a shaft, with a pair of cooperating contact surfaces engaging each other so that the weights form a composite eccentric weight that has a center of gravity which will cause a vibratory motion of a relatively high amplitude;

FIG. 2 is a front elevational view of the weights and shaft shown in FIG. 1, but with the other pair of cooperating contact surfaces in engagement so that the composite eccentric weight has a center of gravity different from that in FIG. 1 for producing a vibration of a relatively low amplitude;

FIG. 3 is a side elevational view of the eccentric weights shown in their position in FIG. 1, with a portion of the freely rotatable weight being broken-away to show its attachment to mounting rings;

FIG. 4 is a front sectional view of the roller of a vibratory road compactor in which eccentric weights of the type shown in FIGS. 1-3 have been installed.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT Referring now to FIGS. 1 and 2, the dual amplitude vibratory mechanism is shown as having a shaft on which is mounted a pair of eccentric weights 12' and 14. The shaft 10 can be of any suitable size and shape, depending on the type of machine in which his to be used. A reversible motor, not shown, is connected to the shaft 10 so that it can be selectively rotated in opposite directions.

The weight 12 is attached to the shaft 10 and, therefore, rotatable with it. In FIGS. 1 and 2, the weight 12 as shown is welded to the shaft 10, but any effective means of attachment can be used. The weight 14 is mounted on the shaft 10 in a way that enables it to be freely rotatable relative to the shaft 10, and to the weight 12 through at least a portion of one revolution. As best shown in FIG. 3, this can be accomplished by attaching the weight 14 to a pair of rings 16 that are mounted on but not'attached to the shaft 10, on each side of the weight 12. The weight 14 is preferably welded to the rings 16, along both its inner and outer edges as shown by the reference numeral 18 in the broken-away portion of FIG. 3, but as with the weight 12 any suitable means of attachment can be used. A groove 19 is formed along the inner edge of the rings 16 so that the inner weld 18 will not interfere with the free rotational movement of the weight 14 relative to the shaft 10 or'the fixed weight 12. Moreover, by arranging the rings 16 on each side of the fixed weight 12, the weight 14 is prevented from moving axially along the shaft 10.

The weight 12 has two

contact surfaces

20 and 22 located on opposite sides relative to its rotational path,

' the

surfaces

20 and 22 cooperating with similarly located contact surfaces 20 and 22 on the weight 14.

The

weights

12 and 14 are preferably identical in shape, weight and size, although this is not essential, and together they form a single composite eccentric weight. When the contact surfaces 20 and 20' abut each other as shown in FIG. 1, the center of gravity of the composite weight is lower relative to the shaft 10, when compared to the composite weight shown in FIG. 2, where the contact surfaces 22 and 22' are shown abutting each other. This is accomplished by the generally rectangular shape of the

weights

12 and 14 and their different combined weight distribution when the different pairs of contact surfaces abut each other.

When the shaft 10 turns in the direction indicated by the arrow 24, as shown in FIG. 1, the fixed weight 12 rotates with the shaft 10, and the contact surface 20 engages the contact surface 20' of the freely rotatable weight 14 so that both the weights 12 and '14 will revolve as a single composite eccentric weight. Such rotation results in the generation of relatively high amplitude vibrations which are transmitted through the shaft 10 to the machine (not shown) in which the shaft 10 is mounted.

To generate vibrations of a lower amplitude, the rotational direction of the shaft 10 is reversed, as indicated by the arrow 26 shown in FIG. 2. The fixed weight 12 then rotates with the shaft 10 and the'contact surface 20 disengages from the contact surface 20. The weight 12 revolves independently of the weight 14 until the contact surface 22 engages the contact surface 22', which results in the

weights

12 and 14 revolving together in this latter direction as the single composite eccentric weight shown in FIG. 2. The combined

weights

12 and 14 now have a center of gravity higher relative to the shaft 10 than when the

weights

12 and 14 are combined as shown in FIG. 1, thereby imparting vibrations of lesser amplitude through the shaft 10 to the machine. In this manner the vibration amplitude of the machine in which the shaft 10 is mounted can be changed simply by reversing the direction of shaft rotation.

As shown in FIGS. 1 and 2, the contact surfaces 20, 20, 22 and 22 do not extend the entire length of the side of the

respective weights

12 and 14 on which they are located in order to prevent contact of the weights immediately adjacent to the shaft.

Alternatively, double-amplitude vibration as described above can be obtained by mounting the weights l2 and 14 on the shaft 10 in such a way that they are both freely rotatable relative to it, with the reversible motor being connected to one of the weights I for revolving them as described above. Moreover, the weights l2 and 14 can be formed of different sizes and shapes and mounted on the shaft 10 relative to each other in various ways, and be within the scope of the invention.

Now, referring to FIG. 4, one application of the invention is shown where two sets of the

eccentric weights

12 and 14 are mounted in a roller 50 of a selfpropelled vibratory road compactor. The roller 50 is journaled in a frame 52 of the compactor by means of bearings 54 so that the roller 50 can be rolled along the surface of the roadway at a suitable speed. For imparting a vibratory motion to the roller 50, each set of

eccentric weights

12 and 14 is mounted, as described above, on shaft sections 56 which are journaled in the roller 50 by means of

bearings

58 and 60 that are positioned in outer and

inner bearing housings

62 and 64,

respectively. Each of the inner bearing housings 62 forms a part of an oil reservoir 66 which is integral with a side wall of the roller 50 and projects inwardly from it, the reservoir 66 containing oil 67 for "oil ba lubrication of the

bearings

58 and 60.

A drive shaft 68 is splined to each of the shaft sections 56 so that the hydraulic motor 70, which is coupled to an end of one of the shaft sections 56, will drive both sets of the eccentric weights l2 and 14. The motor 70 is reversible, with the hydraulic system to which it is connected having a two-way directional valve (not shown) so that the shafts 56 can be rotated in either direction for vibrating the roller 50 at different amplitudes merely by adjusting the valve.

Although many other configurations of component parts can be provided, the shaft sections 56 are preferable because four sets of bearings, 58 and 60 (two on each of the shafts 56), carry the load of the

weights

12 and 14 and shaft bending is reduced to a minimum. This is important because of the high speed at which the shafts 56 are rotated.

Thus, there is provided in accordance with the invention a dual amplitude vibratory mechanism which can be used effectively in conjunction with machines that employ eccentric weights to produce a vibratory motion, and which can impart a vibratory motion of a different amplitude to the machine by simply reversing the rotation of the shaft on which eccentric weights are mounted. The embodiment of the invention described above is intended to be merely exemplary, and those skilled in the art will be able to make modifications and variations without departing from the spirit and scope of the appended claims, and all such modifications and variations are contemplated as being within the scope of the claims.

I claim:

1. A dual amplitude vibration generator comprising a shaft, first and second eccentric weights, first mounting means attaching the first weight to the shaft so that it is rotatable with the shaft, second mounting means rotatably mounting the second weight on the shaft so that it is rotatable relative to the first weight through at least a portion of one revolution, the second mounting means including a pair of mounting rings to which the second weight is attached, the shaft passing through the rings and one of the rings being disposed on either side of the first weight for preventing the second weight from moving axially along the shaft, and drive means for selectively rotating said first weight inopposite directions, the drive means including a coupling to the shaft, a pair of contact surfaces on each of said weights, one contact surface on the first weight cooperating the shaft, and the other contact surface on the first weight cooperating with and engaging the other contact surface on the second weight when said first weight is rotated by the drive means in the opposite direction to rotate both the weights in said opposite direction, said two weights when rotating in said opposite direction forming a second composite eccentric weight having a center of gravity at a second distance from the shaft, whereby the amplitude of vibrations generated by rotation of the composite weights can be changed by reversing the direction of rotation of said first weight.

2. In a vibratory compactor of the type that has a roller journaled in a housing, the roller engaging and rolling along a surface to be compacted a shaft mounted in the roller, an eccentric weight means mounted on the shaft, and means for rotating the weight so that a vibratory motion is imparted through the shaft to the roller, the improvement comprising said shaft, said weight means comprising first and second eccentric weights, first mounting means attaching the first weight to the shaft so that it is rotatable with the shaft, second mounting means rotatably mounting the second weight on the shaft so that it is rotatable relative to the first weight through at least a portion of one revolution,- the second mounting :means including a pair of mounting rings to which the second weight is attached, the shaft passing through the rings and one of the rings being disposed on either side of the first weight for preventing the second weight from moving axially along the shaft, and drive means for selectively rotating said first weight in opposite directions, the drive means including a coupling to the shaft, a pair of contact surfaces on each of said weights, one contact surface on the first weight cooperating with and engaging one contact surface on the second weight when said first weight is rotated by the drive means in one direction to rotate both the weights in said one direction, said two weights when rotating in said one direction forming a first composite eccentric weight having a center of gravity at a first distance from the shaft, and the other contact surface on the first weight cooperating with and engaging the other contact surface on the second weight when said first weight is rotated by the drive means in the opposite direction to rotate both the weights in said opposite direction, said two weights when rotating in said opposite direction forming a second composite eccentric weight having a center of gravity at a second distance from the shaft, whereby the amplitude of vibrations generated by rotation of the composite weights can be changed by reversing the direction of rotation of said first weight.

Claims

1. A dual amplitude vibration generator comprising a shaft, first and second eccentric weights, first mounting means attaching the first weight to the shaft so that it is rotatable with the shaft, second mounting means rotatably mounting the second weight on the shaft so that it is rotatable relative to the first weight through at least a portion of one revolution, the second mounting means including a pair of mounting rings to which the second weight is attached, the shaft passing through the rings and one of the rings being disposed on either side of the first weight for preventing the second weight from moving axially along the shaft, and drive means for selectively rotating said first weight in opposite directions, the drive means including a coupling to the shaft, a pair of contact surfaces on each of said weights, one contact surface on the first weight cooperating with and engaging one contact surface on the second weight when said first weight is rotated by the drive means in one direction to rotate both the weights in said one direction, said two weights when rotating in said one direction forming a first composite eccentric weight having a center of gravity at a first distance from the shaft, and the other contact surface on the first weight cooperating with and engaging the other contact surface on the second weight when said first weight is rotated by the drive means in the opposite direction to rotate both the weights in said opposite direction, said two weights when rotating in said opposite direction forming a second composite eccentric weight having a center of gravity at a second distance from the shaft, whereby the amplitude of vibrations generated by rotation of the composite weights can be changed by reversing the direction of rotation of said first weight.

2. In a vibratory compactor of the type that has a roller journaled in a housing, the roller engaging and rolling along a surface to be compacted a shaft mounted in the roller, an eccentric weight means mounted on the shaft, and means for rotating the weight so that a vibratory motion is imparted through the shaft to the roller, the improvement comprising said shaft, said weight means comprising first and second eccentric weights, first mounting means attaching the first weight to the shaft so that it is rotatable with the shaft, second mounting means rotatably mounting the second weight on the shaft so that it is rotatable relative to the first weight through at least a portion of one revolution, the second mounting means including a pair of mounting rings to which the second weight is attached, the shaft passing through the rings and one of the rings being disposed on either side of the first weight for preventing the second weight from moving axially along the shaft, and drive means for selectively rotating said first weight in opposite directions, the drive means including a coupling to the shaft, a pair of contact surfaces on each of said weights, one contact surface on the first weight coopeRating with and engaging one contact surface on the second weight when said first weight is rotated by the drive means in one direction to rotate both the weights in said one direction, said two weights when rotating in said one direction forming a first composite eccentric weight having a center of gravity at a first distance from the shaft, and the other contact surface on the first weight cooperating with and engaging the other contact surface on the second weight when said first weight is rotated by the drive means in the opposite direction to rotate both the weights in said opposite direction, said two weights when rotating in said opposite direction forming a second composite eccentric weight having a center of gravity at a second distance from the shaft, whereby the amplitude of vibrations generated by rotation of the composite weights can be changed by reversing the direction of rotation of said first weight.