Conveyors: power-driven – Conveyor section – Reciprocating conveying surface
Reexamination Certificate
2001-03-15
2003-12-02
Hess, Douglas (Department: 3651)
Conveyors: power-driven
Conveyor section
Reciprocating conveying surface
C198S763000, C198S766000, C198S770000, C198S771000
Reexamination Certificate
active
06655523
ABSTRACT:
TECHNICAL FIELD
The present invention relates to an excited frame conveyor and more specifically to conveyors which utilize vibratory motion for the distribution, collection, or transfer of a product.
BACKGROUND OF THE INVENTION
Vibratory conveying systems are commonly used in the food and other industries where belt type conveyors are undesirable or where it is difficult to maintain the conveyors in a sanitary condition. Vibratory conveyors make use of a conveyor bed that includes an elongated tray which is made to vibrate predominantly in a desired direction and at an angle such that materials deposited on the bed will migrate or travel at a selected speed from an infeed end of the bed to a discharge end.
Excited frame vibratory conveying devices are known in the art. For example, U.S. Pat. No. 4,313,535, which is incorporated by reference herein, shows an exemplary excited frame conveying apparatus that has performed well in the past for transporting bulk product over relatively short distances.
As best seen in
FIGS. 1 and 2
, a prior art excited frame conveyor similar to that shown in the patent above, includes a vibratory drive mounted on an elongated frame. The frame is supported between a rigid, ground supported base, and the bed of the conveyor receives and moves product along the conveyor length. A resilient suspension in the form of leaf or beam springs project upwardly at spaced intervals along the frame, and are inclined in the direction of the intake or infeed end of the conveyor.
The elongated conveyor or product transporting bed is mounted on the upper ends of the respective beam springs. The conveyor bed is supported by the beam springs in a generally parallel relationship to the frame, and in a substantially overall horizontal orientation. Due to the resiliency of the respective beam springs, the product conveying bed is capable of moving relative to the frame in response to a force supplied to the bed by the vibratory drive mounted on the frame. During operation of the apparatus, the vibratory drive produces an oscillating vibratory force. This force may be generated by rotating eccentric weights mounted on the vibratory drive.
As will be recognized the vibratory drive is mounted on the frame and therefor imparts vibratory motion to the frame, which is then transferred through the beam springs to the conveyor bed. As a result, the bed vibrates at substantially the same frequency as the drive and frame.
Isolation springs are also typically mounted between the frame and the earth's surface by way of supports that are spaced along the length of the conveyor. The isolation springs are used to “isolate” vibration of the frame to minimize transmission of vibratory forces to the supports.
A conveyor bed that is displaced from its “at rest” position and then allowed to oscillate freely will oscillate at its natural or “harmonic frequency”. This frequency is dependent upon the combined spring constant, the number of springs supporting the bed, as well as the mass of the bed.
As a general matter for conveyors of this design, less vibration and force is transferred to the floor or other supporting structure by an excited frame conveyor design because of the small vibrational amplitude of the frame, as compared to the vibrational amplitude of the product conveying bed. The low level of vibrational force transferred to the surrounding structure is a chief advantage of the prior art excited frame vibratory conveyor as seen in
FIGS. 1 and 2
. In view of the relatively short length and rigidity of the frame operational frequencies of the conveyor bed do not generally approach the frequency modes in the frame at which the frame and conveyor bed will begin to move in directions not conducive to transport of product.
It should be understood that it is not unusual for a conventional excited frame conveyor to operate at frequencies over the natural frequencies of the system (system frequencies). An example of such a device is illustrated in the O'Connor patent (U.S. Pat. No. 2,353,492). In this reference the beds and frames are considered to be rigid members (due to the typically short machine length and the rigid mass of the structures). As such, the structural frequencies of the bed and frame are much higher than the operating frequencies. The frequencies of interest in O'Connor are actually isolator frequencies which relate to the springs and masses (as rigid members) only. Conventional drives are easily capable of ramping or accelerating through these isolator frequencies in this type of system, and may operate at frequencies which do not cause the bed or frame structural frequencies to become a design consideration.
It has long been recognized that excited frame vibratory conveyors under certain operational conditions may excite frame structural frequency modes that result in undesirable and even destructive motion of the conveyor bed, or the entire conveyor system. As a general matter this is usually not a problem with the above-noted short frame conveyors where the frame frequencies are well above the operating frequencies. However, if longer frames are fabricated, the structural natural frequencies of the frame decrease and become important factors in the overall conveyor design.
To overcome the problems encountered when conveyor lengths increase, the frame must be stiffened in order to keep the frame structural frequencies well beyond the desired operational frequencies. This solution however does not remain commercially practical beyond a length of approximately 40 feet, due to cost constraints. Thus, when it becomes desirable to transport materials on an excited frame conveyor over distances greater than 40 feet, serious consideration must be given to the issue outlined above.
As would be expected an excited frame will become “soft” or will otherwise bend more readily as the length of the frame increases. Along with increasing frame length, the distance decreases between frequency modes at which the frame may become excited and begin to move in undesirable directions. Still further, as frame length increases, the frequencies at which undesirable modes occur decrease. This relationship is shown graphically in
FIG. 7
of the drawings, where three separate frame structural modes are shown and which decrease in frequency with a corresponding increase in the frame length. Still further the distance between modes correspondingly decrease as the frame length increases. The techniques for designing conveyors less than 200 inches are well known in the art, especially since structural modes do not typically come into play at frame lengths under that length.
If a long conveyor is to be operated below its structural frequency modes to avoid the difficulties noted above, the obvious solution is to lower the operating frequency of the drive below the undesired structural frequency or increase the stiffness of the frame. However, lowering the operating frequency decreases the conveying speed which reduces the capacity of the conveyor; while increasing the frame stiffness can significantly increase the cost.
Experience has shown that excited frame conveyors should move material at flow rates of approximately 20-150 feet per minute. To achieve such flow rates with conveyors greater than 40 feet, the operating frequency must typically be beyond at least the first structural frequency of the conveyor frame, unless the frame is braced or otherwise made sufficiently rigid such that the frequency modes occur beyond the operating frequency.
In addition to the foregoing, the energy required to maintain a desired flow rate must also increase because of the added mass of the bed. As a result, a larger drive will be required which adds significant weight to the conveyor and adds complexity to the frame. Therefore, long excited frame conveyors have heretofore been thought to be uneconomical. At least a part of the problem with long “soft” frames (those that can bend) is seen during start-up of the conveyor drive. As noted above, the drive is typically an eccentric mass vibrator
Gale James
Jones Peter Todd
Ruff James Dale
Hess Douglas
Key Technology Inc.
Wells St. John P.S.
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