Apparatus of staged resonant frequency vibration of concrete

Abstract

Vibrational energy introduced into plastic concrete structures, such as concrete slabs, decks and similar or related concrete structures, at or near the natural resonant frequency of the liquid concrete mass, expedites the consolidation and setting of the concrete. A vibrating apparatus imparts controlled vibrations either onto the surface or beneath the surface of the concrete mass in sequential stages, the frequency of vibrations generally increasing with each subsequent stage, corresponding to the increase in the natural resonant frequency of the progressively-narrowing liquid concrete at the top of the structure. The relatively more consolidated and more dry concrete (typically near the bottom of the slab) is substantially unaffected by the non-resonant frequencies vibrations. In one modification, sensors determine the resonant frequency of the liquid concrete mass during each pass of the vibrator apparatus, and the frequency of the vibrating member is automatically adjusted, accordingly. The number of stages, the amplitude of the vibrations, the physical orientation of the vibration-producing apparatus, the time duration in each stage, is variable depending upon the physical characteristics of the concrete mass.

Description

FIELD OF THE INVENTION

The present invention generally relates to a method and apparatus for introducing vibrational energy into plastic concrete structures in successive stages or increments. More particularly, the present invention relates to a method and apparatus for affecting the firmness profile of a concrete structure by introducing vibrational energy at the resonant frequency of the wet concrete into said structure while it is in a plastic state during its placement.

DESCRIPTION OF THE PRIOR ART

In constructing concrete structures, such as concrete slabs and the like, certain conventional procedures involve simply placing the concrete mass in a form and finishing the top surface in various well known manners and permitting the concrete to harden with no vibration whatsoever. Other procedures involve the use of vibrators placed temporarily into or upon the concrete mass at various locations, with the surface being finished by using various combinations of striking off the surface and/or trowelling operations, including the use of hand trowels, powered rotary trowels and the like.

A problem with prior methods of placing concrete using vibrators is associated with the lack of control of the vibrators. When any one section of a poured concrete slab is vibrated too much, it causes "hard spots" in the concrete slab approximately at the location of the contact with the vibrator. In addition, over-vibration of the concrete can also cause aggregate separation in the vicinity of the vibrator. Aggregate separation and "hard spots" both result in a non-uniform and weakened final slab. For these reasons, prior concrete placing operations typically cautiously "under-vibrate" the concrete mass or may not vibrate the concrete mass at all.

The principal purpose of vibrating plastic concrete in this context is to expeditiously consolidate the concrete mass at as nearly a uniform density as possible by encouraging and assisting the upward migration of water and air which would otherwise migrate slowly or not at all. Entrapment of air and water weakens the concrete, and the slow migration of these materials extends the time required to place and finish the concrete mass.

Prior procedures for the application of vibrations to the concrete mass provide virtually no means to control or to modify the vibrational characteristics (such as frequency, amplitude, etc.) of the vibrators (other than by manually turning the vibrator off and on), and only crude means to control or modify the length of time the vibrators act upon the concrete mass. Therefore, the prior procedures produce a concrete mass in which the degree of consolidation varies from one location to the other (resulting in a structure of inconsistent structural integrity), and in which the time required for water to evaporate from the surface varies from one location to the other (making it very difficult to finish the structure by using automatic or robotic finishing equipment).

Another phenomenon associated with natural (i.e. non-vibrated) consolidation and curing of concrete is the entrapment of moisture inside of the curing mass. As poured, concrete mixtures commonly comprise an amount of water far exceeding the quantity which is actually necessary to effect proper curing and maximum strength of the concrete mass. The excess water is intentionally added to the concrete mixture in order to facilitate transporting, pouring, forming, and finishing operations. If left stagnant (i.e. un-vibrated), pressure from the weight of the concrete mass initially slowly presses some of the excess water upward through the concrete mass, thus initially inducing migration of some of the excess water towards the surface of the slab and, at the same time, effecting the consolidation of the concrete mass near the bottom of the slab. The concrete begins to cure, even while the concrete mass may not yet be optimally consolidated. This curing of the concrete mass retards the migration of the remainder of the excess water towards the surface of the slab. At the same time, in many instances (particularly when the slab is poured in sunlight, on a windy day of low humidity), water may evaporate so quickly from the top surface of the slab that the concrete at the top prematurely dries out and begins to cure. This results in the setting of the concrete at or near the upper surface of the slab, which further retards migration of excessive water from the concrete mass below to the surface. Ultimately, this phenomenon results in the entrapment of the moisture inside of the concrete slab. Over time the moisture bubbles dry out, leaving small air pockets throughout the solid concrete slab. Such air pockets reduce the final strength of the concrete slab.

In prior concrete slab placing operations, de-watering techniques are sometimes used wherein the concrete mass is poured and formed into a structure having an upper surface, and the mass is then de-watered by applying a vacuum water extracting system over the wet concrete surface. Alternatively, the surface of the concrete mass is de-watered by placing absorbent material (such as burlap or the like) over the wet concrete surface, and then spreading a desiccant (such as dry cement) on the burlap. After the de-watering process has been completed the burlap or the vacuum water extraction system is removed. The surface is then conventionally finished. Prior concrete finishing procedures are labor intensive and require extensive use of skilled labor and considerable time expenditure in properly carrying them out.

The following U.S. Patents relate to developments in the introduction of vibration into a concrete mass by the use of vibrating devices that are immersed in or otherwise associated with the concrete mass: U.S. Pat. Nos. 2,015,217; 2,223,734; 2,269,109; 2,293,962; and 2,332,687.

While the above patents relate to the vibration of a concrete mass, none of them suggests a staged or step-by-step vibration of a concrete slab, deck or the like in which each stage of the vibration introduced onto or into the concrete mass affects the mass of concrete to specific desired depths in the concrete mass; nor do any of them describe a means of determining the depth to which the concrete mass has been consolidated or should be vibrated.

Co-pending U.S. patent application Ser. No. 08/055,004 discloses a method and apparatus for applying staged vibration to plastic concrete structures. It is desirable, when employing such staged vibration methods and apparatus, to minimize the amount of vibrational energy which must be imparted into the concrete structure in order to cause the expeditious consolidation of the concrete mass. It is also desirable, when employing such staged vibration methods and apparatus, to minimize the vibrational energy which is imparted into the already sufficiently-consolidated portion of the concrete mass. It is also desirable, when employing such staged vibration methods and apparatus, to simplify the construction, manufacture, and use of the vibrating and sensing equipment.

SUMMARY OF THE INVENTION

Accordingly, it is a primary objective of the present invention to provide a method and apparatus for placing concrete slabs, or similar structures, by use of machine operations, in which the concrete is placed using staged vibration of the uncured, plastic concrete mass.

It is another object of the present invention to provide a method and apparatus of placing concrete slabs of the character described, wherein, during each intermediate stage of vibration, water and air are caused to migrate upward through the uncured concrete mass, thus forming a definable boundary layer, below which boundary layer the concrete mass may be defined as being sufficiently consolidated, sufficiently firm, and sufficiently "dry", and above which boundary layer the concrete mass may be defined as being "wet" and insufficiently consolidated. Another objective of the present invention is to provide a method and apparatus of placing concrete slabs, or similar structures, of the character described, in which the uncured concrete mass is sequentially consolidated from the bottom upward toward the top surface, so as to effect a placed structure of substantially uniform density from the bottom to (or nearly to) the top, wherein the consolidation and integration of adjacent horizontal layers of the concrete mass is effected by a vibrator apparatus which advantageously imparts vibrations into the uncured concrete mass.

Another objective of the present invention is to provide a method and apparatus of placing concrete slabs, or similar structures, by the use of machine operations in which the rate of consolidation of the concrete mass is controlled by a plurality of "stages" (or series of vibrations of the concrete mass), with each "stage" affecting only (or predominantly) a portion of the total thickness of the concrete mass.

It is another object of the present invention to provide a method and apparatus of the character described in which the amount of vibrational energy which must be introduced into the concrete mass to effect the desired effects is minimized.

It is another object of the present invention to provide a method and apparatus of placing concrete slabs, or similar structures, of the character described, in which the amount of vibrational energy introduced into the relatively "wet" concrete mass above the boundary layer is optimized, and the amount of vibrational energy introduced into the relatively "dry" concrete mass below the boundary layer is minimized.

It is another object of the present invention to provide a method and apparatus of placing concrete slabs, or similar structures, of the character described, in which vibrational energy is advantageously introduced into the concrete mass at or near the natural resonant frequency (or harmonic thereof) of the relatively "wet" concrete mass above the boundary layer.

It is another object to provide a modification of the present invention in which the resonant frequency of the relatively "wet" concrete mass above the boundary layer is measured, either directly or indirectly, and one or more characteristics of the vibrational energy imparted into the concrete mass is advantageously varied in accordance with such measurement.

These together with other objectives and advantages which will become subsequently apparent, reside in the details of construction and operation as more fully hereinafter described and claimed, reference being made to the accompanying drawings forming a part hereof, wherein like numerals refer to like parts throughout.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic cross-sectional elevation illustrating a concrete slab under construction immediately after the concrete mass has been poured;

FIG. 2 is a graph which plots the firmness profile of the concrete slab of FIG. 1;

FIG. 3 is a schematic cross-sectional elevation of the concrete slab of FIG. 1 shown a short time after the concrete mass has been poured, prior to vibration of the concrete mass;

FIG. 4 is a graph which plots the firmness profile of the concrete slab of FIG. 3;

FIG. 5 is a schematic cross-sectional elevation of the concrete slab of FIG. 1 shown during the first stage of vibration using the present invention;

FIG. 6 is a schematic cross-sectional elevation of the concrete slab of FIG. 1 shown immediately after the first stage of vibration using the present invention;

FIG. 7 is a graph which plots the firmness profile of the concrete slab of FIG. 6;

FIG. 8 is a schematic cross-sectional elevation of the concrete slab of FIG. 1 shown during the second stage of vibration using the present invention;

FIG. 9 is a graph which plots the firmness profile of the left hand side of the concrete slab of FIG. 8 after the passage of the vibrator;

FIG. 10 is a schematic cross-sectional elevation of the concrete slab of FIG. 1 shown during the final stage of vibration using the present invention;

FIG. 11 is a graph which plots the firmness profile of the left hand side of the concrete slab of FIG. 10 after the passage of the vibrator;

FIG. 12 is a schematic cross-sectional elevation of a concrete slab showing the preferred embodiment of the present invention;

FIG. 13 is a schematic cross-sectional elevation showing a modified embodiment of the vibrator apparatus of the present invention;

FIG. 14 is a schematic flow diagram showing a method of operating the present invention in a "fixed" mode;

FIG. 15 is a schematic flow diagram showing a method of operating the present invention in an "adjustable" mode;

FIG. 16 is a schematic flow diagram showing a method of operating the present invention in a "boundary layer" mode;

FIG. 17 is a schematic flow diagram showing a method of operating the present invention in a "pinger" mode;

FIG. 18 is a schematic flow diagram showing a method of operating the present invention in an "ammeter" mode;

and,

FIG. 19 is a schematic cross-sectional elevation showing a plurality of vibrator apparatuses constructed in accordance with the present invention secured to each other.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

As will be described hereinbelow, the present invention is an apparatus and method of placing concrete slabs (and related structures) in which vibrational energy is imparted into an uncured, plastic concrete mass M in a controlled fashion so as to affect (among other things) the "firmness" of the concrete mass. In this context, the terms "firm" and "firmness" refer to the compactness of the concrete mass, or, more specifically, to the degree of "solidity" when referring to any portion of the concrete mass which predominantly exhibits solid-like properties, or to the degree of "liquidity" when referring to any portion of the concrete mass which predominantly exhibits liquid-like properties. It will be understood that increasing the firmness in any portion of the concrete mass which predominantly exhibits liquid-like properties corresponds to decreasing its "liquidity"; and increasing the firmness in any portion of the concrete mass which predominantly exhibits solid-like properties corresponds to increasing its "solidity".

Although the concrete mass M, when initially poured, is actually a mixture of solids (including cement, aggregates, etc.) and liquid (primarily water), the initially-poured concrete mass predominantly exhibits liquid-like properties and thus may be characterized as being a liquid. In the figures, line 70 generally corresponds to a degree of "firmness" above which the concrete mass may be characterized as acting more like a solid, and below which the concrete mass may be characterized as acting more like a liquid.

FIG. 1 of the drawings illustrates a concrete mass (generally indicated "M" in the figures) which may be in the form of a slab as the concrete has been poured into a form (not shown) or the like from any suitable source onto a slab sub-base B. The concrete mass M typically includes aggregate, cement, water and other additives which may conventionally be employed in concrete slabs.

When the concrete mass M is initially poured, the aggregate, cement, water and other materials incorporated into the concrete are typically randomly distributed throughout the thickness of the concrete mass M between the sub-base B and the exposed top surface 1 of the concrete slab. At the instant at which the concrete mass M is first poured, virtually none of the concrete mass is sufficiently consolidated, firm and dry enough for purposes of finishing the top surface 1 of the slab. (In this context, the word "finishing" is a term of art which refers to the way in which the surface of a concrete slab is smoothed.) Also, at the instant at which the concrete mass M is first poured, there typically exists variations in the moisture content and the degree of consolidation of the concrete mass M from one point to another over the entire volume of the concrete mass M. Such variation in consistency of poured concrete is not crucial to the operation of the present invention, but, as will be appreciated by those skilled in the art, is an inherent (and undesirable) property of randomly mixed concrete.

It will also be appreciated by those skilled in the art that it is not uncommon for great differences in the consistency of mixed concrete to exist from one truckload of concrete to the next. Thus, even when the concrete which is poured from any particular truck is of relatively uniform consistency, there may be extremely wide variations in consistency of the poured concrete when a concrete slab is constructed from multiple-pours. Accordingly, in concrete slabs constructed from multiple-truckload pours, it is not uncommon for there to be relatively large variations in the consistency of the poured concrete in a horizontal plane, even while there may be relatively smaller variations in the consistency of the poured concrete in a vertical plane. Again, such variation in the consistency of poured concrete is not crucial to the operation of the present invention, but, as will be appreciated by those skilled in the art, is a frequently encountered (and undesirable) property of concrete slabs constructed from multiple-pours of concrete.

FIG. 2 is a graph illustrating a typical profile "firmness" gradient between the top and the bottom of the slab at the instant at which the concrete mass M is first poured.

When concrete slabs (and similar structures) are placed, it is conventional practice to employ a concrete mass which initially has far more moisture content, is far less consolidated, and is far less firm than that which is necessary to begin finishing operations. These properties are initially desirable when placing a concrete structure because they render the concrete mass much more "liquid-like" and workable than would otherwise be the case. In addition, the initial surplus of water in the concrete mass has the effect of preventing or retarding the (undesirable) premature curing of the concrete mass. After the overly moist, "liquid-like" concrete mass is poured into place and is roughly brought to the desired depth and shape of the slab, it is then necessary for the excess water to be removed, and for the concrete mass to become more consolidated and more "firm" before finishing operations can be commenced.

As indicated by the irregular line 50 in FIG. 2, at the instant at which the concrete mass is first poured, the firmness of the concrete mass may vary somewhat from the top of the slab to the bottom, but on average it is virtually constant from the bottom of the slab to the top.

Line 70 represents a value of constant firmness in FIGS. 2, 4, 7, 9 and 11, and is representative of the minimum value of "firmness" of the concrete mass which is desirable to be obtained before commencing finishing operations. Also, as discussed previously (above), line 70 generally corresponds to a degree of "firmness" above which the concrete mass may be characterized as acting more like a solid, and below which the concrete mass may be characterized as acting more like a liquid. As indicated in FIG. 2, at the instant at which the concrete mass is first poured, the entire concrete mass is less firm than the minimum desirable value, represented by line 70.

Referring now to FIG. 3: After the concrete mass M has been poured onto the sub-base B into the form of a slab, the weight of the aggregates (not shown) which comprise the concrete mass naturally push downward toward the sub-base B. The aggregates, being of relatively high density, begin to squeeze water and entrapped air out of the concrete mass M. Because there is more pressure near the bottom 2 of the slab than near the top 1 of the slab, more of the water and entrapped air is initially squeezed out of the concrete mass near the bottom of the slab than near the top of the slab, thus resulting in relatively more consolidated, relatively more firm and relatively drier concrete M1 near the bottom 2 of the slab, and relatively less consolidated, relatively less firm and relatively less dry concrete M2 nearer the top 1 of the slab.

FIG. 4 is a graph illustrating a typical profile firmness gradient between the top and the bottom of the slab after the concrete mass M is first poured and natural de-watering has begun. As illustrated in FIG. 4, after natural de-watering has begun, the firmness of the concrete mass is generally greater nearer the bottom of the slab (as indicated by line segment 53) and is generally less nearer the top of the slab (as indicated by line segment 51). Between line segment 51 and line segment 53 is a relatively more flat line segment 52 which corresponds to a transition zone L between the relatively more firm concrete mass M1 nearer the bottom of the slab 2 and the relatively less firm concrete mass M2 nearer the top of the slab 1.

It may be interpreted from a review of FIG. 4 that the relatively less firm concrete mass M2 may be characterized as having predominantly liquid-like properties. Furthermore, because (on average) the water-to-solids ratio in the (liquid) concrete mass M2 decreases with increased depth below the top of the slab, (due to natural de-watering), the firmness of the (liquid) concrete mass M2 may be somewhat less firm nearer the top of the slab than nearer the transition zone L. It may also be understood from a review of FIG. 4 that the relatively more firm concrete mass M1 may be characterized as having predominantly solid-like properties.

Since the concrete mass M2 (i.e. above the transition zone L) is effectively a liquid, and since the concrete mass M1 (i.e. below the transition zone) is effectively a solid, the natural resonant frequency of the (liquid) concrete mass M2 above the transition zone L will, in most instances, be different from the natural resonant frequency of the (solid) concrete mass M1 below the transition zone. In any event, whether the natural resonant frequencies of the (liquid) concrete mass M2 and the (solid) concrete mass M1 are identical or different, the speed of sound (i.e. the rate of propagation of vibrations) through the former will in all cases be different from (i.e. slower than) the speed of sound through the latter. In addition, due to the difference in the natural acoustical impedance between the (liquid) concrete mass M2 and the (solid) concrete mass M1, any mechanical vibration introduced directly into the (liquid) concrete mass M2 will predominantly stay within the (liquid) concrete mass M2, and, accordingly, may have a much greater effect on the (liquid) concrete mass M2 than on the (solid) concrete mass M1.

Referring again to FIG. 3: At the surface 1 of the concrete slab there typically develops a finishing zone 7 which preferably is no more than 1/4 inch thick. In the finishing zone 7 migrated water may collect throughout the placing operation. Also, finishing operations (which will be described in more detail later) may be used which effect a relatively higher concentration of "fines" and "superfines", and a relatively lower concentration of aggregates, in the finishing zone 7 than in the rest of the concrete mass M.

Between the relatively more consolidated, relatively more firm and relatively drier (solid) concrete mass M1 near the bottom 2 of the slab and the relatively less consolidated, relatively less firm and relatively less dry (liquid) concrete mass M2 nearer the top 1 of the slab, is a transition zone L. For purposes of understanding the present disclosure, the transition zone L may be interpreted as representing a boundary layer above which the concrete mass M2 exhibits liquid-like properties and below which the concrete mass M1 exhibits solid-like properties. In the transition zone L the average firmness gradient (i.e. the change in firmness divided by the change in elevation) is typically significantly greater than the average firmness gradients in the (solid) concrete mass M1 at the bottom of the slab and the (liquid) concrete mass M2 at the top of the slab. In practice the transition zone L may be either a relatively narrow layer (measuring, perhaps, only a millimeter thick) or a relatively thick zone, depending on the properties of the concrete mass and its environment.

Because of the inconsistencies inherent in the mixing and pouring of concrete, the depth of the transition zone L which naturally occurs in a poured slab is notoriously uneven, as illustrated in FIG. 3. In addition, there may exist wide variations in the depths of the transition zone L from one area of the concrete slab to another, (i.e. between horizontally separated areas of the concrete slab). Such wide variations in the depth of the transition zone L from one area of the concrete slab to another may occur, for example, whenever a single concrete slab is poured from a plurality of truckloads of mixed concrete. It will be appreciated by those skilled in the art that the curing rate (and, therefore, the strength and consistency) of the concrete mass M will normally vary depending upon the depth of the transition zone L below the top surface 1 of the slab. More specifically, in a given vertical segment of the concrete slab, the greater the depth below the surface 1 to the bottom of the insufficiently consolidated, insufficiently firm and insufficiently dry (liquid) concrete mass M2, the longer the curing time for that particular vertical segment of the concrete slab.

[For purposes of simplifying the explanation and understanding of the present invention, three sub-surface areas of the poured concrete mass M are referred to in this disclosure, namely the areas designated in the figures as M1, M2 and L. Although the concrete mass in each of these designated areas (M1, M2 and L) has individually definable physical properties (i.e. degree of consolidation, firmness, etc.), it should be understood that adjacent "layers" of the concrete mass are continuous, are intrinsically interconnected with each other, and together may form a single concrete slab.]

Referring now to FIG. 5: A vibrator apparatus (generally designated 3 in the figures, and hereinafter referred to in its entirety as the "Apparatus") capable of introducing vibrations into the concrete mass M moves across the top surface 1 of the slab in the forward direction (indicated by arrow 4 in the figures). As the Apparatus 3 is activated, it introduces vibrations (at a first frequency) into the concrete mass M beneath the vibrator Apparatus 3, which causes water and air entrapped inside of the concrete mass M to migrate upwards towards the top surface 1 of the slab. The frequency of vibrations which is introduced into the concrete mass M during this first pass (or "stage") may advantageously be preselected (based, for example, upon prior experience with concrete slabs having similar water content, similar thickness, similar aggregate size, etc.) to be within the range of natural resonant frequencies of the (liquid) concrete mass M2 which are typical for such newly poured slabs.

As the water and air migrate upward due to the vibrations, the depth of the relatively more consolidated, relatively more firm and relatively drier (solid) concrete mass M1 near the bottom 2 of the slab rises, and, correspondingly, the depth of the transition zone La across the slab also rises. It will be appreciated by those skilled in the art that as the depth of the relatively more consolidated, relatively more firm and relatively drier (solid) concrete mass M1 near the bottom 2 of the slab rises, the natural resonant frequency of this portion of the concrete mass M1 changes; and, as the thickness of the relatively less consolidated, relatively more wet (liquid) concrete mass M2 near the top of the slab decreases, the natural resonant frequency of this portion of the concrete mass M2 also changes. More specifically, as the thickness of the relatively less consolidated and relatively more wet (liquid) concrete mass M2 becomes thinner, its natural resonant frequency increases.

FIG. 6 illustrates the condition of the concrete slab after the Apparatus 3 has completed a first pass or first "stage" of vibration of the concrete mass M. It will be understood that the volume of the sufficiently consolidated, sufficiently firm and sufficiently dry (solid) concrete mass M1 is greater after the first stage of vibration is completed (as indicated by dimension D2 in FIG. 6) than existed prior to the first stage of vibration (as indicated by dimension D1 in FIG. 3).

FIG. 7 illustrates a typical profile firmness gradient between the top and the bottom of the slab shortly after the vibrator Apparatus has completed a first pass across the concrete mass. As illustrated in FIG. 7, shortly after the vibrator Apparatus has completed a first pass across the concrete slab, the (solid) concrete mass M1 beneath the transition zone La has not only become deeper, but also somewhat more firm, than was the case prior to the first pass of the vibrator (as indicated by line segment 56 in FIG. 7, as contrasted to corresponding line segment 53 in FIG. 4). The reason the depth of the (solid) concrete mass M1 increases after the Apparatus 3 has introduced vibrations is that, by vibrating the concrete mass, the upward migration of the excess water in the concrete mass is accelerated (relative to the rate of water migration which would naturally occur if left un-vibrated). It has been observed that when a liquid concrete mass (such as concrete mass M2) is vibrated, excess water which may be between the various solid constituents of the concrete mass (i.e. aggregate, cement, etc.) percolates upward toward the top surface of the slab at an accelerated rate so long as there is sufficient quantity of water in the vibrated concrete mass to separate the individual solid constituents from each other. In a sense, the excess water lubricates the solid constituents of the (liquid) concrete mass, giving the mass the characteristics of a liquid. When a sufficient amount of water is removed from the concrete mass, the water can no longer adequately lubricate the solid constituents of the concrete mass, and the individual solid constituents begin to mechanically "lock up" against one another. Once a sufficient amount of water has been removed from a portion of the concrete mass to allow the individual solid constituents to mechanically lock up against one another, that portion of the concrete mass begins to exhibit the characteristics of a solid.

The reason the (solid) concrete mass M1 becomes more firm after the concrete mass has been vibrated by the vibrator Apparatus (as indicated by line segment 56 in FIG. 7) than would occur, for example, due to natural de-watering (as indicated by line segment 53 in FIG. 4), is that, by vibrating the individual constituent solids in the concrete mass, the individual constituent solids can move into voids, thus facilitating greater consolidation and greater "locking up" of the constituent solids. Referring now to FIG. 8: After the transition zone La has been somewhat raised, by the first pass or "stage" of vibration, the same (or a similar) vibrator Apparatus 3 may then be used for a second pass or "stage" of vibration, as shown in FIG. 8, to further raise the transition zone Lb, and thereby increase the thickness of the relatively more consolidated, relatively more firm and relatively drier (solid) concrete mass M1 below the transition zone Lb and decrease the thickness of the relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete M2 mass near the top of the slab.

The frequency of the vibrations introduced into the concrete mass during the second pass is preferably set at a second frequency, corresponding to the natural resonant frequency of the relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete mass M2. By adjusting the frequency of the vibrations to be introduced into the concrete mass during the second pass (i.e. from the first frequency to the second frequency) to correspond to the natural resonant frequency of the (liquid) concrete mass M2 which is above the transition zone La, the amount of energy necessary to sufficiently vibrate the (liquid) concrete mass M2 to cause consolidation and upward migration of water can be minimized. Also, as will be appreciated by those skilled in the art, because the resonant frequency of the relatively more consolidated (solid) concrete mass M1 below the transition zone in most cases significantly differs from the resonant frequency of the (liquid) concrete mass M2 above the transition zone, and because of the difference in the acoustic impedance between the (liquid) concrete mass M2 and the (solid) concrete mass M1, the Apparatus-introduced vibrations will have far more effect (i.e. will cause more severe vibration, and, therefore, more particle consolidation and water migration) within the (liquid) concrete mass M2 near the top of the slab than within the (solid) concrete mass M1 near the bottom of the slab. Thus, by introducing vibrational energy into the (liquid) concrete mass M2 at or near the natural resonant frequency of the (liquid) concrete mass M2, it is possible to minimize the amount of vibrational energy which is required to effect the desired consolidation of the constituent solids of the concrete mass (because vibrating the concrete mass at or near its resonant frequency produces more amplitude with less energy than at other frequencies which are less efficient).

Not only may the amount of vibrational energy introduced into the concrete mass M be reduced because of the increased efficiency of transmission through the relatively wet concrete mass M2, but also because the (liquid) concrete mass M2 (i.e. that portion of the concrete which still needs to be consolidated, dried and "firmed up") comprises only a fraction of the entire mass of the slab. In other words, in accordance with the present invention, it is not necessary to introduce enough energy to excite the entire concrete slab; rather, it is only necessary to excite the "liquid" portion of the entire concrete slab.

It will be understood that by minimizing the amount of vibrational energy introduced by the Apparatus into the concrete mass M, the power requirements, as well as the structural and maintenance requirements, of the Apparatus may be reduced.

It is further understood that by applying controlled vibrations into the concrete mass M in the manner described above, the consolidation and drying of the concrete mass M is expedited relative to that which would naturally occur from natural gravitational settling of the concrete mass.

In addition to more rapidly consolidating and drying the concrete mass M, the structural integrity of the slab is improved by the disclosed method. The structural integrity of the slab is improved by use of the present invention due to the improved consistency of consolidation, (represented by the substantially horizontal orientation of the transition zone Lb in FIG. 8, and as indicated by vertical line segment 59 in FIG. 9); and due to the expedited migration (and subsequent removal) of water and entrapped air from the concrete mass which advantageously results in less entrapped water and air pockets in the concrete slab; and due to the greater degree of consolidation of the constituent solids of the concrete mass facilitated by the vibration/movement of the constituent solids.

Subsequent to the second stage (as shown in FIG. 8) and prior to a final stage (as shown in FIG. 10), there may be any number of intermediate stages (or passes of the vibrator Apparatus) as may be desirable depending on the properties of the particular slab being placed. Generally, the thicker the slab the more stages that are required. It will be understood from the above disclosure of the present invention that by adjusting the frequency of the vibrations introduced into the concrete mass during each pass to correspond to (or nearly to) the natural resonant frequency (during that particular pass) of the relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete mass M2, the drying and curing of the slab can be expedited, and the resulting structure will be of substantially uniform composition.

Referring now to FIG. 10: Preferably, upon completion of a final "stage" of vibration or a final pass of the vibrator Apparatus across the surface 1 of the concrete slab, the depth of the sufficiently consolidated, sufficiently firm and sufficiently dry (solid) concrete mass M1 extends from the bottom of the slab 2 to (or nearly to) the finishing zone 7 at the top surface of the concrete slab 1. Typically, the water which had migrated toward the top of the slab 1 may accumulate in the finishing zone 7, and may subsequently simply evaporate, run off the slab due to gravity, be pushed off the slab by the vibrator Apparatus 3, be vacuumed, or otherwise removed.

It may be appreciated from an understanding of the foregoing disclosure that by using a method and apparatus of placing concrete in accordance with the disclosed invention, the transition zone L, (or more specifically the top of the sufficiently consolidated, firm and dry (solid) concrete mass M1), is evenly brought up toward the top surface of the concrete slab 1. Because the transition zone L, (or more specifically the top of the sufficiently consolidated, firm and dry (solid) concrete mass M1), is evenly brought up toward the top surface of the concrete slab 1, the entire top of the slab 1 (or more specifically, the finishing zone 7) attains the condition for finishing operations at substantially the same time. It will be understood from the foregoing disclosure that the optimal frequency at which to introduce vibrations into the concrete slab during any one pass of the vibrator Apparatus is that frequency which corresponds to the natural resonant frequency of the relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete mass M2 beneath the Apparatus 3 during that particular pass. It will also be appreciated by those skilled in the art that the natural resonant frequency of the relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete mass M2 changes (i.e. increases) with each stage of vibration. Several schemes are disclosed below for accommodating variations and changes in the natural resonant frequency of the (liquid) concrete mass M2.

In one method of using the present invention a series of individual vibrator Apparatuses 3 may pass over the wet concrete at a predetermined fixed speed, with each individual vibrator Apparatus vibrating at a predetermined frequency and amplitude. As an example, there might be three such vibrator Apparatuses 3, the first of which vibrates at a relatively low fixed frequency. A second vibrator Apparatus, passing across the surface of the still-wet concrete after the first vibrator Apparatus has passed, might vibrate at a somewhat higher fixed frequency. A third vibrator Apparatus might vibrate at an even higher fixed frequency. The predetermined frequencies and amplitude of vibration and the speed at which the vibrator Apparatuses move would advantageously be chosen based on experience with concrete of various "slumps", thicknesses, and other factors. More particularly, the predetermined frequency of each vibrator would preferably be set to fall within the range of resonance frequencies typical of unconsolidated, liquid concrete having a thickness corresponding to the expected liquid concrete thickness for which each particular vibrator is used. The individual Apparatuses 3c may be secured to each other (for example by rigid link member 12), as illustrated in FIG. 19; in which instance, of course, all three Apparatuses 3c would travel at the same speed.

A modification of the above method of using the present invention is to employ vibrator Apparatuses which produce vibrations at user-selectable (i.e. variable) frequencies. Vibrators with user-adjustable frequency outputs are well known in other arts. By passing a series of vibrating members over liquid concrete at a speed, frequency and amplitude which is set in the field (i.e. at the job site) by the operator, the user has much more flexibility and could, therefore, custom-set the vibrator output to correspond to the prevailing conditions of the concrete slab. The specific frequencies and amplitude of vibration and the speed at which the apparatuses move would be based on the design thickness, aggregate size, and measured slump, temperature and/or other factors which are relatively easy to determine at the job site. With this method, it may be desirable, for example, to use either fewer or more vibrator apparatuses depending whether the concrete mass is relatively thin or thick, respectively.

For optimal performance, the frequency of the output vibrations from the Apparatus 3 should be adjusted to fall within the range of resonance frequencies typical of unconsolidated, liquid concrete having a thickness, slump, aggregate size, etc., corresponding to the expected liquid concrete thickness beneath each vibrating member. This method has the advantage of being adjustable to meet the conditions found at the specific job site. As with the above mentioned non-adjustable method, no sensors are required to directly measure the resonant frequency of the liquid concrete mass M2, as the choice of vibrator Apparatus output frequency would be made based, instead, on the design factors and other measurable field conditions, such as the thickness of the (liquid) concrete mass M2. A limitation of this method is that it does not take into account variations in the concrete mass which may not be obvious to an observer.

As will be understood from the foregoing disclosure, the optimal frequency at which to vibrate the placed concrete mass is that frequency which corresponds to the natural resonant frequency of the relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete mass M2 beneath the vibrator Apparatus 3. It will also be understood that, as the thickness of the layer of relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete mass M2 becomes thinner, its natural resonant frequency correspondingly changes (i.e. increases).

In the embodiment of the invention illustrated in FIGS. 5, 8 and 10, the Apparatus 3 comprises sensors 5 which extend from a rigid frame 80. The sensors 5 are in electrical communication with a processor unit 6 which is preferably supported from and secured to the rigid frame 80. Based upon data provided by the sensors 5, the processor unit 6 determines the natural resonant frequency of the relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete mass M2 beneath the vibrator Apparatus 3. The electronic controller circuitry 96, which is in electrical communication with the processor unit 6, adjusts the output frequency of a magnetostrictive actuator 81 excited rigid vibrator member 82 to correspond to the determined resonant frequency of the (liquid) concrete mass M2 beneath the vibrator Apparatus 3. The vibrator member 82, which is preferably a rigid plate, is in direct contact with the (liquid) concrete mass M2, and vibrates the (liquid) concrete mass M2 at the output frequency of the magnetostrictive actuator 81 (i.e. preferably at or near the resonant frequency of the (liquid) concrete mass). The entire Apparatus 3 may be supported and be horizontally driven by a boom or rail system 93 or similar means, by attachment to the rigid frame 80.

Two alternative methods for determining the instantaneous resonance frequency of the relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete mass M2 beneath the Apparatus 3 are disclosed below.

In one method for determining the instantaneous resonance frequency of the (liquid) concrete mass M2 beneath the Apparatus 3 illustrated in FIGS. 5, 8 and 10, a sensor (or sensors) 5 in communication with the processor unit 6 monitor the time required for a wavefront ("pulse") to travel through the (liquid) mass M2, reflect off the boundary layer L, and return to the sensor(s). The processor unit 6 then determines the depth of the transition zone L from the speed of sound in liquid concrete and the time required for the wavefront ("pulse") to return. By cross-indexing the determined depth of the transition zone L to empirical data permanently stored in the processing unit 6, the processing unit 6 can determine the approximate resonant frequency of the relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete mass M2 beneath the sensor 5. The electronic controller circuitry 96 then adjusts the frequency of the vibration and/or the amplitude of the vibration of the magnetostrictive actuated vibrator member 82, and/or the duration of the vibration (i.e. by varying the forward speed of the Apparatus 3), as necessary to effect the desired shape and/or elevation of the transition zone La.

In a second method for determining the instantaneous resonant frequency of the (liquid) concrete mass M2 beneath the Apparatus 3 (as illustrated in FIGS. 5, 8 and 10), sensors 5 in communication with the processor unit 6 directly monitor the instantaneous natural frequency of the relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete mass M2 beneath the Apparatus 3 by measuring the response (principally the amplitude of vibrations in the vibrating concrete mass) to the vibrations introduced into the concrete slab by the Apparatus 3 over a range of frequencies. Generally, the response (i.e. the amplitude of the vibrating (liquid) concrete mass M2) will be greatest when the output frequency of the Apparatus 3 is at the natural resonant frequency (or one of its harmonics) of the relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete mass M2 beneath the vibrator Apparatus 3. The electronic controller circuitry 96 which is in communication with the processing unit 6 then adjusts the frequency of the vibration and/or the amplitude of the vibration of the magnetostrictive actuated vibrator member 82, and/or the duration of the vibration (i.e. by varying the forward speed of the Apparatus 3), as necessary to effect the desired shape and/or elevation of the transition zone La. In this method for determining the instantaneous resonant frequency of the (liquid) concrete mass M2 beneath the Apparatus 3, the sensors 5 measure the response (i.e. the efficiency of transmission) to a range of "test" frequencies, and, in effect, chooses that frequency which causes the greatest response (i.e. corresponding to the resonant frequency of the (liquid) concrete mass M2). The "test" frequencies used in this method for determining the instantaneous resonant frequency of the (liquid) concrete mass M2 beneath the Apparatus can either be generated directly by the vibrator member 82 (as illustrated in FIGS. 5, 8 and 10), or by a secondary sensor transmitter 83, as shown in FIG. 12. In the preferred embodiment of the invention, as illustrated in FIG. 12, the frequency range of the "test" vibrations which emanate from the sensor transmitter 83 may be adjusted by electronic controller circuitry 96 which is in communication with the processor unit 6b.

Referring now to FIG. 13: Another modification of the invention is illustrated in FIG. 13. In this modification of the invention the vibrator Apparatus 3a comprises a rigid frame 80 to which is secured a magnetostrictive actuator 81 which oscillates vibrator member 82. A processor unit 6a is also secured to the rigid frame 80. The processor unit 6a and magnetostrictive actuator 81 are powered by electrical energy provided by an external power source (not shown) via electrical conductor 63. A sensor (such as an ammeter or voltmeter) monitors the electrical current (and/or voltage) required to oscillate the magnetostrictive actuated vibrator member 82. It will be appreciated that, in operation, since the vibrator member 82 is in direct contact with the (liquid) concrete mass M2, the energy necessary to maintain oscillation of the vibrator member 82 will be minimized when the vibrator member 82 oscillates at or near the natural resonant frequency of the (liquid) concrete mass M2. Therefore, by simultaneously adjusting the output frequency of the magnetostrictive actuator 81 and monitoring its electrical (i.e. current and/or voltage) demand, it is possible for the processor unit 6 to directly determine the natural resonant frequency of the (liquid) concrete mass M2 adjacent the vibrator member 82. The electronic controller circuitry 96, in communication with the processor unit 6 and the magnetostrictive actuator 81, maintains the output frequency of the magnetostrictive actuated vibrator member 82 at that frequency corresponding to the minimum electrical (i.e. current and/or voltage) demand of the magnetostrictive actuator 81. This corresponds to a vibrator member 82 output frequency which is nearly equivalent to (or a harmonic of) the natural resonant frequency of the (liquid) concrete mass M2 adjacent the vibrator member 82. When the natural resonant frequency of the (liquid) concrete mass M2 changes, more energy will be required for the magnetostrictive actuator 81 to vibrate the vibrator member 82, (due to interference of the non-resonant vibration waves) and, accordingly, the electrical demand of the magnetostrictive actuator 81 will increase. This increase in electrical demand will be sensed by an ammeter or voltmeter (not shown). When the electrical demand for the magnetostrictive actuator 81 exceeds a predetermined level, the electronic controller circuitry 96a will cause the output frequency of the magnetostrictive actuator 81 to vary (i.e. increase) until the electrical demand again drops below the predetermined level. It will be appreciated that in this embodiment of the invention, the processor unit 6, the ammeter or voltmeter (not shown) and the magnetostrictive actuated vibrator member 82 fulfill the dual purposes of introducing vibrations into the (liquid) concrete mass and "sensing" the resonant frequency of that mass. Alternatively, the processor and electronic controller circuitry may cause the magnetostrictive vibrator to periodically "sweep" the frequency range, with the ammeter or voltmeter input to the processor and electronic controller being used to make periodic adjustments to the magnetostrictive vibrator frequency.

The present invention not only expedites the consolidation of the concrete mass M2 and the migration of the water from the interior of the concrete mass M2 to the surface by applying vibrational energy at or near the resonant frequency of the (liquid) concrete mass M2, but it also can be used to restrict the premature hardening of relatively shallow areas of moist and unconsolidated concrete by reducing the effects of (non-resonant) vibrational energy imparted into such shallow areas. It may be appreciated that if constant vibrational forces at random frequencies were equally imparted into all areas of a heterogenous concrete mass (i.e. of varying water-to-cement ratios, or of varying thicknesses, etc.), the transition zone would approach the surface of the slab earlier in some areas than in other areas, thus having the undesirable effect of causing "hard spots" in the concrete mass. Hard spots in concrete typically cause uneven curing, increased cracking of the slab, increase the difficulty of finishing operations, virtually preclude the use of automatic finishing equipment, and significantly reduce the structural integrity of the slab. By adjusting the vibrational energy imparted into various areas of the concrete mass M so as to evenly bring the transition zone L towards the surface 1 of the slab, a concrete slab made with the method and apparatus of the present invention has fewer (or no) hard spots, is more easily finished, has fewer cracks, and is structurally stronger than concrete slabs produced using either uncontrolled vibrations or using no vibrational input.

The disclosed staged vibration method and apparatus for placing concrete is effective due to the reaction of wet (or liquid) concrete to vibration. During vibration, the water, air and certain finer and lighter materials migrate upward, with the materials' migration being affected by the characteristics of the vibration, including the amplitude, frequency and duration of the vibration. The characteristics of the vibration are adjusted in the present invention to consolidate, or "firm up" the (liquid) concrete mass M2 at a controlled rate.

It will be understood from the foregoing disclosure that the optimal frequency at which to introduce vibrations into the plastic concrete slab is the natural resonant frequency of the (liquid) concrete mass M2 beneath the vibrator Apparatus 3. It has been found that if the output frequency of the Apparatus, (or more specifically, the frequency of vibration of the vibrator member 82) is not within 25% of the natural resonant frequency of the (liquid) concrete mass M2, or a harmonic of the natural resonant frequency, the energy imparted by the vibrator member into the concrete mass is quickly dissipated, and may be largely ineffective at exciting the constituent particles of the (liquid) concrete mass. Thus, unless the frequency of vibration of the vibrator member 82 is within 25% of a harmonic of the natural resonant frequency of the (liquid) concrete mass with which it is in contact, an undesirably large amount of energy will be required to vibrate the concrete mass to effect accelerated consolidation and "firming up" of the (liquid) concrete mass M2. Accordingly, in all embodiments of the present invention, it is preferable for the output frequency of the magnetostrictive actuated vibrator member 82 to be within 25% of the natural resonant frequency of the (liquid) concrete mass M2 or a harmonic of the natural resonant frequency. By introducing vibrations into the concrete mass at or near (i.e. with 25% of) the natural resonant frequency of the liquid concrete mass M2, the power requirements for the vibrator Apparatus can be minimized, because energy introduced into the concrete mass at or near the resonant frequency of the still-wet and unconsolidated concrete will result in greater amplitudes of vibration of the (liquid) concrete mass M2 for a given energy input level than would be true at any other frequency.

Representative ranges of the frequencies needed to set common thicknesses of concrete have been determined. To rapidly set the slab, the sound waves (i.e. vibrations) through the liquid concrete mass M2 need to cause the solid particles to move and shift position until they lock in place. The frequencies needed are quite closely related to the wavelength of the sound through the liquid concrete mass M2 and to the thickness of the liquid concrete mass M2. The following table shows representative calculated values of the resonant frequency needed to accelerate setting of wet, unconsolidated concrete layers of various thicknesses:

______________________________________Unset Thickness Frequency Range (Hz)(inches) Minimum Maximum______________________________________ 1/4 21600 43200 1/2 10800 216001 5400 108002 2700 54003 1800 36004 1350 27005 1080 21606 900 18007 770 15408 675 13509 600 120010 540 108011 490 98012 450 900______________________________________

While there is no single frequency that will give perfect results but rather an effective frequency band range, vibrating the relatively less consolidated, relatively less firm and relatively more wet (liquid) concrete mass M2 in the effective resonant range permits the use of much lower power vibrators to achieve the desired effect. Because the resonant frequency of the (liquid) concrete mass M2 typically increases when the thickness of the (liquid) concrete mass M2 decreases, and because the thickness of the (liquid) concrete mass typically decreases during each "stage" of vibration, it is advantageous for the vibrator Apparatus to introduce vibrations into the concrete mass either at the instantaneous resonant frequency of the (liquid) concrete mass M2 during each stage, or, alternatively, at a frequency slightly higher than the resonant frequency of the (liquid) concrete mass M2 at the beginning of each stage. In the latter case the vibrator Apparatus output frequency may be advantageously selected to correspond to the resonant frequency of the (liquid) concrete mass M2 when the (liquid) concrete mass M2 is at a thickness intermediately between the beginning and the end of each stage.

As will be appreciated by those skilled in the art, prior concrete placing vibrators typically comprise small gasoline powered engines which have output frequencies of less than 1500 rpm (25 Hz). It will be understood from review of the above table that even in the case of relatively thick (12-inch) liquid concrete slabs, the natural resonant frequency (450 Hz) of liquid concrete is at least 18 times as high as the maximum output frequency of prior concrete placing vibrators; and for most common concrete slabs the resonant frequency of the liquid concrete mass is more than 100 times the output frequency of prior concrete placing vibrators.

Because the natural resonant frequency of (liquid) concrete in commonly-encountered thicknesses (i.e. 1/4" to 12") is so high (i.e. up to and above 25,000 Hz.), the present invention preferably comprises magnetostrictive actuators which are well-suited to these relatively high output frequencies, rather than, for example, internal combustion engines.

While the foregoing describes the use of the present invention in placing a horizontal concrete slab of substantially constant thickness using a single pour of concrete, it should be understood that the application of this method and apparatus to the placing of slabs having substantially flat inclined top surfaces, and to the placing of slabs on top of uneven or inclined sub-bases are within the scope of the present invention. In addition, the described method and apparatus also has application to the placing of concrete slabs which have integrally bonded toppings, wherein a second pour of concrete (i.e. topping) may be introduced on top of a first concrete pour. In the placing of a concrete slab having an integrally bonded topping, the second concrete pour is preferably made after initial series of staged vibrations have been introduced to the first-poured concrete in accordance with the present invention, but before the boundary layer reaches too close to the top of the first-poured concrete mass. For the sake of facilitating an understanding of the construction and operation of the present invention, the drawing figures (i.e. FIGS. 1-13 and 19) and the above specification describe the manner in which a vibrator Apparatus constructed in accordance with the present invention affects the properties of a typical cross-section of a poured concrete slab, said cross-section taken along the longitudinal path of the Apparatus as it travels over the concrete slab. It will be appreciated by those skilled in the art that the properties (such as moisture content, firmness, elevation of the transition zone, etc.) of the concrete mass M may (and in most cases will) also vary transversely to the direction of travel of the vibrator Apparatus for the same reasons discussed above with respect to such variations parallel to the direction of travel of the vibrator Apparatus. Accordingly it should be understood that it is within the scope of the present invention to provide a plurality of vibrator Apparatuses, each constructed in accordance with the present invention, beside each other and physically secured together (not shown); or, alternatively, to provide a vibrator Apparatus comprising a single processor unit, but having a plurality of individual magnetostrictive actuated rigid vibrator members laterally separated from each and supported from a common frame (not shown). By arranging the present invention in either of these two manners, variations in the properties of the concrete mass, both transverse to the direction of travel of the apparatus(es) as well as parallel to the direction of travel of the apparatus(es), may be independently accommodated.

SUMMARY OF THE PREFERRED METHODS OF PRACTICING THE INVENTION

The disclosed methods of practicing the present invention are summarized below. Individual steps are denoted by three-digit reference indicia in the corresponding drawing figures. Referring now to FIGS. 14 and 19: In the simplest method of practicing the present invention, a vibrator Apparatus 3c having a rigid vibrator member 82 which vibrates at a fixed frequency and amplitude is placed 100 on the top surface 1 of a (liquid) concrete mass M2. The rigid vibrator member 82 vibrates 101 at a fixed frequency and amplitude (which is ideally at or near the natural resonant frequency of the (liquid) concrete mass M2 or a harmonic of the natural resonant frequency). Then, an Operator sets 102 the travel speed of the Apparatus 3c, based on the thickness of the concrete mass and other properties, and the vibrator Apparatus 3c travels 103 across the surface of the (liquid) concrete mass.

Referring now to FIGS. 5 and 15: In an "adjustable mode" of practicing the present invention, a vibrator Apparatus 3 is placed 201 on the top surface of a (liquid) concrete mass M2. The Apparatus 3 has an adjustable-frequency (and adjustable amplitude) magnetostrictive actuated rigid vibrator member 82. An operator determines 202 the probable natural resonant frequency of the (liquid) concrete mass, based on tables or similar sources. The Operator then sets 203 the output frequency of the Apparatus at or near the determined natural resonant frequency or a harmonic of the natural resonant frequency. The Operator may then set 204 the output amplitude of the Apparatus, based on the thickness of the (liquid) concrete mass and/or other properties. The Operator also may set 205 the travel speed of the Apparatus, based on the thickness of the (liquid) concrete mass and/or other properties. The vibrator Apparatus 3 then vibrates 206 at the frequency and amplitude set by the operator, then travels 207 across the surface of the (liquid) concrete mass. The operator may repeat this process as often as he desires or feels necessary (for example, whenever he makes a new "pass" over the same concrete, or otherwise has reason to believe that the properties of the (liquid) concrete have changed).

Referring now to FIGS. 5 and 16: The invention may also be practiced in what may be described as a "boundary layer" mode, as illustrated in FIG. 16. In this method of practicing the present invention, a vibrator Apparatus 3 comprising a sensor 5 in communication with a processor unit 6 determines the depth of the transition zone L, and the processor, together with an electronic controller circuitry 96, adjusts the output of the rigid vibrator member 82 to the optimal frequency and amplitude. As illustrated in FIG. 16, a vibrator Apparatus 3 is placed 301 on the top surface of the (liquid) concrete mass. A sensor 5, (which in actuality may be a transmitter/receiver or separate transmitter and receiver), vibrates 302 at a predetermined frequency for a short duration. The sensor 5 then measures 303 the time to receive the echo. A processor unit 6 determines 304 the distance to the transition zone L, based upon the speed of sound in concrete, and then the processor unit 6 estimates 305 the natural resonant frequency from empirical data. The processor, together with the electronic controller circuitry 96 then sets 306 the vibration amplitude, based on the thickness and other properties of the (liquid) concrete mass. The processor 6 may then set 307 the travel speed of the Apparatus, based on the thickness and other properties of the (liquid) concrete mass. The Apparatus 3 then vibrates 308 at a specified offset above the natural resonant frequency of the (liquid) concrete mass; and the vibrator Apparatus travels 309 across the surface of the (liquid) concrete mass. The amplitude and frequency of vibration and the speed of travel of the vibrator Apparatus may be periodically adjusted as the Apparatus 3 travels across the (liquid) concrete mass M2.

Referring now to FIGS. 12 and 17: The preferred embodiment of the invention may be operated in what may be termed a "pinger mode", as illustrated in FIG. 17. The vibrator Apparatus 3b is placed 401 on the top surface of the (liquid) concrete mass M2 with a magnetostrictive actuated vibrator member 82, a sensor transmitter 10, and a sensor receiver 5 each in contact with the (liquid) concrete mass M2. The sensor transmitter 10 sweeps 402 across a frequency range at constant amplitude. The sensor receiver 5 then measures 403 the echo amplitude at various frequencies. The processor unit 6 determines 404 the frequency with the highest echo amplitude, (which corresponds 405 to the natural resonant frequency of the (liquid) concrete mass M2). The processor 6 then sets 406 the vibration frequency of the magnetostrictive vibrator 81 to a specified offset above the natural resonant frequency of the (liquid) concrete mass, and sets the amplitude 407 of the magnetostrictive vibrator 81 and the travel speed 408 of the apparatus, based on the thickness and other properties of the (liquid) concrete mass. The vibrator member 82 then vibrates 409 at the specified frequency and amplitude; and the vibrator Apparatus 3b travels 410 across the surface of the (liquid) concrete mass. The amplitude and frequency of vibration and the speed of travel of the vibrator Apparatus 3b may be periodically adjusted as the Apparatus travels across the surface, in order to accomodate changing conditions within the (liquid) concrete mass M2. Alternatively, the processor unit 6 may determine 404a multiple points of resonance at different frequencies, and then the processor unit 6 determines 405a the natural resonant frequency of the (liquid) concrete mass, based on the difference between harmonic frequencies (The difference between harmonics being equal to the natural frequency itself). Then the processor sets the vibration frequency 406, amplitude, 407, and speed 408 as described above.

Referring now to FIGS. 13 and 18: The method of practicing the embodiment of the present invention which is illustrated in FIGS. 13 and 18 may be referred to as the "ammeter mode". The vibrator Apparatus 3a is placed 501 on the top surface of the (liquid) concrete mass M2. The magnetostrictive actuated rigid vibrator member 82 vibrates 502 over a range of frequencies for a short duration. A sensor, which essentially comprises an ammeter or voltmeter within the processor unit 6a, measures 503 the energy draw (either current or voltage draw) of the magnetostrictive actuator 81 at various frequencies. The processor unit 6a determines 504 the frequency with the lowest current draw, (which corresponds to the natural resonant frequency of the (liquid) concrete mass M2). The processor 6a then sets the vibration frequency 505 and amplitude 506 of the vibrator member 82, and the travel speed 507 of the apparatus, based on the thickness and other properties of the (liquid) concrete mass. The vibrator member 82 then vibrates 508 at a specified offset above the natural resonant frequency of the (liquid) concrete mass, and at the specified amplitude; and the Apparatus travels 509 across the surface of the (liquid) concrete mass M2. The amplitude and frequency of vibration and the speed of travel of the vibrator Apparatus 3a may be periodically adjusted as the Apparatus travels across the (liquid) concrete mass M2.

The foregoing is considered as illustrative only of the principles of the invention. Many other variations are possible, for example:

The frequency of the vibrations introduced by the vibrator Apparatus may be harmonics of the natural resonant frequency of the (liquid) concrete mass M2, rather than at the actual natural resonant frequency; and, The processor unit 6 (or 6a) may be remote from the rigid frame 80; The frame 80 need not be in contact with the concrete mass M, but may be supported (for example by the rail system 93) above the surface of the concrete mass; The rigid vibrator member 82 may be in contact with the surface of the liquid concrete mass, or may it may be in contact with the liquid concrete mass M2 beneath the top surface 1 of the concrete slab; The vibrator member 82 may be of various shapes (including rods, bars, plates, etc.); The vibrator member may utilize piezoelectric, electromagnetic, or magnetostrictive elements or it may be electrically powered (for example by rotary or reciprocating motor), or driven by internal or external combustion engines, or other means; and Because the resonant frequency for the wet concrete mass changes from a (lower) first frequency to a (higher) second frequency during each pass of the vibrator, it may be desirable to set the frequency of the vibrator Apparatus at an intermediate frequency between the first and second frequency during any given pass of the vibrator Apparatus.

Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation shown and described, and, accordingly, all suitable modifications and equivalents may be resorted to, falling within the scope of the invention. Accordingly, the scope of the invention should be determined not by the embodiment illustrated, but by the appended claims and their legal equivalents.

Claims

1. An apparatus for manufacturing a concrete structure comprising:

a horizontally movable rigid frame member (80);

a rigid tamping member (82) movably supported from said frame member (80);

means for vibrating said rigid tamping member at a plurality of output frequencies from a first frequency to a second frequency,

said means for vibrating said rigid tamping member comprising an actuator member (81) rigidly supported from said frame member (80), and means (96) for varying the output frequency of said tamping member (82) from said first frequency to said second frequency, said means (96) for adjusting the output frequency of said tamping member (82) being in electrical communication with said actuator member (81); and further comprising sensing means for measuring a natural resonant frequency dependent property of plastic concrete,

said sensing means comprising a sensor member (5) supported from said horizontally movable rigid frame member (80) for movement therewith;

and data processing means (6), in electrical communication with said sensor member (5) and said means (96) for varying the output frequency of said tamping member, for calculating a third frequency between said first frequency and said second frequency based on electrical signals from said sensor member (5);

and wherein said means (96) for varying the output frequency of said tamping member comprises means for adjusting the output frequency to said third frequency responsively to electrical signals from said data processing means (6).

2. The apparatus according to claim 1 wherein said third frequency is within 25% of a harmonic of a natural resonant frequency of plastic concrete.

3. The apparatus according to claim 1 wherein said first frequency and said second frequency are at least 6,000 vibrations per minute.

4. The apparatus according to claim 3 wherein said actuator member 81 comprises a magnetostrictive member.

5. The apparatus according to claim 4 further comprising means (93) for horizontally moving said rigid frame member (80).

6. The apparatus according to claim 4, wherein said first frequency and said second frequency are at least 27,000 vibrations per minute.

7. The apparatus according to claim 1, wherein said natural resonant frequency dependent property is an efficiency of vibrational energy propagation through a plastic concrete mass.

8. An apparatus for manufacturing a concrete structure comprising:

horizontally movable rigid frame member (80);

a rigid tamping member (82) movably supported from said frame member (80);

means for vibrating said rigid tamping member at an output frequency greater than 6,000 vibrations per minute,

said means for vibrating said rigid tamping member comprising a magnetostrictive actuator member (81) rigidly supported from said frame member (80), and electronic controller circuitry (96) in electrical communication with said magnetostrictive actuator member (81) for adjusting said output frequency;

and sensing means for measuring a natural resonant frequency dependent property of plastic concrete,

said sensing means comprising a sensor member (5) supported from said horizontally movable rigid frame member (80) for movement therewith;

and data processing means (6), in electrical communication with said sensor member (5) and said controller circuitry (96), for determining within 25% a harmonic of a natural resonant frequency of a plastic concrete mass based on electrical output signals from said sensor member (5);

and wherein said electronic controller circuitry (96) is electrically responsive to electrical output signals from said data processing means (96), and said magnetostrictive actuator member (80) is electrically responsive to electrical output signals from said electronic controller circuitry (96), such that said output frequency of said tamping member is responsive to said electrical output signals from said sensor member (5).

9. An apparatus (3a) for manufacturing a concrete structure comprising:

horizontally movable rigid frame member (80);

a rigid tamping member (82) movably supported from said frame member (80);

means for vibrating said rigid tamping member at a plurality of output frequencies between a first frequency and a second frequency,

said means for vibrating said rigid tamping member comprising a magnetostrictive actuator member (81) rigidly supported from said frame member (80) and movably attached to said rigid tamping member (82),

and said means for vibrating said rigid tamping member further comprising electronic controller circuitry (96a) in electrical communication with said magnetostrictive actuator member (81);

wherein said electronic controller circuitry (96a) comprises means for varying said output frequencies from said first frequency to said second frequency;

and further comprising processor means 6a, in electrical communication with said electronic controller circuitry and said magnetostrictive actuator member (81), for measuring electrical energy draw of said magnetostrictive actuator member (81) at said plurality of output frequencies and for determining a third frequency corresponding to a measurable minimum electrical energy draw to said magnetostrictive actuator member (81),

wherein said electronic controller circuitry (96a) further comprises means for adjusting an output frequency of said rigid tamping member (82) to said third frequency.

10. The apparatus according to claim 9 wherein said third frequency is within 25% of a harmonic of a natural resonant frequency of plastic concrete.

11. The apparatus according to claim 9 wherein said first frequency and said second frequency are at least 6,000 vibrations per minute.

12. The apparatus according to claim 11 wherein further comprising means (93) for horizontally moving said rigid frame member (80).