The invention relates generally to screed devices, and more particularly to a floating screed device that has a leading edge that can pivot to an angular position with respect to a trailing float.
Floating screeds are used to strike off and finish concrete floors or other horizontal surfaces. In general, a floating screed has a heavy planar float with an elongated edge defining a blade. The blade forms the leading edge of the screed that cuts through a volume of plastic concrete as the screed is pulled therethrough. Excess concrete that builds up on the blade side of the screed is raked away by workers standing in the unfinished concrete. As the float moves over an area of the concrete cut by the blade, the float serves to smooth the concrete thereby leaving a finished region of concrete that should be smooth, level, and at a specified elevation.
Typically, the unfinished concrete is adjacent to a section of finished concrete that has not yet cured. The floor finishers generally place a portion of the floating screed on the finished concrete thereby referencing one end of the screed to the finished elevation/grade plane. To make elevation corrections in the unfinished concrete, the floating screed is essentially lifted up/pushed down on the portion thereof that is in the unfinished concrete. While the goal is to place the screed at the same elevation as the finished concrete, this action tends to tilt the floating screed with respect to the desired finished elevation. Further, since the finished concrete is generally not yet fully cured, this tilting action also can cause the floating screed to dig into the finished concrete and/or damage the edge of the finished concrete where it interfaces with the unfinished concrete thereby necessitating repair work.
Accordingly, it is an object of the present invention to provide a floating screed device that can be controlled to produce smooth and level concrete surfaces at a desired elevation.
Another object of the present invention is to provide a floating screed device that can take advantage of a reference elevation defined by finished-but-uncured concrete without subjecting same to subsequent repair.
Other objects and advantages of the present invention will become more obvious hereinafter in the specification and drawings.
In accordance with the present invention, a floating screed device has a first section defining a leading edge for cutting through plastic concrete. A second section has a planar bottom for floating on the plastic concrete. A pivot is used to couple the first section to the second section such that the first section can move rotationally about the pivot relative to the second section. The pivot assures that the rotational movement of the first section is substantially perpendicular to the planar bottom of the second section. An elevation determining system coupled to the second section determines elevation of the second section relative to a datum that is typically indicative of a target elevation of the concrete. A mechanism coupled to the first section and second section supports the first section relative to the second section, and causes the first section to move rotationally about the pivot by an amount based on the elevation determined as the floating screed device is moved through a volume of the plastic concrete that is unfinished.
The first section's leading edge defines an initial contact edge between the floating screed device and the volume of the plastic concrete that is unfinished.
Other objects, features and advantages of the present invention will become apparent upon reference to the following description of the preferred embodiments and to the drawings, wherein corresponding reference characters indicate corresponding parts throughout the several views of the drawings and wherein:
Referring now to the drawings, and with simultaneous reference to
(i) an elongate float 12,
(ii) a bar 14 spaced apart from float 12 and substantially commensurate in length with float 12,
(iii) a pivot coupling (e.g., a pin) 16 that couples one end of bar 14 to a corresponding end of float 12 such that bar 14 can move in a rotational plane about pivot coupling 16 and relative to float 12,
(iv) a support and adjustment (“S/A”) mechanism 18 coupled to each of float 12 and bar 14 for maintaining the spaced-apart relationship therebetween and for adjusting the rotational-plane position of bar 14 relative to float 12; and
(v) an elevation determination system 20 coupled to float 12 for determining the elevation of float 12 and for providing such elevation to S/A mechanism 18 to thereby control the rotational-plane position of bar 14.
The functional relationships of the elements and the operation of floating screed device 10 will be explained in greater detail below.
Float 12 defines a planar bottom 12A that “floats” on a plastic concrete surface (not shown) to be finished. Float 12 can be substantially rectangular in cross-section (as shown), and can have a beveled, lower leading edge 12B to facilitate movement over concrete. However, float 12 can be defined by other geometric shapes without departing from the scope of the present invention. Float 12 can be hollow, solid, or filled with a granular material, a solid material, or a fluid.
Bar 14 is an elongate piece of stiff material movable by the combination of pivot coupling 16 and S/A mechanism 18.
More specifically, pivot coupling 16 and S/A mechanism 18 cooperate to move bar 14 in a rotational plane (indicated by two-headed curved arrow 22) that is substantially perpendicular to planar bottom 12A. Movement of bar 14 in a rotational plane that is substantially perpendicular to bottom 12A will generally result in an angular position of bar 14 with respect to bottom 12A. Bar 14 defines the leading edge of floating screed device 10 as screed device 10 is moved in the direction of arrow 30.
With respect to bar 14, its shape and construction details can be any that would allow bar 14 to cut through plastic concrete as floating screed device 10 was moved along direction 30. For example, bar 14 could be a rigid piece of solid or hollow material (e.g., metal, wood, composite, etc.), and can have a rectangular cross-section as shown. However, it is to be understood that the cross-sectional shape of bar 14 is not a limitation of the present invention.
Pivot coupling 16 is any device or combination of elements that attaches bar 14 to float 12 in a relationship that supports the rotational-plane movement thereof indicated by arrow 22. For example, pivot coupling could place bar 14 in a spaced-apart relationship with respect to float 12 as shown. However, the present invention is not so limited as pivot coupling 16 could also be designed to support bar 14 in an abutting but sliding relationship with float 12, i.e., no space between bar 14 and float 12. In practice, the amount of rotational-plane movement of bar 14 is relatively small (e.g., typically on the order of about 1° or less) as screed device 10 moves through wet concrete during a finishing operation. To minimize the impact of the lower corner 14A of bar 14 on wet concrete when bar 14 is angularly positioned (relative to a horizontal datum), pivot coupling 16 is located as close as possible to lower corner 14A and planar bottom 12A. Additionally or alternatively, lower corner 14A can be “clipped” or otherwise shaped/configured for minimal impact on wet concrete when bar 14 is angularly positioned relative to planar bottom 12A.
With respect to S/A mechanism 18, its design and construction can be any that supports bar 14 in its spaced-apart relationship with float 12, while also facilitating the above-described rotational-plane movement of bar 14 relative to float bottom 12A. S/A mechanism 18 would typically include a powered actuator (e.g., hydraulic, electric solenoid, etc.) that could be controlled/operated manually. However, in most applications, screed device 10 includes a height/level defining system (e.g., elevation determination system 20) coupled to S/A mechanism 18 to effect automatic rotational-plane movement of bar 14 as screed device 10 moves in the direction of arrow 30.
In accordance with the present invention, elevation determination system 20 is mounted to float 12 such that its elevation measurement location is substantially aligned with the point of actuation 18A of S/A mechanism 18 along the device's direction of travel indicated by arrow 30. System 20 can be part of a laser level system, the use of which in concrete floor construction is well known and understood. In general, elevation determination system 20 determines the height of float 12 (e.g., planar bottom 12A of float 12 aligned with point of actuation 18A) relative to a target height that ultimately is indicative of the finish elevation of the concrete.
It has been found that wet concrete tends to bubble up after the leading edge of a screed device passes over/through wet concrete. That is, the leading edge (i.e., bar 14) of a two-section screed device does not necessarily define the finish elevation of wet concrete. Accordingly, the present invention uses float 12 to set the ultimate finish elevation of the wet concrete as bar 14 is adjusted based on the elevation of float 12 relative to a datum or target elevation. By constructing the floating screed in this way, float 12 corrects the “bubbling concrete” condition to thereby finish the wet concrete to the desired elevation.
The output of system 20 is an amount of movement of bar 14 (i.e., relative to planar bottom 12A) required to achieve the target height as floating screed device 10 is moved in the direction of arrow 30. The output of system 20 is supplied to S/A mechanism 18 which, in turn, applies the requisite amount of up or down force to bar 14 to thereby angularly position bar 14 relative to planar bottom 12A. Thus, the present invention allows bar 14 to be tilted (with respect to planar bottom 12A) along the length thereof.
The above-described tilting or angular positioning of bar 14 is necessitated by the general nature of concrete finishing operations where a region of wet concrete is generally adjacent a region of concrete that is already at its finished elevation. Accordingly, one end of screed device 10 (i.e., near pivot coupling 16) is generally located on or next to the finished concrete while the remainder of screed device 10 resides on the wet concrete. In most applications, a screed operator will place one end of the screed device directly on concrete that has already been finished but has not yet cured (or “finished-but-uncured” concrete as it will also be referred to herein). By doing this, the portion of screed device 10 supporting S/A mechanism 18 and elevation determination system 20 can be tilted up or down relative to the finished concrete elevation. The present invention's ability to angularly position bar 14 relative to float bottom 12A during the screed process allows the screed device to direct float bottom 12A to the target or finish elevation as will now be explained with the aid of
The present invention improves concrete finishing as the floating screed device is more easily manipulated to a finished-concrete target elevation. To illustrate operation of the present invention, reference will now be made to
In use, whatever the orientation of planar bottom 12A of float 12 (e.g., horizontal and at the target elevation, tilted above/below the target elevation), the operational goal of screed device is to direct planar bottom 12A to ride on the concrete at the target elevation. In
In
In
Recognizing that screed operators prefer to use an edge of a finished region of concrete as a “one side” reference, the present invention can also be practiced by a floating screed device 50 illustrated in
The front face of float 12 can be configured to support multiple positions for pivot coupling 16. In this way, the floating screed device of the present invention can be adapted to work with finished regions of concrete on either side of an unfinished region of concrete by simple re-positioning of bar 14. Accordingly,
Owing to the weight and density of unfinished concrete, it is necessary for the rake workers (i.e., those workers standing in the unfinished concrete forward of the screed operator) to prevent any substantial build up of unfinished concrete just ahead of the screed as this makes the screed operator's job extremely difficult. To prevent a rake worker's removal of too much or too little unfinished concrete, a novel type of rake guide can be added to bar 14 to provide the rake workers with a guide that would prevent concrete build up at the blade's leading edge. The rake guide is illustrated in
Spacing between adjacent ones of fingers 70 is such that a rake worker's blade (not shown) will rest on at least two of fingers 70 when the rake blade is placed thereon. The protruding length of fingers 70 defines a region forward of bar 14 that will be free of concrete build-up as a rake worker pulls wet concrete therealong. The length of fingers 70 can be any reasonable length over which they remain rigid.
If the length of fingers 70 is such that it causes a change in the bar's balance, counter weights (not shown) can be used to re-balance the bar. The shape of fingers 70 is not a limitation of the present invention. For example, the cross-sectional shape of fingers 70 can be round (as shown) or any other shape without departing from the scope of the present invention. Regardless of their shape, any minor grooves formed by fingers 70 in the unfinished concrete are quickly “floated” to the finish concrete height as float 12 (tracking behind bar 14) moves thereover.
Fingers 70 could also be colored along the length thereof in one or more colors that are different from the color of the plastic concrete being finished. Fingers 70 could just be colored all along their length or just near their outboard ends. By coloring fingers 70 in this way, the rake worker is provided with both tactile feedback (i.e., as the rake contacts fingers 70) and visual feedback.
The advantages of the present invention are numerous. The floating screed's pivoting leading edge presents a novel way for a screed operator to take advantage of a finished region of concrete adjacent to an unfinished region of concrete. By using the trailing float as the point for measuring elevation with respect to a target elevation, the present invention corrects the “bubbling concrete” condition that occurs when a screed device has a leading section followed by a second section spaced apart from the leading section.
Thus, although the invention has been described relative to a specific embodiment thereof, there are numerous variations and modifications that will be readily apparent to those skilled in the art in light of the above teachings. It is therefore to be understood that, within the scope of the appended claims, the invention may be practiced other than as specifically described.
This patent application is co-pending with one related patent application entitled “CONCRETE SCREED WITH VERTICALLY ADJUSTABLE GATE”, Ser. No. 12/069,743, filed Feb. 12, 2008, by the same inventors and owned by the same assignee as this patent application.