This invention relates to an apparatus and method for cutting non-linear trenches into concrete decks and floors in walk-behind fashion to make the resulting concrete resemble natural stone or flagstone pavers.
Concrete is one of the most common building materials in the world. It is used for sidewalks, foundations, roads and numerous other applications. One common application of concrete is as a material for flooring, both indoors and outdoors, e.g., by pouring concrete into a preformed shape by use of forms fabricated from wood or other suitable materials. Over time, horizontal concrete surfaces (concrete ground surfaces), especially outdoors, suffer from deterioration due to aging, freeze-thaw cycles and other environmental factors. In particular, freeze-thaw cycles and the resultant thermal expansion/contraction create cracks in outdoor concrete surfaces such as sidewalks and roads, and cause it to crumble. Various approaches have been devised to repair these cracks in the hope of prolonging the useful life of these outdoor concrete surfaces. For example, cracks can be cleared of debris, e.g., using hand-held electric grinders and the like, and then filled with caulk or other flexible fillers. Such repairs, however, tend to be unsightly and the caulk tends to dry out and require periodic replacement.
Other attempts to prolong the life of outdoor concrete surfaces involve using conventional grinders to make linear cuts in the concrete to form joints that allow for expansion and that provide a controlled crack direction (following the joint which makes the concrete thinner along its length). However, conventional grinders and saws used for this purpose, namely, for making fresh cuts in concrete without following pre-existing cracks, tend to be limited to cutting straight lines. Conventional handheld grinders also tend to be difficult to operate for extended periods of time, forcing the user to be hunched over in close proximity to the cutting wheel.
Moreover, the foregoing approaches produce surfaces with obviously repaired cracks and linear cuts of limited aesthetic appeal. Thus, a need exists for a system and method for restoring concrete surfaces that addresses the aforementioned issues.
In an aspect of the present invention, a walk-behind apparatus for cutting non-linear trenches in concrete includes a frame supported by at least three ground engaging wheels, including one or more fixed direction wheels at a front end portion of the frame disposed to rotate on a fixed axis of rotation, and one or more multi-directional wheels at a rear end portion of the frame disposed to rotate on one or more movable axes of rotation, to permit the frame to rotate about a substantially vertical axis passing through the frame normal to the ground. A handle at the rear end portion of the frame is engageable by a user walking behind the frame for pushing the apparatus forward and/or for steering the apparatus by pushing the handle left or right. A motor-driven ground-engaging cutting wheel has a cutting wheel axis of rotation, a diameter D in a range of from about 5 inches to about 20 inches, and a cutting portion having a width w in a direction parallel to the cutting wheel axis of rotation within a range of from about 0.5 inches to about 1.5 inches. The cutting wheel axis of rotation is substantially parallel to the fixed axis of rotation and extends notionally through the fixed direction wheels. The cutting wheel is disposed within a disc-shaped protective shroud sized and shaped to contain a majority of the cutting wheel therein during operation. The protective shroud is disposed in view of the user to permit the user to visually align the shroud and cutting wheel with a non-linear path on the ground while pushing and/or steering, to guide the cutting wheel along the non-linear path.
In particular embodiments, an additional aspect of the present invention includes the cutting wheel having circumferentially spaced metallic segments, the segments each having a cutting surface of convex cross-section in a plane parallel to the cutting wheel axis of rotation, so that during operation, the metallic segments are configured to cut a kerf in a concrete ground surface while the convex cross-section permits the cutting wheel to ride up and/or into side walls of the kerf while steering to avoid binding.
In another aspect of the invention, a method for restoring a concrete ground surface by forming portions resembling natural stone, pavers or flagstone, includes use of the apparatus of either of the foregoing aspects, in which a user engages the handle to steer the apparatus to a desired location on the concrete ground surface. While engaging the handle, the user visually aligns the shroud and cutting wheel with a non-linear path on the concrete ground surface, and actuates the cutting wheel to rotate about the cutting wheel axis of rotation. The cutting wheel is then engaged with the concrete ground surface to cut a kerf, while the user walks behind and steers the apparatus to guide the cutting wheel along the non-linear path.
The features and advantages described herein are not all-inclusive and, in particular, many additional features and advantages will be apparent to one of ordinary skill in the art in view of the drawings, specification, and claims. Moreover, it should be noted that the language used in the specification has been principally selected for readability and instructional purposes, and not to limit the scope of the inventive subject matter.
The present invention is illustrated by way of example and not limitation in the figures of the accompanying drawings, in which like references indicate similar elements and in which:
In the following detailed description, reference is made to the accompanying drawings that form a part hereof, and in which is shown by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention, and it is to be understood that other embodiments may be utilized. It is also to be understood that structural, procedural and system changes may be made without departing from the spirit and scope of the present invention. In addition, well-known structures, circuits and techniques have not been shown in detail in order not to obscure the understanding of this description. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined by the appended claims and their equivalents.
As used in the specification and in the appended claims, the singular forms “a”, “an”, and “the” include plural referents unless the context clearly indicates otherwise. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation. All terms, including technical and scientific terms, as used herein, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs unless a term has been otherwise defined. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning as commonly understood by a person having ordinary skill in the art to which this invention belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and the present disclosure. Such commonly used terms will not be interpreted in an idealized or overly formal sense unless the disclosure herein expressly so defines otherwise.
In particular embodiments, a method and apparatus is provided for allowing an operator to cut non-linear trenches (kerfs) into concrete decks and floors in walk-behind fashion to make the resulting concrete resemble natural stone or flagstone pavers. In particular embodiments, the apparatus include a relatively large diameter segmented grinding wheel configured to produce kerfs of various depths with generally arcuate or concave cross section of various radii. These kerfs and the configuration of the apparatus serves to provide relatively low transverse forces on the grinding wheel to help prevent the wheel from binding in the kerf as the apparatus is steered to produce the non-linear cuts, while the grinding wheel is configured to accommodate remaining transverse forces. These aspects enable the grinding wheel to be relatively large diameter, for enhanced efficiency and relatively long useful life, while still being able to efficiently cut along non-linear paths. A handle-actuated depth gauge allows the operator to move the grinding wheel into and out of the concrete at various predetermined depths. Particular embodiments also include an integrated dust collector.
The present inventor has recognized that when concrete surface repair may be necessary or desirable for structural or aesthetic purposes, it may be desirable to do so in manner that changes the surface shape, and optionally color, to one that resembles natural stones or pavers. Since natural stone and pavers typically have irregular sizes and shapes with non-linear edges, it would be desirable to cut irregular and non-linear patterns into the surface of the concrete in order to achieve the desired resemblance. The inventor further recognized that prior to the invention there was no wheel-supported (walk-behind) or otherwise useful device available that would allow the operator to make these non-linear cuts in a consistent and operator-friendly manner.
For example, it was recognized that one type of commercially available device is a walk-behind floor cutting saw made for straight cuts, such as to cut contraction/control joints. These cuts are relatively deep and narrow requiring relatively large diameter, thin blades, e.g., ⅛″ wide by 20″ in diameter. One skilled in the art would recognize that deviations from a straight cut would tend to bind the blade against the walls of the kerf, potentially damaging and/or shattering the blade. Conventional hand-held floor cutting saws are similarly configured for straight cuts.
Conventional specialty saws may allow a user to follow pre-existing (e.g., non-linear) cracks. However, these saws are generally not adapted for cutting new non-linear trenches. It was further recognized that conventional hand-grinders would generally be incapable of providing desired levels of efficiency in a high volume and/or large scale application, as the operator would quickly tire of holding and operating the grinder.
The instant inventor recognized that in order to cut kerfs in concrete ground surfaces of consistent depth along non-linear paths, without binding and/or shattering the grinding wheel, at least two issues had to be overcome:
Referring now to the Figures, embodiments of the present invention will be described in detail.
Turning initially to
In this regard, as shown in
In light of the foregoing, it will be recognized that an aspect of embodiments of the present invention is the provision of relatively large diameter cutting/grinding wheels that are capable of being steered during operation to produce non-linear kerfs.
As shown in
In particular embodiments, the frame 20 is foldable to facilitate storage and transportation, e.g., the frame includes articulating members configured to alternately move the rear end portion 25 away from the front end portion 23 into an operational position, and to move the rear end portion 25 toward the front end portion 23 into a closed, storage position. Referring to
In the embodiment shown, multi-directional wheels 24 are held by free spinning (swivel) castors that permit the wheels' axes of rotation to be rotated 360 degrees about a vertical (z) axis. As best shown in
As best shown in
As also shown in
Moreover, while motor 34 may take any of a number of conventional configurations, in particular embodiments, motor 34 may take the form of a conventional handheld grinder which is removeably supported by frame 20 as shown. In these embodiments, motor 34 and the cutting wheel 26 driven thereby form a substantially conventional unitary assembly that may be easily fastened to the frame for use as shown and described herein, while being easily removed therefrom to facilitate maintenance and/or replacement. For example, this unitary assembly may take the form of a commercially available handheld grinder of the type configured to use grinding wheels of approximately 7″ diameter.
Referring now to
Moreover, while particular embodiments include the aforementioned segmented grinding wheel, it should be recognized that cutting wheels of conventional rectilinear cross-section, such as shown in
As best shown in
It is also noted that the resulting concave shape of the kerf 42 may be sized and shaped to resemble the concave shape of a conventional grout or mortar line. This aspect enables the kerf to be colored and/or coated with a thin layer of grout or mortar once cutting is complete, as will be discussed in greater detail hereinbelow.
Turning back to
Thus, the operator adjusts the total weight of the apparatus by adding or removing weights (ballast plates 62) to or from the receptacle 60. Adjusting the total weight in this manner helps ensure that the cutting wheel 26 penetrates the concrete surface to the desired depth, while being limited by a limit stop, according to different levels of workabililty (e.g., compressive strengths) of the various concrete mixes that are encountered, and while minimizing the weight that the operator has to push.
In particular embodiments, the cutting wheel 26 is moveable to the desired depth by cutting depth adjuster 66 (
As best shown in
Referring now to Table I, a method 100 for restoring a concrete ground surface by forming portions resembling natural stone, pavers or flagstone is described.
The method 100 includes providing 102 the apparatus shown and described with respect to
While engaging the handle, the user visually aligns, at 108, the shroud 32 and cutting wheel 26, with the non-linear path. Optionally, the visually aligning 108 includes looking 109 along a clear line of sight s extending from handle 30 through the frame 20 to the shroud 32. The cutting wheel 26 is then actuated 110 with motor 34. At 112, the user engages actuator 68 of the depth adjuster 66 to engage the rotating cutting wheel 26 with the concrete ground surface to cut a kerf 42. At 114, the user walks behind and steers the apparatus to guide the cutting wheel along the non-linear path, so that the kerf extends along the non-linear path. The orientation of the grinding wheel between the fixed direction front wheels as well as the multi-directional rear wheels, keep the grinding wheel in the center of z-axis rotation. The convex shape of the grinding wheel allows for smooth turns along the cut path as the operator turns the machine left or right, without binding in the kerf, e.g., by effectively permitting the cutting wheel to ride up and/or into the side walls of the kerf while turning. Once cutting is complete, the operator releases the actuator 68 at 116 so that the spring bias of depth adjuster 66 lifts the cutting wheel 26 out of the kerf.
Referring now to Table II, additional option aspects of method 100 include placing one or more ballast plates 62 on a ballast receptacle 60 of the frame at 122, prior to said actuating depth adjuster 112. At 126, grout or mortar is optionally applied to the kerf, and at 128, color in the form of paint, stain and/or dye is applied to the concrete ground surface and/or to the grout or mortar. It should be recognized that the term ‘concrete ground surface’ refers to the concrete surface forming the ‘ground’ upon which users walk with the walk-behind apparatus 10. The application of color to the concrete ground surface at 128 may thus help make the portions of the concrete bordered by the kerfs resemble flag stones and the like. At 130, the color application 128 includes applying a base color substantially uniformly to the concrete ground surface including the grout or mortar, and then selectively applying a secondary color to portions, e.g., peaks, of the concrete surface texture, in an irregular and/or selective manner, to produce a color distribution resembling natural stone pavers and flagstones.
Having described various embodiments of devices and methods for cutting nonlinear patterns into concrete surfaces, the following alternative embodiments are provided for cutting linear patterns, e.g., to replicate conventional rectilinear tile installations as often used indoors, but which may also be used in outdoor applications.
These alternate embodiments enable a user to cut line patterns into concrete that are similar to those found in ceramic porcelain, natural floor tile or installations of tiles made from similar materials: namely, patterns formed by a series of straight lines extending along two orthogonal directions, to form rectangular (e.g., square) shapes that repeat to emulate typical floor tile patterns.
These embodiments provide for:
As discussed hereinabove, concrete is widely used as a material for flooring, both indoors and outdoors, e.g., by pouring into a form constructed of wood or other suitable material. The resulting concrete slabs form the basis of flooring in residential and commercial buildings on ground level and additional levels above the ground floor. Historically, there have been many ways to cover the concrete slabs to create useful and attractive flooring for the inhabitants or users. These options include but are not limited to: carpet glued onto the slab, vinyl-composite tile glued onto the slab, hardwood flooring installed over the slab, paint applied over the slab, ceramic or natural or other tile installed over the slab, etc. Each of these flooring options has certain advantages and disadvantages.
One additional way of creating a useful and attractive flooring option using concrete slabs is so-called Concrete Polishing. In concrete polishing, the surface of the slab is ground and polished in various steps to create a smooth surface. These steps include—but are not limited to—the application of a sealer that closes the pores and helps to prevent concrete dusting, among other benefits.
The present inventor has recognized that one additional way to create a useful and attractive flooring using concrete slabs is to cut shapes into the slab that resemble grout lines, in the dimensions and patterns one would commonly associate with ceramic or similar floor tiles. In combination with additional steps/techniques, including the installation of grout within the cuts, one can create the look and feel of ceramic or natural stone tiles in concrete slabs without the material cost and installation time associated with such conventional tile installations. Prior to development of the embodiments shown and described hereinbelow, the present inventor has been unable to locate a portable machine that would allow a user to repeatedly cut a first set of straight, parallel lines in a first direction, and repeatedly cut a second set of straight, parallel lines in a second direction that is orthogonal to the first direction, with sufficient accuracy as one would find in a ceramic or natural stone tile installation, in order to resemble ceramic or natural stone tiles.
The present inventor recognized that one potential approach would be to try and adapt an otherwise conventional CNC moving table and XY-gantry, to provide the desired cuts. The inventor recognized, however, that conventional CNC XY-gantries have significant shortcomings in several key areas. First, they are not mobile. Once assembled, they are not meant to be taken apart and moved frequently. It is difficult—if not virtually impossible—to change their size, e.g., to accommodate different size jobs/job sites. In addition, by design, conventional XY-gantries carry their payload on a horizontally straight and level path which does not conform to the imperfect flatness of a typical poured concrete surface. Still further, conventional XY gantries use linear bearings that require a tightly toleranced setup of the X and Y bars to function properly. For this reason, they would not tolerate, for example, set up at a less-than-precision 90 degree angle, such as may be expected at a job site, potentially leading to cocking of the bearing and a locked-up mechanism. For these reasons, such conventional XY gantries are not used in the embodiments hereof.
The inventor also recognized that suitable equipment to accomplish straight, parallel and perpendicular cuts on concrete surfaces in a production environment, would need to be highly mobile. For example, the equipment would need to fit easily into a conventional 16 ft or 20 ft cargo trailer along with additional unrelated equipment. It would also need to be easily carried to and from the jobsite. It would need to be set up and taken down on the jobsite with minimal effort, and also during multiple moves on the jobsite to cover an entire work area. It would need to be able to be operated by untrained or lightly trained personnel, and would need to be able to cover areas of different sizes and odd shapes, e.g., large rooms, small rooms, large rooms with small alcoves, relatively narrow hallways and so on. The embodiments shown and described hereinbelow provide for such desired mobility, while also being tolerant of dust and physical abuse often found on a typical job site.
Referring to
The main tool trolley (C1) travels along the track (A1), as propelled manually (operator pushes with handle L1), or by machine (motor driven). The main trolley is made by sufficiently strong and stiff material, sufficiently machined to tolerances that allow for straightness as required in this application. As the trolley travels along the path determined by track (A1) and—if cutting tool (D1) is powered on, the cutting blade (E1) cuts a line into the concrete.
The main guide (A1) is temporarily affixable to the perpendicular side bars (B1 and B2). B1 and B2 may include demarcations F1 showing distances along the lengths of side bars B1 and B2. These demarcations F1 allow track A1 to be easily placed and secured at various spaced locations along the length of, and extending orthogonally to, side bars B1 and B2. In particular embodiments, the markings can be substituted or complimented by slots F1′ sized and shaped to receive ends of the track A1 therein, or by similarly suitable mechanical fixtures that allow the affixation of the track A1 to bars B1 and B2. For example, as shown in
Referring now to
To operate the apparatus, the operator may position A1, B1 and B2 on the concrete floor as shown in
Using handle L1, the operator pushes trolley C1 along track A1 and thus cuts a line into the concrete. Note that optionally, the operator may intermittently raise and lower cutting tool D1 and blade E1 to respectively disengage and engage E1 with the concrete, to form discontinuous patterns, such as the offset rectangular patterns shown in
Once trolley C1 has reached the end of track A1, the operator powers off tool D1, removes trolley C1 from track A1, and using demarcations/slots F1, F1′, moves track A1 into a predetermined position between bars B1, B2 parallel to and spaced from the previously cut line. The operator then places trolley C1 onto track A1 and repeats the above steps until a desired number of parallel cuts, e.g., either continuous or discontinuous, in a first direction have been made. When track A1 has reached the distal end of bars B1 and B2, the operator may rotate the entire linear cutter 200 by a desired increment (e.g., ninety degrees in many applications) and repeat the aforementioned process to make a desired number of parallel cuts in a second direction. As mentioned, continuous cuts in first and second directions at 90 degree angles to one another may be used to produce a pattern of squares as shown in
Turning now to
In light of the foregoing, particular embodiments of the present invention include the cutter 200 as shown and described hereinabove, in which bars B1 and B2, and track A1 are fabricated from a lightweight and structurally rigid and tough material such as aluminum, all having the substantially the same cross section of, as a non-limiting example, approximately 4 inches wide×2 inches high (rectangle) and between 4 ft and 20 ft long, e.g., in increments of 4 ft. The pieces that make up the sidebar set are chosen so that they provide flexibility to create different assembly sizes on the job site, as needed for areas of different sizes and shapes, as typical in flooring installations. The side bars B1 and B2 may be stored and transported to the job site in a trailer, truck, etc. The maximum length of the sidebars and tracks is limited by the length of the trailer, truck etc. If needed, the operators can extend the length of a sidebar by attaching another sidebar with special fittings. The materials and cross section choice of the side bars may be selected to provide light weight and resistance to damage when bumped, dropped, etc. In addition, these components should be sufficiently stiff to facilitate being carried by two people without excessively flexing or bending. In particular embodiments, aluminum has been found to be a satisfactory material from which to fabricate these components.
No-slip pads and/or weights may be used as shown and described hereinabove. Moreover, in particular embodiments, spacers are attached to the vertical part of the long side of the sidebars in the following manner. Depending on the required “tile” size for the installation (e.g. 12 inches), the spacers have a length that equals the “tile” width (12 inches) minus the width of the main track (e.g., 4 inches′). This allows the main track to be inserted between and perpendicular to side bars B1, B2, and to be removably held in place for one cut along the main track A1. An exemplary tool cart C1 is approximately 20 inches long, 12 inches wide and 6 inches high. The skilled artisan should recognize that spacers of substantially any configurations may be used, including those formed integrally with, or separate from, bars B1 and B2, without departing from the scope of the present invention.
As shown, in particular embodiments, the cart C1 includes a plurality (e.g., four) support wheels 210. In one particular non-limiting example consistent the dimensions included above, wheels 210 may be about 2 inches in diameter, attached by casters. As shown in
These embodiments may be operated substantially as shown and described hereinabove with respect to
Turning now to
Particular embodiments of the present invention are configured to facilitate accurately cutting dashed lines in order to emulate the aforementioned staggered tile patterns.
One way to accomplish the cutting of dashed lines using embodiments hereof is to:
It should be recognized that with the above process, the accuracy of the raising and lowering of the blade/grinder plays a role in the authentic look of the result. A cut that is slightly too long (over-cutting beyond the transverse cut line) or too short (under-cutting by not reaching the transverse cut line) would make the final installation look inauthentic. And, with typical grout lines having a width of only about ⅛ inch to ¼ inch, the transversely cut lines simply do not provide sufficient tolerance for consistently and efficiently raising and lowering the apparatus by hand without over- or under-cutting. This issue is further complicated by the fact that the cutting blade E1 is round and rotates in a plane parallel to the cut direction/kerf, which means that a sharp beginning and end of the cut is difficult to achieve manually.
An aspect of particular embodiments of the invention is therefore the semi- or fully-automated raising and lowering of the blade E1 as it traverses the track A1. As shown in
This can be achieved in the following ways.
As the cart is moved along the track, the object detector OOD1 recognizes the approaching continuous cut line 220. At one line 220, the OOD1 triggers the HM1 to raise the grinder/blade to disengage from the concrete as shown in
Turning now to
Indeed, the accurate alignment of the apparatus with the desired cut pattern and with previously cut lines is used to achieve an authentic tile look. Since most tiles are square or rectangular, any deviation of the cut lines 220, 222 (
Those skilled in the art will quickly realize that it is indeed possible to align a track A1 and cutting tool C1 with a previously cut line 220 in a way that the new line 222 is perpendicular to the former. Conventional carpenter's squares and/or laser squares may be used for this purpose. However, it will also become quickly clear that the risk of human error is significant when hundreds of lines have to be cut in a short period of time Like with most other cutting operations, cutting into a material is unforgiving, i.e., a wrong cut can't be returned to its original condition. Indeed, while conventional tools are useful, they can not entirely prevent user error, e.g., due to incorrect use of the square or laser correctly, or accidentally positioning the track A1 or cart C1, or even the entire assembly 200, out of alignment with these tools.
Embodiments hereof address this issue by use of one or more side sensors (e.g., optical, proximity, limit switches, etc.) 224 to help ensure proper alignment of the track A1. As shown in
The present invention has been described in particular detail with respect to various possible embodiments, and those of skill in the art will appreciate that the invention may be practiced in other embodiments. First, the particular naming of the components, capitalization of terms, the attributes, or any other structural aspect is not mandatory or significant, and the mechanisms that implement the invention or its features may have different names, formats, or protocols. Also, the particular division of functionality between the various system components described herein is merely exemplary, and not mandatory; functions performed by a single system component may instead be performed by multiple components, and functions performed by multiple components may instead performed by a single component.
Finally, it should be noted that the language used in the specification has been principally selected for readability and instructional purposes, and may not have been selected to delineate or circumscribe the inventive subject matter. Accordingly, the disclosure of the present invention is intended to be illustrative, but not limiting, of the scope of the invention, which is set forth in the following claims. It should be further understood that any of the features described with respect to one of the embodiments described herein may be similarly applied to any of the other embodiments described herein without departing from the scope of the present invention.
This application is a Continuation-In-Part of U.S. patent application Ser. No. 15/881,303, entitled METHOD AND APPARATUS FOR CUTTING NON-LINEAR TRENCHES IN CONCRETE, filed on Jan. 26, 2018, which claims the benefit of U.S. Provisional Patent Application Ser. No. 62/499,484, entitled MACHINE FOR GRINDING NON-LINEAR TRENCH INTO CONCRETE—501, filed on Jan. 27, 2017, and which claims the benefit of U.S. Provisional Patent Application Ser. No. 62/600,566, entitled APPARATUS FOR CUTTING LINE PATTERNS INTO CONCRETE—EXTENDED, filed on Feb. 24, 2017, the contents all of which are incorporated herein by reference in their entirety for all purposes.
Number | Date | Country | |
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62499484 | Jan 2017 | US | |
62600566 | Feb 2017 | US |
Number | Date | Country | |
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Parent | 15881303 | Jan 2018 | US |
Child | 16008575 | US |