Embodiments of the present invention relate to application of materials such as profileable material to driving surfaces.
Lines and other markings (hereafter “markings”) may be applied to surfaces such as driving surfaces for a variety of reasons. For example, solid and/or dashed lines may be drawn along the middle of a roadway to delineate one lane from another. Such lines may indicate various rules of the road, such as when it is permissible to pass other vehicles. Lines may also be drawn in parking lots to demonstrate to visitors where vehicles should be parked.
Markings may be applied to a driving surface using a variety of materials or “binders,” including but not limited to epoxy, thermoplastics, Methyl Methacrylate (“MMA”), and so forth. Some binders may be more viscous than others. For example, some forms of MMA and/or thermoplastic may be viscous enough to be considered “profileable.” A material may be profileable when it is possible to apply the material to a driving surface so that the material retains a profile relative to the surface (e.g., when viewed from the side), rather than spreading across the surface as a less viscous liquid might. Some profileable materials may include sand and/or glass beads to increase profileability/viscosity.
Markings may be applied to a driving surface using a variety of techniques. For example, materials may be sprayed onto a surface using a sprayer. The resulting baseline markings may be fairly uniform; they may not include many “blank” portions or “gaps” through which the underlying surface is visible. Baseline markings also may have a fairly flat profile relative to the surface to which they are being applied. Baselines may typically be applied using materials of relatively low viscosity. Pumping more viscous materials such as profileable material through a sprayer may cause the sprayer head to be damaged quickly and frequently, in turn causing the applied baseline markings to have rough edges. This may be especially true where the profileable binder includes sand or other solid materials. Thus, where clean baseline markings are desired and profileable material is used, it may be necessary to frequently replace damaged sprayer heads.
Markings may be applied to a driving surface in a less uniform matter, such as in a controlled splatter or agglomeration. Unlike baseline markings, a splattered (also referred to as “agglomerated”) marking may not be as uniform when viewed from above, and may include a number of gaps or holes through which the underlying surface is visible. A splattered marking may be applied using profileable binder, resulting in a non-flat or rough profile relative to the surface upon which it is applied. An agglomerated marking may also have less uniform or more rough edges than a baseline.
When using profileable material, in many cases driving surface markings are applied to a surface using a buggy. Buggies typically are not usually much larger than a medium-sized car and typically store profileable material in pressure tanks Pressure tanks may be limited in size by various regulations and practical limitations (e.g., the small size of the buggy). Due to their relatively small size, it may be necessary to stop work and refill pressure tanks frequently. Additionally, static pressurized delivery systems associated with buggies may be dictated by ground speed.
Reflective elements such as glass beads or reflective ceramic elements may be embedded into a marking on a driving surface. The reflective elements may make markings easier to see in the dark because light from horizontally-aligned headlights may be more likely to be reflected from a reflective component embedded in binder. However, embedding relatively large/heavy reflective elements into binder may be challenging. If too much pressure is used to embed the elements into the binder, the binder may be flattened by the impact of the reflective elements or by excess air pressure. If too little pressure is used, on the other hand, the elements may not embed deep enough and may not be retained in the material.
Embodiments of the present disclosure will be readily understood by the following detailed description in conjunction with the accompanying drawings. To facilitate this description, like reference numerals designate like structural elements. Embodiments of the disclosure are illustrated by way of example and not by way of limitation in the figures of the accompanying drawings.
In the following detailed description, reference is made to the accompanying drawings which form a part hereof wherein like numerals designate like parts throughout, and in which is shown by way of illustration embodiments in which the invention may be practiced. It is to be understood that other embodiments may be utilized and structural or logical changes may be made without departing from the scope of the present disclosure. Therefore, the following detailed description is not to be taken in a limiting sense.
Referring now to
Baseline 102 may have a relatively uniform appearance. For example, there may be few, if any, gaps or holes through which surface 100 may be visible. In various embodiments, when viewed from the side and as shown in
Agglomerated line 104 (which may also be referred to as a “splattered line”) may have a less uniform appearance than baseline 102. For example, surface 100 may be visible through various gaps and holes in agglomerated line 104. Additionally, when viewed from the side (as shown in
Combining these two markings may yield dual-swath driving surface marking 106, which may exhibit benefits of both baseline 102 and agglomerated line 104. In various embodiments, baseline 102 may “fill in” gaps or holes in agglomerated line 104, to give dual-swath driving surface marking 106 a uniform appearance when viewed from above. Moreover, when reflective elements are embedded after application of both baseline 102 and agglomerated line 104, the reflective elements may be embedded in portions of baseline 102 that fill in the holes and/or gaps in agglomerated line, further increasing nighttime reflectivity. And reflective elements embedded in baseline 102 may be somewhat protected by agglomerated line 104.
An example multi-application apparatus 200 for applying multiple swaths of material to a driving surface in a single pass, an example result of which is seen in
In various embodiments, vehicle 202 may include one or more reservoirs 206 to hold one or more components that form the material that is applied to a driving surface. In various embodiments, reservoir 206 may include one or more sub-reservoirs (not shown) for binder and one or more sub-reservoirs (not shown) for a catalyst.
Pressure pumps that may be used with reservoirs on buggies may be limited in size, thereby limiting a size of pressure tanks. Accordingly, in various embodiments, reservoir 206 may be a large tank equipped with one or more diaphragm pumps (see
In various embodiments, multi-application apparatus 200 may include a wheel 208 or other supporting structure that may guide and/or support multi-application apparatus 200 along a driving surface. In other embodiments, multi-application apparatus 200 may not include a wheel, and may be supported over a driving surface in part or in whole by structure of vehicle 202.
Referring now to
In various embodiments, a number of parameters associated with baseline applicator 210 may be independently controlled to affect various aspects of a marking applied to a driving surface, including but not limited to the marking's width, thickness, uniformity, and so forth. In various embodiments, the pressure at which air is used by baseline sprayer 210 may be controlled independently of other parameters associated with operation of multi-application apparatus 200, such as ground speed 216 of vehicle 202. In various embodiments, a material application rate of baseline applicator 210 may be controlled independently of other parameters of multi-application apparatus 200, such as material air pressure and/or ground speed. In various embodiments, a material application volume (e.g., how much material is applied per periodic marking) of baseline applicator 210 may be controlled independently of other parameters of multi-application apparatus 200, such as material application rate, air pressure and/or ground speed.
Spraying a profileable material through some sprayers may cause damage to various components, such as a spray head. This may cause a baseline (e.g., 102 in
For example, multi-application apparatus 200 may include an agglomerated marking applicator 220 configured to apply profileable material 212 in a manner that creates splattered or agglomerated markings 222, such as agglomerated line 104 in
As was the case with baseline applicator 210, various parameters of agglomerated marking applicator 220 may be controlled independently of other parameters associated with apparatus 200. In various embodiments, an air pressure used to operate agglomerated marking applicator 220 may be controlled independently of other parameters of multi-application apparatus 200, such as air pressure used to operate baseline applicator 210 and/or ground speed 216 of vehicle 202. In various embodiments, material application rate and/or material application volume associated with agglomerated marking applicator 220 may also be controlled independently from each another and from other parameters such as air pressure and/or ground speed 216 of vehicle 202.
An agglomerated marking may be applied to driving surface 214 in various ways. In some embodiments, such as the one shown in
In various embodiments, the same profileable material 212 may be used by both baseline applicator 210 and agglomerated marking applicator 220. In various embodiments, these components may be configured and/or positioned on vehicle 202 so that material applied by one component is not yet dry when the other component applies material. In this manner, an agglomerated line (e.g., 104 in
For example, a resulting marking on a roadway may include a first swath of a profileable material applied to the driving surface with a substantially uniform profile, and a second swath of the profileable material applied to the driving surface at least in part on top of the first swath. In various embodiments, the second swath may have a profile that is more varied than the profile of the first swath. In various embodiments, the profileable material forming the second swath may be at least partially fused with the profileable material forming the second swath. Ensuring that the profileable material used for both markings is at least partially fused may result in a stronger, more durable and/or longer-lasting surface marking.
Multi-application apparatus 200 may also include, in various embodiments, one or more reflective element applicators 230 to apply reflective elements into markings. For example, in
As noted above, embedding reflective components into a viscous material may be difficult. Thus, reflective element applicators 230 may be controllable to embed reflective elements to a level within the profileable material at which the reflective elements are visible to motorists, and yet where the elements will be retained within the profileable material. For example, one or more reflective element applicators 230 may be configured to propel reflective elements into an agglomerated or splattered MMA marking at a particular pressure, to cause the reflective elements to embed at a suitable level within the MMA. In various embodiments, the pressure used to propel the reflective elements may be controllable independently of other parameters (e.g., profileable material application rate, vehicle ground speed, etc.) described herein.
Applying two or more markings to a driving surface in a single pass may have a number of benefits other than those described above. For example, it may avoid the difficulty of applying material to the same line in two separate passes. Additionally, a single pass may reduce traffic disruption, as many surface marking vehicles tend to move slowly and may limit how much other vehicles may pass.
In various embodiments, baseline applicator 210 and/or agglomerated marking applicator 220 may be fed profileable material using various configurations of one or more pumps. As noted above, these pumps and various associated parameters may be controlled independently to allow adjustment of the parameters described above, e.g., material application rate, application volume, and so forth.
In various embodiments, a skip timer (not shown) may be employed to control timed application of profileable material between two or more applicators, e.g., baseline applicator 210 and agglomerated marking applicator 220, so that the multiple applicators apply profileable material to substantially the same portions of a driving surface. For example, where dashed lines are desired, the skip timer may be used, in some cases in conjunction with adjustment of ground speed of a vehicle on which a multi-application apparatus is mounted, to coordinate a leading edge of an agglomerated/splattered line (e.g., 104 in
Although certain embodiments have been illustrated and described herein for purposes of description of the preferred embodiment, it will be appreciated by those of ordinary skill in the art that a wide variety of alternate and/or equivalent embodiments or implementations calculated to achieve the same purposes may be substituted for the embodiments shown and described without departing from the scope of the present invention. Those with skill in the art will readily appreciate that embodiments in accordance with the present invention may be implemented in a very wide variety of ways. This application is intended to cover any adaptations or variations of the embodiments discussed herein.
The present application is a continuation of U.S. patent application Ser. No. 13/544,574, filed Jul. 9, 2012, entitled “Multi-Application Apparatus, Methods and Surface Markings,” which itself claims priority to U.S. Provisional Patent Application No. 61/505,841, filed Jul. 8, 2011, entitled “Dual Application of Surface Markings.” These entire disclosures are hereby incorporated by reference in their entireties.
Number | Date | Country | |
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61505841 | Jul 2011 | US |
Number | Date | Country | |
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Parent | 13544574 | Jul 2012 | US |
Child | 13863146 | US |