Structural solar arch

The present disclosure includes a vacuum stall canopy assembly for a car wash system having a first post assembly having a base leg permanently attached to the ground, a beam attached to the top of the first post assembly, a roof assembly disposed on an upper portion of the beam, a debris separator disposed on the beam, the debris separator having a first side and a second side, a main airline fluidly connected to the debris separator and configured to be connected to a source of vacuum suction, a first hose on the first side of the debris separator, and having a first nozzle on a distal end of the hose from the debris separator, and a second hose on the second side of the debris separator, and having a second nozzle on a distal end of the hose from the debris separator.

BACKGROUND

Many car wash facilities include vacuum stalls for users to easily vacuum out dust, dirt, and other particles from their vehicle either before or after they use the car wash to clean the outside of their vehicle. To provide protection from the elements such as rain, snow, or excessive sunshine, many of these vacuum stalls include a roof over the stall.

SUMMARY

An aspect of the present disclosure is generally directed to a vacuum stall canopy assembly for a car wash system having a first post assembly having a base leg permanently attached to the ground, a beam attached to the top of the first post assembly, a roof assembly disposed on an upper portion of the beam, a debris separator disposed on the beam, the debris separator having a first side and a second side, a main air line fluidly connected to the debris separator and configured to be connected to a source of vacuum suction, a first hose on the first side of the debris separator, and having a first nozzle on a distal end of the hose from the debris separator, and a second hose on the second side of the debris separator, and having a second nozzle on a distal end of the hose from the debris separator.

An aspect of the present disclosure is generally directed toward a vacuum stall canopy system for covering and defining a vehicle wash bay that includes: a plurality of canopy supports each defining a side of a vehicle wash bay where the plurality of canopy supports include a first canopy support and a second canopy support and the first canopy support has a first canopy post assembly having a first canopy base leg attached to amounting surface; and a first canopy support beam attached to the top of the first canopy post assembly at first canopy support engagement location and extending forward and backward from the first canopy support engagement location where the first canopy support base leg engages the mounting surface at a first predefined angle and the second canopy support includes a second canopy post assembly having a second canopy base leg attached to the mounting surface; and a second canopy support beam attached to the top of the first canopy post assembly at first canopy support engagement location and extending forward and backward from the first canopy support engagement location where the second canopy support base leg engages the mounting surface at a second predefined angle; a roof panel coupled to a portion of the first arch support beam and configured to span between the first arch support beam of the first arch support and the second arch support beam of the second arch support; a debris separator disposed on at least one of the plurality of arch supports, the debris separator having a first side and a second side; a main air line fluidly connected to the debris separator and configured to be connected to a source of vacuum suction; a first hose on the first side of the debris separator, and having a first nozzle on a distal end of the hose from the debris separator; and a second hose on the second side of the debris separator and having a second nozzle on a distal end of the hose from the debris separator. The first predefined angle and the second predefined angle are not 90 degrees typically.

Yet another aspect of the present disclosure is generally directed toward a structural arch system providing for a vehicle wash vacuum system that includes: a first arch assembly having a first post assembly having a base leg secured to the ground and a first beam attached to a top portion of the first post assembly; a second arch assembly having a second post assembly having a base leg secured to the ground and a second beam attached to a top portion of the second post assembly; a roof assembly spanning between the first beam and the second beam on an upper portion of each of the first and second beams; a debris separator disposed on at least one of the first and second beams, the debris separator having a first side and a second side; a main air line fluidly connected to the debris separator and configured to be connected to a source of vacuum suction; a first hose on the first side of the debris separator, and having a first nozzle on a distal end of the hose from the debris separator; and a second hose on the second side of the debris separator, and having a second nozzle on a distal end of the hose from the debris separator.

Another aspect of the present disclosure is generally directed toward a structural arch system providing for a vehicle wash vacuum system that includes: a first arch assembly having a first post attached to the ground and a first beam attached to the first post; a second arch assembly having a second post attached to the ground and a second beam attached to the second post; a roof panel spanning between the first beam and the second beam on an upper portion of each of the first and second beams; a debris separator disposed on the first beam; a main air line fluidly connected to the debris separator and configured to be connected to a source of vacuum suction; and a hose coupled to the debris separator and having a nozzle on a distal end of the hose from the debris separator.

What is disclosed is a vehicle wash canopy system having an arch support defining a side of a vehicle wash bay. The arch support includes a post assembly having a base leg attached to the ground and a beam attached to the top of the post assembly. The system has a roof panel on an upper portion of the beam that spans between the beam and a second beam on a second arch support on a second side of the vehicle wash bay, a debris separator having a first side and a second side on the arch support, a main air line connecting the debris separator a source of vacuum suction, a first hose on the first side of the debris separator, and a second hose on the second side of the debris separator having nozzles on opposite ends of the hoses from the debris separator.

DETAILED DESCRIPTION

As used in the disclosure, the front of the vacuum stall is referred to as the end of the stall into which the vehicle (car, truck, sport utility vehicle, semi-tractor and the like) enters, and the rear of the vacuum stall is the end of the stall with the optional riser and the typically where the base legs are disposed.

Typically, when a user visits a car wash, they will utilize a vacuum in order to remove dust, dirt, and other small contaminants from the inside of their car either before or after the outside is washed by the stationary, moving, standard, or touchless carwash. The vacuum systems are typically installed outside of the car wash building on the same property for easy access for the user.

When a user drives into a vacuum stall they may be protected by one or more canopy12, awning, or other roof covering structure(s). The canopy12may be a single element, typically a fabric covering, as shown inFIGS.6-9, or may be comprised of a number of common or different roof elements14,16that may be metal, fabric or structural supports that may optionally include solar cells on the top, solar facing surface as shown inFIGS.1-5. The overhead elements may protect the user from precipitation such as rain or snow, or may simply provide a user shade in very hot, sunny weather. One embodiment of a vacuum system10is shown inFIG.1.

The canopy12or awning may be supported by a beam18. The beam18may be a straight beam or may be arcuate as the beam is shown inFIG.1. The beams18may be cantilever beams that extend from a wall of the car wash or another structure, may cantilever out from a single post, or preferably may be supported by a separate structure such as the supporting structure20shown inFIG.1. The beams18may be comprised of square rolled steel tubing about 4″×4″ up to about 8″×8″, more preferably about 6″×6″. The steel is preferably about 3/16-¼″ in thickness. The beam may also be steel I-beam configuration, such as W 6″×12″ I-beam, or a variable size I-beam as shown in the embodiment ofFIGS.6-10. The rolled steel tubing may provide increased strength for the structure, while simultaneously providing the operator of the property an easy way to further increase the strength of the structure by welding or otherwise attaching a side plate to the beams18or the individual elements of the support structure20.

In the preferred embodiment, the beams may be supported by a support structure20. The support structure20may be a single post22that reaches from the ground up to the beam18as shown in the embodiment ofFIGS.6-10, or may be a Y-structure base assembly comprising a base leg23and supporting legs24,26, as shown in the embodiment ofFIGS.1-5. The support structure20may locate the beams18up to between 9′-10′ in height and allow the beams to extend out about 12′-18′ in order to cover substantially all of the vehicles that are in the stall for cleaning. The support structure20may include a base leg22that is permanently or semi-permanently attached to a footer36,136on or within the ground or other mounting surface such as cement. The footer36may be a concrete footer that is attached to the ground by ground stakes or in any other way known in the art. The base leg22may be attached to the footer by bolts, or the leg may be placed within the footer while the concrete is still wet such that the footer sets around the base leg and holds it in place once it cures.

In the arch embodiment, the base leg22may reach up to about 6 feet, but also may reach higher or lower depending on structural needs. There may be at least two stabilizing legs24,26that attach to the base leg22at the top of the base leg22. The stabilizing legs24,26may be attached to the base leg by lag bolts, welding, or any other attachment known in the art. The stabilizing legs24,26may extend upwardly from the base leg22to a height of 8-12 feet or more above the ground depending on the requirements of the vacuum stall. The base legs22, stabilizing legs24,26, and beams18may all be finished by a powder coated process to ensure maximum weatherability and offer up many different colors based on individual preferences.

There may also be lighting such as light emitting diode (LED)52lighting disposed on the bottom side of the beams18to offer better and more efficient lighting for a user to see the debris within their vehicle when ambient lighting may not be sufficient. With the beam18in the arch or arcuate configuration, the beam18may provide more structural strength than a straight beam, which may be important if the car wash operator chooses to support more elements from the beams than the simple roof or canopy elements shown or if it is located in a location where much snow is expected. A mat rack32, air hose bracket38,138and a trash can30,130are attached to the base legs22,122through brackets that are bolted to the base legs through drilled holes in the base leg, which allows a user to easily clean up large debris and move the car mats within the vehicle out of the vehicle without placing them on the ground which may be very dirty as well. The system may also include a compressed air delivery hose46,146operably connected with a compressed air source to provide compressed air for use in cleaning interior vehicle surfaces and/or delivery of compressed air for inflation of tires.

In the arch embodiment shown inFIGS.1-5, a debris separator34may be attached to the bottom side of the beams18near the rear of the vacuum stall. Rear as shown in the embodiment is toward the rear of the vehicle as it drives straight into the stall. The debris separator34is connected to an industrial vacuum pump (not shown) that may be remotely located from the vacuum stall. The industrial vacuum pump may be located in a utility room within the car wash facility or in any other located convenient for the operator of the car wash. The debris separator34is connected to the industrial vacuum pump through piping that is disposed along the beams, and removes any debris from the air stream that is sucked up by the user utilizing the vacuum nozzles48,50,148,150before it can get back to the industrial vacuum pump. The location of the debris separators34make it easy for an operator of the car wash to empty the debris by simply reaching up and removing a bottom side dump valve and removing the debris from the separator34. The debris separators each typically have a vacuum air intake47, which does not have a main hose line shown in the drawings, but that would typically engage either a vacuum air supply unit located and associated with each individual vehicle bay or each interconnected with a remotely located vacuum air supply system for all or a plurality of the vehicle vacuum stall canopy system stalls. The debris separator134may also be located at the front of the stall, as shown in the embodiment ofFIGS.6-10.

The debris separators34may have a pair of hoses40,42fluidly attached. Including hoses on either side of the debris separator34allows users on either side of adjacent stalls to use one of the hoses extending from one of the debris separators to vacuum up dirt, dust, and other small debris that builds up within and on either side of a vehicle. In the embodiment shown inFIGS.6-10, the debris separator134is disposed on the beam at the front of the stall to allow operators access to the separators from the front of the stall.

In use, the industrial vacuum pump creates suction that at the debris separator34and134. The suction from the debris separator is available to a user at the vacuum nozzles48,50or148,150. The vacuum nozzles48and50(and148and150) may be the same type of nozzle, or as shown may have different configurations. As the user vacuums, the picked-up dirt, dust, and other particles are pulled through the hoses40,42,140,142and are held within the debris separator. The hoses typically connect to the separator using connectors44that may have threaded connections or a snap fit connection to a hose. The connections are typically at least substantially air tight or air tight to limit loss of vacuum power supplied from the remotely located vacuum unit that provides vacuum air to multiple vehicle vacuuming bays or a vacuum unit associated with an individual vehicle vacuuming bay. In this way, the dust, dirt, and other particles do not travel all the way back to the industrial pump in order to keep it running well. The hoses140,142may connect with a debris separator134at the rear of the system as shown inFIGS.6-10via interconnecting hoses156that typically extend from front to back along the top of the beams118.

The canopy or roof of the vacuum stall may comprise simple flat or corrugated roof panels14, solar panels16, canopy112(typically a fabric canopy), fabric awning, or any combination thereof. Typically, these are uniformly used, e.g. all solar panels, all corrugated, or all fabric awnings, but it is within the scope of the disclosure to mix and match different canopy structures within a single canopy. In the embodiment shown inFIGS.1-5, there are two solar panels16and a simple flat panel14, however, the panels can be placed and installed in any order and in any fashion. For instance, in the arch embodiment there are three panels shown, however there may be a single panel, or more than three panels used. The panels may be attached to the beams18through joists19or stringers. The joists19are preferably a metal joist such as steel joists.

In the arch embodiment shown inFIGS.1-5, there are typically two composite solar panels16in the roof canopy assembly12made up of a plurality of individual solar cells154. In other embodiments, one solar panel16may be used, or more preferably, three or more solar panels16may be used. The solar panels16are used to turn sunlight into electricity in a manner known in the art and deliver power to the overall systems of the present disclosure or back to the mains electrical grid if excess electricity is generated. The solar panels may be used to power the electrical uses of the stall as a stand-alone feature, or they may be tied into the mains electrical grid by power cables run between the solar panels, the electrical components in the vacuum stall, and the local mains power supply. For a facility with many stalls, this may be a much more efficient, cleaner, and inexpensive use of electrical energy.

In another embodiment, as shown inFIGS.6-10, the canopy112is a fabric canopy that typically does not employ solar cells, but conceivably could include them. The fabric canopy may be stretched between the beams118. The canopy112may be held in place by a quick release strap system117. The quick release system may include a nylon strap113that is sewn or otherwise permanently attached to the canopy112. The strap113is fed through a quick release mechanism114, which allows for easy tightening and releasing of tension on the strap113and by extension the canopy112. The quick release mechanism may include a ratcheting device that allows a user to easily attach the strap113without the full tension of the canopy on the strap113.

The other end of the strap113is permanently attached to a bracket115, which may be bolted to the beam118using a nut or head of a bolt116. In this way, the canopy112may be attached to one beam118on one side of the stall and then attached to another beam118on the other side of the stall easily without the fully installed tension of the canopy on the strap113. The strap113may then tightened by the ratcheting device in the mechanism114to provide the necessary structural hold for the canopy. This type of connection to the beams118additionally provides for an amount of tolerance in the canopy112itself in that the fabric need not be cut and sewn perfectly to size. Longitudinal support of the canopy112may be provided by rods or bars119that are placed within sewn pockets on either side of the canopy112. In another embodiment, the strap is permanently or semi-permanently attached to the bar119as opposed to being sewn to the canopy112itself.

In this embodiment, the beams118are held up by posts122, and the debris separators are mounted to the front of the stall. Similar to the arch embodiment, LED lights152may be mounted on the underside of the beams118. Like the arch embodiment, this embodiment may include a garbage or trash can130. In this embodiment, the garbage can130may have a weighted lid130athat rests on the top of the garbage can130. The added weight assists the lid130ain high wind or other situations to keep the lid130aon the top of the garbage can130. The garbage can130may be located directly below the debris separator134and include an inner liner130b. The inner liner130bmay be rigid to ensure that the inner liner may be removed easily from the garbage can130. The inner liner may have a plastic bag inserted in it for easy disposal of waste placed in the inner liner of the garbage can. The garbage can and liner are typically located directly below the debris separator134in this embodiment, which allows a user or a facility maintenance person to easily dump debris from the inside of debris separator134through the bottom door134aof the debris separator134and into the garbage can130, or directly into the inner liner130bif the user removes the lid and lifts the inner liner130bup vertically closer to the bottom door134a. This motion is easier due to the location of the garbage can. Additionally, the bottom door134ais typically a door that is openable using one hand and no tools so the operator can use one hand to hold the inner liner upward and the other to open the bottom door134aof the cyclonic separator.

As shown inFIGS.5and9, when used at a larger facility, the vacuum stalls may be used side-by-side. In this way, a single supporting structure20or single post assembly120may be used for adjoining stalls. The hoses on either side of a single debris separator34,134may be used for stalls on either side of the debris separator. In this way, a facility can use the elements of the disclosure more efficiently by including more stalls in a side by side fashion. Further, if the facility area that the vacuum stalls are being used is not straight, adjoining stalls may be offset slightly at an angle to wrap around the non-linear area.

Additional aspects of the present disclosure are shown inFIGS.11-17.FIGS.11-17show a vehicle vacuuming bay with a Y-shaped upward support base leg23and having supporting legs24,26that engage and hold one side of the canopy12. The canopy12shown inFIGS.11-17is constructed of a series of rectangularly configured solar panels with a plurality of solar cells on each panel. The panels are interconnected with one another to deliver generated power back to the overall vehicle vacuuming system and typically configured and arranged to abut one another in a water-tight configuration to prevent rain from reaching a user located under the canopy. The configuration of the canopy12shown inFIGS.11-17is a planar configuration, but could conceivably be differently shaped. The canopy, while planar, is typically positions at an upward angle from parallel to the ground or vehicle receiving surface under the canopy. Typically, the angle is not substantial, but from about 5 to about 35 degrees or any angle within this range, but the angle also could be more or less as well. Typically, the slight angle captures the sunlight and presents an inviting bay to the user while still providing coverage from sunlight when in use. The canopy may be positioned parallel to the vehicle receiving surface under the canopy as well. As shown in the figures, while a footer may be used and the base23cemented to the mounting surface, a base mounting bracket158may be used and mounting bolts or other attachment devices used to affix the base in position through the apertures160. Each distal end of the beams18typically have a pair of connection nozzles162that operably engage the hoses to be used by the user(s) when vacuuming a vehicle.

As shown inFIGS.16-17, the configuration may include a plurality of upwardly extending mounting plates164that are welded or otherwise attached to the top surface167of the beam18. These mounting plates164engage various solar panel mounting brackets. On one end, the mounting bracket may be a generally S-shaped bracket166. The middle brackets are typically generally J-shaped brackets170so that the top of the J-shaped bracket may engaged two different solar panels and affix them in position. At the other end, while a generally S-shaped bracket may be used, a generally C-shaped bracket168is typically used to create a more aesthetically appealing look when the system is viewed by a user while entering. The generally C-shaped brackets could be replaced with the generally S-shaped brackets and vice versa if needed. Additionally, two generally C-shaped brackets could conceivably be used in the center portion of the mountings in place of the substantially J-shaped brackets170, but this would not typically be done.

It is to be understood that the invention may assume various alternative orientations, except where expressly specified to the contrary. It is also to be understood that the specific devices and processes illustrated in the attached drawings, and described in the following specification are simply exemplary embodiments of the inventive concepts defined in the appended claims. Hence, specific dimensions and other physical characteristics relating to the embodiments disclosed herein are not to be considered as limiting, unless the claims expressly state otherwise. All ranges and parameters, including but not limited to percentages, parts, and ratios, disclosed herein are understood to encompass any and all sub-ranges assumed and subsumed therein, and every number between the endpoints. For example, a stated range of “1 to 10” should be considered to include any and all sub-ranges beginning with a minimum value of 1 or more and ending with a maximum value of 10 or less (e.g., 1 to 6.1, or 2.3 to 9.4), and to each integer (1, 2, 3, 4, 5, 6, 7, 8, 9, 10) contained within the range. In this specification and the appended claims, the singular forms “a,” “an” and “the” include plural reference unless the context clearly dictates otherwise. All combinations of method steps or process steps as used herein can be performed in any order, unless otherwise specified or clearly implied to the contrary by the context in which the referenced combination is made.