This disclosure relates generally to a mobile surface drying apparatus, and more particularly to an apparatus that extracts moisture that accumulates on a surface after a moisture generating event.
Many spectators at sporting events suffer through numerous race delays. For example, at a race car event, moisture may accumulate on the racetrack after a moisture generating event, such as a rainfall, has ceased. A relatively significant amount of time, expense and effort must be exhausted to remove the moisture from the racetrack prior to resuming the sporting event.
A mobile surface drying apparatus includes a vacuum fan, a blower fan, a vacuum and blower assembly and tubing. The vacuum and blower assembly includes a vacuum head powered by the vacuum fan and a blower head positioned next to the vacuum head and powered by the blower fan. The tubing connects the vacuum head to the vacuum fan and the blower head to the blower fan. The vacuum head includes an inlet that suctions moisture from a surface and the blower head includes an outlet that communicates airflow onto the surface to direct moisture toward the vacuum head to enable the vacuum head to extract the moisture from the surface.
A method for removing moisture from a surface with a mobile surface drying apparatus having at least one vacuum and blower assembly includes suctioning the moisture from the surface through an inlet of a vacuum head of the at least one vacuum and blower assembly, and simultaneously with the step of suctioning, communicating an airflow onto the surface through an outlet of a blower head positioned next to the vacuum head to direct the moisture toward the vacuum head to enable the vacuum head to extract the moisture from the surface.
The various features and advantages of this disclosure will become apparent to those skilled in the art from the following detailed description. The drawings that accompany the detailed description can be briefly described as follows.
The mobile surface drying apparatus 10 is traversable along the surface 12 in any direction, including an east/west path X, a north/south path Y and a transverse path Z. The mobile surface drying apparatus 10 extracts, dissipates, retains in a holding tank, and/or evaporates the moisture 14 that accumulates on the surface 12. In this disclosure, the moisture 14 that is extracted by the mobile surface drying apparatus 10 may include water, oil or any other liquid based substance that may accumulate on the surface 12. The mobile surface drying apparatus 10 is also capable of cleaning the surface 12, including removing debris, as is further discussed below.
In the illustrated example, the mobile surface drying apparatus 10 is a self-propelled vehicle. The operator cab 16 houses a hydrostatic drive 22 that powers the wheels 24 of the mobile surface drying apparatus 10 for traversing the mobile surface drying apparatus 10 at an operational speed along a desired path of the surface 12. In one example, the operational speed of the mobile surface drying apparatus 10 is approximately one mile per hour to approximately ten miles per hour. A person of ordinary skill in the art having the benefit of this disclosure would be able to design a self-propelled mobile surface drying apparatus that is capable of traversing along the surface 12 at a desired speed.
An internal combustion engine 26 powers the numerous components of the mobile surface drying apparatus 10. In this example, the internal combustion engine 26 drives a vacuum fan 28 and a blower fan 30 via a direct drive connection, such as a belt connection, for example. In another example, the blower fan 30 is driven by a separate electric motor. The internal combustion 26 also powers a hydraulic system 32 that powers the numerous onboard hydraulic mechanisms of the mobile surface drying apparatus 10. The hydraulic system 32 includes a hydraulic manifold 29 and a hydraulic reservoir 31.
The example mobile surface drying apparatus 10 includes a vacuum and blower assembly 34 that is powered by the vacuum fan 28 and the blower fan 30. In this example, the vacuum and blower assembly 34 is positioned near a front portion 33 of the operator cab 16. The vacuum and blower assembly 34 is selectively actuable to engage the surface 12 to extract, dissipate and/or evaporate the moisture 14 on the surface 12. The example vacuum and blower assembly 34 simultaneously communicates an airflow A onto the surface 12 and suctions the moisture 14 in a direction B opposite from the airflow A. That is, the example vacuum and blower assembly 34 includes an inlet 35 that generates a suction force and an outlet 27 that communicates an airflow onto the surface 12.
The mobile surface drying apparatus 10 further includes an operator communication interface 37 housed within the operator cab 16. The operator communication interface 37 is in electrical communication with an electric panel 39, which interconnects the wiring from the various components of the mobile surface drying apparatus 10. The operator communication interface 37, the electric panel 39 and the hydraulic system 32 cooperate to control the functioning of the numerous components of the mobile surface drying apparatus 10. A person of ordinary skill in the art having the benefit of this disclosure would understand how to design these components to control the functionality of the mobile surface drying apparatus 10.
The operator communication interface 37 acts as the command center for the mobile surface drying apparatus 10. For example, each system and associated component (i.e., the vacuum and blower assembly 34, etc.) of the mobile surface drying apparatus 10 is independently activated/deactivated by the operator via the operator communication interface 37. The operator communication interface also provides diagnostic information to the operator, including displaying component performance and warning aids to the operator.
In one example, the vacuum and blower assembly 34 is engaged relative to the surface 12 at the command of the operator via the operator communication interface 37. The vacuum and blower assembly 34 will not function to extract moisture from the surface 12 absent a command from the operator communication interface 37. In one example, the operator communication interface 37 selectively commands the hydraulic system 32 to lift, lower, extend, and/or retract the components of the mobile surface drying apparatus 10 to enable the extraction of moisture 14 from the surface. The carriage 20 may be hydraulically controlled by the hydraulic system 32 at the command of the operator communication interface 37 to position the carriage 20 at a desired spacing relative to the surface 12. In one example, the hydraulic system 32 includes pneumatic cylinders (not shown) for positioning the carriage 20.
A traction control system 41 is also selectively actuable by the operator via command from the operator communication interface 37. The traction control system 41 includes a plurality of dual contact wheels 43 that are lowered and raised to selectively engage/disengage the surface 12. The dual contact wheels 43 are raised and lowered via the hydraulic system 32. The traction control system 41 permits the mobile surface drying apparatus 10 to remain square to the surface 12 during areas of steep embankments, such as 30°-40° banked roadways encountered on race tracks, and reduces the tendency of the mobile surface drying apparatus 10 to slide down the embankments. The traction control system 41 may also include additional outrigger dropdown support wheels and counterweights that provide additional stability to the mobile surface drying apparatus 10.
A plurality of video cameras 45 are strategically located about the mobile surface drying apparatus 10 to provide the operator with visual confirmation of the positioning of the mobile surface drying apparatus 10 and the effectiveness of the moisture extraction. In one example, the operator communication interface 37 includes a video monitor that provides the operator with a live feed of the video recorded by the video cameras 45.
The blower head 38 is powered by the blower fan 30, and is operable to communicate an airflow A from the vacuum and blower assembly 34 onto the surface 12 to dry the surface 12. The blower head 38 also effectively directs the moisture 14 toward the vacuum head 36 to enable to vacuum head 36 to extract the moisture 14 from the surface 12. The blower head 38 is connected to the blower fan 30 via flexible tubing 44. The vacuum head 36 and the blower head 38 are mounted between rollers 46 on a support bracket 48. In this example, the vacuum head 36 is positioned fore the blower head 38 as the vacuum and blower assembly 34 traverses in a direction D along the surface 12.
The vacuum and blower assembly 34 is positionable at a distance X relative to the surface 12. The actual value of the distance X is not critical; however, a person of ordinary skill in the art having benefit of this disclosure would understand that it is desirable to position the vacuum and blower assembly 34 in close proximity to the surface 12, and would be able to position the vacuum and blower assembly 34 at any desired distance relative to the surface 12.
As depicted in
The dryer assembly 54 communicates hot air onto the surface 12 for facilitating the removal of the moisture 14 from the surface 12. The example dryer assembly 54 includes a forced air platform 58, an airflow system 60 and a jet burner system 62. The airflow system 60 includes a plurality of high flow air blowers 64 each having their own ducting 66 that communicate airflow to the forced air platform 58.
The jet burner system 62 of the dryer assembly 54 includes a plurality of jet burners 68 (See
The forced air platform 58 is mounted to the carriage 20 adjacent an rear most portion R of the mobile surface drying apparatus 300. In one example, the forced air platform 58 is mounted to the carriage 20 via a hydraulic cylinder 56. However, other mounting configurations are contemplated as within the scope of this disclosure. In one example, the forced air platform 58 is only operable when engaged in a lowered position LP relative to the surface 12.
The internal combustion engine 26 powers the blower assembly 80, which directs heated air through the ducting 86 to the hot air platform 84 to facilitate a final stage of drying of the surface 12. The burner 82 heats the air communicated from the blower assembly 80 prior to communicating the air to the hot air platform 84. In one example, the burner 82 heats the air to approximately 800° F. and 12,000 CFM. A fuel delivery system 88 having fuel tanks 90 fires the burner 82. In one example, the blower assembly 80 includes two centrifuge blowers that are belt driven by the internal combustion engine 26.
Yet another mobile surface drying apparatus 500 is depicted in
A person of ordinary skill in the art having the benefit of this disclosure would be able to implement a debris management system 96 within any of the example mobile surface drying apparatuses 10, 100, 200, 300, 400, 500 and 600. In this example, the debris management system 96 is mounted to a front most portion of the operator cab 16. However, other mounting locations are contemplated as within the scope of this disclosure.
Although specific features of this disclosure are illustrated in some figures and not in others, this is for convenience only; as each feature may be combined with any or all of the other features in accordance with this disclosure.
The foregoing description shall be interpreted as illustrative and not in any limiting sense. A worker of ordinary skill in the art having the benefit of this disclosure would recognize that certain modifications could come within the scope of the disclosure. For these reasons, the following claims should be studied to determine the true scope and content of this disclosure.
This application is a continuation of U.S. patent application Ser. No. 12/512,270, filed Jul. 30, 2009, which claims priority to U.S. Provisional Application No. 61/085,122, filed Jul. 31, 2008.
Number | Date | Country | |
---|---|---|---|
61085122 | Jul 2008 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 12512270 | Jul 2009 | US |
Child | 13608136 | US |