PARRWASH

Abstract

The present disclosure provides a movable device and system for the application of pressurized fluid, collection of that fluid, and cleaning and recycling of that fluid for subsequent use. An application of the current device is in the washing of items, for example, automobiles.

Claims

1) A moveable washing system for reclaiming and processing fluid, comprising: a first holding compartment for holding the fluid; a second holding compartment in fluid in fluid communication with the first holding compartment; a third holding compartment in fluid communication with the second holding compartment; a support surface to support the movable washings system; and wherein the movable washing system is movable across the support surface.

2) A moveable washing system for reclaiming and processing fluid as in claim 1, wherein the movable washing system includes an inlet conduit to receive the fluid.

3) A moveable washing system for reclaiming and processing fluid as in claim 2, wherein the movable washing system includes a vacuum tank connected to the inlet conduit.

4) A moveable washing system for reclaiming and processing fluid as in claim 2, wherein the vacuum tank is connected to a vacuum device to generate a vacuum.

5) A moveable washing system for reclaiming and processing fluid as in claim 1, wherein the first holding compartment includes a tank baffling device to baffle the input fluid.

6) A moveable washing system for reclaiming and processing fluid as in claim 3, wherein the vacuum tank includes a sensor to control the fluid level within the vacuum tank.

7) A moveable washing system for reclaiming and processing fluid as in claim 1, wherein the first holding compartment is connected to the second holding compartment by a first transfer channel.

8) A moveable washing system for reclaiming and processing fluid as in claim 7, wherein the first transfer channel includes a filter to filter the fluid flowing between the first holding compartment and the second holding compartment.

9) A moveable washing system for reclaiming and processing fluid as in claim 1, wherein the second holding compartment includes the discharge pump to remove unwanted material from the second holding compartment.

10) A moveable washing system for reclaiming and processing fluid as in claim 1, wherein the second holding compartment includes a clarifier.

11) A moveable washing system for reclaiming and processing fluid as in claim 10, wherein the clarifier includes a plurality of inclined plates.

12) A moveable washing system for reclaiming and processing fluid as in claim 1, wherein the third holding compartment includes a high pressure pump to discharge the cleaning fluid.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] FIG. 1 is a schematic drawing of a system made in accordance with the current disclosure.

[0018] FIG. 2 is an image of a system made in accordance with the current disclosure.

DETAILED DESCRIPTION

[0019] Referring now generally to FIGS. 1 and, one embodiment of the present disclosure provides a system 10 for the reclamation of wastewater during a washing process. The system 10 may be movably connected to the support surface 5 which may be a concrete floor. The system 10 includes first, second, and third liquid holding compartments/containers 12, 14, and 16 respectively, which can also be described as holding tanks or processing tanks. These liquid holding compartments 12, 14, and 16 are fluidly connected to each other.

[0020] The first liquid holding compartment 12 is connected to a vacuum tank 18 which is operatively attached to a vacuum 20 and an intake conduit 22. The intake conduit 22 absorbs the fluid which may be contaminated from a force imparted by the vacuum 20 through the vacuum tank 18. Intake conduit 22 can be those items known in the industry to intake fluid, such as a hose with a proper nozzle or receptacle at the end. Alternately, the intake conduit 22 may be a collection tank used to collect the fluid used in the washing process.

[0021] The fluid can be moved through the intake conduit 22 and into the vacuum tank 18 by a vacuum 20. Within the vacuum tank 18, there can be a vacuum tank baffling/panel 17 used to direct the fluid into a desired location within the vacuum tank 18. This facilitates the fluid to remain in the vacuum tank 18 and not transferred to the vacuum 20. Additionally, a sensor 19 can be positioned within the vacuum tank 18. This vacuum tank sensor 19 can be a safety sensor used to control the vacuum 20 when the fluid level within the vacuum tank 18 gets to an undesirable level. This vacuum fluid sensor 19 can also indirectly control the opening 24 in the vacuum tank 18 that communicates with the first liquid holding compartment 12. The opening 24 can have a valve or other fluid control to regulate the flow of fluid from the vacuum tank 18 to the first liquid holding compartment 12. The filter or a valve can be controllable by the logic controller 11 of the system 10. The fluid can flow from the vacuum tank 18 through the opening 24 into the first liquid holding compartment 12.

[0022] The fluid enters the first liquid holding compartment 12 through an opening in the top of the first liquid holding compartment 12 and proceeds to a first side of the baffle/panel 26. Particles in the fluid can settle to the bottom of the first liquid holding compartment 12. Oil, since it is lighter than water, the fluid typically used in washing items, will maintain its position on top of the water. Further, since the baffle 26 preferably extends the full width of the first liquid holding compartment 12, the oil will remain on the first side of the baffle. As the water flows down and around the baffle, the oil does not flow with it. On the second side of the baffle 26 is a first transfer channel 28, or first opening, between the first tank 12 and the second 14.

[0023] This first transfer channel 28 can include a filter or valve as desired. This facilitates movement of the liquid from the first holding tank 12 to the second holding tank 14. Additionally, a discharge pump (not shown) can be operatively connected to the bottom area of the second holding tank 14. This discharge pump can remove sludge and solidified impurities from the second holding tank 14. In practice, a grate or filter-type device can be spaced from the bottom of the second holding tank 14. This can allow the impurities to fall to the bottom to a removable location for their removal through the discharge pump.

[0024] As the liquid transfers to the second holding tank 14, a lamella-style incline plate clarifier 30 is positioned which may extend the width of the second holding tank 14. A lamella clarifier or inclined plate settler (IPS) is a type of settler designed to remove particulates from liquids.

[0025] They are often employed in primary water treatment in place of conventional settling tanks. They are used in industrial water treatment. Unlike conventional clarifiers, they use a series of inclined plates. These inclined plates provide a large effective settling area for a small footprint. The inlet stream is stilled upon entry into the clarifier. Solid particles begin to settle on the plates and begin to accumulate in collection hoppers at the bottom of the clarifier unit. The sludge is drawn off at the bottom of the hoppers and the clarified liquid exits the unit at the top over a weir

[0026] The liquid within the second holding tank 14 will enter the second holding tank 14 on the backside of the clarifier 30 and travel down the second holding tank 14 behind the clarifier 30. The clarifier 30 extends the full width, and/or depth, of the second holding tank 14. There is a filtering area 32 of the clarifier 30 through which the fluid travels as it moves from the backside of the clarifier 30 through to the front side of the clarifier 30. This filtering area further helps cleanse and filters the liquid. A coagulator that causes coagulation (clumping or solidifying). is formed in the holding tank 14 to solidify particles floating within the liquid. These particles will then drop to the bottom of the second holding tank 14 and can be removed by the discharge pump 34.

[0027] The liquid, once it passes through the filtering area 32, can pass through an opening 36 between the second holding tank 14 and the third holding tank 16. This opening 36 can include an additional screen, filter, or valve as desired. A sensor 38 can be positioned in the second holding tank 14 (for example on the wall of the tank 14) to monitor the level of liquid within the second holding tank 14. If this level gets too high, the sensor 38 can initiate through the logic controller 11, the discharge pump 34 to remove fluid from the second holding tank 14.

[0028] The liquid, as it passes through opening 36, enters the third holding tank 16. The third holding tank 16 can include an opening 40 connected to a high pressure pump 42 that is connected to a discharge conduit 44 and/or a hose or nozzle. The high pressure pump 42 through the discharge conduit 44 can send the fluid to its use and operation as desired by an operator of the system 10, for example, washing items such as automobiles. Within the third holding tank 16, there can be a fluid applicator 46, such as an aerator 46, that add fluid, such as a liquid or gas, including oxygen, to the liquid in the third holding tank 16. Alternately, this fluid applicator can add other liquids or gases as desired.

[0029] Additionally, the third holding tank 16 can include another chemical applicator 48 in which additional products can be added to the liquid contained therein. The chemical applicator 48, can, for example, add a defoamer to the fluid to remove foam that has been introduced into the fluid.

[0030] Further, a sensor 50 can be included in the third holding tank 16 to connect to the logic controller 11. This sensor 50 can regulate the amount of liquid within the third holding tank 16 by reading the level of the liquid in that third holding tank 16. When the liquid gets to a predetermined level, the sensor 50 can activate the high pressure pump 48 to discharge the fluid. This sensor 50 can be a float valve, or a high water level sensor 50, or other sensors known in the art. Additionally, through the fluid applicator 46, additional fluid can be added to the third holding tank 16 as desired. This can be beneficial for example if there needs to be make-up water to properly supply the system 10 for the cleaning as desired. For example, additional fresh make-up water can be added to third holding tank 16 to supply the high pressure pump 42 and discharge conduit 44 with a proper amount of water to wash items as intended by the system 10.

[0031] In operation, the system 10 can be filled to a desired capacity with fresh liquid, such as water. Each tank can have applied to it fresh water to fill them up to a desired starting or operating level. Once the high pressure pump 42 is turned on, water will flow through the discharge conduit 44 to clean items as desired by a user of the system 10. An intake conduit 22 can be proximate the item being washed by the system 10. The intake conduit 22 can use a force from the vacuum 20 to vacuum up the water into the vacuum tank 18.

[0032] During the operation, the water can hit the vacuum tank baffle 17 and drop into the vacuum tank 18. The opening 24 can be regulated such that the sensor 50 or the vacuum fluid sensor 19 can regulate when the opening 24 opens to allow fluid to pass to the first holding tank 12. These switches are connected to a logic control 11, which can be described as a programmable logical control which can generally control the operation of the system 10. The opening 24 can be a check valve that can close on a high vacuum pressure and open on a low vacuum pressure while in the vacuum fluid sensor 19 can be a float switch or other type sensor used to monitor the water level in the vacuum tank 18.

[0033] Once the liquid is in the first holding tank 12, it takes the path as previously described moving in front of the baffle 26 with the water flowing under and around to the opening 28 between the first holding tank 12 and second holding tank 14. Again, solids can fall to the bottom of the first holding tank 12 and be picked up by a discharge pump 27. As the level of fluid increases in the first holding tank 12 as received from the vacuum tank 18, the water level rises to a point where it enters that opening 28 and flows into the second holding tank 14.

[0034] In the second holding tank 14, the liquid flows, as previously described, behind the clarifier 30 and through the filtering area 32 up to the opening 36. The discharge pump 34 can remove particles that fall to the bottom of the second holding tank 14 as induced by the introduction of a coagulant into the second holding tank 14. As the fluid rises, it passes through opening 36 and into the third holding tank 16. In the third holding tank 16, make-up water and gases, such as air, can be added through the fluid applicator 46, which can include a liquid conduit and a gas conduit, or aerator. This make-up water and oxygen can be added into the fluid while in the third holding tank 16. The sensor 50 can regulate when the high pressure pump 42 is activated such that the water can continue through the discharge conduit 44 and continue the cleaning process that the user of the system 10 desires. Additionally, in the third holding tank 16 a chemical applicator 48 can apply a defoamer or other chemicals as desired to the fluid. The applicator 46 can include a valve 47 to regulate the flow of liquid and gas into the third holding tank 16. This valve 47 can again be controlled by the logic controller 11.

[0035] In a preferred embodiment, the system 10 can contain 360 gallons of liquid, such as water, and can be described as a self-contained wash water recovery system. The system has a modular wash treatment capability that can meet or exceed pretreatment regulations for automobile washing and water discharge. The device can be moved and relocated.

[0036] The system 10 can include first, second, and third holding tanks 12, 14, and 16 that can each hold 120 gallons of fluid. The system 10 has a control panel, such as the logic controller 11 that can be a Micrologix 820 PLC that can be modified and programmed and preset as desired by the user for efficient operation. The system can be set up for remote control operation of the system 10, such as Wi-Fi or internet connectivity.

[0037] The system 10 can include a square steel tubing exoskeleton frame with high density polyethylene walls and internal dividers between the holding tanks 12, 14 and 16. The system 10 is capable of a totally closed loop operation with a reclamation of approximately 100% of the water used during the washing process. This can be accomplished by gravity separation of oils and settable solids from the water used to clean. A second aspect of the system 10 includes a coagulation mixed into the water to further remove particles from the water. These particles have settled to the bottom and removed, such as pumped into a sanitary sewer system. The resulting clean water then overflows into the third holding tank 16 which can have a reservoir for the water used in the cleaning process.

[0038] The system 10 can use its high pressure pump 42 to replace a traditional pressure washer and alleviates bacteria and other items within the water by oxygenation, coagulation, and removal of sludge and sediment.

[0039] The system 10 can be programmable to use a preferred, or desired, amount of reclaimed water for return to the cleaning operation. There is a control knob which allows a percentage of the water to be reclaimed and adjusted based upon the amount of contaminants washed off the automobiles.