Patent Application
20140263751
The present invention relates generally to pressure washer systems, and in particular, to a foaming nozzle assembly useable with such devices.
Pressure washers generally include a motor or engine that is operatively connected to a water pump. A high pressure hose connects a wand to a discharge side of the water pump. The wand commonly includes a pistol grip or the like that includes a trigger whose actuation effects discharge of a high-pressure water stream from the nozzle. Both the simplicity of operation and effectiveness associated with using such devices has made pressure washers a staple for various residential and commercial cleaning and surface preparation tasks. Understandably, many cleaning and surface preparation operations are best carried out with the use of extraneous cleaning or surface treatment agents. For instance, many deck and fence cleaning agents, automotive and/or fiberglass soaps, concrete cleaners, excreta, are commercially available and tailored to improve the efficiency of the particular cleaning operation. To better effectuate the cleaning or surface preparation operations, many power washers are configured for use with such soaps or agents.
Such agents are commonly introduced either via a high-pressure injector that introduces the agent to the pressurized water-stream downstream of the pump or a low-pressure injector that introduces the agent to the water-stream before feed water enters the pump. Regardless of the delivery methodology and the type of treatment agent, it is periodically desired to create a foaming action of the mixture upon delivery of the mixture to the surface intended to be treated. To generate the foaming action, air must be introduced to the agent and water mixture. Various attempts have been made to improve the foaming action associated with various power washing devices. Some such systems include extraneous systems such a compressed air sources that can be connected to the fluid stream generated by the nozzle associated with the wand associated with the pressure washing device. Still others having attempted to improve foaming action by providing supplemental nozzle assemblies that cooperate with either the wand or a nozzle associated therewith. Such systems commonly include a fairly tortuous fluid path associated with generating the mixing action of the water, treatment agent, and the air associated with generating the foaming action. Such systems are not however not without respective drawbacks.
Systems that rely on extraneous pressurized air sources are commonly more expensive to implement as a function of the additional hardware associated with generating the pressurized air flow. Such systems also increase the cost and complexity associated with the wand to facilitate the desired introduction of the air stream with the liquid fluid flow. Whether upstream or downstream of the wand nozzle assembly, such systems commonly require extraneous connection ports associated with communicating the air stream to the liquid fluid flow. Such systems also complicate operation of the systems in that users are required to monitor the operation of the various components associated with maintaining the desired air flow.
Although foaming nozzle assemblies resolve some of the complications associated with extraneous air systems, such nozzle assemblies are generally fairly complex and can include multiple fixed and/or moving parts associated with generating the desired communication of the liquid fluid and air flow through the nozzle assembly. Some such systems also require cooperation with a nozzle having a specific configuration and previously associated with the wand of the power washing system. Still other systems include auxiliary attachments that require direct contact between the attachment and the surface to be treated to generate the desired foaming action. Some such systems include a stringent multi-step connection methodology associated with engaging the components associated with the foaming activity to the underlying wand thereby detracting from the convenience of configuring the pressure washing device for other uses wherein foaming may not be desired.
Therefore, there is a need for a foaming nozzle assembly that is convenient to use and is operable with an underlying pressure or power washer without the need for extraneous systems to generate the desired foaming action.
The present invention provides a foaming nozzle or foaming nozzle assembly and method of forming a foaming nozzle for use with pressure washing systems that overcomes one or more of the drawbacks mentioned above. A foaming nozzle assembly according to one aspect of the invention includes a tube and a cover that cooperates with the tube. An interior surface of the tube defines a fluid path having by a first restriction, a second restriction, and an expansion chamber between the restrictions. An air path is defined between the cover and tube and fluidly connects the expansion chamber to atmosphere for introducing air to fluid associated with the fluid path. An atomizer is disposed downstream of the restrictions and expansion chamber and mixes the fluid and air to generate foam upon discharge of the mixture from the nozzle assembly.
Another aspect to the invention that is usable with one or more of the features of the above aspect discloses a nozzle assembly for foaming a fluid flow generated by a power washer. The nozzle assembly includes an inner body having first end constructed to cooperate with a discharge end of a wand and second end that is longitudinally offset from the first end. A passage is formed through the inner body and a first restriction and a second restriction are formed in the passage and defined by the inner body. A first expansion chamber is formed between the first restriction and the second restriction and a second expansion chamber is formed downstream of the first expansion chamber and the second restriction. An outer body is disposed over a portion of the inner body and defines an outlet associated with fluid communicated through the inner body. At least one port is formed through the outer body and fluidly connects the first expansion chamber to atmosphere to allow air to enter a fluid stream between the first and second restrictions.
Another aspect of the invention that is useable with one or more of the above aspects discloses a foaming nozzle having an outer housing that has a discharge opening. An aeration port extends through the outer housing at a location that is offset from the discharge opening. A tube is disposed in the housing and overlaps the aeration port. The tube has a first end that faces a wand and a second end that is proximate the discharge opening of the outer housing. A fluid path is formed by an interior surface of the tube and an aeration path is formed between the outer housing and the tube. The aeration path fluidly connects the aeration port with the fluid path such that air that enters the aeration port travels in an opposite direction relative to a direction of flow through the fluid path.
A further aspect of the invention that is usable with one or more of the above aspects discloses a method of forming a foaming nozzle for use with a pressure washer. The method includes providing a tube that removably cooperates with a wand of a pressure washer. The method further defines that the tube has an internal fluid path that includes a first restriction, a second restriction, and an expansion chamber formed between the first and second restrictions. A cover is provided that overlies a portion of the tube such that the cover and the tube cooperate with one another to directly connect the expansion chamber to atmosphere for introducing air to the internal fluid path at a location that is between the first and second restrictions. An atomizer is disposed between the tube and the cover at a location that is downstream of the second restriction and improves the air and fluid stream mixing prior to discharge of the mixture from the foaming nozzle.
Other aspects, features, and advantages of the invention will become apparent to those skilled in the art from the following detailed description and accompanying drawings. It should be understood, however, that the detailed description and specific examples, while indicating preferred embodiments of the present invention, are given by way of illustration and not of limitation. Many changes and modifications may be made within the scope of the present invention without departing from the spirit thereof, and the invention includes all such modifications.
The drawings illustrate the best mode presently contemplated of carrying out the invention.
In the drawings:
With respect to pressure washer 40, engine 42 can be directly or indirectly (via a power transmission system such as a belt or other flexible drive member) coupled to pump 44. When engine 42 directly cooperates with pump 44 without supplemental power transmission systems, pump 44 can be considered a direct drive pump. It is appreciated that there a number of methodologies associated with generating a desired fluid pressure output associated with use of pressure washer 40. One methodology includes providing a pressure output of the pump that is a function of the operational revolutions per minute (rpm) of the pump and which is directly correlated to the operation speed or revolutions per minute (rpm) of the engine crankshaft. The higher the rpm of the pump, the higher the pump output pressure—assuming other system variables to be constant. In such a confirmation, the input rpm of the pump is controlled by the engine rpm by means of controlling the engine throttle such that, variable pressures can be provided at the pump output pressure via manipulation of the engine throttle or engine speed. Alternatively, it is appreciated that the pressure output of pump 44 may be manipulated by a regulator as disclosed below. The variable pressure pump output in conjunction with an engine speed or pump pressure selector dial allows one pressure washer to act as though it were capable of providing several different fixed operating pressures.
As alluded to above, another methodology for manipulating the pump discharge pressure delivered to the wand includes providing a variable setting regulator or bypass valve assembly associated with operation of the pump. Such a configuration includes a valve assembly that is integral to the pump or disposed between pump 44 and a wand 46 for communicating the pressurized fluid flow to wand 46 connected to pump 44. As explained further below, the valve assembly includes a control or regulator associated with regulating the pressure flow communicated to the wand in a manner partially independent of engine operating speed. That is, such a regulator allows the delivery of fluid to wand 46 at variable pressures at or below a maximum output pressure associated with the available water source pressure and given operating conditions of engine 42.
Still referring to
Pressure washer 40 can include a panel, bezel, or dashboard 61 that can include one or more instructional indicia 64 associated with the desired operation or intended use of pressure washer 40. Preferably, dashboard 61 includes one or more indicia that explain, either textually or pictographically, proper operation of pressure washer 40. Preferably, dashboard 60 includes one or more receptacles or mounting portions 66 associated with supporting replaceable or interchangeable tips or nozzles 72, 74, 76, 78, 80 associated with the desired use of pressure washer 40. As is readily understood, nozzles 72-80 are configured to interchangeably cooperate with the discharge end 52 of wand 46 so as to replace foaming nozzle 38 for non-foaming operations. Alternatively, it is appreciated that one more of nozzles 72, 74, 76, 78, 80 could be adjustable such that the discrete nozzles could provide more than one desired spray pattern.
It is further appreciated that wand 46 or pressure washer 40 include a treatment agent introduction system 104 for introducing a cleaning or treatment agent to the fluid flow delivered to wand 46 via hose 48. It is appreciated that agent introduction system 104 could be configured to introduce such a treatment agent to the feed water stream at a low pressure or a high pressure side of pump 44, prior to delivery of the operating fluid to wand 46, or immediately prior to the introduction of the operating fluid stream to foaming nozzle 38 at discharge end 52 of wand 46. It is further appreciated that although agent introduction system 104 is shown as being supported proximate engine 42 and pump 44 associated with chassis 54, agent introduction system 104 could be associated with hose 48 and/or supported and/or integrated with wand 46. Regardless of the specific location of agent introduction system 104, each such configuration allows introduction of the treatment agent to the water stream at a location that is upstream of foaming nozzle 38—relative to the operating direction of the fluid stream, such that the fluid stream introduced to foaming nozzle 38 is a mixture of treatment agent and the pressurized water stream.
Referring to
Cover 90 includes one or more openings, passages, aeration ports or simply ports 108 that extend in a radial direction through cover 90 relative to axis 98. Preferably, aeration ports 108 are spaced radially along the circumference of cover 90 between first end 94 and second end 96 of cover 90. Preferably, aeration ports 108 are nearer second end 96 than first end 94. As explained further below, aeration ports 108 form a portion of an air path associated with connecting the fluid stream directed through foaming nozzle 38 to atmosphere and facilitate the introduction of air into the fluid stream prior to discharge of a mixed air and fluid stream at discharge opening 104.
A radially outward surface 120 of tube 92 between first end 114 and second end 116 includes a first channel or groove 124 that is nearer threaded portion 100 and a second channel or groove 126 that is nearer second end 116. A first and a second gasket or seal 128, 130 are shaped to be received in grooves 124, 126 and to extend beyond surface 120. Seals 128, 130 are shaped to slidably and sealingly cooperate with an interior facing surface 127 of cover 90 when foaming nozzle 38 is assembled. As explained further below, such a construction mitigates the fluid flow passing through tube 92 from entering any cavities or passages formed between the outer surface of tube 92 and the inner facing surface 127 of cover 90.
A portion 132 of tube 92 between groove 124 and groove 126 includes a number of slots, cavities, channels, or recesses 136 and a number of ribs or ridges 138 that are positioned between adjacent recesses 136. Recesses 136 and ridges 138 preferably extend in a longitudinal direction that is generally aligned with axis 98 and are preferably spaced about the circumference of portion 132 of tube 92. An opening or slot 140 is associated with each recess 136 and extends in a radial direction through tube 92. Slots 140 provide a fluid connection between an interior passage or fluid path 142 of tube 92 and outer surface 120 of tube 92. However, as explained below, cover 90 and tube 92 are constructed to cooperate with one another and manipulate the fluid flow directed therethrough to allow air to infiltrate the fluid flow associated with fluid path 142 while preventing the egress of fluid flow via ports 108. When foaming nozzle 38 is assembled, slots 140 and recesses 136 of tube 92 are oriented to be generally rotationally aligned with a respective aeration port 108 associated with cover 90.
A portion 160 of first expansion chamber 156 is oriented upstream, or in a direction inapposite to the working fluid flow direction, indicated by arrow 162, relative to an outlet opening 164 of first restriction 152. Slots 140 of tube 92 are fluidly connected to portion 160 of first expansion chamber 156. An aeration passage 166 extends in a longitudinal direction, indicated by axis 98, between each of slots 140 of tube 92 and ports 108 of cover 90. As explained further below, air traveling through aeration passages 166 travels in upstream direction 162, or a direction opposite to the fluid flow direction 150 within tube 92, from atmosphere around foaming nozzle 38. The air communicated along aeration passages 166 enters the agent and water fluid stream as the fluid flow progresses through tube 92 in downstream flow direction 150 from first expansion chamber 156 and toward second restriction 154. As explained further below, the downstream manipulation of the combined fluid and air solution generates foam upon egress of the mixture at discharge opening 104 of cover 90.
An atomizer 168 is disposed between second end 116 of tube 92 and discharge opening 104 of cover 90. Atomizer 168 is preferably constructed of a mesh wire material or is otherwise constructed to fully mix the fluid and air flow mixture introduced thereto from second expansion chamber 158 of tube 92. The pressure and physical mixing of the constituents associated with the flow discharged from second end 116 of tube 92 generates foam 170 during use of foaming nozzle 38.
During operation of pressure washer 40, a water and treatment agent mixture is introduced to tube 92. This fluid mixture is pressurized as it passes through first restriction 152. Upon egress of the fluid mixture at an outlet 164 associated with first restriction 152, an increase in volume associated with first expansion chamber 156 creates a vacuum pressure that allows atmospheric air to be drawn through port 108 of cover 90, travel upstream along aeration passage 166 between tube 92 and cover 90, and be introduced to the fluid flow via slots 140 associated with tube 92. The water, agent, and air mixture progresses downstream 150 along second restriction 154 gradually increasing the pressure of the fluid flow prior to entry of the fluid and air mixture into second expansion chamber 158.
Second restriction 154 and expansion chamber 158 of tube 92 provide preliminary mixing of the water, agent, and air carried on the fluid stream downstream of expansion chamber 156 prior to introduction of the mixture to atomizer 168. Atomizer 168 provides further mixing of the water, agent, and air prior to discharge of the air infused mixture at discharge opening 104 of cover 90 as foam 170. Foaming nozzle 38 provides a compact and eloquent foaming nozzle assembly that includes no moving parts and which is convenient to service. Foaming nozzle 38 provides a nozzle assembly that cooperates with pressure washer 40 in a manner that does not detract from the functionality of the pressure washer 40 or use of the pressure washer for foaming and other non-foaming applications.
Many changes and modifications could be made to the invention without departing from the spirit thereof. The scope of these changes will become apparent from the appended claims.
