Parts washer system Number:7,146,991 from the United States Patent and Trademark Office (PTO) owispatent An industrial parts washer system includes washing fluid, an assembly operable to apply the washing fluid to the part, a turbidity sensor coupled to the assembly operable to sense a condition of the washing fluid after the fluid washes the part, and a control unit connected to the sensor that compares the sensed condition of the washing fluid to a value and thereby determines whether the part should be washed further.<H system, washer, Parts, washer, sy, 7146991.html, Patent, pto, 7146991

Title: Parts washer system

Abstract: An industrial parts washer system includes washing fluid, an assembly operable to apply the washing fluid to the part, a turbidity sensor coupled to the assembly operable to sense a condition of the washing fluid after the fluid washes the part, and a control unit connected to the sensor that compares the sensed condition of the washing fluid to a value and thereby determines whether the part should be washed further.

Patent Number: 7,146,991 Issued on 12/12/2006 to Stockert

Inventors: Stockert; David L (New Boston, MI)
Assignee: Cinetic Automation Corporation (Farmington Hills, MI)

Appl. No.: 10/342,977

Filed: January 15, 2003

Current U.S. Class: 134/57R ; 134/111; 134/131; 134/184

Current International Class: B08B 3/02 (20060101)

Field of Search: 134/56R,57R,111,124,129,131,184

References Cited [Referenced By]

U.S. Patent Documents


2202344	May 1940	Hamilton et al.
2405838	August 1946	Lawson et al.
2837685	June 1958	Umbricht
2857922	October 1958	Effinger
2926674	March 1960	Umbricht et al.
3030896	April 1962	Umbricht et al.
3030971	April 1962	Umbricht et al.
3059861	October 1962	Umbricht et al.
3102057	August 1963	Umbricht et al.
3276458	October 1966	Iversen et al.
3439810	April 1969	Newman et al.
3443567	May 1969	Moore
3605775	September 1971	Zaander et al.
3614231	October 1971	Shaw
3624750	November 1971	Peterson
3664355	May 1972	Adams
3870417	March 1975	Bashark
3888269	June 1975	Bashark
4054148	October 1977	Gurr
4067293	January 1978	Probst
4117855	October 1978	Olcott et al.
4222250	September 1980	Torita
4323398	April 1982	Simon
4325161	April 1982	Wood et al.
4381794	May 1983	Stimac et al.
4409999	October 1983	Pedziwiatr
4469526	September 1984	Budinsky et al.
4571270	February 1986	Sasaki
4582077	April 1986	Gabriel et al.
4600444	July 1986	Miner
4722295	February 1988	Young
4731154	March 1988	Hausman Hazlitt et al.
4796042	January 1989	Mappin et al.
4893320	January 1990	Yanagi et al.
4941971	July 1990	Albright
4995409	February 1991	Watts
4996160	February 1991	Hausman Hazlitt et al.
5154199	October 1992	Thompson et al.
5172572	December 1992	Ono
5174315	December 1992	Hellstern et al.
5188135	February 1993	Neumann et al.
5201958	April 1993	Breunsbach et al.
5265446	November 1993	Kuroda et al.
5272892	December 1993	Janutka et al.
5276998	January 1994	Joen et al.
5284523	February 1994	Badami et al.
5291626	March 1994	Molnar et al.
5330580	July 1994	Whipple, III et al.
5339844	August 1994	Stanford, Jr. et al.
5346629	September 1994	Wuller
5357648	October 1994	Noestheden
5368053	November 1994	Wilson
5396178	March 1995	Rybarski
5411042	May 1995	Suzuki et al.
5421883	June 1995	Bowden
5444531	August 1995	Foreman et al.
5470394	November 1995	Michel et al.
5545259	August 1996	Suzuki et al.
5555583	September 1996	Berkcan
5560060	October 1996	Dausch et al.
5586567	December 1996	Smith et al.
5647386	July 1997	Kaiser
5661872	September 1997	Meyer et al.
5706840	January 1998	Schneider et al.
5730163	March 1998	Meyer et al.
5746233	May 1998	Kuroda et al.
5800628	September 1998	Erickson et al.
5923432	July 1999	Kral
5931173	August 1999	Schiele
5954070	September 1999	Abad et al.
5954071	September 1999	Magliocca
5960804	October 1999	Cooper et al.
6007640	December 1999	Neff et al.
6073540	June 2000	Garrett
6073640	June 2000	McTaggart
6115541	September 2000	Rhodes
6119365	September 2000	Wuller et al.
6126099	October 2000	Fachinger et al.
6129099	October 2000	Foster et al.
6244279	June 2001	Bowden
6334266	January 2002	Moritz et al.
2001/0015096	August 2001	Hoffman

Foreign Patent Documents


656624	Jan., 1963	CA
667441	Jul., 1963	CA
669262	Aug., 1963	CA
699331	Dec., 1964	CA
699537	Dec., 1964	CA
0 227 275	Jul., 1987	EP
817851	Aug., 1959	GB
817860	Aug., 1959	GB
55-103608	Aug., 1980	JP
59-97512	Aug., 1981	JP
60-16275	Jan., 1985	JP
60-21798	Feb., 1985	JP
60-163689	Aug., 1985	JP
61-25599	Feb., 1986	JP
62-259442	Nov., 1987	JP
2-107296	Apr., 1990	JP

Other References

Owner's Manual, "Model 215W Liquidborne Laser Particle Counter", (believed to have been published and/or offered for sale in 1995). cited by other.

Primary Examiner: Perrin; Joseph L.
Attorney, Agent or Firm: Harness, Dickey & Pierce, P.L.C.

Claims

The invention claimed is:

1. An industrial parts washer system operable to wash an industrial part, the parts washer system comprising: washing fluid; a flushing assembly operable to apply the washing fluid to the industrial part; a single turbidity sensor coupled to the assembly operable to sense a condition of the washing fluid after the fluid washes the industrial pad; and a control unit connected to the sensor, the control unit operably comparing the sensed condition of the washing fluid to a value in order to determine if the industrial part should be washed further, the control unit operably stopping the assembly from flowing the washing fluid to the part, moving the washed part out of the assembly, and moving a subsequent dirty part into the assembly, if the sensed condition of the washing fluid substantially equals the value.

2. The parts washer system of claim 1 wherein the assembly includes: a seal and flushing device being automatically advanced toward the part; and an inflow system operable to transport the washing fluid to the flushing device; the seal operably contacting against the part such that the flushing device operably causes the washing fluid to flow to the part.

3. The parts washer system of claim 2 wherein the assembly further includes an outflow system operable to transport the washing fluid away from the part after the part is washed, and the sensor being coupled downstream of at least a section of the outflow system.

4. The parts washer system of claim 3 wherein the outflow system includes a manifold having multiple inlets, and the sensor is located downstream of the manifold.

5. The parts washer system of claim 1 further comprising a conveyor operably carrying multiples of the part to the assembly in an automatic manner.

6. The parts washer system of claim 5 further comprising: a filter located downstream of the assembly operably filtering undesired particles from the washing fluid; a settling tank located downstream of the filter operably removing further undesired particles from the washing fluid; and a pump operably flowing the fluid from the settling tank to the assembly.

7. The parts washer system of claim 1 wherein the cleaning fluid is a liquid which includes an industrial degreasing detergent.

8. The parts washer system of claim 1 wherein the part is an automotive vehicle powertrain component and the parts washer system cleans the automotive vehicle powertrain component.

9. The parts washer system of claim 8 wherein the part includes an elongated internal passage and the parts washer system provides fluid to flow through the elongated internal passage.

10. The parts washer system of claim 1 wherein the sensor is a particle counter.

11. The parts washer system of claim 1 wherein the assembly flows the fluid to the part without submersing the part in the fluid.

12. The parts washer system of claim 1 further comprising a substantially closed loop system flowing the cleaning fluid to the assembly.

13. The parts washer system of claim 1 wherein the control unit is an electronic control unit.

14. The parts washer system of claim 1 wherein the flushing assembly includes a submersion tank.

15. An industrial parts washer system comprising: an automotive vehicle, powertrain part; a flushing assembly operable to apply the washing fluid to the part, the flushing assembly comprising a seal and a flushing device, the seal operably contacting against the part such that the flushing device operably causes the washing fluid to flow to the part; an inflow system operable to transport the washing fluid to the flushing device; a turbidity sensor operable to sense a condition of the washing fluid after the fluid washes the part; and a controller connected to the sensor, the controller automatically evaluating the sensed condition of the washing fluid and determining if the part should be washed further, and the controller outputting historical statistical trends.

16. The parts washer system of claim 15 further comprising an outflow system operable to transport the washing fluid away from the part after the part is washed, and the sensor being coupled downstream of at least a section of the outflow system.

17. The parts washer system of claim 15 further comprising a conveyor automatically carrying multiples of the part to be cleaned by the washing fluid.

18. The parts washer system of claim 15 wherein the flushing assembly includes a submersion tank.

19. The parts washer system of claim 15 further comprising a shuttle operably moveable into and out of a housing, the housing containing the flushing assembly.

20. The parts washer system of claim 15 wherein the part is an engine block.

21. The parts washer system of claim 15 wherein the part is a crankshaft.

22. The parts washer system of claim 15 wherein the seal has a substantially semi-circular part-contacting surface shape.

23. The parts washer system of claim 15 further comprising a cantilevered arm operably pivoting to move at least a portion of the flushing assembly.

24. An industrial parts washer system comprising: an automotive vehicle part; washing liquid, a flushing assembly operable to apply the washing liquid to the part; a shuttle automatically moving the part adjacent to the flushing assembly; a sensor operable to sense a turbidity condition of the washing liquid; and an electrical controller connected to the sensor, the controller automatically evaluating the sensed condition of the washing liquid and determining if the part should be washed further; the controller automatically stopping the flow of washing liquid to the part based at least in-part on the sensed condition of the washing liquid, and thereafter the controller being operable to cause the shuttle to move the part away from the flushing assembly and move a new dirty part adjacent to the flushing assembly to begin a new washing cycle.

25. The parts washer system of claim 24 wherein the assembly further includes an outflow system operable to transport the washing liquid away from the part after the part is washed, and the sensor being coupled downstream of at least a section of the outflow system.

26. The parts washer system of claim 25 wherein the outflow system includes a manifold having multiple inlets, and the sensor is located downstream of the manifold.

27. The parts washer system of claim 24 further comprising a seal having a substantially semi-circular part-contacting surface shape, the seal coupling the flushing assembly to the part.

28. The parts washer system of claim 24 wherein the part includes internal bores, the flushing assembly causing the washing liquid to flow into the bores, the controller determining if one of the bores is undesirably blocked.

29. The parts washer system of claim 24 wherein the flushing assembly includes a submersion tank.

30. The parts washer system of claim 24 wherein the part is an engine block.

31. The parts washer system of claim 24 wherein the part is a crankshaft.

32. The parts washer system of claim 24 further comprising a cantilevered arm operably pivoting to move at least a portion of the flushing assembly.

33. The parts washer system of claim 24 wherein the assembly includes: a seal and a flushing device being automatically advanced toward the part; and an inflow system operable to transport the washing liquid to the flushing device; the seal operably contacting against the part such that the flushing device operably causes the washing liquid to flow to the part; and the sensor being a turbidity sensor.

Description

BACKGROUND OF THE INVENTION

The present invention relates generally to industrial machinery and more specifically to a parts washer system.

Industrial parts washers are commonly used to remove debris, such as machining burrs, grease and dirt, from metallic parts such as engine blocks and crankshafts. Two such conventional devices are disclosed in Canadian Patent No. 669,262 entitled "Washing Apparatus" which issued to Umbricht on Aug. 27, 1963, and United Kingdom Patent No. 817,851 entitled "Improvements in or Relating to Washing Apparatus" which was published on Aug. 6, 1959. Another known industrial parts washer is disclosed in U.S. Pat. No. 3,059,861 entitled "Adjustable Spray Nozzle Assembly" which issued to Umbricht et al. on Oct. 23, 1962, and is incorporated by reference herein. Many traditional industrial parts washers typically flow a cleaning liquid onto the part for a predetermined period of time regardless of how clean the part actually is and regardless of part-to-part variability. Thus, the historical worst case scenario is commonly used to define the future predetermined period for cleaning which often leads to a sometimes slower than necessary process even for parts which are relatively clean after the prior machining operations.

Other cleaning devices are known in different industries as disclosed, for example, in the following U.S. patent application and patents: US 2001/0015096 A1 entitled "Monitoring of Particulate Matter in Water Supply" which was published on Aug. 23, 2001; U.S. Pat. No. 5,647,386 entitled "Automatic Precision Cleaning Apparatus with Continuous On-Line Monitoring and Feedback" which issued to Kaiser on Jul. 15, 1997; and U.S. Pat. No. 5,560,060 entitled "System and Method for Adjusting the Operating Cycle of a Cleaning Appliance" which issued to Dausch et al. on Oct. 1, 1996; all of which are incorporated by reference herein. These conventional devices, however, appear to have little application in the industrial parts industry for cleaning machining burrs and manufacturing plant dirt, especially for large parts having long internal passageways.

SUMMARY OF THE INVENTION

In accordance with the present invention, a parts washer system includes a cleaning fluid and a sensor. In another aspect of the present invention, an industrial parts washer includes a housing, a conveyor, a cleaning solution and a particle detector. Still another aspect of the present invention employs a controller which is operable to stop the cleaning of an industrial part if a debris-to-cleaner ratio reaches a target value. A method of operating a parts washer is also provided.

The present invention is advantageous over conventional machines in that the present parts washer easily determines the cleanliness of an industrial part in a non-obtrusive and real time manner. Thus, the cleaning cycle can vary from part-to-part as needed. Accordingly, cleaning quality is improved for parts having excessive burrs and debris while cycle time is quickened for relatively clean parts. The present invention thereby improves overall processing speed and quality while reducing traditional energy costs to run the process based on average or worse case times. Additional advantages and features of the present invention will become apparent from the following description and appended claims, taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagrammatic view showing the preferred embodiment of a parts washer system of the present invention;

FIG. 2 is a perspective view showing a portion of the preferred embodiment parts washer system;

FIG. 3 is a side elevational view showing a portion of the preferred embodiment parts washer system;

FIG. 4 is a perspective view, adjacent a part entry, showing a portion of the preferred embodiment parts washer system;

FIG. 5 is a perspective view, adjacent a top corner, showing a seal and flush mechanism employed in the preferred embodiment parts washer system;

FIG. 6 is a side diagrammatic view showing the seal and flush mechanism employed in the preferred embodiment parts washer system, with the mechanism in a raised position;

FIG. 7 is a side diagrammatic view, like that of FIG. 6, showing the seal and flush mechanism employed in the preferred embodiment parts washer system, with the mechanism in a closed position;

FIG. 8 is an end diagrammatic view showing the seal and flush mechanism employed in the preferred embodiment parts washer system, with the mechanism in a raised position;

FIG. 9 is a diagrammatic top view showing a first alternate embodiment of the parts washer system of the present invention;

FIG. 10 is a diagrammatic top view showing a second alternate embodiment of the parts washer system of the present invention; and

FIG. 11 is a diagrammatic top view showing a third alternate embodiment of the parts washer system of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring to FIGS. 1, 2, 4 and 6, the preferred embodiment of a parts washer system 21 is used in an industrial manufacturing plant to clean machining burrs, grease, dirt and other manufacturing debris from industrial parts or workpieces such as automotive vehicle powertrain components, including an engine block 23 (see FIG. 1), a metallic crankshaft 25 (see FIGS. 4 and 6), or the like. Parts washer system 21 operates as a cleaning station after a machining station (not shown) where the part has elongated internal pasageways or other features added by a milling machine, lathe, or similar automatic tools. Parts washer system 21 includes a sheet metal housing 27 affixed to the factory floor. Housing 27 essentially encloses the parts cleaning station yet has an entryway 29 for allowing access entry and exit by a horizontally moving shuttle 31 or other type of automatically operating conveyor. Shuttle 31 has a pair of parallel rails 33 upon which are mounted spaced apart perches 35 for carrying a set of parts 25 into the housing. A vertically movable access door (shown in a raised position in FIG. 2) is lowered after shuttle 31 moves inside housing 27.

FIGS. 4 8 show the internal components of parts washer system 21 for use with the crankshaft-type parts 25. A programmable logic controller ("PLC") first causes shuttle 31 to be automatically moved inside housing 27 to align each part 25 with a corresponding seal and flush unit 51. Seal and flush unit 51 includes a set of offset and parallel upper seals 53 having a generally semi-circular contacting surface shape made from a polymeric material such as polypropylene, polyurethane or nylon. Each upper seal 53 is affixed to a seal support 55 which has hollow bores to allow for internal fluid flow from an attached upper manifold 57. A flexible in-flow pipe or hose 59 is coupled to upper manifold 57 whereby clean washing fluid sequentially flows through in-flow pipe 59, through upper manifold 57, through upper seal supports 55, around a concave cross-sectional channel within the semi-circular contacting surface of each upper seal 53, which then contacts and seals against an upper matching surface of part 25. Each seal and flush unit 51 further includes a set of lower seals 61 and hollow seal supports 63 which are all in communication with and coupled to an outflow manifold 65. Lower seals 61 serve to collect the washing fluid that has been transmitted through the outside surface and internal passages in part 25 and then transfer the now dirty washing fluid to the outflow manifold 65.

A movement mechanism 71 employs a pivot bar 73 which is rotatably fixed to a frame 75, stationary relative to housing 27. An L-shaped arm 77 is rotatably cantilevered about pivot bar 73 at its elbow, and has a first end pivotally coupled to upper manifold 57 at a first pivot 79. A roller 81 is coupled to an outside of an opposite end of arm 77 and is located between two upstanding structures 83 which are fastened to one of the rails 33 of shuttle 31. Furthermore, guide pins 85 vertically slide within upstanding collars 87 affixed to a top wall of frame 75 in order to assist in accurate movement of the upper segment of seal and flush assembly 51. Accordingly, normal movement of shuttle 31 and parts 25 from the initial loading position external to housing 27, to the washing position aligned with seal and flush assembly 51 internal to housing 27 (parts 25 moving from right to left as shown in FIG. 8), causes structures 83 to rotate arm 77 about pivot bar 73 thereby lowering upper manifold 57 and the attached upper seals 53 to contact against part 25. A proximity or other electrical switch senses that seal and flush assembly 51 has engaged parts 25, whether directly or indirectly, and an appropriate signal is sent to the attached programmable logic controller 91 or other electrical control unit, such as a micro processor based personal computer controller 93 (see FIG. 3); the controller subsequently causes the cleaning process to begin by operating a set of motors and pumps to begin the flow of cleaning fluid.

Reference should now be made to FIGS. 1, 3, 7 and 8. A particle counter-type turbidity sensor 101 is coupled to an outflow pipe 103 which is, in turn, coupled to a downstream end of outflow manifold 65. One satisfactory particle counter sensor 101 is a model 215W Liquidborne Laser particle counter which can be obtained from Met One of Grants Pass, Oreg. Such a particle counter sensor includes a water weir flow controller 105, a sensor 107, an electrical module 109 for power and communications, an adapter 111, personal computer 93 for real-time sensing, data processing, storing and outputting particle counting data from the out flowing cleaning fluid and for comparing the actual sensed readings to either predetermined targets (representing a satisfactory cleaning fluid value or range) or previously sensed values thereby optimizing and controlling each washing cycle based on these real-time sensed values relative to the target values. In other words, the parts washer system performs by: (a) removing debris from a first machined workpiece by washing the first workpiece with a cleaning liquid; (b) sensing the cleanliness of the solution after workpiece washing; (c) communicating a signal of the sensed value to an electronic control unit; (d) automatically comparing the signal to a predetermined or target value; (e) determining the amount of debris in the liquid; (f) removing at least some of the debris from the liquid; (g) automatically varying a fluid flow characteristic of the liquid if the sensed value is substantially the same or different as compared to the predetermined value, wherein the characteristic includes, but is not limited to, re-using the liquid to subsequently remove debris from the same workpiece if the values are different, or automatically terminating the fluid flow and cleaning of the first workpiece if the sensed value of the liquid reaches the target debris-free value; (h) automatically removing the workpiece from the washer if the sensed value is substantially the same as the predetermined value; and (i) reusing the liquid to subsequently remove debris from additional workpieces. Furthermore, computer 93 stores, calculates and outputs historical statistical trends based on sensed cleaning fluid readings; this can include standard deviation and averaging calculations. Additionally, computer and particle counter sensor 101 can provide an output as to the filtering success for various desired time periods for the recycled cleaning fluid, in order to inform the operator as to when filter cleaning, cleaning fluid disposal or other maintenance may be desired in order to further optimize the process. The computer and particle counter sensor are further able to sense and calculate the cleanliness of the prior machining operations through sensed values and even if part aperture blockages have occurred as will be discussed in more detail with various of the alternate embodiments.

FIG. 1 shows the remainder of the parts washer system 21 fluid flow outside of the housing. A "dirty" settling tank 121 is connected to the downstream end of outflow pipe 103. A motor and pump 123 serve to pump cleaning fluid from tank 121 to a pre-filter separator 125 by way of another pipe 127. Pre-filter separator 125 employs an approximately 75 micron filtering system. Machining chips, debris and other settled out or filtered out particulate matter is then moved and discarded by way of a conventional chip drag and chip waste mechanism 129. A final filter assembly 131 is disposed downstream of pre-filter separator 125 to further filter out undesired particles and debris from the cleaning fluid by use of an approximately 50 micron filtering system. Final filter assembly 131 includes a media filter while pre-filter 125 employs a centrifugal filter. A "clean" settling tank 133 is located downstream of final filter assembly 131 and further allows for holding of the cleaning fluid for subsequent washing while allowing some additional particulate settling. Settling tank 133 includes a weir 135, an overflow pipe 137 and a cleaning drain 139. Another pump and motor 141 serve to flow the cleaning fluid from settling tank 133 to the part washing station within housing 27 when energized by the controller. It should be appreciated, however, that many other filtering and settling components can be used in place of or in addition to those disclosed herein. Notwithstanding, it is highly desirable to employ a closed loop and recyclable cleaning fluid system in order to reduce disposal costs and to save on cleaning fluid expense. The cleaning fluid is preferably a water borne, alkaline liquid solution containing a degreaser and a detergent. It is also envisioned that an electrolyte solution including disodium phosphate, sodium bicarbonate and water can be employed; such a solution is disclosed in U.S. Pat. No. 6,264,823 entitled "Non-Caustic Cleaning of Conductive and Non-Conductive Bodies" which issued to Hoffmann, Jr. et al. on Jul. 24, 2001, and is incorporated by reference herein.

Only a single particle counter sensor is needed, thereby saving equipment cost and reducing controller processing speed requirements, however, it is alternately envisioned that a second particle counter sensor located upstream of the part to be washed can be used in addition to the downstream particle counter sensor 101 in order to allow a more direct comparison calculation of real-time sensed fluid value measurements by the controller without possible variations caused by the closed loop system filters and tanks.

FIG. 9 illustrates a first alternate embodiment of a parts washer system 251 of the present invention. An in-flow pipe 253 and sealing unit 255 are automatically moved to contact and seal against a first side of an oil gallery, including a crankshaft bore, rocker arm paths, piston cylinder bores and the like, of an automotive vehicle engine block part or workpiece 257. At an opposite end of the oil gallery of engine block 257, an outflow pipe 259 and a corresponding sealing unit 261 are automatically moved to interface with part 257. This occurs within a housing of a parts washing station such as in the closed loop system of FIG. 1. A particle counter sensor 263 is coupled to outflow pipe 259 and an electrical control unit 265 is electrically connected to particle counter sensor 263. Thus, "clean" cleaning fluid automatically flows into the upstream side of part 257 and then exits as "dirty" cleaning fluid containing debris through outflow pipe 259. At this point, particle counter sensor 263 senses the concentration of debris within the cleaning fluid and sends a corresponding signal to controller 265 for processing of this information and comparing the real-time sensed values to the target cleaning fluid particulate concentration values in order to further control the cleaning cycle time.

FIG. 10 illustrates a second alternate embodiment of a parts washing system 301 of the present invention wherein an engine block part or workpiece is fully immersed or submerged into a tank 305 essentially filled with cleaning fluid. The cleaning fluid automatically enters through an upstream inlet 307, flows through passageways in and completely around part 303, and then subsequently exits through an outlet pipe 309 coupled to a particle counter 311 and an electrical control unit 313.

A third alternate embodiment parts washing system 351 of the present invention is shown in FIG. 11. An engine block part 353 or the like is placed within a housing of a cleaning station wherein a first end is automatically contacted by a sealing unit 355 connected to an in-flow pipe 357. An opposite end of part 353 has a sealing plug unit 359 automatically attached. A set of outlet lines or tubes 371 is automatically moved to contact and seal against corresponding external openings such as piston cylinder bores, of part 353. A cantilevered movement mechanism such as that disclosed with the preferred embodiment can be employed to automatically move lines 371 relative to part 353. A flow sensor 373 is located within each line 371 to sense the volume, speed or pressure of fluid flowing through the corresponding line. An electrical control unit 375, connected to the flow sensors 373 compares the real-time flow sensor readings against either predetermined desired target values or against a baseline reading from a flow sensor mounted within a diversion line 377 located upstream of part 353. A diversion valve 379 allows for a diverted initial fluid flow through diversion line 377 at the beginning of each part cleaning cycle which may thereafter be shut off. The controller comparisons and calculations based on the flow sensor signals allow for an automatic and computerized determination of whether a blockage, such as by incomplete machining, is present in any internal passageway or aperture within part 353. This provides real-time and automated quality control checking on every manufactured part even in hidden internal and elongated passageways. A particle counter sensor 381 is also positioned downstream and connected to outlet lines 371 and 377. Particle counter sensor 381 is electrically connected to controller 375 to determine the concentration of debris or other undesired particles within the cleaning fluid to thereby automatically monitor and control the parts washing cycle for each part or batch of parts. It should be appreciated that the flow sensor inspection/monitoring, calculations and system control can be used independently of the particle counter sensor functions.

Various embodiments of the present invention parts washer system have been disclosed, however, it should be appreciated that other modifications may be made. For example, while a liquid cleaning fluid has been disclosed, air or other gaseous cleaning fluids can also be used. It should also be appreciated that other nonindustrial and nonautomotive parts can be employed with the apparatus of the present invention although some of the advantages of the present invention may not be achieved. Furthermore, movement mechanisms such as those using sprockets and chains, jackscrews, cams or gears can be used instead of or in addition to the cantilevered mechanism disclosed. Moreover, magnetic, optical or electrical sensors can be substituted in place of the particle counter sensor disclosed, although the performance may vary. While various materials have been disclosed, it should be appreciated that other materials may be employed. It is intended by the following claims to cover these and any other departures from the disclosed embodiments which fall within the true spirit of this invention.

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