1. Field of the Invention
The present invention relates to oil removal devices used in combination with compressed air, heavy vehicle braking systems. More particularly, this invention is directed to a spin-on filtering oil removal cartridge disposed downstream from an air brake compressor that is easy to assemble and install, and which is easily serviced.
2. Discussion of the Art
Compressed air systems are used in brake systems to provide and maintain air under pressure to operate vehicle brakes and associated auxiliary air systems. Conventional systems include an air compressor for generating pressurized air and a drying device or air dryer disposed downstream from the compressor for removing entrained liquid from the air. The air dryer includes a desiccant material that removes water vapor from the air as it passes therethrough.
As will also be appreciated, air brake compressors are typically supplied with oil from the vehicle engine in order to lubricate the bearings and other components of the compressor. However, because oil is difficult to contain, it passes into the pressurized air stream exiting the compressor. Air exiting the compressor usually passes directly to the downstream components. As a result, elastomeric seals and seats of downstream components, as well as the desiccant material housed within the air dryer, often become contaminated with the oil accompanying the pressurized air.
In order to minimize oil contamination of the downstream components, attempts have been made to place a filtering element at or adjacent the inlet area of the air dryer. The filtering element or oil filter would effectively remove oil from the compressed air before reaching the desiccant material. However, when the compressed air reaches the air dryer, much of the water vapor and oil will have condensed since the compressor and air dryer are remotely spaced. The condensed water vapor and oil mixture forms a viscous emulsion. The condensed oil and water emulsion is high in viscosity and presents difficulties in draining the mixture. In addition, the filter must be equipped with a drain passage or system to dispose of the filtered material. Moreover, a relatively large draining capacity is required since a considerable amount of the water vapor condenses to liquid water upon reaching the air dryer. This, unfortunately, adds to the complexity and cost of the compressed air system.
Furthermore, water resulting from the condensed vapor has the potential to freeze. In order to prevent both freezing and the water vapor from condensing to form an emulsion, heaters have been incorporated into filter devices to maintain the water in liquid form. Again, however, the addition of a heating element adds to the complexity and cost of the compressed air system. In commonly assigned, co-pending application entitled “Compressor Discharge Oil Filter”, (Ser. No. 09/810,280, filed Mar. 16, 2001 and published under publication no. 2002-0131874 on Sep. 19, 2002), a system is disclosed which addresses the foregoing shortcomings, namely reducing contamination of components downstream from a vehicle air brake compressor without having to use a complex drainage system or a separate heating element. In this application, a discharge oil filter has been placed proximate to the air compressor for filtering oil before reaching and contaminating the downstream components. The strategic placement of the filter allows oil to be effectively removed before emulsions have the opportunity to form and before moisture cools and condenses into a liquid. The cited application is expressly incorporated herein by reference.
While it is important to maintain the oil filter at an elevated temperature, thereby avoiding emulsions, it is also important not to allow the temperature at the oil filter to reach the flash point of the oil therein. Oil, at the pressure of the compressor discharge, will ignite around 400° F. If oil ignites within the oil filter it can cause major damage to the vehicle. Normally, the compressor discharge is around 350° F., well below the flash point of oil.
The present invention is directed to an improvement to the above-cited application and in particular to an improvement to the oil removal device. Typical oil filters used in combination with air compressor systems include a cartridge having a housing enclosing a filter element. To change the filter element, a user needs to disassemble the housing which is cumbersome and often requires the use of special tools. The used or defective filter element must be removed and replaced with a new filter element. Oftentimes, a sump needs to be emptied which creates the risk of liquids spilling and damaging the system. After the new filter element has been installed, the user must make sure the housing is tightened and properly pressurized. These steps require considerable time and cause the removal and installation process to be rather complex. Accordingly, a need exists to provide an oil removal cartridge that is quick and easy to remove and install.
The present invention provides a spin-on filtering oil removal cartridge for an air compressor system used in pneumatic brake applications that meets the above needs and others in a simple and economical manner.
More particularly, the invention provides a compressed air system for an air brake system having a compressor for generating a stream of compressed air. A disposable oil removal cartridge is disposed downstream from the compressor for filtering oil from the stream of compressed air. In one embodiment, the oil removal cartridge has an outer housing enclosing a filtering element and a load plate for supporting the filtering element. In another embodiment, the load plate includes a connecting portion dimensioned to allow the oil removal cartridge to be removed and installed as a single unit. In another embodiment, the filter element is connected by a threaded annulus.
Another aspect of the present invention is a thermal vent located within the oil removal cartridge for controlling the temperature of the compressed air system. In one embodiment, a plug is disposed within a thermal vent housing and upon reaching the melting point of the plug composition, the plug ruptures releasing pressure to atmosphere.
This invention is also directed to a method for installing and removing an oil removal cartridge from a compressed air system of a vehicle air brake system. One embodiment of the method includes the step of engaging a threaded annulus, defining a passage in the load plate, with a threaded member of a body assembly. When the cartridge needs to be replaced, the threaded annulus is threadably disengaged from the threaded member of the body assembly.
In
With reference also to
Disposed within the housing is a filtering element 30 configured to agglomerate oil passing therethrough. The filtering element is annular in shape having a first or inner wall 32 and a second or outer wall 34 which together define a chamber containing a filtering media 36. Inner and outer walls are preferably made from a perforated material, and the filtering media is preferably a fiber material capable of filtering out small particles. In one embodiment, the filter material is made from a wound fibrous material. In one embodiment the filter material is made from wound micro glass filaments; however other embodiments incorporate other wound synthetic materials. The filtering element includes a first or upper axial end 38 and a second or lower axial end 40. First and second end caps 42, 44 are attached to the first and second axial ends, respectively, of the filtering element. The end caps are preferably adhesively secured to the filtering element, but may be secured in any other suitable manner without departing from the present invention.
The filtering element 30 and end caps are supported within the housing by a load plate 46 located at the housing lower end 26. Sheet metal 48 is secured (e.g., welded) along an outer perimeter of the load plate and is crimped with an edge of the housing lower end 26 to form a first seal 50. Alternatively, a portion of the load plate can be crimped with the edge of the housing lower end to form the first seal. The first seal minimizes leakage of pressure generated by the compressor and used to power vehicle pneumatic systems, such as the air brake system. A second seal 52 is provided on a lower surface to further minimize pressure leakage. The second seal is preferably made from an elastomeric material, that conforms to another surface and effectively establishes a seal therewith. However, other suitable seal materials may be used.
Openings 54 are provided in the load plate 46 and allow the compressed air and oil to enter and exit the oil removal device. In a preferred embodiment, eight (8) openings are circumferentially spaced around the load plate but other numbers of openings are possible. The load plate further includes a connecting portion 56 for connecting the oil removal device to a head assembly 58. The connecting portion is preferably an annulus extending from a top surface of the load plate and defining a passage 60 extending therethrough. The annulus includes threads 62 disposed on the inner surface of the annulus which are preferably ¾″ by 20″ threads. However, other suitably sized threads are contemplated.
The threaded annulus has a smaller diameter than that of the filtering element 30. The threaded annulus is dimensioned to allow the oil removal device to be spun onto a hollow threaded stud member 64 extending from the head assembly 58. Although a threaded annulus has been disclosed as the preferred connecting portion, it should be appreciated that other suitable connecting members are contemplated by the present invention. For example, the connecting portion could snap or frictionally fit to the head assembly.
A biasing member 68, such as a spring, is disposed at an opposite end of the filtering element 30 for continuously urging the filtering element toward the load plate 46. The biasing member 68 is preferably a spring member having an intermediate portion 70 that fits within a recess 72 of the upper end cap 42. Of course, it will be appreciated that the filtering element 30 may be secured via other means such as, for example, an interference fit and such alternative securing means are within the scope and intent of the present invention as defined by the claims herein.
The oil removal cartridge 10 is strategically positioned so that oil may be effectively filtered without the use of complex drainage systems or heating elements. More specifically, air brake compressors and other heat generating elements of a vehicle operate at temperatures sufficiently elevated to maintain water in a vapor state. The oil removal cartridge of the present invention is located near one of these heat generating elements, such as the compressor shown in
As shown in
By mostly filtering oil, the need for complex water drainage systems is eliminated. In addition, the need for a separate heating element is also eliminated by advantageously using the heat supplied from the compressor or other heat source. Moreover, maintaining the air stream at an elevated temperature during oil filtration prevents water from freezing and, thus, the attendant problems associated therewith.
With reference also to
In operation, the compressor 12 pressurizes air which exits at port 16. Upon exiting the port 16, the compressed air enters the oil removal cartridge 10 through openings 54. The compressed air travels axially in the housing and radially through the filtering element 30 where the filtering media 36 removes oil from the compressed air. Although this is the preferred direction, the opposite flow direction is also acceptable. When the oil enters the oil filter, it is substantially segregated, i.e., in the form of aerosols. These aerosols are filtered by the removal media and agglomerated into larger particles or oil droplets. The agglomerated oil droplets are subsequently drained from the system or alternatively the oil droplets are transported to the engine sump (not shown) or recycled back to the air compressor.
When one of the components of the oil removal cartridge 10 (i.e. the filtering element 30) needs replacement, the cartridge is simply rotated and spun-off the body assembly. The entire cartridge is then replaced and a new cartridge is simply spun-on. This provides significant advantages over conventional oil removal devices which are much more complex and time consuming to remove and install. More particularly, changing conventional filter elements requires a user to disassemble the device which often requires the use of special tools. The used or defective filter element must be removed and properly replaced with a new filter element. Oftentimes, a sump needs to be emptied which creates the risk of spilling liquids and damaging the system. After the new element has been installed, the user must make sure the housing device is tightened and properly pressurized. These steps require considerable time and cause the removal and installation process to be rather complex. In addition, these cartridges are generally larger and waste valuable space. The oil removal cartridge of the present invention is simple to install/remove and is relatively small compared to existing models.
As shown in
While the plug 106 can be made from a variety of materials, it is desirable to provide a plug that melts at within a selectable temperature range. Since the flashpoint of oil vapor is approximately 400° F., the thermal vent should contain a plug 106 with a melting point under 400° F., preferably between about 250° F. and about 350° F.; although these temperatures can vary as determined by pressure, the type of system, and the desired rupture point. Since it is desirable for the plug 106 to completely melt and thereby allow discharge of the compressed air as soon as the threshold temperature is reached, it is also preferable to use a plug 106 that is eutectic. As such, the plug 106 may be made from a solder, alloy, or any other suitable material. In one embodiment, the inner plug 106a is made from a solder comprising about 55.5% bismuth and 45.5% lead, while the outer plug 106b is made from a solder comprising about 43% tin, about 43% lead, and about 14% bismuth. Using such compositions, the inner plug 106a has a rupture temperature of about 255° F. and the outer plug 106b has a rupture temperature of about 290–325° F. Other illustrative example of the composition of the stop are about 96.5% tin and about 3.5% silver (melting temperature at approximately 430° F.); about 60% tin and about 40% lead (melting temperature at approximately 370° F.); or tin-zinc, tin-silver, tin-silver-copper, tin-silver-nickel, tin-copper, tin-lead-silver, bismuth-tin, or INDALLOY® alloys. It should be appreciated that these compositions are merely illustrative examples and the scope of the present invention should not be limited by or to such examples.
The plug 106 is about 0.15 inches in thickness and spans the width of the thermal vent housing 102 diameter d. The diameter of the inner plug 106a is approximately 0.062 inches. The plug 106 is held within the thermal vent housing 102 by the solder material; however, one of ordinary skill in the art should appreciate that the plug may be welded, crimped, friction-fitted, or glued into the thermal vent housing. Once the inner plug 106a ruptures, compressed air immediately exits the compressed air system, thereby lowering the temperature within the system. In addition, the melting of the plug and the release of the compressed air provides a noise that operates as an audible warning to the vehicle operator. If the temperature continues to increase, the outer plug 106b will melt, allowing additional pressure to be released from the system. The audible warning signal increases when the outer plug ruptures. In addition, electrical sensors, such as transducers, may be placed at the thermal vent port 104 to trigger an electrical warning to the vehicle operator upon the detection of the pressure release. The size of the two different plugs are designed such that the rupture of the inner port 106a will not adversely effect the operation of the vehicle braking system, whereas the rupture of the outer port 106b will interfere in pumping up the vehicle braking system, thereby allowing only five or six more complete brake applications. Once the pressure in the brake system reaches a minimum threshold, the primary brakes will not be capable of actuation and the spring brakes will be applied to ensure that the vehicle does not continue to operated until the problem that caused the thermal vent rupture is repaired.
Additionally, cap 120 shown best in
The invention has been described with reference to the preferred embodiments. Obviously, modifications and alterations will occur to others upon a reading and understanding of the detailed description. The invention is intended to include all such modifications and alterations insofar as they come within the scope of the accompanying claims and the equivalents thereof.
This application is a continuation-in-part of U.S. patent application Ser. No. 09/880,493, filed on Jun. 13 ,2001 for SPIN-ON FILTERING OIL REMOVAL CARTRIDGE, now U.S. Pat. No. 6,527,839 issued Mar. 4, 2003, the entire disclosures of which are fully incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
875432 | Hetlesaeter | Nov 1907 | A |
3252270 | Paul et al. | May 1966 | A |
3527027 | Knight et al. | Sep 1970 | A |
3572008 | Hankinson et al. | Mar 1971 | A |
4203739 | Erdmannsdorfer | May 1980 | A |
4311439 | Stofen | Jan 1982 | A |
4468239 | Franz | Aug 1984 | A |
4519819 | Franz | May 1985 | A |
4632682 | Erdmannsdorfer | Dec 1986 | A |
4883023 | Tsang et al. | Nov 1989 | A |
4892569 | Kojima | Jan 1990 | A |
5002593 | Ichishita et al. | Mar 1991 | A |
5087178 | Wells | Feb 1992 | A |
5110327 | Smith | May 1992 | A |
5429101 | Uebelhoer | Jul 1995 | A |
5607500 | Shamine et al. | Mar 1997 | A |
5674393 | Terhune et al. | Oct 1997 | A |
5779772 | Unger et al. | Jul 1998 | A |
5851269 | Strope | Dec 1998 | A |
5961698 | Dossaji et al. | Oct 1999 | A |
6076272 | Conklin, III et al. | Jun 2000 | A |
6309436 | Holch | Oct 2001 | B1 |
6319296 | Fornof | Nov 2001 | B1 |
6358300 | Fornof et al. | Mar 2002 | B1 |
6514051 | Fornof et al. | Feb 2003 | B1 |
6527839 | Fornof et al. | Mar 2003 | B1 |
6558457 | Kolcxyk | May 2003 | B1 |
6581297 | Ginder | Jun 2003 | B1 |
Number | Date | Country |
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0875432 | Nov 1998 | EP |
Number | Date | Country | |
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20030110949 A1 | Jun 2003 | US |
Number | Date | Country | |
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Parent | 09880493 | Jun 2001 | US |
Child | 10353285 | US |