LEAK DETECTION ASSEMBLY
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates generally to an evaporative emission control system for automotive vehicles and, more particularly, to a leak detection assembly for determining if a leak is present in a portion of the system which includes a vapor collection canister.
2. Description of the Related Art Modern automotive vehicles typically include a fuel tank and an evaporative emission control system that collects volatile fuel vapors generated in the fuel tank. The control system includes a vapor collection canister, usually containing an activated charcoal mixture, to collect and store the emitted fuel vapors. Normally, the canister collects volatile fuel vapors which accumulate during refueling of the automotive vehicle or from increases in fuel temperature. During conditions conducive to purging, a purge valve placed between an intake manifold and the canister is opened by an engine control unit in an amount determined by the engine control unit to purge the canister; i.e., the stored vapors are drawn into the intake manifold from the canister for ultimate combustion within a combustion chamber of an engine.
Governmental regulations require that certain vehicles powered by volatile fuels such as gasoline have their evaporative emission control systems checked to determine if a leak exists in the system. On board vehicle diagnostic systems have been developed to determine if a leak is present in a portion of the evaporative emission control system. One such system utilizes a vacuum regulator/sensor unit to draw a vacuum on the control system and sense whether a loss of vacuum occurs within a specified period of time.
Diagnostic systems also exist for determining the presence of a leak in the evaporative emission control system which
utilize positive pressurization rather than negative pressurization, i.e. a vacuum. In positive pressurization systems, the evaporative emission control system is pressurized to a set pressure, typically through the use of an electric air pump. A sensor determines whether the pressure remains constant over a certain amount of time.
Positive pressurization systems have a benefit over negative pressurization systems in that the increased pressure suppresses the rate of fuel vapor generation in the fuel tank. Such a situation is desirable when the test is given under hot weather conditions which typically promote fuel vapor generation.
SUMMARY OF THE INVENTION It is, therefore, one object of the present invention to provide a leak detection assembly for use in testing the integrity of an evaporative emission control system.
It is another object of the present invention to provide a leak detection assembly which incorporates two primary functions, a vacuum actuated pump which performs leak detection and a vacuum actuated canister vent control valve which seals the evaporative emission control system so the leak detection test can be performed
It is yet another object of the present invention to provide a leak detection assembling having a vacuum actuated canister vent control valve which is actuated by a vacuum actuated pump.
It is still another object of the present invention to provide a leak detection assembly having a check valve between the vacuum actuated pump and the vacuum actuated canister vent control valve to maintain the canister vent control valve in a closed, sealed position during operation of the pump.
To achieve the foregoing objects, the present invention is a leak detection assembly and for use in pressurizing and sealing an evaporative emission control system to determine if a leak is present in a portion of the system. In general, the present invention includes a vacuum actuated pump and a vacuum
actuated canister vent control valve. The pump performs the leak detection function and the vent control valve seals the evaporative system so the leak detection test can be performed. A three-port solenoid activates both functions. The pump includes a switch, two check valves and a diaphragm. The vent control valve includes a valve connected to a diaphragm such that initializing the pump by drawing a vacuum in a pump actuation cavity also draws a vacuum in a vacuum chamber which closes the vent control valve and seals off the canister from an atmospheric air vent and corresponding air filter. The vent control valve remains closed while the pump is cycling due to an check valve.
The pump operates in a typical diaphragm pump fashion, i.e. energizing the solenoid creates a vacuum in the pump activation cavity which causes the diaphragm to deflect inward and draw air into the pump chamber. Once the diaphragm is fully deflected, the solenoid is de-energized allowing atmospheric pressure to enter the pump actuation cavity and permitting a spring to drive the diaphragm outward forcing air out of the pump chamber and into the system. When the diaphragm reaches the end of its stroke, a switch is closed which signals the engine control unit to activate the solenoid to start the cycle again by supplying a vacuum to the pump actuation cavity. <
One advantage of the present invention is that the actuation of the pump automatically seals the evaporative emission control system so that the leak detection test can be performed. A further advantage of the present invention is that when a leak occurs, the pump will continue to pump at a rate which is representative of the flow characteristics of the size of the leak. It is also an advantage that a flow test is performed by opening a purge valve, in effect creating a leak, and checking the cycle rate of the pump to see if the corresponding increase in pump rate compares to the flow characteristics through the purge valve. Other objects, features and advantages of the present invention will be readily appreciated as the same becomes better
understood after reading the subsequent description taken in conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a representative evaporative emission system control utilizing a leak detection assembly, according to the present invention.
FIG. 2 is a fragmentary side view of the leak detection assembly of FIG. 1.
DESCRIPTION OF THE PREFERRED EMBODIMENT(S) Referring to FIG. 1, an evaporative emission control system 10 is shown for an automotive vehicle (not shown) utilizing a leak detection assembly, according to the present invention and generally indicated at 12. A carbon canister 14 is connected to the leak detection assembly 12 by a conduit 27. A fuel tank 16 is connected to the carbon canister 14 by a rollover and vapor flow control valve 20 and a conduit 22. An intake manifold 18 is connected to the canister 14 by a conduit 23 having a purge valve 24 mounted thereon. An engine control unit 26 is connected to and operative to control the leak detection assembly 12 and the purge valve 24.
A supply of volatile liquid fuel' for powering an engine (not shown) of the automotive vehicle is placed in the fuel tank 16. As fuel is pumped into the fuel tank 16 or as the temperature of the fuel increases, vapors from the fuel pass through the conduit 22 and are received in the canister 14. Vapors are drawn from the canister 14 through the conduit 23 and purge valve 24, and into the intake manifold 18 for ultimate combustion within combustion chambers (not shown) of the engine. During vehicle operation, the purge valve 24 is normally closed. Under certain conditions conducive to purging the engine control unit 26 energizes a purge solenoid (not shown) connected to the purge valve 24 to open the purge valve 24 such that a certain amount of engine intake manifold vacuum is delivered to the canister 14 causing the collected vapors to flow from the
canister 14 through the purge valve 24 to the intake manifold 18 for combustion in the combustion chambers.
The leak detection assembly 12 includes a vacuum actuated pump 28 and a vacuum actuated canister vent control valve 32 coupled by a vacuum line 34. The leak detection system assembly 12 also includes a check valve 31 positioned on the vacuum line 34 to maintain the vacuum necessary to keep the vent control valve 32 in a closed position during operation of the pump 28. It should be appreciated that the vacuum actuated canister vent control valve 32 seals or closes the conduit 27 between the canister 14 and an atmospheric vent and air filter 30 in order to positively pressurize the evaporative emission control system 10.
In accordance with the present invention, the leak detection assembly 12 is used to perform a test on the integrity of the evaporative emission control system 10. To conduct the test, the engine control unit 26 closes the purge valve 24 and actuates the vacuum actuated pump 28. The vent control valve 32 is vacuum actuated such that a vacuum drawn the pump 28 to activate the pump 28, results in a corresponding vacuum being drawn through a vacuum line 34 connected to the vent control valve 32 which causes the vent control valve 32 to close and seal the canister 14 from the atmospheric vent and air filter 30. Once the conduit 27 is sealed off, the pump 28 then positively pressurizes the canister 14 and tank 16 to a predetermined pressure. Once the predetermined pressure is reached, the pump 28 ceases operation. If the system 10 has a leak, the pressure is reduced and the pump 28 will sense the reduced pressure and will actuate. The pump 28 will continue to pump at a rate which will be representative of the flow characteristic as related to the size of the leak. From this information, it can be determined if the leak is larger or smaller than the required detection limit set by federal governmental standards. Referring now to >FIG. 2, the leak detection assembly 12 includes a three-port solenoid 42. The leak detection assembly 12 further includes a housing 40. A diaphragm 46 is disposed within the housing 40 and cooperates
with the housing 40 to define a pump actuation cavity 44 and a pump chamber 54. A spring 48 is disposed within the pump actuation cavity 44 and acts on the diaphragm 46. A switch 50 is mounted to the housing 40. The switch 50 is connected to the engine control unit 26. A pair of one way check valves 52, 56 are disposed in the housing 40. A vacuum line (not shown) extends from and couples the vacuum drawn by the intake manifold 18 to an inlet port 35 of the three-port solenoid 42. The three-port solenoid 42 is connected to the housing 40 and upon receiving a signal from the engine control unit 26 selectively draws and releases a vacuum in the pump actuation cavity 44. It should be appreciated that when a vacuum is drawn in the pump actuation cavity 44, the diaphragm 46 is pulled upward against the spring 48. When the vacuum is released, the diaphragm is then urged outward by the spring 48 in a pump stroke. The switch 50 is placed adjacent the diaphragm 46 such that when the diaphragm 46 reaches the end of its stroke, the switch 50 is closed. Closure of the switch 50 sends a signal to the engine control unit 26 to activate the solenoid 42 and supply a vacuum to the pump actuation cavity 44.
In operation, the solenoid 42 is energized by the engine control unit 26, and connects the pump actuation cavity 44 with the vacuum drawn by the intake manifold 18 to initialize the pump 28 by drawing the diaphragm 46 upward and compressing the spring 48. Drawing the diaphragm 46 upward draws air in through the one way or check valve 52 into the pump chamber 54. The solenoid 42 is then de-energized which allows atmospheric pressure to enter the pump actuation cavity 44 whereby the spring 48 drives the diaphragm 46 outward to force the air out of the pump chamber 54 through the second one way or check valve 56 into the canister 14 and corresponding elements of the evaporative emission control system 10 through the connecting conduit 27. As the diaphragm 46 reaches the end of its stroke, the switch 50 closes. Closure of switch 50 signals the engine control unit 26 to energize the solenoid 42 and provide a vacuum to the pump actuation cavity 44. In this manner the cycle is repeated to create flow in a typical diaphragm pump fashion.
As illustrated in FIG. 2, during normal operation of the vehicle, the canister 14 is coupled to the atmospheric vent and air filter 30 through the vent control valve 32. In order to pressurize the evaporative emissions control system 10, the vent control valve 32 must be closed. The vent control valve 32 includes a housing 58. A diaphragm 60 extends across the housing 58 and in combination with the housing 58 defines a vacuum chamber 62. A valve 64 is connected to the diaphragm 60. The valve 64 includes a valve stem 66 connected to the diaphragm 60 on one end. A valve head 68 is disposed on the valve stem 66 opposite the diaphragm 60. The housing 58 further includes an opening or orifice 70 to allow communication between the canister 14 and the atmospheric vent and air filter 30. A seal element 72 is disposed about the valve head 68. The seal 72 engages and seals, the orifice 70 to seal off the canister 14 from the atmospheric vent and air filter 30. A spring 74 is disposed in the vacuum chamber 62. The spring 74 acts upon the valve 64 to urge the valve 64 into an open position such that the diaphragm 60 is seated on projections 76 extending outward from the orifice 70. It should be appreciated that when the valve 64 is in an open position, air may be drawn through the atmospheric vent and air filter 30 past the open valve 64 and into the canister 14 in the direction shown by the arrows 78.
In order to pressurize the evaporative emission control system 10, the valve 64 must be closed. It should be appreciated that the valve 64 is urged closed when the solenoid 42 is initialized causing a vacuum to be drawn in the pump actuation cavity 44. When a vacuum is drawn in the pump actuation cavity 44, a corresponding vacuum is also drawn in the vacuum chamber 62 as the vacuum chamber 62 is coupled to the pump actuation chamber 44 by the vacuum line 34 connected between a port 82 on the pump actuation chamber 44 and a port 84 on the vacuum chamber 62. The vacuum drawn in the vacuum chamber 62 acts against the spring 74 to draw the valve 64 into a closed position wherein the seal element 72 engages the orifice 70.
The check valve 31 includes a one-way valve 88, an orifice 90 and a sintered filter 92 placed adjacent the orifice 90. The check valve 31 maintains the valve 64 in the closed position while the pump 28 is cycling. As illustrated in FIG. 2, when a vacuum is drawn in the pump actuation cavity 44, the check valve 31 allows the vacuum to be drawn in the vacuum chamber 62 through the one way valve 88. During cycling of the pump 28, the time constant of the bleed down through the sintered filter 92 and orifice 90 is substantially longer than the cycle rate of the pump 28, therefore while the pump 28 is operating, the vent control valve 32 remains closed.
In operation, the solenoid 42 is energized to draw a vacuum in both the pump actuation cavity 44 and the vacuum chamber 62 which seals the vent control valve 32. Once the vent control valve 32 is sealed, the solenoid 42 is cycled through periods of energizing and de-energizing causing the vacuum actuated pump 28 to pump air through the pump chamber 56 into the evaporative emission control system 10. The spring 48 in the pump actuation cavity 44 is set to a control pressure of about five inches (5") of water (H20) . The cycle rate of the vacuum actuated pump 28 is quite rapid and the control pressure is quickly achieved. Once the control pressure is achieved, the cycle rate starts to drop off. If there is no leak in the system, the pump 28 will stop pumping. If a leak exists, the pump 28 will continue to pump at a rate that will be representative of the flow characteristics of the size of the leak. Since the pump rate is now known, it can be determined if the leak is larger or smaller than the required governmental leak limit.
After passing the leak detection phase of the test, a flow test is performed wherein the engine control unit 26 energizes the purge valve 24 which in effect creates a leak. The cycle rate of the pump 28 is then checked. The rate of the pump 28 should increase due to the flow through the purge valve 24. It should be appreciated that the purge valve 24 is opened to a predetermined amount which results in a specified flow characteristic, and the pump rate should correspond to the flow characteristics.
Once the diagnostic test is complete, the solenoid 42 is de-energized which allows atmospheric pressure to bleed into the pump actuation cavity 44 and correspondingly through the sintered filter 92 and orifice 90 into the vacuum chamber 62 to allow the spring 74 to open the vent control valve 32. Normal purge flow is then initiated.
The present invention has been described in an illustrative manner. It is to be understood that the terminology which has been used is intended to be in the nature of words of description rather than of limitation.
Many modifications and variations of the present invention are possible in light of the above teachings. Therefore, within the scope of the appended claims, the present invention may be practiced otherwise than as specifically described.