Fluid handling – Line condition change responsive valves – With separate connected fluid reactor surface
Reexamination Certificate
2000-02-24
2001-09-18
Huson, Gregory L. (Department: 3753)
Fluid handling
Line condition change responsive valves
With separate connected fluid reactor surface
C137S497000, C138S046000, C062S528000
Reexamination Certificate
active
06289924
ABSTRACT:
FIELD OF THE INVENTION
The invention relates generally to variable flow metering devices and more particularly to variable flow area refrigerant expansion devices for use in controlling compression refrigeration systems so as to be responsive to a pressure differential between high and low pressure areas of a refrigeration system.
BACKGROUND OF THE INVENTION
Most small commercial vehicles and particularly automotive and mobile air conditioning systems, as represented in
FIG. 1
, utilize a fixed area refrigerant expansion device for flow control to reduce or eliminate moving parts and reduce costs. Known fixed area expansion devices are long capillary tubes or relatively short orifice tubes in the high-pressure liquid line between the condenser and evaporator. The refrigerant flow is primarily dependent on the inlet pressure (head pressure) at the orifice and the amount of liquid subcooling. In fixed area expansion devices, increasing head pressure or subcooling increases flow while increasing gas at the inlet decreases flow. Suction pressure changes have no effect on flow in normal system operation at higher ambient since flow is at “sonic” velocity and suction pressure is usually below the pressure at which this sonic flow occurs. As described in detail in my U.S. Pat. No. 5,901,750, incorporated herein by reference, these characteristics make the fixed area expansion device or capillary tube self regulating and produces adequate performance in a wide range of conditions encountered in normal automotive air conditioner operation with the exception of performance at idle. In automotive use the fixed orifice tube is sized for high ambient load at high speed vehicle operation and is generally about twice as large at idle as is optimal, resulting in increased compressor horsepower and a reduction in cooling.
FIG. 2
depicts a performance chart of a typical automotive system using a fixed orifice tube versus that of smaller orifices at idle.
Another known expansion device for use in flow control in refrigerant systems is a thermostatic expansion (TXV) valve. A TXV valve is a variable area expansion device and operates to control the flow rate of liquid refrigerant entering the evaporator as a function of the temperature of the refrigerant gas leaving the evaporator. However, while fixed area devices cannot match the efficiency of the TXV except at certain defined operating conditions, TXV valves are more complicated to manufacture and thus, more costly than the fixed devices.
An example of an automotive refrigerant system operation at high vehicle operation speed as compared to vehicle idle is as follows: At high operation speeds the head pressure may be approximately 250 PSIG and the sub-cooling 20° F. with a system capacity of approximately 24,000 BTU/Hr. At idle the head pressure of the vehicle rises to 350 PSIG due to reduction of condenser air flow and re-circulation of hot under-hood air into the condenser. Accordingly, balance is achieved at idle by reducing sub-cooling at the expansion device inlet. Initially, the rise in head pressure increases flow through the orifice tube. The result is that the sub-cooled liquid in the condenser is flushed out and uncondensed gas enters the orifice tube inlet. Gas greatly reduces flow until the flow rate out of the compressor is equal to flow through the orifice tube. Since capacity per pound of refrigerant is a function of liquid percentage after expansion, a gaseous mixture entering the expansion device greatly reduces capacity and system efficiency. At idle this capacity reduces to 12,000 BTU/Hr. in this example. If a smaller flow area is utilized in the expansion device refrigerant flow is reduced allowing liquid backup in the condenser and thus sub-cooling to occur. The net result is more cooling at reduced compressor work.
However, when small orifice are used at high load high speed operational conditions, more refrigerant is required in the system as more back up of liquid occurs until enough subcooling and head pressure are available to again flow enough to satisfy evaporator requirements. Unfortunately, this causes the head pressure to rise to the range of 300-400 PSIG, substantially reducing the compressor life. Accordingly, the variable flow orifice must be adequate in flow area at high speed high load conditions, in order to operate satisfactory. Further, a very short orifice tube relative to it's diameter becomes more restrictive as sub-cooling is increased. This characteristic of the short orifice tube is a detriment in automotive use since flow starvation may occur at high vehicle operational speeds if the small orifice size is engaged. Starvation results in high compressor discharge superheat temperatures, which may be very detrimental to compressor durability.
An object of this invention is to provide a variable flow area valve sensitive to system operating pressure.
Another object of this invention is to provide a metering valve, which closely matches the flow characteristics of a capillary or orifice tube as opposed to a short orifice plate.
Another object of this invention is to isolate the spring from refrigerant flow for reasons of vibration, durability, and noise.
SUMMARY OF THE INVENTION
In accordance with the invention, a variable flow area refrigerant expansion device includes a valve body having an axially extending aperture therethrough, a piston member slidably received in the valve body aperture, and a spring member operatively connected to the piston to resiliently urge the piston in a predetermined direction in the valve body aperture to insure fluid flow through the expansion device. The valve body aperture includes an inlet end and an outlet end. In accordance with one aspect of the invention, the interior surface of the valve body aperture at the outlet end is tapered from a first diameter to a second diameter, wherein the first diameter is larger than the second diameter, and terminates in a bore. The bore is a preferably a cross-bore.
The piston includes a flow passageway partially extending therethrough, with an inlet end and an outlet end. The outlet end terminates in a cross-bore formed though the piston body. In accordance with the invention, the piston further includes a tapered portion positioned downstream from the direction of fluid flow through the expansion device. The tapered portion has a first end defined by a first diameter and a second end defined by a second diameter, where the first diameter is larger than the second diameter. The piston is positioned within the valve body aperture with the tapered portion of the piston being received in the tapered outlet end of the valve body. In a preferred embodiment the tapered portion of the piston is tapered to a first predetermined angle and the tapered outlet end of the valve body is tapered to a second predetermined angle such that the tapers are not parallel to provide a mechanism for metering fluid through the expansion valve in response to pressure differentials between the inlet and outlet ends of the valve body.
In one embodiment, the spring member is disposed around the outer surface of the piston and contacts an annular wall within the valve body to resiliently urge the spring into a full open position. Alternatively, the valve body may be formed with a spring chamber positioned downstream of a distal end of the piston, such that an end of the spring engages the distal end of the piston to resiliently urge the spring into a full open position.
In accordance with another aspect of the invention, to insure that fluid flows through the passageway in the piston, it is preferred that the device include at least one valve body seal and at least one piston seal member. An outer surface of the valve body is preferably formed with an annular groove to receive a valve body seal, such as an O-ring. A second annular groove and valve body seal are preferably provided as a back-up seal, downstream of the first annular groove.
The interior surface of the valve body inlet end is preferably provided an annular surface for engaging piston sea
Huson Gregory L.
Krishnamurthy Ramesh
Rader & Fishman & Grauer, PLLC
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