Temperature dependent variable flow orifice

Abstract

A variable flow orifice for a hydraulic control system in a transmission includes a shape memory alloy that selectively increases and decreases the size of an orifice. The deformation of the shape memory alloy, and therefore the size of the orifice, is a function of the temperature of the transmission. During cold conditions the orifice size is increased and during normal operating conditions the size of the orifice is decreased.

Claims

1. A variable flow orifice for a transmission comprising: a spacer body that defines a bore and having an outer surface, wherein the spacer body includes a recess in the outer surface formed around the bore; and a single valve closing member consisting of a shape memory alloy (SMA) insert disposed within the recess and the bore, the SMA insert having a first shape and a second shape, wherein the bore has a first effective flow area when the SMA insert is in the first shape and a second effective flow area when the SMA insert is in the second shape, and wherein the first effective flow area is less than the second effective flow area, and wherein the SMA insert remains substantially co-planar with the outer surface when in both the first shape and the second shape, wherein the SMA insert is a semi-circular plate having a circular outer side and only a single straight outer side, wherein the recess and the bore are circular and wherein the circular outer side of the SMA insert has a radius that approximately equals a radius of the recess, and wherein the straight outer side of the SMA insert does not intersect a center radius of the circular outer side of the SMA insert when the SMA insert is in the first shape.

2. The variable flow orifice of claim 1 wherein the first shape of the SMA insert corresponds to a memory shape and the second shape of the SMA insert corresponds to a deformed shape.

3. The variable flow orifice of claim 1 wherein the SMA insert partially covers the bore when in both the first shape and the second shape.

4. The variable flow orifice of claim 1 wherein the SMA insert is comprised of copper-zinc-aluminum-nickel, copper-aluminum-nickel, or nickel-titanium alloys.

5. The variable flow orifice of claim 1 wherein the SMA insert changes from the first shape to the second shape when the temperature of the SMA insert falls below a transition temperature.

6. A variable flow orifice in a transmission comprising: a spacer body that defines a bore, wherein the spacer body includes a recess disposed concentric with the bore; and a single valve closing member consisting of a shape memory alloy (SMA) insert disposed within the recess and the bore, the SMA insert having a memory shape at a first temperature and a deformed shape at a second temperature, wherein the bore has a first effective flow area when the SMA insert is in the memory shape and a second effective flow area when the SMA insert is in the deformed shape, and wherein the first effective flow area is less than the second effective flow area, wherein the SMA insert is a semi-circular plate having a circular outer side and only a single straight outer side, wherein the recess and the bore are circular and wherein the circular outer side of the SMA insert has a radius that approximately equals a radius of the recess, and wherein the straight outer side of the SMA insert does not intersect a center radius of the circular outer side of the SMA insert when the SMA insert is in the first shape.

7. The variable flow orifice of claim 6 wherein the first temperature is greater than the second temperature.

8. The variable flow orifice of claim 7 wherein the first temperature corresponds to an operating temperature of the transmission and the second temperature corresponds to a cold start temperature of the transmission.

9. The variable flow orifice of claim 6 wherein the SMA insert partially covers the bore when in both the memory shape and the deformed shape.

10. The variable flow orifice of claim 6 wherein the SMA insert is comprised of copper-zinc-aluminum-nickel, copper-aluminum-nickel, or nickel-titanium alloys.

Description

DRAWINGS

(1) The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way.

(2) FIG. 1 is a top view of an exemplary valve body spacer plate having a variable flow orifice according to the principles of the present invention;

(3) FIG. 2 is an enlarged, top view of a portion of the exemplary valve body spacer plate having a variable flow orifice;

(4) FIG. 3 is an exploded view of the exemplary valve body spacer plate and variable flow orifice shown in FIG. 2;

(5) FIG. 4A is an enlarged, top view of a portion of the exemplary valve body spacer plate having a variable flow orifice in a first condition;

(6) FIG. 4B is an enlarged, top view of a portion of the exemplary valve body spacer plate having a variable flow orifice in a second condition;

(7) FIG. 5 is a top view of a gasket having a variable flow orifice according to the principles of the present invention; and

(8) FIG. 6 is an exploded view of the gasket having a variable flow orifice shown in FIG. 5.

DETAILED DESCRIPTION

(9) The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses.

(10) With reference to FIG. 1, a component of a hydraulic control system in a transmission is generally indicated by reference number 10. In the example provided, the component 10 is illustrated as an exemplary valve body spacer plate. The spacer plate 10 includes various bores, openings, flanges and features that receive, locate, support and protect the valve body halves, valves, and solenoids of the valve body. For example, the spacer plate 10 includes a variable flow orifice 12 that communicates hydraulic fluid from a first side 14 of the spacer plate 10 to a second side 16 of the spacer plate 10. The orifice 12 may hydraulically connect any number of components in the hydraulic control system together. For example, the orifice 12 may connect a pump outlet with a supply line in the valve body, or connect an accumulator with a pump or supply line, etc. However, it should be appreciated that the variable flow orifice may be located in various other transmission components, such as the valve body, without departing from the scope of the present invention.

(11) Turning to FIGS. 2 and 3, the variable flow orifice 12 is shown in detail. The variable flow orifice 12 includes a bore 18 that extends through the spacer plate 10. A recess 20 is formed around the bore 18 on the first surface 14. The recess 20 extends into the spacer plate 10 a predefined depth but does not extend through the spacer plate 10. A shape memory alloy (SMA) insert 22 is disposed within the recess 20. The SMA, also known as a smart metal, memory metal, memory alloy, muscle wire, and smart alloy, undergoes a transformation from one crystal phase to another over a particular temperature range. Above this range, the material exists as austenite. Austenite has a rigid crystal structure. The shape of a component while in the austenite phase is termed the memory shape. The low temperature phase, martensite, is soft and can be deformed about 6% from its original shape without causing any permanent deformation. Once deformed, martensitic material will remain in this deformed shape indefinitely. When heated later, the material transforms to the high temperature phase and returns to its memory shape. Exemplary SMA's include copper-zinc-aluminum-nickel, copper-aluminum-nickel, and nickel-titanium (NiTi) alloys. For example, the SMA insert 22 may be made from a NiTi alloy from Intrinsic Devices Incorporated, San Francisco, Calif., under the designation UNILOK.

(12) The SMA insert 22 is a semi-circular plate having a circular outer side 24 and a straight outer side 26. The circular outer side 24 has a radius that approximately matches a radius of the recess 20. The SMA insert 22 partially covers or obstructs the bore 18 in both the memory shape and the deformed shape, as seen in FIGS. 4A and 4B. For example, in FIG. 4A, the SMA insert 22 is in its shape memory state. In the shape memory state the SMA insert 22 has a surface area A1 which covers a portion of the bore 18 and leaves an area B1 of the bore 18 open to hydraulic fluid communication. In FIG. 4B, the SMA insert 22 is in its deformed state. In the deformed state the SMA insert 22 has a surface area A2 which covers a portion of the bore 18 and leaves an area B2 of the bore 18 open to hydraulic fluid communication. The surface area A1 of the SMA insert 22 in the shape memory state is less than the surface area A2 of the SMA insert 22 in the deformed shape. Therefore, the size of the opening B2 of the bore 18 when the SMA insert 22 is deformed is greater than the size of the opening B1 of the bore 18 when the SMA insert 22 is not deformed. Accordingly, the orifice 12 provides a variably sized opening via SMA insert 22 overtop the bore 18 that is controlled by the transition temperature of the SMA insert 22. Furthermore, since the opening of the bore 18 is controlled by the overlap between SMA insert 22 and bore 18, the percentage change of the opening area B1 to B2 is larger than the strain rate of the SMA insert 22 itself, which is critical in making the difference between area B1 and B2 larger than the typical 6% deformation of SMA material.

(13) The transition temperature of the SMA insert 22 is tuned to the operating conditions of the transmission and includes adjustments for hysteresis. For example, during normal operating conditions, the temperature of the hydraulic fluid, and therefore the SMA insert 22, is at an elevated temperature. This temperature is greater than the transition temperature of the SMA insert 22. Therefore, during normal transmission operating conditions, the SMA insert 22 is in the memory shape. However, during cold start conditions when the hydraulic fluid is cool and therefore has a higher viscosity, the SMA insert 22 is at a temperature below the transition temperature and the SMA insert 22 is in the deformed shape. This allows the orifice 12 to have a greater flow rate therethrough during cold start conditions.

(14) With reference to FIGS. 5 and 6, an alternate embodiment of the variable restriction orifice is indicated by reference number 12. The orifice 12 is disposed over the bore 18 of the spacer plate 10. The orifice 12 includes a first gasket 50 having a hole 52 formed therethrough, the SMA insert 22 described above, and a second gasket 54 having a hole 56 formed therethrough. The SMA insert 22 is disposed between and sandwiched by the gaskets 50 and 52. The SMA insert 22 is aligned with the bore 18 as described above. In the variable flow orifice 12, the gaskets are held in place by compression between the spacer plate 10 and the valve body (not shown), and accordingly the recess 20 is not present. The variable flow orifice 12 operates in a manner similar to the variable flow orifice 12.

(15) By using a variable flow orifice, the transmission response time during cold operating conditions is improved by increasing the flow rate of the relatively high viscous hydraulic fluid. In addition, the device is passive and does not require active control. Finally, the known transition temperature range of the SMA makes calibration of the variable flow orifice robust.

(16) The description of the invention is merely exemplary in nature and variations that do not depart from the gist of the invention are intended to be within the scope of the invention. Such variations are not to be regarded as a departure from the spirit and scope of the invention.