Power management sensing rotating platter with liquid contact switch responsive to platter rotational speed

Abstract

The present invention relates to an electrical switch including an arcuate cavity partially filled with an electrically conducting fluid. The fluid is adapted to move into electrical contact with a pair of electrodes positioned within the cavity in response to a rotational force acting thereupon. The switch is electrically connectable to a rotatable platter. When connected to the platter, the switch is positioned radially outward from the platter's axis of rotation, such that the forces generated by the platter upon rotation urge the electrically conducting fluid into contact with the electrodes and thus complete a circuit.

Description

TECHNICAL FIELD OF THE INVENTION

The present invention relates generally to electrical switches and, more particularly, to an apparatus for automatically switching an electrical circuit when a platter is rotated.

BACKGROUND OF THE INVENTION

Many medical analytical techniques, such as blood and urine analysis, rely on centrifugation as part of the testing procedure. Generally, automated devices designed to perform these tests include a built-in centrifuge having a rotatable platter or carousel in which fluid samples are mounted. It is often desirable to separate the carousel rotating function from the analytical functions, in order to conserve resources such as power and/or computer time. Power conservation is especially important if the device is battery operated. To this end, it is attractive to include switching means in the rotatable platter capable of switching on the analytical functions only after the platter has achieved a predetermined rotational rate.

One way of performing this switching function is to rely on the user to activate the analytical function when the platter is rotating at the proper speed. This switching method suffers from the disadvantages of requiring the user to spend valuable time and attention manually actuating the analytical functions of the device. Moreover, manual actuation is not as reliable as an automatic switching means.

One automatic switching means involves the connection of a mechanical switch to the platter. While more reliable than manual switching, mechanical switches are prone to error arising from dirty electrical contacts, broken or worn springs, and broken or worn actuators. Moreover, mechanical switches rely on moving parts with lifetimes adversely affected by the rotational forces generated by the rotating platter.

There is therefore a need for a non-mechanical switch usable with a rotatable platter capable of actuating an electrically connected device, such as an analytical device, upon rotation of the platter to a predetermined speed. The present invention addresses this need.

SUMMARY OF THE INVENTION

The present invention relates to an electrical switch including an arcuate cavity partially filled with an electrically conducting fluid. The fluid is adapted to move into electrical contact with a pair of electrodes positioned within the cavity in response to a rotational force acting thereupon. The switch is electrically connectable to a rotatable platter. When connected to the platter, the switch is positioned radially outward from the platter's axis of rotation, such that the forces generated by the platter upon rotation urge the electrically conducting fluid into contact with the electrodes and thus complete a circuit.

One form of the present invention relates to an electrical switch including a cavity partially filled with an electrically conducting fluid adapted to move into electrical contact with a pair of electrodes positioned within the cavity in response to a rotational force acting thereupon. The switch is adapted to be operationally connected to a rotatable platter and spaced radially from the platter's axis of rotation, such that the forces generated upon rotation of the platter urge the electrically conducting fluid into contact with the electrodes, thus completing a circuit.

Another form of the present invention relates to an electrical switch formed as part of a modular cartridge and including a cavity formed in the cartridge and partially filled with an electrically conducting fluid. The electrically conducting fluid is adapted to move in response to a rotational force acting thereon and into electrical contact with a pair of electrodes positioned within the cavity. The cartridge is operationally connectable to a rotatable platter through matable electrical contacts positioned in both the cartridge and the platter. Rotation of the platter urges the electrically conducting fluid into contact with the pair of electrodes, thus completing a circuit.

One object of the present invention is to provide an improved apparatus for electrical switching in response to a change in angular momentum. Related objects and advantages of the present invention will be apparent from the following description.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective schematic view of a rotatable platter containing a first electrical switch embodiment of the present invention.

FIG. 2 is a cross-sectional illustration of the electrical switch of the embodiment of FIG. 1 .

FIG. 3 is a perspective view of a cartridge containing a second electrical switch embodiment of the present invention.

FIG. 4 is a perspective schematic view of the cartridge of FIG. 3 inserted in a rotatable platter.

FIG. 5 is a perspective schematic view of a rotatable platter containing a third electrical switch embodiment of the present invention.

FIG. 6A is a cross-sectional illustration of the electrical switch of the of FIG. 5 having electrically conducting fluid occupying a first position.

FIG. 6A is a cross-sectional illustration of the electrical switch of the of FIG. 5 having electrically conducting fluid occupying a second position.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

For the purposes of promoting an understanding of the principles of the invention, reference will now be made to the embodiment illustrated in the drawings and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended, such alterations and further modifications in the illustrated device, and such further applications of the principles of the invention as illustrated therein being contemplated as would normally occur to one skilled in the art to which the invention relates.

The present invention relates to an apparatus for closing an electrical circuit in a rotatable member in response to rotation of that member. FIGS. 1 and 2 illustrate one embodiment of the present invention, a rotation-actuated electrical switch 10 positionable in a rotatable platter 12 . FIG. 1 illustrates the preferred positioning of switch 10 within platter 12 . Rotatable platter 12 preferably has a generally circular shape and rotates about shaft 13 . Platter 12 is more preferably generally planar and includes a primary axis of rotation 14 substantially colinear with shaft 13 and substantially perpendicular to platter 12 . Switch 10 is preferably formed integrally within platter 12 , but may also be formed separately from platter 12 and connected thereto by any convenient means, such as through a modular cartridge (see FIGS. 3 and 4 ). Switch 10 preferably extends generally radially outward from axis of rotation 14 . More preferably, axis of rotation 14 does not intersect switch 10 .

FIG. 2 illustrates switch 10 in greater detail. Switch 10 comprises an elongated enclosure or compartment 20 defining a cavity, at least a portion of which is generally arcuate or substantially arch-shaped. Preferably, enclosure 20 has a simple arcuate shape, but may also have any convenient shape incorporating an arched or likewise bent portion, such as a “dogleg” shape or the like. The generally arcuate enclosure 20 has a proximal portion (or inner leg) 22 , a middle portion 24 , and a distal portion (or outer leg) 26 . Middle portion 24 may range in size from large enough to occupy a majority of enclosure 20 to just large enough to connect proximal portion 22 to distal portion 26 . Enclosure 20 is preferably positioned relative axis of rotation 14 such that proximal portion 22 is the closest portion to axis of rotation 14 . More preferably, proximal portion 22 extends upwardly through platter 12 to middle portion 24 . Middle portion preferably extends from proximal portion 22 away from axis of rotation 14 to distal portion 26 . Distal portion 26 extends from middle portion 24 downwardly through platter 12 and away from axis of rotation 14 . As used herein, the term “upwardly” indicates a direction generally opposite the pull of gravity, such that a body moving upwardly would gain gravitational potential energy. Likewise, the term “downwardly” indicates a direction generally congruent with the pull of gravity, such that a body moving downwardly would lose gravitational potential energy.

Switch 10 also includes a pair of spaced electrical contacts 28 , 29 adapted to electrically connect the interior of distal portion 26 to the exterior of switch 10 . Switch 10 further includes an electrically conducting fluid 30 (such as mercury or an aqueous electrolytic solution) partially filling the enclosure 20 . Fluid 30 preferably rests in proximal portion 22 of switch 10 when platter 12 is at rest. Preferentially, switch 10 is oriented such that distal portion 26 is positioned generally radially outward from proximal portion 22 relative to primary axis of rotation 14 . More preferentially, switch 10 is also oriented such that proximal portion 22 and distal portion 26 are positioned below (i.e., having less gravitational potential energy than) middle portion 24 .

Rotation of platter 12 generates a radially outwardly acting force (represented by arrow 36 ) urging fluid 30 into distal portion 26 of switch 10 and into contact with the pair of spaced electrical contacts 28 , 29 . Force 36 is proportional to the rate of rotation of platter 12 . As platter 12 is rotated beyond a predetermined threshold rate, the value of force 36 becomes sufficient to displace fluid 30 from proximal portion 22 to distal portion 26 of switch 10 and into electrical contact with the pair of spaced electrical contacts 28 , 29 , thus completing an external electrical circuit (not shown) coupled to spaced electrical contacts 28 , 29 and enabling current to flow between spaced electrical contacts 28 , 29 .

The threshold rate of rotation at which fluid 30 becomes displaced into distal portion 26 may be predetermined by varying the amount of fluid 30 , the composition (specifically, the viscosity and/or density) of fluid 30 , and/or varying the curvature of enclosure 20 . Generally, as the density and/or viscosity of fluid 30 increases, a greater force 36 will be required to displace fluid 30 into distal portion 26 . Likewise, as enclosure 20 becomes more arcuate (or as the slope from inner leg 22 to middle portion 24 becomes steeper), a greater force 36 will be required to displace fluid 30 into distal portion 26 . By choosing the appropriate degree of curvature of enclosure 20 and amount and composition of fluid 30 , the rotation rate of platter 12 at which switch 10 trips may be predetermined. After switch 10 has been subjected to rotational force 36 and tripped, switch 10 may be disengaged and reset by repositioning enclosure 20 such that fluid 30 flows from distal portion 26 back into proximal portion 22 . This operation may be performed manually or automatically.

FIGS. 3 and 4 illustrate a second embodiment of the present invention, a switch 10 formed in a modular cartridge 40 A adapted to be electrically connected to a rotatable platter 12 A. FIG. 3 illustrates cartridge 40 A in detail. Cartridge 40 A includes a substantially arcuate or generally arch-shaped elongated enclosure or compartment 20 A defining a cavity having an upwardly-inclined proximal portion or inner leg 22 A, a middle portion 24 A, and a downwardly-inclined distal portion or outer leg 26 A, whereas the inclinations of the proximal and distal portions 22 A, 26 A are relative to the cartridge 40 A orientation when electrically connected to rotatable platter 12 A (see FIG. 4 ). Switch 20 A also includes a pair of spaced electrical contacts 28 A, 29 A adapted to electrically connect the interior of distal portion 26 A to the exterior of the switch 10 A. First and a second electrical lead 28 A and 29 A extend from within distal portion 26 A of enclosure 20 A to the exterior of cartridge 40 A and terminate in cartridge electrodes 42 A and 43 A. Switch 10 A further includes an electrically conducting fluid 30 A partially filling the enclosure 20 A.

FIG. 4 illustrates cartridge 40 A as operationally connected to platter 12 A. Fluid 30 A preferably rests in proximal portion 22 A of switch 10 A when cartridge 40 A is inserted into resting platter 12 A. Preferentially, switch 10 A is oriented such that distal portion 26 A is positioned generally radially outward from proximal portion 22 A, relative to primary axis of rotation 14 A. In other words, as positioned within cartridge 40 A as inserted into platter 12 A, switch 10 A extends generally radially outward from axis of rotation 14 A and has the form of an elongated enclosure 20 A having an upwardly-inclined elongated proximal portion 22 A and a downwardly-inclined elongated distal portion 26 A and is positioned relative to platter 12 A such that upwardly-inclined proximal portion 22 A lies radially inward relative to middle portion 24 A and downwardly-inclined distal portion 26 A lies radially outward middle portion 24 A.

Rotatable platter 12 A includes a recess 50 A adapted to receive cartridge 40 A. Recess 50 A also preferably includes platter electrodes 52 A and 53 A adapted to make electrical contact with cartridge electrodes 42 A and 43 A when cartridge 40 A is inserted into platter recess 50 A. As with the previous embodiment, rotation of platter 12 A generates a radially outwardly acting force 36 A urging fluid 30 A into distal portion 26 A of switch 10 A and into contact with pair of spaced electrical contacts 28 A and 29 A (see FIG. 3 ). Force 36 A is proportional to the rate of rotation of platter 12 A, and as a threshold rate of rotation is achieved, the value of force 36 A becomes sufficient to displace fluid 30 A from proximal portion 22 A to distal portion 26 A and into electrical contact with spaced electrical contacts 28 A and 29 A, thus completing an external electrical circuit (not shown) coupled to platter electrodes 52 A and 53 A. After rotational forces 36 A have tripped switch 10 A, switch 10 A may be reset by orienting cartridge 40 A such that fluid 30 A returns to proximal portion 22 A. This may be accomplished by automatically reorienting cartridge 40 A while in platter recess 50 A, or by manually removing cartridge 40 A from platter recess 50 A and orienting cartridge 40 A such that fluid 30 A flows from distal portion 26 A.

FIGS. 5 and 6 illustrate yet another embodiment of the present invention, a rotation-actuated electrical switch 10 B positionable in a rotatable platter 12 B, wherein switch 10 B has a generally linear configuration. FIG. 5 illustrates the preferred positioning of switch 10 B within platter 12 B. Rotatable platter 12 B is preferably generally circular, and is more preferably generally planar and includes a primary axis of rotation 14 B oriented substantially perpendicular to the plane of platter 12 B. Switch 10 B is preferably positioned within platter 12 B, but may also be attached externally thereto by any convenient means. Switch 10 B preferably extends generally radially outward from axis of rotation 14 B and more preferably does not intersect axis of rotation 14 B.

FIGS. 5 and 6 illustrate yet another embodiment of the present invention, a rotation-actuated electrical switch 10 B positionable in a rotatable platter 12 B, wherein switch 10 B has a generally linear configuration. FIG. 5 illustrates the preferred positioning of switch 10 B within platter 12 B. Rotatable platter 12 B is preferably generally circular, rotates about shaft 13 B, and is more preferably generally planar and includes a primary axis of rotation 14 B oriented substantially colinear with shaft 13 B and substantially perpendicular to the plane of platter 12 B. Switch 10 B is preferably positioned within platter 12 B, but may also be attached externally thereto by any convenient means. Switch 10 B preferably extends generally radially outward from axis of rotation 14 B and more preferably does not intersect axis of rotation 14 B.

Switch 20 B also includes a pair of spaced electrical contacts 28 B, 29 B adapted to electrically connect the interior of distal portion 26 B to the exterior of switch 10 B. Switch 10 B further includes an electrically conducting fluid 30 B (such as mercury or an aqueous electrolytic solution) partially filling enclosure 20 B. Fluid 30 B preferably rests in proximal portion 22 B of switch 10 B when platter 12 B is at rest. Switch 10 B is preferably oriented such that distal portion 26 B is positioned generally radially outward from proximal portion 22 B relative to axis of rotation 14 B. More preferentially, switch 10 B is also oriented such that proximal portion 22 B is positioned below distal portion 26 B such that while platter 12 B is at rest, gravity acts to retain fluid 30 B in proximal portion 22 B.

FIG. 6B illustrates the effects of rotation of platter 12 B on switch 10 B. Rotation of platter 12 B generates a radially outwardly acting force (represented by arrow 36 B) urging fluid 30 B into distal portion 26 B and into contact with the spaced electrical contacts 28 B and 29 B. Force 36 B is proportional to the rate of rotation of platter 12 B, such that when a threshold rate of platter 12 B rotation is achieved, force 36 B becomes sufficient to displace fluid 30 B from proximal portion 22 B into distal portion 26 B and thus into electrical contact with spaced electrical contacts 28 B and 29 B to complete an external electrical circuit (not shown).

The rate of rotation at which fluid 30 B becomes displaced into distal portion 26 B may be predetermined by varying the amount of fluid 30 B in enclosure 20 B, the composition (specifically, the viscosity and/or density) of fluid 30 B, varying the inclination of enclosure 20 B with respect to the plane of platter 12 B, and/or varying the positioning of electrical contacts 28 B and/or 29 B within distal portion 26 B. Generally, as the density and/or viscosity of fluid 30 B increases, a greater force 36 B will be required to displace fluid 30 B into distal portion 26 B. Likewise, as the inclination of enclosure 20 B becomes steeper, a greater force 36 B will be required to displace fluid 30 B into distal portion 26 B. Moreover, the farther the electrical contacts 28 B and 29 B are positioned from proximal portion 22 B, the greater the amount of force 36 B necessary to move fluid 30 B into electrical communication therewith. The precise rotational rate at which fluid 30 B electrically connects electrical contacts 28 B and 29 B may therefore be determined by choosing the appropriate inclination of enclosure 20 B, the appropriate amount and composition of fluid 30 B, and/or the appropriate positioning of electrical contacts 28 B and 29 B in distal portion 26 B in the appropriate combination.

While the invention has been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only the preferred embodiment has been shown and described and that all changes and modifications that come within the spirit of the invention are to be desired to be protected.

Claims

1. An apparatus for automatically closing an electrical circuit, comprising:a generally circular generally planar rotatable platter having a primary axis of rotation substantially perpendicular to the plane of the platter; a substantially arcuate enclosure defining a cavity and having a proximal portion, a middle portion, and a distal portion and connected to the platter; a pair of spaced electrical contacts electrically connecting the interior of the distal portion of the cavity to an exterior of the cavity; an electrically conducting fluid partially filling the cavity; wherein the pair of spaced electrical contacts are adapted to be electrically connected to a circuit exterior to the cavity desired to be actuated by spinning the platter; wherein the distal portion is oriented generally radially outward from the proximal portion relative to the primary axis of rotation; wherein the proximal portion and the distal portion are positioned below the middle portion; wherein rotation of the platter generates a radially outwardly acting force urging the fluid into the distal portion of the cavity and into contact with the pair of spaced electrical contacts.

2. The apparatus of claim 1, wherein the primary axis of rotation of the platter does not intersect the cavity.

3. The apparatus of claim 1, wherein the electrically conducting fluid is mercury.

4. An electrical switch actuated by rotation, comprising:a rotatable platter having a central axis of rotation; a generally arched compartment connected to the platter and having an upper middle portion, an inner leg portion, and an outer leg portion; a first electrical lead extending through the outer leg of the compartment; a second electrical lead spaced apart from the first electrical lead and extending through the outer leg of the compartment; and an electrically conducting fluid partially filling the compartment; wherein rotation of the platter beyond a predetermined threshold rate will generate sufficient angular momentum to urge the electrically conducting fluid into the outer leg of the compartment.

5. The switch of claim 4, wherein the generally arched compartment is oriented substantially in a plane containing the axis of rotation of the platter.

6. The switch of claim 5, wherein the inner leg of the compartment is positioned closer to the axis of rotation of the platter than the outer leg of the compartment.

7. The switch of claim 4, wherein the platter is generally circular.

8. The switch of claim 4, wherein rotation of the platter urges the electrically conducting fluid into electrical contact with the first electrical lead and the second electrical lead in the outer leg of the compartment to complete an electrical circuit.

9. The apparatus of claim 1 wherein the substantially arcuate enclosure is integral with the generally circular generally planar rotatable platter.

10. The apparatus of claim 1 wherein the substantially arcuate enclosure is distinct from the generally circular generally planar rotatable platter.

11. A method of automatically detecting rotation, comprising the steps of:a) providing a rotatable platter having an axis of rotation; b) providing an elongated enclosure having a radially inner elongated portion and a radially outer elongated portion formed therein; c) partially filling the radially inner elongated portion with an electrically conducting fluid; d) connecting the elongated enclosure to the rotatable platter; e) positioning the elongated enclosure relative to the rotatable platter such that the radially inner elongated portion is upwardly inclined; f) extending a pair of spaced electrical leads from the radially outer elongated portion of the enclosure; g) rotating the platter to generate sufficient angular momentum to urge the electrically conducting fluid into electrical contact with the spaced electrical leads.

12. An electrical switch for automatically closing a circuit in a rotating platter, comprising:a rotatable platter; a recess formed in the rotatable platter; a first pair of electrical contacts formed in the recess; a cartridge adapted to engage the recess; an elongated cavity formed in the cartridge and having a proximal portion and a distal portion; a second pair of spaced electrical contacts extending from the distal portion and adapted to electrically engage the first pair of electrical contacts; an electrically conducting fluid partially filling the cavity; wherein the fluid is adapted to rest in the proximal end when the platter is at rest; and wherein the fluid is adapted to make electrical contact with the second pair of electrical contacts when the platter is rotated beyond a predetermined threshold rate.

13. The switch of claim 12 wherein the cavity further includes a middle portion connecting the proximal portion and the distal portion.

14. The switch of claim 12 wherein the primary axis of rotation of the platter does not intersect the cavity.

15. An electrical switch, comprising:a rotatable platter having an axis of rotation; a generally linear enclosure operationally coupled to the platter and having an upper distal portion and a lower proximal portion; a pair of electrical connections extending through the distal portion; and an electrically conducting fluid partially filling the enclosure; wherein spinning the platter in excess of a predetermined threshold rate of rotation will generate sufficient angular momentum to urge the electrically conducting fluid into the distal portion.

16. The switch of claim 15, wherein the generally linear enclosure is oriented substantially in a plane containing the axis of rotation of the platter.

17. The switch of claim 16, wherein the proximal portion is positioned closer to the axis of rotation than the distal portion.

18. The switch of claim 15, wherein the platter is generally circular.