US2003197139A1PendingUtilityA1
Valve for use in microfluidic structures
Est. expiryJun 23, 2020(expired)· nominal 20-yr term from priority
Inventors:Clinton L. Williams
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Claims
Abstract
A valve for use in microfluidic structures. The valve uses a spherical member, such as a ball bearing, to depress an elastomeric member to selectively open and close a microfluidic channel. The valve may be operated manually or by use of an internal force generated to shift the spherical member to its activated position.
Claims
exact text as granted — not AI-modifiedWhat is claimed is:
1 . A valve for use in a microfluidic structure, comprising:
a first rigid layer; a first flexible layer; a first channel, formed between said first rigid layer and said first flexible layer, said channel having an inlet and an outlet and capable of fluid flow from said inlet to said outlet; a spherical actuator located adjacent said flexible layer on the side opposite said rigid layer; and means for shifting said actuator to an actuating position such that a portion of said flexible layer is shifted toward said rigid layer, restricting fluid flow within said first channel.
2 . The valve of claim 1 , wherein said first flexible layer is constructed from an elastomeric material.
3 . The valve of claim 1 , wherein said first flexible layer is constructed from polyvinylidene chloride.
4 . The valve of claim 1 , wherein said spherical actuator comprises a metal ball bearing.
5 . The valve of claim 1 , wherein said shifting means comprises a finger of a human operator.
6 . The valve of claim 1 , wherein said shifting means comprises mechanical operating means.
7 . The valve of claim 1 , further comprising:
a second rigid layer, located adjacent said first flexible layer on the side opposite said first channel; a second flexible layer; a second channel, formed between said second rigid layer and said second flexible layer, for containing said spherical actuator; a third rigid layer; a first aperture, located in said second rigid layer, for positioning said spherical actuator within said second channel during actuation; a third channel, formed between said second flexible layer and said third rigid layer, for containing said shifting means.
8 . The valve of claim 7 , wherein said shifting means comprises a fluid flowing within said third channel.
9 . The valve of claim 7 , wherein said second flexible layer comprises an elastomeric material.
10 . The valve of claim 7 , wherein all of said rigid layers are constructed from MYLAR.
11 . A microfluidic control system, comprising:
a plurality of valves, with each valve comprising
a first rigid layer;
a first flexible layer;
a first channel, formed between said first rigid layer and said first flexible layer, said channel having an inlet and an outlet and capable of fluid flow from said inlet to said outlet;
a spherical actuator located adjacent said flexible layer on the side opposite said rigid layer;
and means for shifting said actuator to an actuating position such that a portion of said flexible layer is shifted toward said rigid layer, restricting fluid flow within said first channel;
and means for controlling the operation of said plurality of valves.
12 . The system of claim 11 , wherein said controlling means comprises a computer.
13 . The system of claim 11 , wherein said controlling means comprises a programmable controller.Cited by (0)
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