Pulse Dampener with Automatic Pressure-Compensation

We claim: 1 . A fluid pulse dampener with an auto-compensation mechanism comprising: a main body comprising an elongated fluid channel having a fluid input port at a first end of the fluid channel and a fluid output port at a second end of the fluid channel, wherein the fluid input port and the fluid output port are adapted for connecting to a pressurized fluid conduit, and wherein the fluid channel has a first opening and a second opening, wherein the first opening is closer to the fluid input port than the second opening and the second opening is closer to the fluid output port than the first opening; a membrane adjacent to a portion of the fluid channel, wherein said membrane covers the first and second openings; a pneumatic cover comprising: a dampening chamber adjacent to at least a portion of the first opening in the fluid channel, wherein the pneumatic cover defines a portion of the dampening chamber and said membrane encloses a remaining portion; a variable-restrictive element (“VRE”) chamber adjacent to at least a portion of the second opening in the fluid channel, wherein the pneumatic cover defines a portion of the VRE chamber and said membrane encloses a remaining portion; an air pressure buffer chamber, wherein said air pressure buffer chamber is connected to said dampening chamber by a first channel, and wherein said air pressure buffer chamber is connected by a second channel to said VRE chamber, wherein said air pressure buffer chamber has an air input port that connects said air pressure buffer chamber to an external gas source, and wherein the air input port is adapted for connecting to a pressurized air source as the external gas source; and an air output port connected by a channel to said VRE chamber and open to an external gas. 2 . The fluid pulse dampener of claim 1 , further comprising a membrane stop within said dampening chamber. 3 . The fluid pulse dampener of claim 1 , further comprising a restrictive element having a first end and a second end, wherein said restrictive element limits the flow of air and is connected to a pressurized air source at the first end and to the air input port at the second end. 4 . The fluid pulse dampener of claim 1 , further comprising an air output restrictive element, wherein said air output restrictive element is adapted to limit the flow of air therethrough and is adapted for connection to the air output port. 5 . The fluid pulse dampener of claim 3 , further comprising an air output restrictive element, wherein said air output restrictive element is adapted to limit the flow of air therethrough and is adapted for connection to the air output port. 6 . The fluid pulse dampener of claim 1 further comprising: a protruding inner ring on a surface of the pneumatic cover located adjacent to a portion of the membrane, wherein said protruding inner ring has a diameter which extends from a point on said dampening chamber that is nearest to the fluid input port to a point on said VRE chamber that is nearest to the fluid output port, and wherein said protruding inner ring surrounds said dampening chamber and said VRE chamber; a protruding middle ring on a surface of said main body located adjacent to said membrane wherein said middle ring is larger in diameter than the inner ring and wherein said middle ring is concentric with said inner ring; an outer ring larger in diameter than said middle ring and concentric with said middle ring; and wherein the diameter of said membrane is larger than the diameter of said outer ring and said outer ring and said inner ring push the membrane around said middle ring and said membrane forms a seal across said dampening chamber and said VRE chamber. 7 . The fluid pulse dampener of claim 1 wherein said main body and said pneumatic cover comprise a material selected from the group consisting of: stainless steel, aluminum, polyetheretherketone, acrylic, ceramic, a cyclic-olefin polymer or co-polymer, polysulfone, polyphenylsulfone, or polyetherimide (Ultem). 8 . The fluid pulse dampener of claim 1 wherein said membrane comprises a flexible material comprising a material selected from the group consisting of: natural rubber, silicone, thermoplastic elastomers, ethylene propylene diene monomer (EPDM), fluorelastomers (FKM, such as Viton), perfluoroelastomer (FFKM, such as Kalrez), fluoropolymers like Teflon, and PharMed. 9 . The fluid pulse dampener of claim 8 wherein said membrane has a durometer measurement of between Shore A10 and Shore A95. 10 . The fluid pulse dampener of claim 1 wherein said main body, said pneumatic cover, and said membrane are each adapted to withstand fluid pressure of up to at least 100 pounds per square inch. 11 . The fluid pulse dampener of claim 1 wherein said dampener chamber comprises a hemispherical shape. 12 . The fluid pulse dampener of claim 1 wherein said dampener chamber comprises an eye shape. 13 . The fluid pulse dampener of claim 1 wherein said fluid input port is adapted to be connected, directly or indirectly, to a peristaltic pump. 14 . The fluid pulse dampener of claim 1 wherein said fluid input port is adapted to be connected, directly or indirectly, to a piston pump. 15 . The fluid pulse dampener of claim 1 wherein said main body is adapted to receive a fluid having a flow rate of between 0 to 1000 microliters per minute. 16 . The fluid pulse dampener of claim 15 wherein said fluid pulse dampener is adapted to compensate for pulse sizes of between 0 and 50 microliters. 17 . The fluid pulse dampener of claim 1 wherein said air input port and said air output port are open to an ambient fluid. 18 . The fluid pulse dampener of claim 1 wherein said air input port is adapted for connection to a source of pressurized gas in excess of atmospheric pressure. 19 . A fluid pulse dampener comprising: a main body comprising an elongated fluid channel having a fluid input port at a first end of the fluid channel and a fluid output port at a second end of the fluid channel, wherein the fluid input port and the fluid output port are adapted for connecting to a pressurized fluid conduit, and wherein the fluid channel has a plurality of openings, wherein at least a first one of the plurality of openings is closer to the fluid input port than at least a second one of the plurality of openings and the at least a second one of the plurality of openings is closer to the fluid output port than the at least first one of the plurality of openings; a first membrane adjacent to a portion of the fluid channel, wherein said first membrane covers the at least first one of the plurality of openings; a second membrane adjacent to a portion of the fluid channel, wherein said second membrane covers the at least second one of the plurality of openings; a pneumatic cover comprising: a dampening chamber adjacent to at least a portion of the at least first one of the plurality of openings in the fluid channel, wherein the pneumatic cover defines a portion of the dampening chamber and said first membrane encloses a remaining portion; a variable-restrictive element (“VRE”) chamber adjacent to at least a portion of the at least second one of the plurality of openings in the fluid channel, wherein the pneumatic cover defines a portion of the VRE chamber and said second membrane encloses a remaining portion; an air pressure buffer chamber, wherein said air pressure buffer chamber is connected to said dampening chamber by a first channel, and wherein said air pressure buffer chamber is connected