Electrochemical Cell Unit with Improved Separator Plate

1 . An electrochemical cell unit comprising: a cell layer comprising an electrochemically active cell region; and, a separator plate comprising a metal sheet overlying the cell layer; wherein the separator plate has a selectively shaped three dimensional (3D) region that overlies at least part of the electrochemically active cell region; and in that three dimensional (3D) region: the metal sheet has been deformed into a first plurality of outwardly extending dimpled protrusions that define the height of a first fluid volume on a first side of the separator plate; additionally, the metal sheet has been deformed into a second plurality of outwardly extending dimpled protrusions that define the height of a second fluid volume on a second side of the separator plate; whereby a mid-plane region is disposed between the protrusions; and, the mid-plane region is so shaped as selectively to vary its height in at least one direction across the active cell region such that the interrelated respective heights of the first and second fluid volumes are correspondingly increased and decreased as a result. 2 . The electrochemical cell unit of claim 1 , wherein the height of the mid-plane region is varied as a discontinuous transition. 3 . The electrochemical cell unit of claim 1 , wherein the height of the mid-plane region is varied as a continuous transition. 4 . The electrochemical cell unit claim 1 , comprising an inlet to and an outlet from the first fluid volume positioned towards opposing edges of the cell unit with the electrochemically active cell region positioned therebetween, and wherein the at least one direction of height variation in the mid-plane region is such that the height of the first fluid volume is smaller in a central area of the cell unit than in an area adjacent to an edge of the cell unit. 5 . The electrochemical cell unit of claim 1 , wherein the at least one direction of height variation in the mid-plane region is generally perpendicular to a straight line between an inlet to and an outlet from the first fluid volume, and wherein the height of the first fluid volume is smaller along the straight line than to at least one side of the straight line. 6 . The electrochemical cell unit of claim 1 , comprising an inlet to and an outlet from the first fluid volume positioned towards opposing edges of the cell unit with the electrochemically active cell region positioned therebetween, and wherein the at least one direction of height variation in the mid-plane region is such that the height of the first fluid volume decreases from the inlet to the outlet of the first fluid volume. 7 . The electrochemical cell unit of claim 6 , comprising an inlet to and an outlet from the second fluid volume positioned towards or outwith opposing edges of the cell unit with the electrochemically active cell region positioned therebetween, the inlet and outlet of the second fluid volume positioned such that the height of the second fluid volume increases from the inlet to the outlet of the second fluid volume. 8 . The electrochemical cell unit of claim 7 , wherein the second fluid volume includes a bypass for second fluid around a portion of the 3D region proximal to the inlet to the second fluid volume. 9 . The electrochemical cell unit of claim 1 , wherein the 3 dimensional (3D) region overlies all of the electrochemically active cell region. 10 . The electrochemical cell unit of claim 1 , whereby the dimpled protrusions of the first and second plurality of dimpled protrusions are shaped such that their outermost portions do not comprise any laterally extending contact portions that extend heightwise the full height of a fluid volume so as to form a channel within that fluid volume within which flow is constrained. 11 . The electrochemical cell unit of claim 1 , wherein the first side of the separator plate faces the cell layer and a contact portion of each of the first plurality of dimpled protrusions contact the cell layer. 12 . The electrochemical cell unit of claim 11 , wherein the contact portion of each of the first plurality of dimples and a contact portion of each of the second plurality of dimples respectively form first and second planes, the first and second planes each being planar and parallel to one another. 13 . (canceled) 14 . The electrochemical cell unit of claim 1 , wherein the cell unit is a metal-supported cell unit such that the cell layer comprises a metal support plate carrying, on a first side thereof, the electrochemically active cell region provided over a porous region. 15 . The electrochemical cell unit of claim 14 , wherein: at least one of the separator plate and the metal support plate comprises flanged perimeter features formed by pressing the plate to a concave configuration; and the separator plate and the metal support plate are directly adjoined at the flanged perimeter features to form the first fluid volume therebetween, optionally by welding. 16 . The electrochemical cell unit of claim 14 , further comprising a spacer plate disposed between the metal support plate and separator plate, the spacer plate having an aperture therein which defines the first fluid volume, and the metal support plate cell layer, spacer plate, and separator plate are joined around their perimeter. 17 . The electrochemical cell unit of claim 1 , wherein the first fluid volume is for fuel, and the second fluid volume is for oxidant. 18 . The electrochemical cell unit of claim 1 , wherein the height of the first fluid volume is less than the height of the second fluid volume. 19 . An electrochemical cell stack comprising a plurality of electrochemical cell units according to claim 1 , wherein: the first side of the separator plate of a first electrochemical cell unit faces the cell layer of the first electrochemical cell unit and encloses the first fluid volume therebetween, and the second side of the separator plate of the first electrochemical cell unit faces a cell layer of a second, neighbouring, electrochemical cell unit in the stack of cell units and encloses the second fluid volume therebetween. 20 - 24 . (canceled) 25 . The electrochemical cell stack of claim 19 , further comprising means for supply and exhaust of first fluid from the first fluid volume, wherein the means for supply and exhaust of first fluid from the first fluid volume comprises at least one fluid port provided through the separator plate and the cell layer which is in fluid communication with the first fluid volume, wherein the at least one fluid port of the respective cell units align to form at least one passageway extending in the stack direction, these being internally manifolded passageways. 26 . A method for manufacturing a separator plate, comprising providing a planar metal sheet; and deforming the metal sheet to provide a three dimensional (3D) region, the three dimensional (3D) region comprising: a first plurality of outwardly extending dimpled protrusions that define the height of a first fluid volume on a first side of the separator plate; a second plurality of outwardly extending dimpled protrusions that define the height of a second fluid volume on a second side of the separator plate; whereby a mid-plane region is disposed between the protrusions; and, the mid-plane region is so shaped as selectively to vary its height in at least one direction across the active cell region such that the interrelated respective heights of the first and second fluid vo