Separator plate for an electrochemical system

The invention claimed is: 1. A separator plate for an electrochemical system, comprising: at least one first through-opening in the plate for conducting a medium through the plate; a distribution or collection region comprising a plurality of lands and channels formed between the lands, which are each in fluid connection with the through-opening; a flow field in fluid connection with the through-opening, the flow field comprising guiding structures for guiding a medium through the flow field and the guiding structures comprising lands, and the lands of the flow field have a mean height h 1 determined perpendicularly to the planar surface plane of the plate; and a contiguous, lowered transition region arranged between the distribution or collection region and the flow field in such a way that, for each of the channels of the distribution or collection region, medium flowing from the channel of the distribution or collection region into the flow field, or from the flow field into the channel of the distribution or collection region, flows through the transition region, and the transition region comprising lands formed by the lands of the distribution or collection region and/or the lands of the flow field extending into the transition region and transitioning to a maximum height h max in the transition region where h max ≤0.95 h 1 , and the maximum height h max determined perpendicularly to the planar surface plane of the plate. 2. The separator plate according to claim 1 , wherein the lands of the distribution or collection region have a mean height h 2 determined perpendicularly to the planar surface plane of the plate, where applies: h max ≤0.9 h 2 . 3. The separator plate according to claim 1 , wherein the lowered transition region has a straight progression transversely to the flow direction of the medium through the transition region, or substantially transversely to the flow direction of the medium through the transition region. 4. The separator plate according to claim 1 , wherein the lands of the flow field extend into the transition region to form the lands of the transition region and the lands of the transition region curve from the path of the lands of the flow field. 5. The separator plate according to claim 1 , wherein the lands of the transition region are formed by both the lands of the distribution or collection region and the lands of the flow field extending into the transition region. 6. The separator plate according to claim 5 , wherein at least one of the lands of the transition region connects lands of the distribution or collection region transition with lands of the flow field to form a continuous land. 7. The separator plate according to claim 6 , wherein lands of the distribution or collection region extend into the transition region to form the lands of the transition region and the lands of the transition region curve from the path of the lands of the distribution or collection region. 8. The separator plate according to claim 7 , wherein at least every twelfth of the lands of the flow field extends into the lowered transition region. 9. The separator plate according to claim 8 , wherein at least every sixth of the lands of the flow field extends into the distribution region. 10. The separator plate according to claim 9 , wherein the lands extending through the transition region and/or the lands extending into the transition region have the same maximum height in the transition region. 11. The separator plate according to claim 10 , wherein the flow field comprises a number n 1 of channels, and the distribution or collection region comprises a number n 2 of channels, where applies: n 1 ≥2 n 2 , preferably n 1 ≥3 n 2 . 12. The separator plate according to claim 1 , wherein a depth of at least one channel which is determined perpendicularly to the planar surface plane of the plate varies so as to influence the flow direction of the medium in the transition region and/or distribution or collection region. 13. The separator plate according to claim 12 , wherein the depth of at least one channel varies along the progression thereof in the transition region and/or the distribution or collection region. 14. The separator plate according to claim 13 , wherein the depth of at least one channel varies in the transition region and/or distribution or collection region transversely to the flow direction of the medium. 15. The separator plate according to claim 1 , comprising a bead that completely encloses the through-opening so as to seal the through-opening, wherein the bead includes passages or conducting a medium through the bead, and the channels of the distribution or collection region are in fluid connection with the through-opening by way of the passages in the bead. 16. A bipolar plate for an electrochemical system, comprising a first separator plate, comprising: at least one first through-opening in the plate for conducting a medium through the plate; a distribution or collection region comprising a plurality of lands and channels formed between the lands, which are each in fluid connection with the through-opening; a flow field, which by way of the distribution or collection region is in fluid connection with the through-opening and comprises guiding structures for guiding a medium through the flow field and the guiding structures comprising lands, and the lands of the flow field have a mean height h 1 determined perpendicularly to the planar surface plane of the plate; and a contiguous, lowered transition region, which is arranged between the distribution or collection region and the flow field in such a way that, for each of the channels of the distribution or collection region, medium flowing from the channel of the distribution or collection region into the flow field, or from the flow field into the channel of the distribution or collection region, flows through the transition region, and the transition region comprising lands formed by the lands of the distribution or collection region and/or the lands of the flow field extending into the transition region and transitioning to a maximum height h max within the transition region where h max ≤0.95 h 1 , and h max is determined perpendicularly to the planar surface plane of the plate; and comprising a second separator plate, which includes at least one second through-opening, wherein the first separator plate and the second separator plate are joined, and the at least one first through-opening of the first separator plate and the at least one second through-opening of the second separator plate are aligned with one another so as to form at least one through-opening in the bipolar plate. 17. The bipolar plate according to claim 16 , wherein only the first separator plate includes a lowered transition region wherein the following applies to the maximum height h max of the transition region of the first separator plate and to the maximum height h 1 of the lands of the flow field of the second separator plate: h max ≤0.9 h 1 . 18. The bipolar plate according to claim 16 , wherein the following applies to the maximum height h max,1 of the transition region of the first separator plate and to the maximum height h 11 of the lands of the flow field of the first separator plate: 0.85 h 11 ≤h max,1 ≤0.95 h 11 ; and wherein the following applies to the maximum height h max,2 of the transition region of the second separator plate and to the maximum height h 12 of the lands of the flow field of the second separator plate: 0.85 h 12 ≤h max,2 ≤0.95 h 12 . 19. The bipo