Method for influencing a fluid flow

What is claimed is: 1. A method for influencing a fluid flow in a fluid line, the method comprising: providing a wall; providing a fluid flow in a fluid line having the wall; providing a honeycomb body with a fluid inlet side and a fluid outlet side, the honeycomb body arranged in the fluid line; a honeycomb structure having a cross-sectional area, the honeycomb structure being part of the honeycomb body; providing a plurality of ducts through which the fluid flow may pass from the fluid inlet side to the fluid outlet side, the plurality of ducts being part of the honeycomb structure; providing an outer boundary being part of the honeycomb body; providing an encircling outer zone close to the outer boundary; providing a central zone arranged within the outer zone, such that the outer zone accounts for at most 70% of the cross-sectional area of the honeycomb structure; providing the fluid flow upstream of the honeycomb body; introducing the fluid flow into the honeycomb body via the fluid inlet side, wherein, at the fluid inlet side, an average first inflow speed of the fluid flow in the outer zone close to the boundary is lower than an average second inflow speed of the fluid flow in the central zone; and at least partially diverting the fluid flow in an outward radial direction, such that, at the fluid outlet side, an average first outflow speed of the fluid flow in at least one subregion of the outer zone close to the boundary is at least 20% higher than an average second outflow speed of the fluid flow in the central zone; wherein the honeycomb body has at least one at least partially structured metallic layer; and wherein the honeycomb body is formed from alternating smooth and structured metallic layers, wherein the smooth metallic layers have at least openings, and the structured metallic layers have at least flow-guiding surfaces. 2. The method of claim 1 , wherein the honeycomb body has at least one at least partially structured metallic layer. 3. The method of claim 1 , wherein the at least one at least partially structured metallic layer is wound in spiral-shaped form. 4. The method of claim 2 , wherein the honeycomb body is formed from alternating smooth and structured metallic layers, wherein the smooth metallic layers have at least openings, and the structured metallic layers have at least flow-guiding surfaces. 5. The method of claim 1 , wherein the fluid flow, as it flows through the honeycomb body, is at least partially catalytically converted by way of a catalytic coating of the honeycomb body. 6. The method of claim 1 , wherein, on the fluid outlet side, the average first outflow speed of the fluid flow in the entire outer zone close to the boundary is at least 20% higher than the average second outflow speed of the fluid flow in the central zone. 7. A honeycomb body, comprising: an outer boundary; a fluid inlet side; a fluid outlet side; a honeycomb structure having a cross-sectional area; a plurality of ducts being part of the honeycomb structure, the plurality of ducts being traversed by a fluid flow from the fluid inlet side to the fluid outlet side; a plurality of openings, each of the plurality of openings being part of one of the plurality of ducts; a plurality of flow-guiding surfaces being part of the plurality of openings; a catalytic coating disposed on each of the plurality of ducts; a central zone; and an encircling outer zone close to the outer boundary, the central zone arranged within the outer zone, such that the outer zone accounts for at most 70% of the cross-sectional area of the honeycomb structure; wherein the openings and flow-guiding surfaces divert the fluid flow in an outward radial direction, and at the fluid outlet side, an average first outflow speed of the fluid flow in at least one subregion of the outer zone close to the boundary is at least 20% higher than an average second outflow speed of the fluid flow in the central zone; wherein the honeycomb body has at least one at least partially structured metallic layer; and wherein the honeycomb body is formed from alternating smooth and structured metallic layers, wherein the smooth metallic layers have the plurality of openings, and the structured metallic layers have the flow-guiding surfaces. 8. The honeycomb body of claim 7 , wherein the honeycomb body has at least one at least partially structured metallic layer. 9. The honeycomb body of claim 5 , wherein the at least one at least partially structured metallic layer is wound in spiral-shaped form. 10. The honeycomb body of claim 8 , wherein the honeycomb body is formed from alternating smooth and structured metallic layers, wherein the smooth metallic layers have at least openings, and the structured metallic layers have at least flow-guiding surfaces. 11. The honeycomb body of claim 7 , wherein the fluid flow, as it flows through the honeycomb body, is at least partially catalytically converted by way of a catalytic coating of the honeycomb body. 12. The honeycomb body of claim 7 , wherein, on the fluid outlet side, the average first outflow speed of the fluid flow in the entire outer zone close to the boundary is at least 20% higher than the average second outflow speed of the fluid flow in the central zone.