Temperature control device for controlling the temperature of a battery

The invention claimed is: 1. A temperature control device for a battery, comprising: a fluid duct flowable at least one of through and around by a fluid, the fluid duct delimited by a duct wall composed of an electrically conductive material; at least one electrically insulating insulation layer disposed on an outer side of the duct wall facing away from the fluid via at least one of a screen printing process and a stencil printing process, the at least one insulation layer composed of a plastic material and having a first side interfacing with the duct wall and a second side disposed opposite the first side and facing away from the duct wall; and the at least one insulation layer including a plurality of layer sections arranged spaced apart from one another and an intermediate region disposed on the flow duct between the plurality of layer sections, the intermediate region having a reduced layer thickness compared to a layer thickness of the plurality of layer sections to provide the at least one insulation layer with a variable thickness; and wherein the plurality of layer sections are distributed relative to an elevated view onto the outer side of the duct wall in a grid-like arrangement with respect to one another where the plurality of layer sections are arranged along at least two grid lines and at least two grid gaps extending transversely to the at least two grid lines such that the second side of the at least one insulation layer defined at the intermediate region is depressed from the second side defined at the plurality of layer sections of the grid-like arrangement with respect to the outer side of the duct wall. 2. The temperature control device according to claim 1 , wherein at least one of: the plastic material includes an elastomer; and the plastic material includes at least one of a mixing material and a filling material to increase the thermal conductivity of the at least one insulation layer. 3. The temperature control device according to claim 1 , wherein the intermediate region separates the at least two grid gaps from one another and the at least two grid lines from one another, and wherein a distance between two adjacent grid gaps of the at least two grid gaps is greater than that between two adjacent grid lines of the at least two grid lines. 4. The temperature control device according to claim 1 , wherein the at least one insulation layer further includes at least two individual layers arranged stacked on one another along a stacking direction running orthogonally to a wall plane defined by the outer side of the duct wall. 5. The temperature control device according to claim 4 , wherein a first individual layer of the at least two individual layers extends completely over the outer side of the duct wall and defines the intermediate region, and wherein a second individual layer of the at least two individual layers is arranged stacked on top of the first individual layer in the stacking direction and only in sections along the outer side of the duct wall and includes the plurality of layer sections. 6. The temperature control device according to claim 1 , wherein the at least one insulation layer further includes a base layer covering the outer side of the duct wall and the plurality of layer sections of the grid-like arrangement are disposed on the base layer, and wherein the base layer defines the intermediate region. 7. The temperature control device according to claim 6 , wherein at least one layer section of the plurality of layer sections with respect to the elevated view onto the duct wall defines a geometry of a polygon. 8. The temperature control device according to claim 6 , wherein the intermediate region is disposed between each of the plurality of layer sections of the grid-like arrangement. 9. The temperature control device according to claim 1 , wherein the fluid duct is configured as a flat tube, wherein the duct wall forms a part of the flat tube. 10. A battery arrangement, comprising: a temperature control device, including: a fluid duct having a fluid channel for conveying a fluid in a flow direction, the fluid duct delimited by a duct wall composed of an electrically conductive material and defining an outer side facing away from the fluid channel; at least one insulation layer composed of an electrically insulating elastomer material disposed on the outer side of the duct wall via at least one of a screen printing process and a stencil printing process, wherein the at least one insulation layer includes a plurality of individual layers arranged stacked on one another along a stacking direction, the stacking direction extending orthogonally to a wall plane defined by the outer side of the duct wall; the plurality of individual layers including a first layer arranged on the outer side of the duct wall and a second layer arranged over the first layer, the second layer including a plurality of layer sections arranged spaced apart from one another along the duct wall; the plurality of layer sections provided with respect to one another in a grid arrangement relative to an elevated view onto the outer side of the duct wall, the grid arrangement including the plurality of layer sections disposed along at least two grid lines extending in the flow direction and at least two grid gaps extending transversely to the at least two grid lines, wherein the at least two grid lines and the at least two grid gaps of the grid arrangement are separated from one another by an intermediate region extending between each of the plurality of layer sections; and a battery coupled thermally to the duct wall of the temperature control device and including at least one battery cell; wherein the at least one insulation layer is disposed in a sandwich-like arrangement between the duct wall and the at least one battery cell of the battery; wherein the plurality of layer sections of the second layer have a different layer thickness compared to that of the intermediate region, the layer thickness defined by a distance from the wall plane of the outer side of the duct wall to an outer side of the at least one insulation layer facing away from the duct wall; and wherein the first layer defines the intermediate region disposed on the duct wall between each of the plurality of layer sections of the second layer, and wherein the intermediate region has a reduced layer thickness compared to the layer thickness of the plurality of layer sections. 11. The battery arrangement according to claim 10 , wherein a number of the plurality of individual layers of the at least one insulation layer in a region of the at least one battery cell is one of greater and smaller than a number of the plurality of individual layers of the at least one insulation layer in a region spaced away from the at least one battery cell. 12. A method for producing a temperature control device, comprising the following steps: applying via at least one of a screen printing process and a stencil printing process an electrically insulating insulation layer composed of a plastic material onto an outer side of a duct wall, the duct wall defining at least in part a fluid duct flowable through by a fluid, wherein applying the insulation layer onto the outer side of the duct wall includes providing at least two layer sections arranged spaced apart from one another along the flow duct with a different layer thickness than that of an intermediate region disposed between the at least two layer sections on the flow duct, the layer thickness defined by a distance from a wall plane of the outer side of the duct wall to an outer side of the insulation layer facing away from the duct wall; arranging a battery compris