Injection mold assembly and method of designing same

The invention claimed is: 1. A method of designing an injection mold assembly comprising: providing an initial layout of a predetermined number of cooling channels representing cooling flow paths; wherein each cooling channel is modeled by a selected number of cooling elements; wherein each cooling channel is in contact with and follows a contoured surface on a cooled side of a mold tool element; calculating temperatures of tool surface elements of a tool surface on a tool surface side of the mold tool element opposite the cooled side; wherein the tool surface elements spatially correspond with the cooling elements and are cooled by coolant flow in the cooling channels via heat conduction through the tool element; determining whether a predetermined condition is satisfied by the calculated temperatures of the tool surface elements; generating a revised layout of the cooling channels according to an optimization algorithm that uses the calculated temperatures of the tool surface elements when the predetermined condition is not satisfied; repeating said calculating, determining, and generating until the predetermined condition is satisfied; and manufacturing the tool element and fins that define a cooling cavity at the cooled side having coolant flow paths corresponding to the cooling channels of the revised layout in which the predetermined condition is satisfied. 2. The method of claim 1 , wherein each tool surface element is positioned on the tool surface normal to a respective different one of the cooling elements. 3. The method of claim 1 , wherein the temperatures are calculated based on steady state heat conduction through the tool element. 4. The method of claim 1 , wherein the revised layout of the cooling channels is established by repositioning the cooling elements such that a pattern of adjacent ones of the cooling elements is maintained. 5. The method of claim 1 , wherein the predetermined condition is the temperature of all of said tool surface elements being within predetermined range of temperatures. 6. The method of claim 1 , wherein the predetermined condition is a predetermined number of iterations of said calculating temperatures. 7. The method of claim 1 , wherein the optimization algorithm is based on at least one of temperature distribution of the tool surface elements, minimization of cooling cycle time, balancing of heat flow from plastic at the cavity side to coolant at the cooling side, minimizing a temperature change in each of the cooling channels, maintaining turbulent flow through the cooling channels, maintaining uniform heat flow through the tool element, avoiding cyclical stress failure of the tool assembly, and pressure drop in each of the cooling channels. 8. The method of claim 1 , wherein the fins are connected to and extend from the second side of the tool element; wherein a base supports the fins; wherein the tool element, the fins and the base define the coolant flow cavity at the second side of the tool element; wherein the tool element is configured to have a substantially uniform thickness between the first tool surface and the coolant flow cavity; and wherein the fins are positioned to establish the coolant flow paths in the coolant flow cavity, each of the coolant flow paths being between adjacent ones of the fins; and further comprising: configuring widths of each of the cooling channels between adjacent ones of the fins so that the fins are sized to ensure that tensile stress, shear stress, and deflection of the tool element are below predetermined maximum limits.