Lamination planning method for laminate molded object, and laminate molded object manufacturing method and manufacturing device

The invention claimed is: 1. A depositing planning method for an additively-manufactured object, to build an additively-manufactured object using three-dimensional shape data of the additively-manufactured object by an additive manufacturing apparatus for depositing a weld bead on a base plate, wherein a computer executes: a step of acquiring the three-dimensional shape data; a step of creating a depositing plan that defines a welding pass for forming each layer obtained by dividing a shape of the three-dimensional shape data into layers using the weld bead, and a welding condition for forming the weld bead; a step of setting an inter-pass time from an end of a welding pass to a start of a next welding pass for a plurality of the welding passes, and calculating an inter-pass temperature by performing heat transfer calculation in the inter-pass time; a step of determining whether the inter-pass temperature falls within a preset inter-pass temperature range, adjusting the inter-pass time until the inter-pass temperature falls within the inter-pass temperature range, and repeating the heat transfer calculation; a step of calculating a building time required for building the additively-manufactured object according to the inter-pass time when the inter-pass temperature falling within the inter-pass temperature range is calculated and a welding pass time required for forming the weld bead in the welding pass; a step of repeatedly correcting, by comparing the building time with a preset upper limit value, the welding condition in the depositing plan until the building time becomes equal to or less than the upper limit value; a step of creating an operation program based on the depositing plan including the corrected welding condition; and a step of sending commands to perform additive manufacturing according to the operation program. 2. The depositing planning method for an additively-manufactured object according to claim 1 , wherein the welding condition is corrected by correcting any one of travel speed, the number of passes, and a bead shape. 3. The depositing planning method for an additively-manufactured object according to claim 1 , wherein the computer executes: a step of creating built-up object shape data of the additively-manufactured object during thermal contraction based on the inter-pass time and the inter-pass temperature calculated after the heat transfer calculation is completed; a step of calculating an excess thickness amount from a difference between a building shape of the built-up object shape data and a building shape of the three-dimensional shape data; and a step of estimating a cutting time, which is a processing time for the additively-manufactured object, from the excess thickness amount, and the correction is performed by adding the cutting time to the building time. 4. The depositing planning method for an additively-manufactured object according to claim 2 , wherein the computer executes: a step of creating built-up object shape data of the additively-manufactured object during thermal contraction based on the inter-pass time and the inter-pass temperature calculated after the heat transfer calculation is completed; a step of calculating an excess thickness amount from a difference between a building shape of the built-up object shape data and a building shape of the three-dimensional shape data; and a step of estimating a cutting time, which is a processing time for the additively-manufactured object, from the excess thickness amount, and the correction is performed by adding the cutting time to the building time. 5. A method for manufacturing an additively-manufactured object, comprising: providing the base plate, depositing the weld bead on the base plate to create the object based on the operation program created by the depositing planning method for the additively-manufactured object according to claim 1 . 6. A depositing planning method for an additively-manufactured object, to build an additively-manufactured object using three-dimensional shape data of the additively-manufactured object by an additive manufacturing apparatus for depositing a weld bead on a base plate, wherein a computer executes: a step of acquiring the three-dimensional shape data; a step of creating a depositing plan that defines a welding pass for forming each layer obtained by dividing a shape of the three-dimensional shape data into layers using the weld bead, and a welding condition for forming the weld bead; a step of setting an inter-pass time from an end of a welding pass to a start of a next welding pass for a plurality of the welding passes, and calculating an inter-pass temperature by performing heat transfer calculation in the inter-pass time; a step of determining whether the inter-pass temperature falls within a preset inter-pass temperature range, repeating the heat transfer calculation until the inter-pass temperature falls within the inter-pass temperature range, and adjusting the inter-pass time; a step of creating built-up object shape data of the additively-manufactured object during thermal contraction according to the inter-pass time and the inter-pass temperature calculated by the heat transfer calculation, and calculating a shape difference between a building shape of the built-up object shape data and a building shape of the three-dimensional shape data; a step of comparing the shape difference with a preset appropriate value, creating corrected three-dimensional shape data corrected according to the shape difference until the shape difference is smaller than the appropriate value, and repeating steps from the creation of the depositing plan to the calculation of the built-up object shape data; a step of creating an operation program based on the depositing plan created from the corrected three-dimensional shape data; and a step of sending commands to perform additive manufacturing according to the operation program. 7. The depositing planning method for an additively-manufactured object according to claim 6 , wherein the computer executes a step of predicting a deformation amount of the additively-manufactured object due to a release strain caused by processing of the additively-manufactured object, and correcting the built-up object shape data based on the deformation amount. 8. The depositing planning method for an additively-manufactured object according to claim 6 , wherein the computer executes a step of predicting a deformation amount of the additively-manufactured object due to a release strain caused by removing the base plate from the additively-manufactured object, and correcting the built-up object shape data based on the deformation amount. 9. The depositing planning method for an additively-manufactured object according to claim 7 , wherein the computer executes a step of predicting a deformation amount of the additively-manufactured object due to a release strain caused by removing the base plate from the additively-manufactured object, and correcting the built-up object shape data based on the deformation amount. 10. A method for manufacturing an additively-manufactured object, comprising: providing the base plate, depositing the weld bead on the base plate to create the object based on the operation program created by the depositing planning method for the additively-manufactured object according to claim 6 . 11. An apparatus for manufacturing an additively-manufactured object, to build the additively-manufactured object by depositing a weld bead on a base plate using three-dimensional shape data of the additively-manufactured object, the apparatus comprising: an input unit configured to acquire the t