Once the detail designing of engineering assets is completed, these assets have to be built or prefabricated, and erected or assembled, physically in their respective facilities in order to carry out the rest of the life cycle processes such as operation and maintenance. Prefabrication is initiated via shop orders created on a design object and assembly is initiated via work orders created on a design object.
For an example, a pipe system (isometric) which is a part of a Mechanical Completion package might need to manufacture some of its pipe parts (spools) while the manufacturing process requires the purchase of some of the Bill of Materials. Prefabrication in this scenario, is easily and effectively handled by a direct integration between Asset Design, Manufacturing and Purchasing. More specifically a Shop Order and Purchase Order. Likewise, early prefabricated parts (spools) need to be assembled in order to complete the isometric and can then be erected. The integration to work orders is therefore useful at this instance, in carrying out all the assembly activities while receiving the planning, scheduling and reporting support.
The picture above shows an Asset Design Piping System (ISO1), consisting of many assembly parts (SPOOL1, SPOOL2 and SPOOL 3). Each of these assembling parts have to be prefabricated by using the material demand in the BOM (PIPE and BEND). In other words, ISO 1 is assembled by Spool 1 and Spool 2 and Spool 1 is prefabricated using Pipe Part, Equal T Square and Flange. At the completion of prefabrication, the required number of spools is received to carry out the assembling and complete the isometric.
It is very important to define the required material demand of the design object, including all additional parts, purchasing, fabrication and assembly quantities.
This process involves identifying the assembling parts (spools) of a design object and registering the prefabrication demands (defined in BOM) either in manufacturing or purchasing depending on the supply options. For example, consider an isometric object of two spools (Spool-1 & Spool-2). The demands of each spool are handled and then prefabricated as a single unit via a shop order and purchase order. These prefabricated units are then readily available for assembling activities.
Most of the isometrics, spools and design objects which are imported from AIIM or any other third party design tool might not have a design part connected. So It might not be possible to create shop orders on these isometrics unless a design part is manually connected to a design object. So it is possible to create and connect a design part with a part number to the design object to be manufactured. The design part ID and part number are the same as the design object ID, by default.
Prefabricated parts (spools) might need to be assembled in order to complete an isometric design object. In such cases an assembly structure, comprising of objects with connected design parts and part numbers can be defined for an isometric design object. The design parts of the objects defined in the structure could be enabled to become the material demands of the assembly parent when work orders are created for the assembly parent.
Assembly is the next phase of an isometric object which has gone through both the design and prefabrication phases. This involves assembling a design object combining all of its assembling parts (spools) on the facility. This could either be carried out by an in-house team or by an external party. Due to the complexity and the workload it is easier to create a work order from the design object while transferring the required materials and operations. A completion management activity has to be considered as the next step of assembly.
The picture below shows an assembly structure to be made, and is followed by a list of the potential scenarios for which the assembly should be carried out and how work orders can be created in order to do so:
In
Scenario 1, three spools have been received into inventory
either as prefabricated material or as purchased material, and the isometric object
(ISO1) needs to be assembled by combining Spool 1, Spool 2 and Spool 3. In order
to do so, a work order can be created on the isometric object (ISO1) including
Spool
1,2 and 3 as the main material requirement.
In Scenario 2, the material demands are received into inventory via Receive
Inventory or Receive Purchased Order, and Spool 3 needs to be erected by
combining pipe and bend. In order to do so, a work order can be created for
spool 3 including bend and pipe
as the main material requirement.
Therefore depending on the nature of assembly, IFS/Asset Design supports the
creation of work orders for either ISO 1, Spool 3 or both ISO 1 and Spool 3, to handle the
main material requirement of
the assembly work.