ANALYSIS OF STACK-UP TOLERANCE AND MODIFICATIONS FOR CONSTRUCTION OF CONVENTIONAL BRAIDING MACHINE CARRIER MOVEMENT SYSTEMS
The conventional braiding machine is a tool in the textile industry that is commonly used to produce prusik ropes. The term "braiding" refers to the process of intertwining multiple threads or yarns to form new patterns and shapes. Working principle of a conventional braiding machine is...
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| Format: | Theses |
| Language: | Indonesia |
| Subjects: | |
| Online Access: | https://digilib.itb.ac.id/gdl/view/80925 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The conventional braiding machine is a tool in the textile industry that is commonly used
to produce prusik ropes. The term "braiding" refers to the process of intertwining multiple
threads or yarns to form new patterns and shapes. Working principle of a conventional
braiding machine is similar to braiding, where several carriers move following a specific
pattern to create the desired product. Term "conventional" refers to the machine's design,
which utilizes plastic carriers without spring tensioners. Production efficiency of
conventional braiding machines heavily relies on the smooth movement of the carriers.
Issues with carrier movement can lead to an ineffective and inefficient production
process. This research aims to address this problem by analyzing the stack-up tolerances
in the carrier movement system of a conventional braiding machine. The analysis begins
by measuring every component of the existing braiding machine using manual measuring
tools or a Coordinate Measuring Machine (CMM). The measurement results are then
recreated as a model using SolidWorks software. This model is called the "real product
model". Next, a "ideal model" is created based on standard components. This model is
analyzed for the functionality of each feature of the components that affects carrier
movement. The appropriate type of geometric tolerance is then determined for each
feature. The model is then modified to eliminate the shortcomings of the previous model.
The modified model is called the "new model". Next step is to determine the values for
dimensional and geometric tolerances using a worst-case analysis approach. Outcomes
of this research are a stack-up tolerance analysis and the technical drawing of carrier
movement system in a conventional braiding machine. |
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