Case design
Initial casing is meant to be made of a recyclable vegetable oil based plastic. Also, the idea of a modular design gave us even more sustainable materials to look at – pressed used clothes in resin, cans recycled pressed aluminium and even resin-ed wood saw. Also new materials come up regularly.
Here are elements we have been working with so far and slowly shaping the final design and certain materials together.
On our Github page you can look into the print files too.
Chronological pictures and phases of the development, with the newest developments on the top. Below is shown a latest construction of a casing, with all the elements fitting in. This prototype is consisting of 4 cover units and 7 lower units inclusive the hinge. All construction elements are stitched using small orange plastic pegs. It is envisaged
This was a first trial of constructing the mono case and assembling modular elements below:
Design theory against the mass production methods
The theory is that electronics are a thing of beauty, meticulously engineered, a modern wonder, so why not show it? It hides one of the most interesting things about it, the electronic circuits, the electronic elements on it, connections between them or wiring, etc. What better way than enclosing it in a translucent housing?
There are a few ways on how to do this housing. One is, also most popular one, you make a mold (done in Balthazar case) and inject hot melted plastic into it and scoop out all the necessary components of the housing and assemble it. This is how almost every company does it. The drawbacks of it are high cost of the mold, so one would need a rather large financial injection in order to make the mold, the other is updating the mold. Any changes or new ideas you want add to the housing will be met with very high costs.
It is natural to evolve the product throughout the designing process and one should have this ability. It was a no-brainer that this method is off the table, unless big volume might be required.
The second one is 3D printing. It is accessible to anyone, in-house development is a great thing, but also drawbacks with it - more from the perspective of our view on designing. While it is cheap and can be updated meanwhile design process it rather serves as a prototype only thing. However that option is offered - Balthazar as a school project doable in one middle school semester.
The surface quality, and more surface aesthetic is not an viable option in a final product, mass production with printers is another minus this method has, as it takes up a lot of time and in some cases one encounters issues while printing. Perfect room condition are needed and also a lot of printers printing at the same time. Estimate is that it is expensive in the long run because it consumes time for a small manufacturing series, let alone big series.
For a see-through computer, 3D printing method is not an option. While it does have translucent materials it is difficult to show and see anything inside.
The third option is a layering. Why not laser cut flat sheets of polycarbonate-fibre glass and stack it one on top of another? Every layer has a different internal shape depending on the components inside. It is sturdy, it is translucent or can be any other color and finish. It is fast to manufacture, computer guided laser cutting contoreus are relatively cheap and very fast. Almost no additional work is needed, only assembly of the unit and that's pretty much it.
The development scheme explains that.
Video even better.
The most important thing, is the clean, flat shape that the method generates. This method makes sure it is elegant and very modern, which is what we aim since Balthazar PCD is as of now in the last developing phase.
It fits the whole Balthazar's way of thinking, which is customization. This will also serve as »think different« mindset we all should follow and abide by now. After realizing hardware engineers made electronic circuits with that in mind, appearing very aesthetic this has to be shown and not hidden.
Also some details show cooling possibilities and easy assembly and disassembly.
Closer..
Close up on fitting layers and components.
Copper cooling plate protects the batteries and shields cabling while dispersing internal heat.
Modular internals fitting.
Hinged design
The design has made significant progress on the laptop enclosure project, with a focus on incorporating a torsion spring hinge and precision-cut metal sheet for added rigidity and structural integrity.
While the majority of the enclosure has been completed, the lower part, bottom remains to be finished. The design team is confident that the remaining components will integrate seamlessly, providing a robust and well-designed laptop housing.
A prototype has been commissioned from a plexi glass company, which has assured the design team that the finished product will look sleek and premium, eliminating any concerns about tackiness or cheap construction. The team is currently in discussions with the supplier about the production costs of the housing, ensuring that the final product will be both durable and affordable.
The design team's focus on honesty and practicality has resulted in a product that is both functional and visually stunning. The torsion spring hinge, precision-cut metal sheet, and metal clamp all contribute to a premium look and feel, while the carefully designed enclosure ensures that the laptop's upper half, housing the screen, is both rigid and balanced.