Spheres and street lamps

What starts as a really cool aluminum sphere made on one of our CNC lathes is actually the bottom of street lamp brackets all over downtown Saskatoon.

Here is a Google street view of an example of this part.  If you can see the bracket attached to the pole, the sphere is opposite the light fixture.

Here is a Google street view of an example of this part.  If you can see the bracket attached to the pole, the sphere is opposite the light fixture.

Laser Precision Beer

Some trick tap handles one of our engineers designed up for a local brewery.  We don't normally do smaller jobs like this at Lean Machine but sometimes you have to break the rules.  I think the results show that if you have access to the most advanced equipment in the world the possibilities are endless.

Normally cutting 10g thick steel with this much detail would result in a glob of molten metal left on the table but our HK laser and a great programming sequence made it happen.  The rear handle is Stainless Steel and the front handle is Mild steel.

Normally cutting 10g thick steel with this much detail would result in a glob of molten metal left on the table but our HK laser and a great programming sequence made it happen.  The rear handle is Stainless Steel and the front handle is Mild steel.

Steel High Speed Machining

This post is about a cute little steel part (yes, steel can be cute) that started as a quick brainstorming session in engineering and resulted in a cool finished product for a Saskachewan electronics manufacturer.  Even the smallest job at Lean Machine can involve all of management, engineering, administration, and of course our machining department.  There are some pretty neat circular machining marks left on the part due to a unique machining method that we will explain below.

This part looks like it could be made from steel flatbar but here at Lean Machine we almost never use pre-cut shapes.  This started as a laser cut blank off our HK Laser then we put it through our Haas VF4 mill and this is the resulting part.  By not using pre-cut shapes we can reduce our inventory (as you can imagine we would almost never have the correct shape and qty in stock) and shorten our lead times because we can custom cut whatever we need out of a large plate.

This part looks like it could be made from steel flatbar but here at Lean Machine we almost never use pre-cut shapes.  This started as a laser cut blank off our HK Laser then we put it through our Haas VF4 mill and this is the resulting part.  By not using pre-cut shapes we can reduce our inventory (as you can imagine we would almost never have the correct shape and qty in stock) and shorten our lead times because we can custom cut whatever we need out of a large plate.

Below is the difference between traditional machining vs high speed.  The idea is to take smaller (thinner) cuts at a faster rate.  We try to achieve a cut with the entire diameter and height of the cutter engaged in order to spread the chip load over the whole tool (instead of just the leading edge).  High speed machining also gets super technical by trying to match your cutting frequency with the resonant frequency of the machine but we will leave the explanation of that for another post.

Here is a pretty accurate description of the old (we'll call it traditional to be nice) machining method vs the new better, faster way. 

Here is a pretty accurate description of the old (we'll call it traditional to be nice) machining method vs the new better, faster way. 

The is a top down view of a cutting tool.  By burying the cutter deep into the material you can take thin cuts that load the tool around more of the diameter which distributes the load evenly.  Dropping the tool down into the middle of the material used to be a scary thing to do if you just tried to plow through as you would quickly overload the cutter and it would break.  Now we can even use smaller (cheaper) tools because they spin faster to eject the chip (and the heat).

The is a top down view of a cutting tool.  By burying the cutter deep into the material you can take thin cuts that load the tool around more of the diameter which distributes the load evenly.  Dropping the tool down into the middle of the material used to be a scary thing to do if you just tried to plow through as you would quickly overload the cutter and it would break.  Now we can even use smaller (cheaper) tools because they spin faster to eject the chip (and the heat).

We use both MasterCam and Inventor HSM to complete our machine programs.  This is a screen shot of what MasterCam calls "Dynamic Milling".

We use both MasterCam and Inventor HSM to complete our machine programs.  This is a screen shot of what MasterCam calls "Dynamic Milling".

Happy Anniversary to Lean Machine

Lean Machine is officially 10 years old! We have enjoyed every day of the past 10 years (six for Zach and Shaun) and we look forward to the future as there is exciting things to come.  We stand by our motto of: A Better Part for a Better Price.  There is more automation, leaner processes, added capabilities, and much more to watch for from the team at Lean Machine. 

Here is Zach and Shaun doing what they love best....Making chips!

Here is Zach and Shaun doing what they love best....Making chips!

Aggregate sawing

Aggregate sawing

An aggregate tool is a combination of a gear box and a right angle adapter.  Aggregate tools allow us to drill or cut from the side of a part instead of just from the top on a typical 3 axis machine.

Here is an an example of an aggregate tool.  The top of the tool attaches to the spindle and turns at a speed of 10,000 rpm.  Different drills or cutting tools can be attached to the collets at either end.

Here is an an example of an aggregate tool.  The top of the tool attaches to the spindle and turns at a speed of 10,000 rpm.  Different drills or cutting tools can be attached to the collets at either end.

This is a saw blade attached to the aggregate head mounted to the spindle of the machine.  The machine is about to cut a part for a customer made from aluminum extrusion.  The extrusion is mounted in a custom fixture on our C-axis router.

This is a saw blade attached to the aggregate head mounted to the spindle of the machine.  The machine is about to cut a part for a customer made from aluminum extrusion.  The extrusion is mounted in a custom fixture on our C-axis router.

Here is the finished angle cut on the end of the extrusion.  Conventional tools would have to be very long to make a cut like this from the top plane and would not have the great finish and accuracy that the aggregate saw tool has. 

Here is the finished angle cut on the end of the extrusion.  Conventional tools would have to be very long to make a cut like this from the top plane and would not have the great finish and accuracy that the aggregate saw tool has. 

CNC wood cutting

CNC wood cutting

Although lean machine regularly cuts metal, we are also more than capable of cutting wood, plastics, and composites!

 

3/4" MDF being cut on one of our CNC routers for a local kitchen cabinet making shop. 

3/4" MDF being cut on one of our CNC routers for a local kitchen cabinet making shop. 

Stacks of consistent and accurate parts on a pallet ready to ship.  Notice each one has a label with the part number, thickness, and dimensions.

Stacks of consistent and accurate parts on a pallet ready to ship.  Notice each one has a label with the part number, thickness, and dimensions.

Assemblies

Assemblies

A huge part of Lean Machine's business is assembling parts.  We offer a complete solution to our customers because we can design, cut, machine, bend, weld, and assemble parts.  This article is an example of an assembly that we laser cut out of galvanized sheet, bend on a CNC brake, and assemble.  To get consistent parts, we also designed and built a jig. The jig was laser cut, welded, machined, and assembled all in our shop.

Here is the jig sitting on an assembly table.  Notice the part numbers of each sub-component are laser cut into the jig.

Here is the jig sitting on an assembly table.  Notice the part numbers of each sub-component are laser cut into the jig.

The galvanized steel sub-components are placed on the jig and bolted together.

The galvanized steel sub-components are placed on the jig and bolted together.

The stacking method is planned out ahead of time to make sure counting and sorting of completed parts is easy. 

The stacking method is planned out ahead of time to make sure counting and sorting of completed parts is easy.