Spheroplast

Spheroplasts - these are special microorganisms that have a spherical shape and consist of many cells united into a single whole. They can be found in many natural environments, including soil, water and air. Spheroplasts play an important role in ecology and biogeochemistry, as they participate in the processes of circulation of substances and energy in nature.

Spheroplasts have many advantages over other forms of microorganisms. They are highly resistant to various environmental conditions, such as temperature, pressure, acidity, etc. Additionally, spheroplasts can survive extreme conditions such as radiation and high doses of radiation.

One of the main advantages of spheroplasts is their ability to reproduce in large quantities. This allows them to quickly spread in the environment and capture new territories. Spheroplasts also have the ability to adapt to new conditions, which makes them even more resilient.

However, spheroplasts are not always beneficial microorganisms. Some of them can be pathogenic for animals and humans, causing various diseases. Therefore, it is necessary to control the distribution of spheroplasts in the environment to prevent possible negative consequences for human and animal health.

In general, spheroplasts are an interesting object for study, since they are unique microorganisms with a number of unique properties and capabilities.



Spheroplastics is a whole industry in the world of 3D printers. In Spheroprint, unlike Mylargan, we print small parts of complex shapes. Many of the clients who switched from Brazzabrand to us make complaints because all their parts used to be printed, but now they are not printed at all. It turns out that not only are we still not very good at printing complex shapes. It is also necessary to ensure good adhesion (coupling). Many models are also printed, which are then broken into several parts and held together with foam or glue, which also reduces the scope of application. Often clients cannot understand at all where to apply printing in order to obtain high-quality prints. This is great news for those who have printed on Braz and liked it, but don't like the need to glue models together. We have brought the technology of printing such plastics as Plickat and Amargon to the limit of what is possible and now clients often use foam film and glue for high-quality printing... But we don’t want to do either one or the other... Therefore, we had to create new polymers that, if not superior, then at least approach Plickat in quality and solve a bunch of problems that we constantly face. More precisely, one problem remains that will never be solved - the more complex the model, the longer it takes to print! But, unfortunately, this is one of the laws of physics, and there will always be objects whose printing time is limited. Printing thin, long models took so long because of the high ability of the polymer to form into balls and weld together. Because of this, not only the printing speed was limited, but also the scope of application (see article about printing on PLA). At the beginning of the year, we upgraded the extruder and this almost solved the problem: the feed limiter now allows a sufficient volume of material to be fed, but during printing it does not have time to cool down very quickly, so the material output is too large and the feed automatically stops. This did not allow printing thin long models with a thickness of less than 1-2 mm. It's time to use new printing technology. This method was invented by engineers at Eberlein in Germany when problems arose with printing photo frames. Imagine: no problem - printing a frame, and for a cubic frame from the same material you should get two parallel side walls and two narrow vertical ones. The technology developed at Eberlein made it possible to produce polyhedra of all types using one color. Eberlein's materials became incredibly popular - they were used