Virtual prototyping a modular robotic system for mushroom controlled cultivation and integrated processing.
Nicolescu, Adrian ; Enciu, George ; Dobrescu, Tiberiu 等
1. INTRODUCTION
In a previous paper, an automatic installation with a modular
structure dedicated for continuous processing of sacks containing
sterilized compost inoculated with productive mycelium, and alimentary and therapeutic mushrooms production was developed. The installation
included several unsterile zones (ZN-A ... ZN-K) for compost
preparation, as well as several sterile zones (ZS-A ... ZS-K) for both
automatic sterilization and inoculation of the sacks containing
secondary mycelium compost and for therapeutic mushrooms cultivation,
harvest and processing. This approach has some important advantages
versus conventional technologies, including total sterile conditions for
appropriate biological material cultivation by eliminating any hazards
regarding human contamination of the workspace. This is done by
preventing human access in the sterile zones, because the sacks
handling, transport, transfer, storage, inoculation, cooling,
sterilizing, harvesting and other operations are performed by modular
robotic equipments.
The central operation of the process, the inoculation of the
compost sacks with secondary mycelium, is performed by a gantry robot
with three degrees of freedom, with a special design (Petre et al.,
2008). The section of the installation that incorporates the inoculation
robot is shown in Fig. 1.
[FIGURE 1 OMITTED]
2. SECTION DETAILED STRUCTURE AND FUNCTIONING
The sterile zone D (ZS-D) is designed for automatic transfer and
transport of the sacks from zone C (ZS-C) to zone E (ZS-E) and includes
an automatic pallet transfer system that moves the pallets from the
cooling area to the temporary storage posts, where the inoculation
process will take place.
The sterile zone E (ZS-E) is designed for the automatic inoculation
with liquid mycelium of the compost sacks. It includes temporary pallets
storage posts and a gantry robot with two degrees of freedom and a
multiple end-effector that can simultaneously inoculate the sacks on the
same support with a controlled volume of liquid mycelium. This is
accomplished by repeatedly positioning the end-effector according to
each pallet's coordinates.
The sterile zone F (ZS-F) is designed for sacks manipulation and
transfer from zone E (ZS-E) to zone G (ZS-G) and includes a pallet
transfer system which moves the sacks from the inoculation area to a
transfer gate in the sterile zone H (ZS-H) (Nicolescu et al., 2009).
3. INOCULATION ROBOT
The robot has the role to inoculate mycelium in the compost sacks.
For this purpose, it will gradually position itself above each
inoculation post, and the end-effector will perform the operation in
three sacks simultaneously. The mycelium is uniformly stored in a
low-capacity collector and transported by a pump and several injectors.
After the inoculation, the robot will retract to a home position,
allowing the recharging of the collector. The robot is specially design
for sterile environment operations (Nicolescu, 2005).
The overall layout of the gantry robot is shown in Fig 3. The robot
has three degrees of freedom, as following: X longitudinal axis, Y
transversal axis and the Z vertical axis. The driving system is entirely
composed of electrical motors, and the programming is made through
teach-in techniques (Nicolescu, 2009).
4. SECTION AND ROBOT VIRTUAL PROTOTYPING
During the second development phase, virtual prototyping for all
sections has been performed. For exemplifying specific achievements in
this work, Fig. 2a and 2b present overall structure of inoculation
section, Fig. 3a and 3b present overall structure of the included gantry
robot, and finally Fig. 4 illustrates specific design features of robot
Z vertical axis as well as inoculation effector and related
complementary equipment (Petre et al., 2009).
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
[FIGURE 4 OMITTED]
5. CONCLUSION
The modular robotic system presented in this paper, already patent
protected, is the first fully automated mushrooms cultivation and
conditioning integrated system. Achievements in performing virtual
prototyping of inoculation section from a modular robotic system for
mushroom controlled cultivation and integrated processing have been
presented. Similar tasks have been performed for all sections of the
modular robotic system. Real scale production system will be fully
operational starting at June 2011. Next phases including functioning
simulation, detailed design phases, system's sections building up
and testing, as well as overall system programming and real functioning
adjusting will be presented in further papers.
6. REFERENCES
Nicolescu, A. (2005). Industrial Robots (in Romanian), EDP Publishing House, Bucharest, Romania
Nicolescu, A. (2009). Industrial Robots Implemented into Robotic
Manufacturing Systems (work in progress in Romanian), EDP Publishing
House, Bucharest, Romania
Nicolescu, A.; Enciu, G.; Ivan, M.; Dobre, M. & Petre, M.
(2009), Conceptual model of a modular robotic system for mushroom's
controlled cultivation and integrated processing, Proceedings of The
20th International DAAAM Symposium, 25-28th November 2009
Petre M.; Nicolescu A. & Dobre M. (2008). Biotechnological
model for controlled cultivation and integrated processing of mushrooms
in a modular robotic system for obtaining ecological products in
alimentary security and safety conditions, Contact Nr. 52143, National
R&D Program PNCDI-2, Prioritary domains partnership
Petre M.; Nicolescu A. & Dobre M. (2008) An approach and an
installation for alimentary and therapeutic mushrooms cultivation,
patent request nr 00610, Official Bulletin of Industrial
Property--Inventions Section, OSIM, Bucharest
