Design and development of artificial pollinizer for pollinating tropical vegetables under protected cultivation
By: Ramya R.
Contributor(s): Sureshkumar, P K (Guide).
Material type:
BookPublisher: Tavanur Department of Farm Machinery and Power Engineering, Kelappaji College of Agricultural Engineering and Technology 2018Description: v, 97p.Subject(s): Farm and Power EngineeringDDC classification: 631.3 Online resources: Click here to access online Dissertation note: MTech Abstract: Artificial pollination is a process that is highly require in vegetable crops
grown under protected cultivation since, protected environment offers barriers to
natural agents for pollination such as insects, wind or water.
A study was undertaken to design and develop an artificial pollinizer for
pollinating tropical vegetable crops under protected cultivation.
To obtain
preliminary data required for the design, floral and physical characteristics of flower,
anther and pollen of selected tropical vegetable crops were studied in laboratory
conditions. Accordingly a conceptual design was evolved and two models of artificial
pollinizers were developed. Suitability of the developed pollinizer was evaluated in
laboratory as well as field conditions. Results of the evaluation have been presented
and analyzed.
Six tropical vegetable crops were selected for the preliminary studies like
floral characteristics, physical and dimensional measurements of flowers, anther and
pollen grains were conducted in the laboratory. Sizes of pollen grains were measured
by using Olympus Bx43 light microscope and the measurements were taken using the
software Ultrascope version 9.1. Shape was determined from standard shape charts
suggested by UPOV, 2007. The shape of pollen grains of tomato, pumpkin and ash
guard are found to be „circular‟ with a Length/Width ratio ranging from 1: 1 to 1: 1.1.
Pollen grain of chilli is „broad deltate‟ with L/W ratio of 1: 1.2. Pollen grains of water
melon and cucumber are „narrow oblate‟ with a L/W ratio of 1: 1.13 to 1:1.15.
Based on the preliminary studies, functional requirements and conceptual
designs two models of the artificial pollinizers were designed and developed.
Artificial pollinizer Model – I uses air as the medium for collection of pollen
from flowers. Suction pressure developed by a vacuum pump suck the pollen grains
from the male flower to a pollen collection chamber. The pollen collection unit is
provided with a brush tip which detach the pollen grains from the flower and sucked
by a vacuum pump are deposited in a pollen collection chamber. A screen mesh filter
of 15 μm aperture is used in the chamber to prevent the pollen grains from carry
away. Components of artificial pollinizer model – I includes pollen collection unit,
pollen collection tube, adaptor for pollen collection chamber, pollen collection
chamber, air tube, air tube adaptor, a connector and a vacuum pump. An electric
powered air blower of 220 V, 50 Hz and 0.55kW is used as vacuum pump. The
blower produces a suction velocity of 20-22 ms-1 at 13,000 rpm.
Artificial pollinizer Model – II uses water as the medium for collection of
pollen from male flowers. Water is sprayed from a nozzle to the male flower kept
carefully in a pollen collection chamber. Water spray produced by a pneumatic hand
pump from the nozzle wash out the pollen grains from the flower and is collected in
the water tight container. Components of artificial pollinizer Model – II includes a
spray nozzle, pneumatic hand sprayer, water container and pollen collecting chamber.
Collected pollen can be sucked by a syringe for spraying to the female flower
for artificial pollination. Dry pollen collected by Model – I is also mixed with water
and used for artificial pollination using a syringe.
Evaluation of artificial pollinizer was done by accessing pollen viability and
fruit set efficiency. Viability of pollen was observed under laboratory condition and
fruit set efficiency was observed under field conditions.
From the studies it is observed that, pollen viability is decreasing with
increase in storage period for both the crops. Maximum pollen viability is observed
when artificial pollination was done with fresh pollen grains. Also, the viability is
found higher for pollen stored in 1 % sucrose solution than pollens stored in plain
water in both crops.
Study on fruit set efficiency is also seems to be decreasing with increase in
storage period for both the crops. Maximum fruit set efficiency is observed when
artificial pollination was done with fresh pollen grains. Fruit set efficiency is higher
for pollen stored in 1 % sucrose solution than pollens stored in plain water in both
crops. Also the fruit set efficiency values are on par with manual pollination. Stages
of fruit development in cucumber and watermelon crops are also observed on the 3 rd,
7th and 15th days after artificial pollination and found that the artificial pollination
done using the artificial pollinizer was successful.
| Item type | Current location | Collection | Call number | Status | Date due | Barcode |
|---|---|---|---|---|---|---|
Theses
|
KAU Central Library, Thrissur Theses | Reference Book | 631.3 RAM/DE (Browse shelf) | Not For Loan | 174474 |
MTech
Artificial pollination is a process that is highly require in vegetable crops
grown under protected cultivation since, protected environment offers barriers to
natural agents for pollination such as insects, wind or water.
A study was undertaken to design and develop an artificial pollinizer for
pollinating tropical vegetable crops under protected cultivation.
To obtain
preliminary data required for the design, floral and physical characteristics of flower,
anther and pollen of selected tropical vegetable crops were studied in laboratory
conditions. Accordingly a conceptual design was evolved and two models of artificial
pollinizers were developed. Suitability of the developed pollinizer was evaluated in
laboratory as well as field conditions. Results of the evaluation have been presented
and analyzed.
Six tropical vegetable crops were selected for the preliminary studies like
floral characteristics, physical and dimensional measurements of flowers, anther and
pollen grains were conducted in the laboratory. Sizes of pollen grains were measured
by using Olympus Bx43 light microscope and the measurements were taken using the
software Ultrascope version 9.1. Shape was determined from standard shape charts
suggested by UPOV, 2007. The shape of pollen grains of tomato, pumpkin and ash
guard are found to be „circular‟ with a Length/Width ratio ranging from 1: 1 to 1: 1.1.
Pollen grain of chilli is „broad deltate‟ with L/W ratio of 1: 1.2. Pollen grains of water
melon and cucumber are „narrow oblate‟ with a L/W ratio of 1: 1.13 to 1:1.15.
Based on the preliminary studies, functional requirements and conceptual
designs two models of the artificial pollinizers were designed and developed.
Artificial pollinizer Model – I uses air as the medium for collection of pollen
from flowers. Suction pressure developed by a vacuum pump suck the pollen grains
from the male flower to a pollen collection chamber. The pollen collection unit is
provided with a brush tip which detach the pollen grains from the flower and sucked
by a vacuum pump are deposited in a pollen collection chamber. A screen mesh filter
of 15 μm aperture is used in the chamber to prevent the pollen grains from carry
away. Components of artificial pollinizer model – I includes pollen collection unit,
pollen collection tube, adaptor for pollen collection chamber, pollen collection
chamber, air tube, air tube adaptor, a connector and a vacuum pump. An electric
powered air blower of 220 V, 50 Hz and 0.55kW is used as vacuum pump. The
blower produces a suction velocity of 20-22 ms-1 at 13,000 rpm.
Artificial pollinizer Model – II uses water as the medium for collection of
pollen from male flowers. Water is sprayed from a nozzle to the male flower kept
carefully in a pollen collection chamber. Water spray produced by a pneumatic hand
pump from the nozzle wash out the pollen grains from the flower and is collected in
the water tight container. Components of artificial pollinizer Model – II includes a
spray nozzle, pneumatic hand sprayer, water container and pollen collecting chamber.
Collected pollen can be sucked by a syringe for spraying to the female flower
for artificial pollination. Dry pollen collected by Model – I is also mixed with water
and used for artificial pollination using a syringe.
Evaluation of artificial pollinizer was done by accessing pollen viability and
fruit set efficiency. Viability of pollen was observed under laboratory condition and
fruit set efficiency was observed under field conditions.
From the studies it is observed that, pollen viability is decreasing with
increase in storage period for both the crops. Maximum pollen viability is observed
when artificial pollination was done with fresh pollen grains. Also, the viability is
found higher for pollen stored in 1 % sucrose solution than pollens stored in plain
water in both crops.
Study on fruit set efficiency is also seems to be decreasing with increase in
storage period for both the crops. Maximum fruit set efficiency is observed when
artificial pollination was done with fresh pollen grains. Fruit set efficiency is higher
for pollen stored in 1 % sucrose solution than pollens stored in plain water in both
crops. Also the fruit set efficiency values are on par with manual pollination. Stages
of fruit development in cucumber and watermelon crops are also observed on the 3 rd,
7th and 15th days after artificial pollination and found that the artificial pollination
done using the artificial pollinizer was successful.
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