Final SPH -JHS Coverpage 16-2 Jan 2021 single




C O N T E N T S

JOURNAL OF HORTICULTURAL SCIENCES

Volume 16 Issue 2 June 2021

In this Issue i-ii

Review
Phytoremediation of indoor air pollutants: Harnessing the potential of 131-143
plants beyond aesthetics
Shalini Jhanji and U.K.Dhatt

Research Articles
Response of fruit yield and quality to foliar application of micro-nutrients in 144-151
lemon [Citrus limon (L.) Burm.] cv. Assam lemon
Sheikh K.H.A., Singh B., Haokip S.W., Shankar K., Debbarma R.
Studies on high density planting and nutrient requirement of banana in 152-163
different states of India
Debnath Sanjit Bauri F.K., Swain S., Patel A.N., Patel A.R., Shaikh N.B.,
Bhalerao V.P., Baruah K., Manju P.R., Suma A., Menon R., Gutam S. and P. Patil
Mineral nutrient composition in leaf and root tissues of fifteen polyembryonic 164-176
mango genotypes grown under varying levels of salinity
Nimbolkar P.K., Kurian R.M., Varalakshmi L.R., Upreti K.K., Laxman R.H. and
D. Kalaivanan
Optimization of GA3 concentration for improved bunch and berry quality in 177-184
grape cv. Crimson Seedless (Vitis vinifera L)
Satisha J., Kumar Sampath P. and Upreti K.K.
RGAP molecular marker for resistance against yellow mosaic disease in 185-192
ridge gourd [Luffa acutangula (L.) Roxb.]
Kaur M., Varalakshmi B., Kumar M., Lakshmana Reddy D.C.,
Mahesha B. and Pitchaimuthu M.
Genetic divergence study in bitter gourd (Momordica charantia L.) 193-198
Nithinkumar K.R., Kumar J.S.A., Varalakshmi B, Mushrif S.K.,
Ramachandra R.K. , Prashanth S.J.
Combining ability studies to develop superior hybrids in bell pepper 199-205
(Capsicum annuum var. grossum L.)
Varsha V., Smaranika Mishra, Lingaiah H.B., Venugopalan R., Rao K.V.
Kattegoudar J. and Madhavi Reddy K.
SSR marker development in Abelmoschus esculentus (L.) Moench 206-214
using transcriptome sequencing and genetic diversity studies
Gayathri M., Pitchaimuthu M. and K.V. Ravishankar



Generation mean analysis of important yield traits in Bitter gourd 215-221
(Momordica charantia)
Swamini Bhoi, Varalakshmi B., Rao E.S., Pitchaimuthu M. and Hima Bindu K.

Influence of phenophase based irrigation and fertigation schedule on vegetative 222-233
performance of chrysanthemum (Dendranthema grandiflora Tzelev.) var. Marigold
Vijayakumar S., Sujatha A. Nair, Nair A.K., Laxman R.H. and Kalaivanan D.

Performance evaluation of double type tuberose IIHR-4 (IC-0633777) for 234-240
flower yield, quality and biotic stress response
Bharathi T.U., Meenakshi Srinivas, Umamaheswari R. and Sonavane, P.

Anti-fungal activity of Trichoderma atroviride against Fusarium oxysporum f. sp. 241-250
Lycopersici causing wilt disease of tomato
Yogalakshmi S., Thiruvudainambi S., Kalpana K., Thamizh Vendan R. and Oviya R.

Seed transmission of bean common mosaic virus-blackeye cowpea mosaic strain 251-260
(BCMV-BlCM) threaten cowpea seed health in the Ashanti and
Brong-Ahafo regions of Ghana
Adams F.K., Kumar P.L., Kwoseh C., Ogunsanya P., Akromah R. and Tetteh R.

Effect of container size and types on the root phenotypic characters of Capsicum 261-270
Raviteja M.S.V., Laxman R.H., Rashmi K., Kannan S., Namratha M.R. and
Madhavi Reddy K.

Physio-morphological and mechanical properties of chillies for 271-279
mechanical harvesting
Yella Swami C., Senthil Kumaran G., Naik R.K., Reddy B.S. and Rathina Kumari A.C.

Assessment of soil and water quality status of rose growing areas of 280-286
Rajasthan and Uttar Pradesh in India
Varalakshmi LR., Tejaswini P., Rajendiran S. and K.K. Upreti

Qualitative and organoleptic evaluation of immature cashew kernels under storage 287-291
Sharon Jacob and Sobhana A.

Physical quality of coffee bean (Coffea arabica L.) as affected by harvesting and 292-300
drying methods
Chala T., Lamessa K. and Jalata Z

Vegetative vigour, yield and field tolerance to leaf rust in four F1 hybrids of 301-308
coffee (Coffea arabica L.) in India
Divya K. Das, Shivanna M.B. and Prakash N.S.

Limonene extraction from the zest of Citrus sinensis, Citrus limon, Vitis vinifera 309-314
and evaluation of its antimicrobial activity
Wani A.K., Singh R., Mir T.G. and Akhtar N.

Event Report 315-318
National Horticultural Fair 2021 - A Success Story
Dhananjaya M.V., Upreti K.K. and Dinesh M.R.

Subject index 319-321

Author index 322-323



271

J. Hortl. Sci.
Vol. 16(2) : 271-279, 2021

This is an open access article d istributed under the terms of Creative Commons Attribution-NonCommer cial-ShareAl ike 4.0 International License,
which permits unrestricted non-commercial use, d istribution, and reproduction in any med ium, provide d the original author and source are credited.

Original Research Paper

Physio-morphological and mechanical properties of
chillies for mechanical harvesting

Yella Swami C.*1, Senthil Kumaran G. 1, Naik R.K.2, Reddy B.S.3 and
Rathina Kumari A.C.1

1Division of Post Harvesting Technology and Agricultural Engineering
ICAR-Indian Institute of Horticultural Research (IIHR), Bangalore

2Department of Farm Machinery and Power Engineering, SVCAET&RS, IGKV, Raipur
3ICAR-Central Research Institute for Dryland Agriculture, Hyderabad

*Corresponding author Email : yellaswami@gmail.com

ABSTRACT
The plants and its produce characteristics are the basis to design a crop specific harvester. The
objective of this study was to determine the physical, morphological and mechanical properties
of chilli plant and fruits, that can be used in the design of harvester machine. The observations
and data were collected by taking measurements at harvesting stage of three chilli cultivars.
The fruit bearing behavior of plants was solitary with fruit position erect in Demon F1 and
pendent in Arka Meghana and Mahyco Tejaswini. The plant height ranged between 81.76 to
84.87 cm depending on cultivars number of fruits per plant were 170.25, 158.96 and 156.15 in
Tehaswini, Arka Meghana and Menon respectively. It was observed that the length and diameter
at shoulder of fruits was in the range of 4.97 to 10.44 cm and 0.8 to 1.25 cm, respectively. The
moisture content reduced in leaves, stems and fruits as the maturation changed from matured
green fruits bearing of plants to semi dry condition. The detachment force of fruits from plants
increased as the fruits colour changed from matured green to fully ripened red and there
after decreased.
Keywords: Chillies, erect, detachment force, mechanical harvester and pendent

Chilli is a seasonal vegetable that is part of the spicy
food culture in India. Chilli (Capsicum annuum L.)
belongs to the Solanaceae family (Farhan et al., 2014).
It is well known for its edible, colourful, juicy and
crispy flesh, as well as for its nutritious contents. Red
chilli is an important commercial crop used as a
condiment, culinary supplement or as a vegetable,
physiological matured greens, ripened red color and
red dried fruits. In India, among the spices consumed,
dried chilies contribute a major share and grown in
different agro-ecological zones and is the largest
producer  in the wor ld.  During 2019-20, India
produced approximately 17.52 lakh tonnes of chillies
from an area of 7.03 lakh ha and the productivity was
2.49 tonnes ha-1 as per the report of Spice Board of
India.

Chilli harvesting is not mechanized in the country and
it depends entir ely on the ma nua l wor k for ce

prolonging the extended period of field operation. The
chilli fruit harvesting period occurs during the hot
summer season, and the labour costs are very high,
because the population residing in rural areas is
decreasing and it is difficult to supply sufficient
workforce to harvest in a timely manner. Therefore,
mechaniza tion of chilli ha rvesting is an urgent
requirement to reduce the cost due to labour employed
partly, faster operations at reduced drudgery and other
production difficulties (Nam et al., 2018).

To reduce mechanical damage due to harvest and post-
ha r vest oper a tions r equir es studies on the
morphological, physical and mechanical properties of
plants as well as fruits to design a harvesting machine.
To optimize ma chines design a nd development
par a meter s for oper ations such a s ha rvesting,
handling, cleaning and conveying, the morphological,
physica l a nd mecha nica l a ttr ibutes a nd their

INTRODUCTION



272

Yella Swami et al

J. Hortl. Sci.
Vol. 16(2) : 271-279, 2021

relationships play a major role (Rokayya and Khojah,
2016). Physical characteristics of agricultural crops,
products are the most important para meters to
determine the proper standards of grader design,
conveying,  pr ocessing a nd pa cka ging systems
(Tabatabaeefar and Rajabour, 2005). Several studies
were conducted on pepper varieties in different
countries, like Turkey (Ozgur et al., 2011; Kadri and
Murat, 2010), Nigeria (Ilori et al., 2010), Thailand
(Toontom et al., 2012), Germany (Romano et al.,
2012), Spain (Vega-Galvez et al., 2008), India (Nidhi
et al., 2016) and Malaysia (Noryati and Revathi,
2006). Previous studies on chilli varieties and cultivars
revealed that great variations existed in plant growth,
other qualitative attributes and yield under different
agro-climatic zones. In country like India, a large
diversity in chilli with different quality factors and
other traits is expected due to different agro ecological
zones. Any developments in chilli harvesters should
consider domestic cultivars and cropping systems
because these are entirely different from exotic chilli
varieties. Hence, more studies are required to collect
data and standardize the design parameters pertinent
to harvesting and post-harvest operational machines.
So,  the a im of the present work was to study
morphological, physical attributes and mechanical
properties of chilli plants and fruits of three most
popular cultivars (hybrids) grown in southern states
at different stages pertinent to harvesting, cleaning and
grading machines.

MATERIALS AND METHODS
The chilli cultivars selected for the present study were
Arka Meghana, Mycho Tejaswini and Demon F1 and
cultivated as per the recommended agronomical
practices at ICAR- Indian Institute of Horticultural
Research, Bangalore. The observations and pertinent
data collection study were carried out between 125 to
150 days after transplanting, at which the crop reached
to full growth, maximum fruiting and harvestable
ripped red fruits were present in considerable number.
In the identified crop rows, 50 randomly selected
plants from each cultivar were tagged and from each
plant 100 fruits were plucked covering all directions
and from fruit bearing lower to top branches. The
instruments used in this study to measure linear
dimensions were steel rule, digital caliper with an
accuracy of 0.01 mm and fruits weight using a digital
electronic balance with an accuracy of 0.01 g.

Plant growth and morphological attributes

T he pla nt gr owth ha bits a nd fr uit bea r ing
characteristics qualitative information was collected
from reliable secondary sources of literature and
characterization descriptors of IPGRI (1995). The
plant growth attributes were measured when 100 per
cent of the plants had at least certain proportion of
fully ripped fruits. These attributes include plant height
(cm), plant canopy spread across (cm) and along the
row (cm), stem diameter (cm), stem length (cm), height
of the lower most (cm) and upper most chilli fruit (cm)
from ground. Plant height was measured from the
ground surface to the uppermost tip of the plant using
the steel rule. Plant stem girth measured at ground
level and stem length was measured from the soil
surface to the first internode of primary branch. The
total number of fruits per plant was calculated by
noting down harvested fruits at every picking from
selected 50 plants. The moisture contents of three
major portions of plants namely leaves, stems and
fruits at different stages of fruits ripeness was collected
randomly and estimated as per the standard laboratory
drying procedure.

Geometrical and physical properties of fruits

The geometrical and physical properties of fruits
measured were length, diameter just below the calyx
part where fruit is maximum in diameter and weight
of 1000 fruits.

Fig. 1. Measurement standard for
chilli plant and fruits



273

Physio-morphological and mechanical properties of chillies for mechanical harvesting

Moisture content of plant parts

As  t he f r u i t s  a nd veget a b les  c h a nges  f r om
physiological maturity to full ripeness, the moisture
content of various plant parts like leaves, stems and
branches may change in addition to changes in
textural property. This property plays a major role
in harvesting, especially fruits moisture content has
profound effect beyond harvesting operation. The
moisture contents were measured using oven dry
method at different ripeness stages of fruits by
collecting sa mples fr om differ ent p la nt p a r ts
randomly. The moisture content was determined by
using standard procedure of AOAC (1970).

Detachment force/ pulling force of chilli fruit

The force of detachment or pulling force of fruit
to separate from the chilli plants was measured
using digita l for ce gauge (Fig.  2), which ca n
measure maximum 50 Newton (N). The digital
force gauge used for the experiment was Model No.
SF-50, maximum load 50N and the least count of
the instrument was 0.01N. The push and pull type
digital force gauge was held with one hand one side

hook and the other side hook was connected to the
chilli fruit pedicle and the applied maximum force
was noted from the display on the screen. For each
cultivar detachment force of fruits was measured
at four sta ges (i. e.) green, semi red,  red/ fully
ripped, partly dry and full dry condition (Fig.3).

The statistical analysis was carried out for the each
obser ved cha racter under the study using MS-
Excel. The mean values of data were subjected to
analysis of variance as described by (Gomez and
Gomez, 1984).

Fig. 2. Images showing fruit detachment force
with digital force gauge

Green Semi-red Red Semi-dry Dry

Fig. 3. Image shows different stages of Arka Meghana cultivar

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274

RESULTS AND DISCUSSION

Plant growth characteristics

The three cultivars selected for the study were dual
purpose (i.e.) useful as green vegetable and as well
as dried red chilli. The Arka Meghana had branches
spr ea ding gr owth type a nd r est  of two semi-
spreading in nature either sparse or intermediate
dense (Table 1). The stem shape was found to be
round for all three. The fruits shape was determined
based on comparison with the shapes proposed in
the list of descriptors of the IPGRI (1995), the Arka
Meghana and Mahyco Tejaswini possess elongate
shaped fruits and Demon F1 erect narrow fruits.
Based on fruit position the cultivars fall in two
groups viz., Demon F1 erect position fruits and
remaining two in pendent position. As per the fruit

bearing characteristic all the three falls in solitary
behaviour.

The plant gr owth, br anching pa tter n,  physica l
structure of fruits and other biological features have
a  s ignif ic a nt  imp a c t  on ma c hine ha r ves t ing
efficiency. Low plant structure and small branch
angles make positive impact on machine harvesting
efficiency. High canopy density vegetable crops
need vigor ou s  s ha king of  t he b r a nc hes  b y
harvesting devices, which causes the high quantity
of foreign material like tender branches, twigs in
the harvested produce. This cause makes the quality
produce separation process more energy intensive,
because of necessary additional strength required
for the mechanism to separate and transmit the
unwanted material out of the harvesting machine.

Table 1. Plant growth characteristics of selected three cultivars of chilli

Characteristics Arka Meghana Tejaswini Demon F1
Utility - Green / Dual purpose Dual purpose Dual purpose
Dried red / Dual purpose

Plant growth habit Medium height and Medium height and Medium height and
spreading Semi spreading Semi spreading

Branching habit Dense Sparse Intermediate

Stem Shape Round Round Round

Fruit shape Elongate Elongated Erect narrow

Fruit position Pendent Pendent Erect

Fruit bearing Solitary Solitary Solitary

Fig. 4. Fruit shape and fruit position of different cultivars of chilli

Yella Swami et al

J. Hortl. Sci.
Vol. 16(2) : 271-279, 2021

Arka Meghana Tejaswini Demon F1



275

Chilli cultivars morphological attributes

The distance from the ground level to the upper
most tip of the plant is measured as the height of
the plant. The average height of the plants was
found as 82.20 cm, 84.87 cm and 81.76 cm for
Arka Meghana, Mahyco Tejaswini and Demon F1,
respectively       (Table 2). The height of the plants
varied from 64 to 115 cm and maximum height 115
cm observed in Demon F1 and minimum of 64 cm
in Arka Meghana.

Plant canopy width across and along the rows

The minimum and maximum distances between the
tips of the lengthiest branches spread in the tagged
plant samples across the row (canopy width in
East- West direction) ranged from 59 to 98 cm and
along the row (ca nopy width in North - South
direction) from 56 to 93 cm in Mahyco Tejaswini.
Generally, in crops sown in rows, the harvesting
machine being operated along the rows, so the

spread width of canopy across the row plays a
critical role in deciding the harvester head size to
cover  entir e ca nopy f or  ma ximum ha r vesting
efficiency.

Plant stem length, stem diameter and number of
fruits per plant

The stem lengths of the chilli cultivars varied from
2 cm to 13 cm and the mean value of stem lengths
recorded varied from 5.44 to 8.99 cm. The higher
mean stem length to first bifurcation was recorded
in D emon F 1 .T he st em dia meter  of  t he chilli
cultivars varied from 1.82 to 2.16 cm. The plant
stem diameter is higher 2.16 cm in Arka Meghana
and lower in 1.82 cm in Demon F1. The minimum
and maximum number of fruits per plant ranged
from 61-343 number for  Demon F 1with lowest
mean value of 156.15 number of fruits per plant.
Among the three cultivars, a maximum mean value
170.25 fruit per plant was recorded for the Mahyco
Tejaswini.

Table 2. Morphological characteristics of different chilli cultivars

Characteristics Plant Across Along Plant Stem Number Height of Height of
height row row stem dia of fruits the lower the upper
(cm) EW NS length meter per most fruit most fruit

(cm) (cm) (cm) (cm) plant (cm) (cm)

Arka Meghana
Mean 82.20 79.55 76.18 6.35 2.16 158.96 21.46 84.71

Minimum 64.00 63.00 59.00 3.00 1.60 76.00 10.00 62.00
Maximum 108.00 97.00 93.00 13.00 2.72 243.00 31.00 100.00

Standard deviation 9.28 7.46 7.90 1.90 0.63 39.91 4.24 10.43

Standard error 0.92 0.74 0.79 0.19 0.06 3.97 0.80 1.97

Mahyco Tejaswini
Mean 84.87 75.16 72.17 5.44 1.90 170.25 20.83 67.66

Minimum 69.00 59.00 56.00 2.00 1.06 73.00 12.00 65.00

Maximum 108.00 98.00 93.00 11.00 2.52 234.00 32.00 98.00

Standard deviation 14.98 11.35 1.99 1.99 0.34 36.47 4.71 18.14
Standard error 1.50 1.14 1.10 0.23 0.04 4.27 0.87 3.37

Demon F1
Mean 81.76 73.40 63.89 8.90 1.82 156.15 28.11 98.56

Minimum 65.00 60.00 57.00 4.00 1.44 61.00 17.00 90.00
Maximum 115.00 92.00 88.00 13.00 2.68 343.00 36.00 112.00

Standard deviation 9.52 9.47 9.67 1.85 0.31 50.28 6.29 7.02

Standard error 0.94 0.93 0.95 0.18 0.03 4.93 2.10 2.34

Physio-morphological and mechanical properties of chillies for mechanical harvesting

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276

Height of the lower most and higher most fruits
bearing branches

Though there is not much considerable variation in the
mean plant heights among the three cultivars, but
considerable variation was observed in fruits bearing
canopy zone lengths. The fruits bearing canopy spread
height was maximum (70.45cm) for Demon F1 and the
least 46.83cm for Mahyco Tejaswini. The average
height of the lowermost chilli fruits bearing was
observed 20.83 cm in Mahyco Tejaswini and highest
value 28.11 cm in Demon F1.

Fruits geometrical and physical properties

The size and shape of fruits play major role in
separation of unwanted biomass and also immature
harvested ones from the quality produce and otherwise
more prone to storage disease in crop like chillies. The
fruit shape description of chilli grown for dual purpose
use in India is difficult, however in general it is
triangular in shape with obtuse truncated shape pedicel
attachment portion and blunt sunken at blossom end
portion. Maturation is indicative of the fruit being
ready for harvest and after full maturation, there will
not be much change in fruit size and shape, since the
edible part of the fruit or vegetable is fully developed.
Dependence on colour parameter alone to harvest the
matured vegetables at green colour stage may mislead
in certain vegetables. Rather than decision taken based
on fruit size, shape and colour may yield best results.
Apart from that, fruits and vegetables geometrical
parameters like length, width, thickness or diameter
will give us an idea to design and develop sieve set to
separate the discard able biomass from produce and
graded marketable produce based on size.

In chilli the total fruit length and diameter at shoulder
are two geometrical dimensions, based on which the
separation and grading of produce equipment could be
planned. The fruit length measured without pedicle for
the selected chilli crops ranged from 2.60 to 14.70 cm
and for the same the mean length values varied 4.97
to 10.44 cm. The maximum mean fruit length was
observed in Arka Meghana (10.44 cm) and minimum
value 4.97 cm in Demon F1.
Fruit diameter and 1000 fruits weight
In cer tain fruits the sha pe ca n cha nge during
maturation and can be used as a characteristic to
determine harvest maturity. As the fruit or vegetable
matures on the plant the relationship between the
shoulders of the fruit and the point at which the stalk
is attached may change. The shoulders of immature
ones slope away from the fruit stalk and on full
maturity the shoulders become level with the point of
attachment, and in certain cases the shoulders may be
raised above this point also.
As per the forgone discussion, in chilli the size of fruits
is maximum at shoulder s, so the diameter  was
measured at this point. For the selected chillies, overall
fruit diameter varied from 0.51 to 1.58 cm and the
mean values were ranged from 0.80 to 1.25 cm (Table
3). The maximum values in all respects were observed
in Arka Meghana and minimum in Demon F1.
The weight of 1000 ripened chilli fruits widely ranged
from minimum 1.24 kg to maximum 9.21 kg. The
mean weight of 1000 ripped fruits was 1.96 to 6.97
kg. The maximum 1000 chilli fruits weight was
recorded in Arka Meghana 6.97 kg and minimum
value in case of Demon F1 (1.96 kg).

Table 3.  Ripened chilli fruits geometrical and physical properties

Cultivars        Arka Meghana     Mahyco Tejaswini           Demon F1
Properties Fruit Fruit 1000 Fruit Fruit 1000 Fruit Fruit 1000

length dia fruits length dia fruits length dia fruits
(cm) meter weight (cm) meter weight (cm) meter weight

(cm) (kg) (cm) (kg) (cm) (kg)
Mean 10.44 1.25 6.97 7.74 0.92 3.81 4.97 0.80 1.96

Minimum 6.20 0.81 4.13 4.30 0.69 2.40 2.60 0.51 1.24

Maximum 14.70 1.58 9.21 9.80 1.18 5.43 10.50 1.05 2.98
Standard 2.00 0.16 1.02 1.30 0.09 0.64 1.06 0.11 0.30
deviation

Standard 0.20 0.02 0.10 0.13 0.01 0.08 0.10 0.01 0.03
error

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277

Moisture content

The moisture contents data of different plant parts at
different ripeness stages was presented in Table 4. At
full matured green stage of fruits, the moisture content
of the leaves was about 72% (db) and fruits possessed
considerably higher amount of moisture about 80%.As
the fruits maturation changes from physiological
mature green colour to full red and beyond, all the
plant parts namely leave, stems and fruits moisture
contents decreased. When compared to other parts, the
per cent of moisture loss was more rapid in leaves
followed by stems and minimum gradual reduction
was observed in fruits. The moisture content trend is
more or less same in all the three cultivars.

Moisture content is an influential factor in all the crop
processing operations and greatly influences other
physical and mechanical properties (Ilori et al., 2010).
In harvesting stage of crops, excessive loss of moisture
may lead to the structural parts of the plant to become
softer. The softer plant parts cling to the rotating or
oscillating or jolting components which shake or
vibrate or comb or push the plant branches reducing
its effectiveness thus reducing harvesting efficiency of
the fruits and vegetables. In certain species, reduced
moisture contents in plant parts result in excessive
detachment of leaves, twigs in considerable quantity
thus increasing energy expenditure in cleaning and
grading unit of harvesting machine.

Table 4. Moisture content of plant parts at different maturity stages of different cultivars

Plant part Green Semi-red Red Semi-Dry Dry
Arka Meghana

Leaf 71.33±2.08 54.04±0.47 40.78±0.64 33.63±0.64 20.53±0.87

Stem 68.90±0.87 66.54±0.76 49.15±0.31 46.15±0.75 39.71±1.27
Fruit 81.29±2.85 84.35±0.81 77.86±0.31 79.77±0.78 72.70±0.82

Mahyco Tejaswini
Leaf 72.17±2.13 62.96±2.63 48.66±1.16 33.33±1.53 18.23±1.09

Stem 63.69±2.29 54.45±1.27 53.83±2.40 53.16±1.04 38.05±2.10
Fruit 77.86±0.31 76.72±0.46 74.85±0.17 74.76±1.57 72.17±1.02

Demon F1
Leaf 71.78±1.65 54.16±2.13 45.59±0.94 33.30±1.20 18.21±1.20

Stem 60.85±1.57 58.83±1.22 52.87±1.57 44.12±0.58 37.12±1.50
Fruit 77.58±0.59 76.96±0.93 74.79±1.40 72.49±0.69 71.04±1.72

Detachment force of chilli fruits at different
stages of ripeness

The principles dictating at what stage of maturity the
fruits or vegetable should be harvested are crucial to
its subsequent drying /storage and marketable life and
quality. Post-harvest physiologists distinguish different
impor ta nt sta ges in the life spa n of fruits a nd
vegetables namely maturation (green), semi – ripeness,
ripened, semi dried, dried and crop senescence (ageing)
itself. All these stages have its own importance
depending on how and where the produce being used
a nd str a tegies being followed in collection,
transportation, storing and marketing. Ripening
follows or overlaps maturation, rendering the produce
edible, as indicated by colour and taste in majority of

fruits and vegetables. In certain crops plant senescence
(ageing) also considered as indicative of crop harvest.
Senescence is the last stage, characterized by natural
degradation of the plants, as in loss of texture, colour,
etc. In case of certain fruits and vegetables colour and
moisture content are two majorly determining factors
to harvest the produce that are to be dried to preserve
for round the year use as it is or in size reduction form
with or without pre-treatment.

Ripening stage has an important effect on the force
required for removal or detachment of fruits or
vegetables or nuts from the branches of plants or trees
and on relative susceptibility to mechanical damage.
Some researchers reported that the holding force of
fruits and vegetables to pedicle decreased as the fruit

Physio-morphological and mechanical properties of chillies for mechanical harvesting

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278

matured, due to cork that is formed in the stem holding
place. The detachment force required to pluck the
fruits of selected cultivars of chillies at various stages
of ripeness is presented in Table 5. The results
indicates that, the detachment force increased as the
fruits maturation increased from green to full red and
there after it decreased. This may be due to the fact
that up to full maturation of fruits, pedicle contains
more fibre content compared to remaining stages and
at dry stage pedicle contain less fibre content. It was
observed that, the average force required to pluck the
chillies at green stage for Arka Meghana, Mahyco
Tejaswini and Demon F1 was found to be 3.45± 2.11
N, 2.43±1.53 N and 5.19± 2.31 N, respectively.
Similarly, in fully ripped red stage maximum plucking
force noted, 5.85± 2.80N, 4.92± 2.23N and 8.58±
2.07N, respectively.

The data also indicates that, specifically the cultivars
having pendent position fruits have recorded lower
plucking force than erect position. These observations
concur with the findings of Funk and Walker (2010),
pendant fruit position with minimum fruit attachment
force in gr een chilli genotypes aides for better
mechanical harvesting. When mechanical harvesting

components designs involving working principles such
as rotating, oscillating, push-pull, combing and jolter
actions are employed to harvest fruits and vegetables;
fruit/ vegetable detachment force, size properties, mass
and puncture property against mechanical damages
must be known. Polat et al., (2010) reported that for
pistachio nut the pod detachment force decreased from
436 to 118 N within 100 days prior to harvesting to
harvest date of partially dried nuts.

CONCLUSIONS
Red chilli is an important commercial crop, besides
its wide spread use in Indian food culture. However,
the fruits harvesting still being carried manually at
incr ea sed ha rvesting costs a nd in hot wea ther
conditions. So, important morphological attributes,
p hys ic a l a nd mec ha nic a l p r op er t ies  of  t hr ee
popularly grown cultivars were studied to provide
a n idea  a bout these for  ha r vester  developer s,
r es ea r c her s .  T he r es u lt s  ha ve r evea led t he
importance of the difference among cultivars, while
designing and ma nufacture of machines. T hese
properties are highly useful in harvesting machine
development and as well as post harvesting like
cleaning and grading equipment.

Table 5. Force (N) required to detach chilli fruit at different growth stages

Different
Arka Meghana Mahyco Tejaswini Demon F1stages

Green Semi Red Semi dry Green Semi Red Semi Dry Green Semi Red Semi Dry
(N)  red (N) Dry (N) (N) red (N) dry (N) (N) red (N) Dry (N)

(N) (N) (N) (N) (N) (N)

Mean3.45 4.07 5.85 2.36 1.08 2.43 2.11 4.92 1.52 0.87 5.19 6.39 8.58 1.98 0.98

Minimum 0.78. 1.04 1.90 0.39 0.75 0.99 0.45 1.23 0.50 0.69 1.18 1.02 1.20 0.93 0.78

Maximum 9.86 11.30 17.49 6.21 1.43 8.79 5.80 13.18 4.47 1.13 13.82 12.21 15.65 5.95 1.32

Standard 2.11 2.19 2.80 1.51 2.32 1.53 0.93 2.23 0.80 0.95 2.31 2.21 2.07 1.15 1.76
deviation

Standard error 0.19 0.22 0.28 0.15 0.19 0.15 0.09 0.22 0.08 0.14 0.21 0.22 0.21 0.11 0.34

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(Received on 10.11.2021, Revised on 15.12.2021 and Accepted on 31.12.2021)

Physio-morphological and mechanical properties of chillies for mechanical harvesting

J. Hortl. Sci.
Vol. 16(2) : 271-279, 2021


	00 Contents.pdf
	16  Yella swami.pdf
	19 Lamesssa.pdf
	20 Divya.pdf
	21 Wani.pdf
	23 Index  and Last Pages.pdf