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Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8707-8711 8707 
 

www.etasr.com Oria & Palconit: Performance Investigation of an Inflatable Solar Dryer with Steel-Can Solar Air … 

 

Performance Investigation of an Inflatable Solar 

Dryer with Steel-Can Solar Air Heater for Drying 

Coffee and Corn 
 

Charity L. Oria 

School of Engineering, Ateneo de Davao University  
Davao City, Philippines and 

College of Engineering, Sultan Kudarat State University 

Sultan Kudarat, Philippines 
charityoria@sksu.edu.ph  

Eleonor V. Palconit 

School of Engineering  
Ateneo de Davao University 
Davao City, Philippines 

evpalconit@addu.edu.ph 

Received: 5 April 2022 | Revised: 14 April 2022 | Accepted: 18 April 2022 

 

Abstract-Coffee and corn are the two most important crops in 

the Philippines. One of the most critical stages, where crop 

management can be improved, is drying. In coffee, a moisture 

level of 12% is optimum for minimizing quality degradation 

throughout lengthy storage periods, whereas, corn requires a 

moisture content of 13%. With the demand for simple and cost-

effective drying technologies, an Inflatable Solar Dryer (ISD) was 
created and adapted using a Hohenheim-type solar tunnel and 

Salvatierra-Rojas’ study. A mesh wire served as a drying space 

and was placed inside the ISD to avoid moisture condensation. A 

clear polyethylene (PE) film is attached to a reinforced black 

Polyvinyl Chloride (PVC) film by a zipper to produce a drying 

tunnel. The tunnel does not require a foundation because the 
pressure generated by a solar-powered fan sufficiently stabilizes 

it. The ISD also incorporated steel cans as solar air heaters to 

boost the temperature of entering air into the chamber and 

gradually provide heated air temperature to the bottom parts of 

the crops. Crops were scattered on the mesh wire and blended 

with a rake. Drying in the open sun was also done in parallel for 

comparison purposes. After protracted drying, both crops 
reached the required moisture content. The trial found that the 

weight of both crops was affected by the drying duration. The 

difference in weight for coffee is 1.1kg, while for corn is 0.5kg 
exhibiting a significant advantage in ISD. 

Keywords-postharvest management; corn; coffee; inflatable 

solar dryer; solar air heater; solar-powered fan 

I. INTRODUCTION  

Agriculture is vital to the economies of developing 
countries as it is the primary source of food, currency, and 
employment for rural populations. On the other hand, 
agriculture and land-use reforms are critical for achieving food 
security, poverty alleviation, and overall sustainable 
development. According [1], farming employs 28.4% of the 
workforce in the Philippines and contributes an average of 
10.18% of the country's GDP. Given this percentage, the 
Philippines continues to import agricultural products. Corn and 
coffee are two essential crops imported in the Philippines. 
According to the Department of Agriculture (DA), the 

Philippines imports 75,000 MT to 100,000 MT of dry coffee 
beans from Vietnam and Indonesia each year at P7 billion to 
P10 billion [2]. At the same time, corn imports averaged 
604,000 tons from 2017 to 2019. Based on the data from the 
United State Department of Agriculture (USDA), corn imports 
are predicted to remain steady from 2021 to 2022 as a result of 
improved local production and ample feed grain inventories 
[3], while the country's coffee production would increase to 
214,626 MT by 2022, based on the Philippine Coffee Roadmap 
[2]. By undertaking pest and disease management activities and 
providing seeds, fertilizers, and pesticides, many government 
agencies along with the private sector are working to boost the 
country's corn and coffee production. Postharvest management, 
such as the provision of dryers, was, on the other hand, 
negligible, even though it is equally vital in the entire 
production of crops. According to [4], post-production losses in 
the country occur mainly in handling and drying, resulting in 
delayed, incomplete, or inefficient drying.  

Open Sun Drying (OSD) was introduced for agricultural 
product preservation and storage. This method of drying is still 
widely used even today. However, OSD faces many inherent 
limitations like overexposure, which causes food damage, high 
losses in yield production due to insects, rodents, and birds, 
longer drying time, and unpredictable climate conditions [5]. In 
the Philippines, OSD is the main practice of the farmers. In 
fact, with the absence of drying facilities, many crops, 
including coffee beans and corn, are dried on highways or road 
pathways where vehicles may run over and ruin the products. 
Other corn and coffee producers, on the other hand, choose to 
trade their crops immediately after harvesting to prevent farm 
losses and additional expenses. It can be noted that freshly 
picked coffee beans and corn when sold will have a low farm 
gate price as compared to dried crops. Locally, newly gathered, 
or wet corn is priced at Php.12.00 at the farm gate, whereas dry 
corn with an optimal moisture content of 13% is priced at 
Php.17.00. The farm gate price for newly picked coffee beans 
is Php.30.00, while the farm gate price for dry coffee with an 
optimal moisture content of 12% is Php.110.00. With such 

Corresponding author: Charity L. Oria



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disadvantages and differences between the price of wet and dry 
crops, the need for solar dryers and their implementation has 
drawn the attention of researchers.  

Many types and models of solar dryers have been studied 
and developed worldwide. However, in the Philippines, there 
are limited published articles about the implementation of solar 
dryers. The latest solar dryer study done in the country was the 
ISD by Salvatierra-Rojas in 2017, using rice as the commodity 
[6]. The dryer gives a promising result in drying rice in humid 
climates like in Philippines. Furthermore, the study 
demonstrates that the ISD is an ideal dryer for small-scale 
farmers due to its low-cost materials and simple operation. 
Therefore, the goal of this study is to employ such an ISD to 
dry corn and coffee beans. The results were compared to the 
performance of OSD in terms of drying time and final weight 
when reaching the desired moisture content of 13% for corn [7] 
and 12% for coffee beans [8]. Recycled steel-can Solar Air 
Heater (SAH) was integrated into the ISD to increase air inlet 
temperature and determine its contribution to the ISD by 
closely monitoring the inlet, mid, and inside humidity and 
temperature. Mesh wire was also placed inside the ISD to 
prevent condensation. 

II. MATERIALS AND METHODS 

A. Design of the Inflatable Solar Dryer 

The ISD was based on [6], which was constructed from the 
Hohenheim-type solar tunnel [9] that has been developed and 
commercialized to dry different agricultural products in 
different climatic conditions. Unlike the Hohenheim-type dryer 
and the Salvatierra-Rojas study, which laid the grains barely in 
black PVC films inside the chamber, this study incorporated an 
elevated mesh wire inside the ISD chamber to allow double 
pass of hot air into the lower and upper part of the dried 
products and to allow better circulation of the moist inside the 
chamber. The dryer is still collapsible, just like in [6]. 

The ISD drying chamber comprises 150µm UV-transparent 
polyethylene (PE) film and is joined to a 0.52mm reinforced 
black PVC film by a heavy-duty zipper. A heavy-duty zipper is 
positioned and sewn along the margins of both plastic layers. 
The entire unit is placed directly on the ground. The tunnel 
does not require structural support and is effectively stabilized 
by air pressure from inflation. One 220V solar-powered fan 
blows air into the tunnel, which is then expelled through the 
opposite side's vents. The inclusion of renewable energy was 
based on the findings of [6], which recommended that more 
research should focus on incorporating photovoltaic power 
supply for the ventilators to enable off-grid operation [6]. The 
chamber's tested drying space is 2.5m long and 1.5m wide. To 
prevent moisture condensation inside the ISD chamber, this 
study used a 15×15cm mesh wire supported by four pieces of 
2×2ft. wood. The crops were then spread at the height of 20mm 
on top of the mesh wire and were mixed with a rake to 
minimize overheating of the top layer exposed to the sun.  

B. Design of the Solar Air Heater (SAH) 

The SAH was used in the study to raise the temperature of 
the air entering the ISD. The SAH was made out of 390ml steel 
cans. For the first layer, 49 pieces of steel cans were arranged 

vertically in 7 groups and for the second layer, 30 pieces of the 
same cans were laid in 5 groups. There was a gap between the 
cans for the second layer to allow air circulation inside the 
SAH. The SAH's frame was made of a 5mm plyboard and was 
measured to be 0.905m in length, 0.6m in width, and 0.2m in 
height. The SAH has round perforations on one end to allow 
the incoming air to pass through. On the opposite end of the 
SAH, a single rectangular hole connects to the fan and ISD 
through a 10mm foam insulator. The SAH was painted black as 
a coating material to increase its thermal operation [10]. The 
SAH's top cover and glazing system were made of 5mm 
transparent glass to restrict the steel cans' radiant and 
convective heat absorbance. Four heavy-duty caster wheels 
were installed at the bottom of the SAH to make it portable and 
easy to transport. 

A two-layer design composed of insulator foam and black 
PVC film was stitched together, and magic tape was attached to 
link the sides and form a tunnel to connect the SAH, fan, and 
ISD, as shown in Figure 1. Table I shows the design 
parameters, such as the overall size of the SAH, ventilator size, 
and the overall size of the ISD. 

 

 
Fig. 1.  Design of ISD and integrated SAH with a solar powered fan. 

 



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TABLE I.  DESIGN PARAMETERS OF THE EXPERIMENTAL SETUP 

Design parameters Details 

Solar Air Heater (SAH) 

Type Steel can solar energy heat absorber 

Overall size of the SAH 0.905m length × 0.6m width × 0.2m 

height 

Overall size of the steel can 

heat absorber 

0.755m length × 0.6m width × 0.15m 

height 

Ventilator 

Type of ventilator Solar-powered fan 

Diameter of ventilator 16 inches 

Ventilator 220 V AC/DC 

Airflow rate 1.7 m/s 

Inflatable solar dryer (ISD) 

Overall size of the ISD 2.5m length x 1.5m width 

Height of the inflated tunnel 0.75m 

Mesh wire drying space 

Overall size of the drying space 2.1m length x 1.1m width 

Height from the ground 0.15m 

Capacity (fresh) 100 kg 

 

C. Drying Experiment 

The dryer was used in the Philippines' Sultan Kudarat 
province (6.5069° N, 124.4198° E). The dryer was set up in the 
middle of a paddy field that was completely unoccupied. The 
crops used in the trials were Robusta coffee and yellow corn. 
Each experiment trial was conducted a day after the crops were 
harvested. The initial moisture content of both crops and their 
initial weight were measured at the start of the drying 
experiment. Similarly, before the crops were set aside 
throughout the night or during heavy rains, the weight and the 
moisture content were tested again to see how much had 
changed over the drying period within the day. The trial began 
at 7 a.m. and ended at 5 p.m. every day, i.e. for a daily duration 

of 10 hours. The coffee had a moisture content of 40.5% on a 
wet basis, whereas the corn had 38.9%. During each 
experiment trial, the solar-powered fan was permitted to run 
continuously within the drying duration. At 1-hour intervals, 
the crops were dried and scattered with a rake. Each dryer had 
three batches of crops to dry. The OSD was used as a control 
method, with each batch containing 16.3kg of coffee beans and 
16.9kg of corn. The sample crops were spread out on a black 
PVC film next to the ISD with a bulk height of 20mm. The 
crops in the OSD were mixed with a rake at the same time as 
the ISD. The crops were kept aside throughout the night or 
when there was severe rain but were dried the next day until the 
ideal moisture content for each crop was reached. 

D. Instrumentation of Drying Experiments 

To evaluate the study's goal, four essential tools were used. 
A 25kg capacity digital weighing scale was used to determine 
the initial and final weight of the crops, whereas a digital 
moisture content meter (AR991 KERRO Smart Sensor Digital 
Grain Moisture Meter) was used to determine the moisture 
content. A self-logging humidity and temperature sensor 
(BSIDE Mini USB Humidity Temperature Data Recording 
Logger) was mounted on the inlet, in the middle (in the fan, 
where the wind is blown), and on the ISD chamber to 
determine the temperature and relative humidity as shown in 
Figure 2. When linked to a computer, data were logged every 
10s and were automatically generated and exported. 

E. Statistical Analysis  

T-test experimental design was conducted using the Excel 
statistical software, with p values less than 0.05 considered 
significant. 

 

Fig. 2.  Position of humidity and temperature sensor top view  

III. RESULTS AND DISCUSSION 

A. Temperature and Relative Humidity (SAH, Fan, ISD) 

The humidity and temperature loggers were positioned in 
three different locations in the dryer. The first location was in 
the SAH, where there was incoming air, the second was next to 
the solar-powered fan to see if the steel can SAH could boost 

the incoming air temperature, and the third was on the top of 
the crops inside the ISD. The dryer's ambient temperature 
varied from 31 to 46ºC, 31 to 51ºC, and 31 to 70ºC respectively 
from the SAH air inlet, alongside the fan, and within the ISD. 
Figure 3 shows the air temperature and humidity profile within 
the dryer over 10h, using the chosen intervention phase data. In 
general, there was a progressive temperature rise between the 



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SAH input and the fan, but the most increase was between the 
fan and the ISD. The highest temperature of the day was 
between 11 a.m. and 2 p.m. However, the temperature in the 
three places gradually declined after sundown, eventually 
approaching ambient temperature. The temperature rises in the 
dryer continued to be minimal due to evaporative cooling 
provided by the crops and more significant convective losses 
due to a higher difference in temperature out from ambient air. 

 

(a) 

 

(b) 

 

(c) 

 

Fig. 3.  The dryer's temperature and humidity at (a) SAH air inlet, (b) the 

fan in the middle, (c) ISD at the top of the crops. 

B. Moisture Content and Drying Behavior  

The moisture content of the crops during ISD and OSD 
drying is shown in Table II. Under ISD, coffee with an initial 
moisture content of 40.5% reached the ideal moisture content 
of 12% in 3 days (27h), while in OSD, coffee with the same 
initial moisture content dried to 12% moisture content within 5 
days (47h). For the corn, the crops placed in the ISD with an 
initial moisture content of 38.9% dried to the target of 13% 
within a day, while when drying under OSD, the crops with the 

same initial moisture content dried in 2 days (14h). The target 
moisture content of 12% for coffee and 13% for corn may be 
easily obtained by continuously drying. However, when the 
crops were retrieved from the dryer at night, remoistening 
occurred, resulting in an increase in moisture content overnight. 
On the other hand, remoistening becomes minimal to none 
once the target moisture content is obtained. 

TABLE II.  MOISTURE CONTENT IN ISD AND OSD 

Products 
The moisture content of the products 

Fresh product ISD OSD 

Coffee 40.5% 12.00% 12.1% 

Corn 38.9% 12.25% 12.76% 
 

C. Weight 

The results of coffee weight shown in Table III and Figure 
4 revealed a significant difference with a p-value of 0.018 
under ISD and OSD, with a difference of 1.1kg in the final 
weight of coffee after reaching the desired 12% moisture 
content. However, corn weight results in Table IV show no 
significant difference. The difference in the final weight of corn 
after reaching the 13% moisture content is 0.5kg with a p-value 
of 0.09. This means that the product's drying time impacts the 
final weight when it reaches the target moisture content. 

TABLE III.  T-TEST OF WEIGHT OF COFFEE 

Dryer Mean SD Diff. t P-value Interpretation 

ISD 7.7 0.17 
0.35 3.89 0.018 Sig. 

OSD 7.35 0.1 
 

 
Fig. 4.  Coffee weight with respect to time. 

TABLE IV.  T-TEST OF WEIGHT OF THE CORN 

Dryer Mean SD Diff. t P-value Interpretation 

ISD 11.40 0.1 
0.23 2.21 0.09 No sig. 

OSD 11.17 0.14 
 

D. Drying Duration and Condensation Phenomena 

The drying time is determined by the time it took for the 
ideal moisture content to be achieved. Table V and Figures 4-5 
show the drying duration of coffee and corn under ISD and 
OSD. The difference in drying time between coffee and corn, 
20h for coffee and 6h for corn, is significant for farmers 
looking to save revenue on labor and other expenses. 
Condensation in the ISD's floor was eliminated due to the mesh 
that acts as a drying surface inside the ISD. Condensation 



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happens when the temperature of the crops or the dryer's 
surfaces falls below the drying air's moisture content. Without 
the mesh wire, the temperature of the crops will be higher at 
the top than at the bottom because the top layer of the crops is 
subjected to solar radiation and the temperature is enhanced by 
heat absorption. Incoming air from the SAH, on the other hand, 
reaches the bottom portion of the crops through the mesh wire 
and progressively dries the crops at the bottom. Another 
strategy to avoid condensation from forming is to increase the 
mixing rate after sunrise to transport the warm top layer of the 
crops to the bottom layer. 

 

 

Fig. 5.  Corn weight with respect to time. 

TABLE V.  DRYING DURATION OF COFFEE BEANS AND CORN 

Products 
Moisture content Drying duration (hours) 

Dried product ISD OSD 

Coffee 12.0% 27 47 

Corn 13.0% 8 14 
 

IV. CONCLUSION 

Due to the erratic rainfall, drying crops, particularly corn 
and coffee, is difficult in the Philippines, even during the dry 
season. To prevent such a situation, some farmers trade their 
products as soon as they are harvested (wet crops). However, 
because the market for freshly picked corn and coffee beans 
has poor farm gate prices, most farmers are drying their crops 
on roads and walkways to increase their income, even though 
this results in unclean and hazardous quality. The proposed ISD 
can help with these issues since it preserves the crops from 
damage, high yield losses due to pests, prolonged drying times, 
and uncertain weather changes. The dryer is easy to transfer, 
fix, and set up in a new area. Since it is made out of plastic and 
only has a few mechanical components, its simple design is 
easy to maneuver and maintain. The results of the trials reveal 
that 3 batches of 16.3kg coffee may be dried to an ideal 
moisture content of 12% on the third day or an exact period of 
27h of drying. However, drying the same amount of coffee in 
the open sun takes 5 days or 47 hours. In the case of corn, the 
results demonstrate that 13% moisture content can be achieved 
in less than a day, or 8h, whereas it must be dried for a second 
day, or an equivalent of 14h, in the open sun. Based on the data 
acquired throughout the testing, the drying time will 
considerably impact the weight of the crops in a way. The 
ventilators are turned off after 5 p.m., and the crops are 

retrieved from the dryers since this experiment should be based 
on farmers' actual practice of OSD. Further study should 
concentrate on integrating solar energy storage [11, 12] on the 
solar air heater to continuously heat the air entering the drying 
chamber, even during the night or when there is no sunlight. 
Additionally, automatic control and notification of the 
condition of the dryer and dried products are necessary to avoid 
over-drying, which results in excessive moisture loss. 

ACKNOWLEDGEMENT 

This publication, and specifically the coffee commodity, 
was prepared under the Grant funded by WCR under the 
PhilCAFE Cooperative Agreement/Grant No. 22107CS01609 
funded by USDA and led by ACDI/VOCA. The authors would 
also like to thank the helpful research assistants, Carissa Oria 
and the rest of the group, Ms. Velessa Jane Dulin for assessing 
the results, and Ms. Rosela Sazon for proofreading the article. 

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