Performance of the Prototype Furnace Evaporator with PLC Control
Tossin Alamsyah
1
, Bagas Aji Rotama
2
, Eri Catur Rahmad
2
and Muhammad Mukhbi
2
1
Lecturer of Applied Electrical Engineering Magister Program, Politeknik Negeri Jakarta, Indonesia
2
Electronic Engineering Study Program, Department of Electrical Engineering Politeknik Negeri Jakarta, Indonesia
Keywords: Furnace, Evaporator, Heater, Programmable Logic Controlled (PLC).
Abstract: Furnace Evaporator (FE) is an instrument that has two (2) functions as a furnace and evaporation, in an effort
to increase the capacity of the material both activities are needed. The Furnace Evaporator was first patented
by Pierce, James Louis, in 1917, using an energy source from gas, used for processing natural materials. This
Furnace Evaporator (FE) is designed to use a heat energy source (heater) from electricity, to later become a
prototype FE with a working temperature of 50°C-900˚C, and heat control based on Programmable Logic
Control (PLC). The FE prototype has two horizontal and vertical doors, with a combustion chamber area of
about 36 cm3. Prototype has accuracy in generating heat, the temperature value on the HMI monitor screen
when compared to a measuring instrument has a chi square (R2) value of 0.995. Operational testing was
carried out in three (3) conditions, namely when the prototype hood was closed (C1), half closed (C2) and
open (C3), the results had different temperature resolution responses, namely, 2.14 V/s, 1.25 V/ s and 0.83
V/s. If the three parameters are combined, they have a non-linear relationship with a chi square (R2) value of
0.9939, which means that they are significantly related.
1 INTRODUCTION
Furnace is an instrument that has the function of
heating materials / materials with a heater. Furnace
can be used in sintering and calcining processes.
Sintering process is a process of heating the material
not to exceed the melting point in order to improve
the structure and quality of the material. Calcination
is the process of heating solids in the absence or with
very little supply of air or oxygen to carry out thermal
decomposition.
Evaporator is an instrument that functions to
change part or all of a solvent from a solution from a
liquid to a vapor. Evaporators have two basic
principles, to exchange heat and to separate the vapor
formed from the liquid. Furnace Evaporator (EF) is
an instrument that has two (2) functions as a material
furnace and chemical evaporation. This tool was first
patented by Pierce, James Louis, in 1917 with Patent
No. 1,228,240, 1917. This prototype Furnace
Evaporator (FE) is gas-fueled, fuel is injected into the
chamber at the top to form a vortex fire inside. This
Furnace Evaporator (FE) is designed to use a heat
energy source (heater) from AC electricity. heater
used has a capacity of 300°C-1200˚C. This tool is
used as a support in the design of Gas sensors with
Si
(1-x)
Al
(x)
O3 substrates, this tool functions as a
furnace for the calcination process (furnace) and an
evaporator when the chemical liquid process is
evaporated to the sensor cover.. The prototype of the
sensor design in question can be shown in Figure 1,
Figure 1: Sensor prototype.
Sensitive layer is a chemical material as a sensor
cover that functions to respond to the gas to be
detected. The evaporation temperature for chemical
liquids ranges from about 90
0
C to 200
0
C, depending
on the melting point.
The higher the heating temperature with the
longer coating time, the thicker the layer thickness on
the sensitive layer (cover sensor). The coating
Alamsyah, T., Rotama, B., Rahmad, E. and Mukhbi, M.
Performance of the Prototype Furnace Evaporator with PLC Control.
DOI: 10.5220/0011861200003575
In Proceedings of the 5th International Conference on Applied Science and Technology on Engineering Science (iCAST-ES 2022), pages 651-655
ISBN: 978-989-758-619-4; ISSN: 2975-8246
Copyright © 2023 by SCITEPRESS – Science and Technology Publications, Lda. Under CC license (CC BY-NC-ND 4.0)
651
thickness setting can be adjusted based on the rotation
time and speed if the material is placed on a swivel
stand. The results of the study [2] with SnO material
as the sample showed that at a heating temperature
of 100 °C - 200 °C, the thickness of the coating
attached to the substrate ranged from 83.8 to 80.9 nm.
The higher the annealing temperature, the lower the
refractive index of the thin film, that is, at a heating
temperature of 100°C, the refractive index is higher.
The three (3) dimensional shape of the prototype
Furnace Evaporator (FE) that has been designed can
be shown in Figure 2. There is a hole above it which
is intended to regulate the air in the combustion
chamber inside. The condition of C1 when the hole is
closed, so that the combustion chamber does not
come into contact with the outside air.
The condition of C2 when only a small gap is
given, so that the combustion chamber is in contact
with the air and in the condition of C3, the hole is not
closed, it means that the combustion chamber is in
contact with the outside air.
Figure 2: Photo Furnace Evaporator (FE).
Figure 2 shows a photo Furnace Evaporator (FE),
frame made of steel with walls made of calcite,
refractory brick. Above it is a hole intended to
regulate air when operated or also needed when
cooling. Physical dimensions of 41 cm x 41 cm x 75
cm with a volume of space is 36 cm
3
(30 cm x 30 cm
x 40 cm), the overall weight is about 12.5 Kg.
This tool has several electrical components,
including, Table 1.
Table 1.
Name of Tool Specifications
PLC Modicon
TM221CE16R
16 digital I/O, 2 analog
inputs
1 Serial port, 1 Ethernet
port
220-250 VAC power
suppl
y
, 24 VDC ou
t
Heater 1500 WATT
Solid State Relay 5A
MCB 16 A
Transmitter
Thermocouple
0-16 V
Temperature range -100–
1000 C
NYAF CABLE 2.5 mm, 0.75 mm
2 PLC Modicon TM221CE16R
Programmable Logic Controlled (PLC) used in this
tool is Modicon M221 is one of the products that
issued by Schneider Electric. This M221 PLC can be
programmed using software provided for free by
Schneider Electric, namely SoMachine Basic. PLC
M221 has 16 Digital I/O ie 9 inputs and 7 outputs and
also 2 Analog inputs, with a power supply of 100-240
Vac, with an ethernet port and also some LED
indicators. Figure 3 below shows the physical form of
the TM221CE16R PLC.
This PLC uses SoMachine Basic software, which
is PLC software that is used to configure,
communicate all devices connected to these devices,
including the Human Machine Interface (HMI)
system and networks related to automation functions.
Figure 3: PLC TM221CE16R.
2.1 HMI and SCADA
Vijeo Citect is one of the software used in the
creation, programming, and application software
iCAST-ES 2022 - International Conference on Applied Science and Technology on Engineering Science
652
SCADAVijeo Citect can be applied to handle various
cases in industries such as wastewater treatment, food
and beverage production, mining, automobile
assembly, metal casting, transportation, aerospace,
defense systems, security, etc.
software consists of four main applications, namely
Vijeo Citect Explorer, Vijeo Citect Project Editor,
Vijeo Citect Graphic Builder, and Vijeo Citect
Runtime.
1) Vijeo City Explorer is an application that is at the
top level of Vijeo Citect applications that
functions in programming and system
configuration. In figure 2.4 is the view of Vijeo
City Explorer which used for:
a) Starting and stopping the Citit Project Editor and
the Citit Graphics Builder.
b) Selecting and managing Projects
c) Create projects, delete, backup and restore
projects
d) Run other applications, such as Cicode Editor.
e) Explore and access the components of the
software being worked on.
2) Configuring Software Vijeo Citect
Before creating a layout in the software, it is
necessary to set up or initialize the project to be
created. The things that must be set are clusters and
servers, communication parameters, variable tags,
trend tags, IO devices, alarms, roles and users. All
these settings are done using the Vijeo City Project
Editor software. However, for Vijeo Citect Version
7.5, the only parameter that must be configured is the
IO Device. The other parameters are already
configured (default from Citit). However, if you use
a client and server network system, it needs to be
reconfigured.
3 METHODOLOGY
This applied research uses experimental methods,
designs and builds to produce a prototype. The level
of Technology Readiness is at levels 5 and 6, namely.
The validation, Prototype and or a collection of
Prototype in the relevant environment and
Demonstration of System/Subsystem Models or
Prototypes in the relevant environment.
Planning and design is carried out at the Electrical
Engineering Laboratory of the Politeknik Negeri
Jakarta and some mechanical work is carried out in a
private mechanic workshop around Depok.
Some of the materials needed are as follows;
a) Input Prototype;
Thermocouple Sensors and Transmitters,
b) the Output Prototype;
Heater and some Relay Contacts Multiple
Indicator Lights.
c) Control Prototype,
PLC Modicon TM221CE16R With
specifications of 16 digital I/O, 2 analog inputs
1 Serial port, 1 Ethernet port 220-250 VAC
power supply, 24 VDC out
4 RESULTS AND DISCUSSION
Results Thermocouple sensor readings from the FE
combustion chamber are sent to the transmitter to be
amplified voltage as input from PLC (Programmable
Logic Controlled). Furthermore, this data will be
changed by the PLC into BCD and processed by the
PLC program to control the Actuator (Heater),
through Solid State Relay (SSR).
The control and monitoring system uses
HMI/SCADA with the Vijeo City Project Editor
software. The connection from the FE Module to the
Laftop as a monitor uses from a PLC using TCP/IP
communication, which is connected by an Ethernet
cable. Some of the tests carried out were
a) Measurement of the EF prototype Thermocouple
and Display in Monitor.
To take measurements, it is necessary to prepare
this thermocouple which has been added a meter to
measure temperature, in the EF Prototype combustion
chamber. Then the results are compared with the
readings on the HMI, which are displayed on the
laptop/PC.
The results can be shown in the diagram shown in
Figure 4, below.
From the picture, the readings on the HMI / Scada
are almost the same as the readings with a
temperature meter using a thermocouple in Figure 4.
From the picture, the readings on the HMI / Scada
are almost the same as the readings with a
temperature meter using a thermocouple.
Notation R2 is useful for testing the relationship
or effect of two nominal variables and measuring the
strength of the relationship between one variable and
another nominal variable (C = Coefficient of
contingency). From the explanation and the R2 ;
0.9995
, it shows that the generated by this EF
Prototype can be stated as accurate and reliable.
Performance of the Prototype Furnace Evaporator with PLC Control
653
Figure 4: Temperature measurement.
b) EF Prototype Responsive Testing.
There are three (3) patterns in this test, namely;
The first test when the hood of the EF prototype is
closed. This test is intended so that the combustion
chamber does not come into contact with air, in this
condition the EF Prototype is used as a Furnace for
Calcination activities. The second and third
conditions are when the hood is half opened and fully
opened.
The temperature on the EF set at a lower
temperature of 345
o
C and an upper temperature limit
of 360
o
C. The Prototype's Temperature Response will
work between these temperatures. Then in the
observed conditions the response of temperature to
the increase in time (in second) is /∆𝑡 , when the hood
is closed, half opened and opened. Figure 5, shows
the EF performance for the three conditions.
Figure 5: EF Temperature Response for the three
conditions.
The diagram above shows a comparison of
performance responses when the hood is closed (C1),
half closed (C2) and open (C3).
EF Temperature Response when the hood is
closed (C1), thus the combustion chamber is not in
contact with outside air,
S or Resolution can be stated (R1)
𝑅1
𝑉
𝑡
15
7
2.14 𝑉/𝑠
(1)
Then for Temperature Response when the hood is
opened halfway (C2) has a resolution or temperature
response (R2) of;
𝑅2
𝑉
𝑡
15
12
1.25 𝑉/𝑠
(2)
Then for the Temperature Response when the
hood is fully opened (C3) has a resolution or
temperature response (R3) of:
𝑅3
𝑉
𝑡
15
18
0.83 𝑉/𝑠
(3)
Figure 6 shows a diagram of the Temperature
Resolution value for the three conditions, if the three
conditions are connected to each other then it has a
non-linear relationship with the chi square value
(
)
R2of 0.9939.
Figure 6: Temperature Resolution.
5 CONCLUSION
From the results of the discussion it can be concluded
that;
iCAST-ES 2022 - International Conference on Applied Science and Technology on Engineering Science
654
The prototype Furnace Evaporator (FE) which is
designed to have an accuracy in generating heat,
displays the temperature value on the HMI monitor
screen (laftpo) when compared to a measuring
instrument with a Thermocouple meter with a chi
square value (R2
)
of 0.995. The test was carried out
under three (3) conditions, namely when the
prototype hood was closed (C1), half closed (C2) and
open (C3). The three have different temperature
resolution responses, namely, 2.14 V/s, 1.25 V/s and
0.83 V/s. If the three parameters of the Temperature
Resolution Response are connected, all three have a
non-linear relationship with the chi square value (R
2
)
0.9939 which means it has a significant relationship.
ACKNOWLEDGMENTS
We would like to thank the Director of DRPM
Kemenristek Dikti, who has provided this Higher
Education Excellence Research grant (PUPT).
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