Plane Thermoelastic Waves in Infinite Half-Space Caused


FACTA UNIVERSITATIS  
Series: Mechanical Engineering Vol. 13, N

o
 2, 2015, pp. 169 - 180 

OPTICAL MODEL AND NUMERICAL SIMULATION 

OF THE NEW OFFSET TYPE PARABOLIC CONCENTRATOR 

WITH TWO TYPES OF SOLAR RECEIVERS 

UDC 535.2; 536.2; 536.6; 536.7 

Saša Pavlović
1
, Darko Vasiljević

2
, Velimir Stefanović

1
,

Zoran Stamenković
1
, Sadoon Ayed

3

1
Faculty of Mechanical Engineering, University of Niš, Serbia 

2
Institute of Physics, Photonics Center, University of Belgrade, Serbia 

3
University of Technology, Department of Mechanical Engineering, Baghdad, Iraq 

Abstract. The paper presents a physical and mathematical model of the new offset type 
parabolic concentrator and a numerical procedure for predicting its optical performances. 

Also presented is the process of design and optical ray tracing analysis of a low cost solar 

concentrator for medium temperature applications. This study develops and applies a new 

mathematical model for estimating the intercept factor of the solar concentrator based on its 

geometrical and optical behavior. The solar concentrating system consists of three offset 

parabolic dish reflectors and a solar thermal absorber at the focus. Two types of absorbers 

are discussed. One is a flat plate circular absorber and the other a spiral smooth pipe 

absorber. The simulation results could serve as a useful reference for design and 

optimization of offset parabolic concentrators. 

Key Words: Optical Modeling, Parabolic Offset Reflector, Solar Energy, Ray Tracing 

Methodology, Geometric Factors, Characteristics of Concentration. 

1. INTRODUCTION 

Solar energy is one of the alternative sources that can meet energy demands. This 

form of energy can be harnessed at a comparatively low cost. The device which is used to 

transform solar into heat energy is referred to as a solar thermal collector or STC. 

Depending on the temperatures gained by them, STCs can be divided into low, middle 

and high temperature systems. Mid-temperature systems are applicable for refrigeration 

systems and industrial processes. Among several types of solar concentrators, the multi-

dish concentrator consisting of several discrete small dishes arouses wide interest. They 

Received June 28, 2015 / Accepted July 29, 2015
Corresponding author: Saša Pavlović 

Faculty of Mechanical Engineering, University of Nis, Aleksandra Medvedeva 14, 18000 Niš, Serbia 

E-mail:saledoca@gmail.com 

Original scientific paper



170 S. PAVLOVIĆ, D. VASILJEVIĆ, V. STEFANOVIĆ, Z. STAMENKOVIĆ, S. AYED 
 

are convenient for manufacturing, installation and mending discrete dishes. To avoid 

design complexity of a specific shaped surface solar concentrator, a common offset 

parabolic antenna is used to make the solar reflector. These types of antennas are widely 

used both in developed and underdeveloped countries and they are cheap and easy to obtain. 

A configuration with several offset parabolic antennas offers many advantages over most 

common centered-focus solar parabolic concentrators (focal point concentrators), like lower 

wind resistance and higher stability of the structure because of a lower center of gravity. 

Munir [1] presented an experimental study of transforming solar energy into thermal 

energy by using a parabolic solar concentrator with a system of continual tracking of the 

sun. The experiment was carried out on a prototype of concentrator of 1 m in diameter 

and a copper receiver, 10 cm in diameter and 20 cm length. The receiver was located at the 

focal plane of the parabola. This model of parabolic solar concentrator led to the levels of 

temperatures ranging between 200
0
C and 350

0
C.  

Bellel [2] studied the difference in performance of two types of solar cylindrical 

receivers. Bellel dealt particularly with problems of heat transfer in the absorber. In fact, 

the concentration of solar energy, which the absorber converts into thermal energy, allows 

one to meet various needs: hot water for different uses, production of electricity through the 

generation of steam, sterilization of objects (medical devices). Bhirud and Tandale [3] and 

Delaney [4] developed concentrators that are capable of delivering temperatures in the 

range of 300
0
C and are technically suitable for medium temperature applications. With a 

higher concentration ratio, there is an increase in temperature at which heat is delivered. It 

is observed from the comparison that the two axes tracking paraboloidal dish, which always 

faces the sun, is the most promising design for the concentrating systems justifying the use 

of the Scheffler concentrator for industrial process heat applications. These concentrators 

also provide an automatic tracking system. Scheffler [5] has shown that about half of the 

power of sunlight which is collected by the reflector becomes finally available in the 

cooking vessel. The use of solar energy for the generation of steam is now an economically 

attractive possibility since the payback period of such a system lies between 1.5 and 2 years. 

Ruelas et al. [6] developed and applied a new mathematical model for estimating the intercept 

factor of a Scheffler-type solar concentrator (STSC) based on the geometric and optical 

behavior of the concentrator in Cartesian coordinates. Reinalter et al. [7] investigated thermal 

and geometric features of the 10 kW receiver CNRS-PROMES system (parabolic reflector 

with diameter 3.8m, focal length 4.5m). The validation process of the thermal model was 

performed by comparing the experimental results reported for the 10 kW cavity receiver 

CNRS-PROMES system to the results obtained from the simulation of incoming solar 

radiation in laboratory conditions by using a solar simulator. Munir et al. [8] showed the 

design principle and calculation of a Scheffler fixed focus concentrator with the surface area 

of 8 m
2
 for medium temperature applications. The authors proved mathematically that it is 

possible to construct a concentrator that can provide a fixed focus for each day in a year. 

Bugarin [9] presented the process of design and construction of a low-cost solar concentrator 

for cooking. This type of solar cooker produces vertically reflected rays that reach the food pot 

at the bottom like in conventional stoves. Rapp and Schwartz [10] constructed and 

successfully tested a 2m
2
 parabolic dish solar concentrator (Scheffler Concentrator) to focus 

sunlight onto a stationary target. They described some ideas about the intricate design of 

the Scheffler reflectors and how they are developed. The parabolic Scheffler reflectors 

can provide for a high temperature heat for all types of cooking, steam generation and many 



        Optical Model and Numerical Simulation of New Offset Type Parabolic Concentrator... 171 

 

other applications. Macosko et al. [11] described a solar concentrator system designed to 
supply both thermal and electrical energy to a hydrogen reduction reactor modeled after 

the NASA Roxygen first generation system. A concept is defined that utilizes an offset 

parabolic concentrator to collect and focus solar energy directly into the Roxygen reactor. 

The offset parabolic concentrator was rotated to track the sun. A two axis solar tracking 

system and a concentrator positioning system were utilized to keep the concentrator 

perfectly aligned with the sun and the focal point centered at the reactor (receiver) aperture. 

Asmelash et al. [12] also designed and manufactured an offset type of solar concentrating 

system for cooking purposes. The concentrating offset collector had major and minor 

diameters of 90 by 80 cm respectively. The system was tested for its thermal performance 

following standard testing procedures of the American Society of Agricultural Engineers 

(ASAE) and it was found useful with an encouraging results. Maximum temperature of 

940
0
C was achieved in the cooking vessel after 25 minutes. Patil et al. [13] investigated 

convection heat loss that inevitably occurs in receivers with high concentrating solar 

concentrators. They presented an experimental investigation of natural convection heat loss 

from the hemispherical cavity receiver with diameter 540 mm. The aim of the project was 

to develop the setup that may be used to identify the total heat loss and convective heat loss 

from the receiver. Cabanillas and Kopp [14] developed a solar parabolic dish concentrator 

with a diameter of 2.44 mm and focal length of 0.92 m. They studied a solar spiral heat 

exchanger made from carbon steel in order to measure the energy efficiency and net energy 

gain of the concentration system. Saravanan et al. [15] designed solar biomass hybrid dryer 

for the purpose of drying 40 kg of cashew nut per batch. They have investigated the thermal 

performance of a solar biomass dryer. Their system consists of a solar flat plate collector, a 

biomass heater, a drying unit, a blower and a chimney. The solar air heating collector 

system consists of an absorber, a double glass cover, a back plate and insulation.  
The offset parabolic reflectors are more efficient since objects placed at the focus do not 

create shadows over the reflecting surface. This paper also describes a prototype of an offset 
parabolic dish with 2400 mm in diameter. The system consists of three identical offset 
satellite dishes that are positioned in such a way that they concentrate sun radiation in the 
integral focal area with the desired area and geometry. This study develops and applies a new 
mathematical model for estimating the intercept factor of the solar concentrator based on its 
geometrical and optical behavior. This paper, however, does not devote much attention to 
experimental measurement and testing of thermal performance of the concentrating solar 
collectors. As a next step in the research, the experimental verification of simulated results is 
planned. 

2. DESCRIPTION OF THE LOW-COST PARABOLIC OFFSET CONCENTRATING COLLECTOR FOR 

THERMAL APPLICATION 

Fig. 1 shows a parabolic offset solar concentrator system installed in the Laboratory for 
Thermal Engineering at the Faculty of Mechanical Engineering, University of Niš. The 
system consists of three identical offset satellite dishes that are positioned in such a way that 
they concentrate sun radiation in the integral focal area. The inner surface of the offset 
parabolic dishes that faces the sun is covered with aluminum foil. The reflectivity of the foil 
ranges from 58 to 60%. The reflective foil should be cut in such a way that there are no 
wrinkles when they are glued to the surface of the dish; hence 10 cm wide rectangular 



172 S. PAVLOVIĆ, D. VASILJEVIĆ, V. STEFANOVIĆ, Z. STAMENKOVIĆ, S. AYED 
 

pieces are the optimum cut size for the offset parabolic dish. The concentration of solar 
radiation in a spiral absorber – receiver (focus surface area) is shown in Fig. 2. 

          

Fig. 1 Experimental model of a parabolic 

offset solar concentrator system 

Fig. 2 Concentration of solar radiation at 

the spiral absorber pipe 

 

Fig. 3 Infrared image of the coil receiver taken at 15:05 pm on September, 30, 2014 

Fig. 3 shows an infrared image of the coil receiver. The maximum measured surface 

temperature was 335 C. The day was clear and sunny. The measurement was performed with 

the thermal imaging camera FLIR E30. It was expected that the temperature at the coil 

receiver would be about 400 C in July or August.  

2.1. Physical model of the offset type parabolic dish concentrator  

with a thermal spiral tube absorber 

The offset solar parabolic concentrator is the result of the interception of the open circular 

area with a small side section of the parabola. It directs solar radiation to a fixed focus point 

where a solar absorber - receiver is installed and secured by a fixed support structure. 



        Optical Model and Numerical Simulation of New Offset Type Parabolic Concentrator... 173 

 

It was made from low carbon manganese steel. The support structure of the offset solar 

parabolic dish concentrator was made by welding a large number of metal profiles with a 

square cross-section (0.03  0.03m). Parabolic offset reflectors were placed on the support 

structure by using adequate trusses which enabled the reflectors to be dismantled from the 

support structure at any given moment. Adjustment of the elevation angle of each of three 

offset reflectors is possible in the range from 0 to 30 relative to the horizontal plane of the 

support structure. 

The mechanical structure should allow the positioning of the three parabolic offset 

reflectors into the optimal position in which solar rays strike the solar concentrator at angle 

of 90. The authors performed several numerical simulations of dynamic loads for various 

wind speeds and angle of attack. The system was designed in the following way. The 

reflectors track the sun up to the wind speed of vw = 20m/s. At greater speeds, the system 

stops tracking the sun and gets itself into the most stable position which is the horizontal 

one. The system was designed with the applied CAD technologies and calculated to 

withstand the maximal wind speed of vwmax = 25m/s (Finite Element Method). Figs. 4a and 

4b show the solar concentrating system in the working and safety positions. 

    
 a) b) 

Fig. 4 a) Working position of the offset parabolic dish solar concentrator (axonometric view); 

b) safety position (elevation angle of 900) 

The main elements of the offset parabolic dish concentrator system in the working 

position are shown in Fig. 4a. One of the essential elements of the solar system is the 

possibility of a permanent tracking position of the sun (azimuth and elevation). The incident 

angle of sun rays is parallel to the optical axis of the solar concentrating system. The system 

remains in the safety position during the night, only to take up the working position after 

sunrise (tracking mode). 

2.2. Mathematical modeling of the solar offset parabolic concentrator 

Design parameters of the solar offset parabolic concentrator are illustrated in Table 1 

[16]. Mathematical modeling (calculation) for the whole geometric model of the offset 



174 S. PAVLOVIĆ, D. VASILJEVIĆ, V. STEFANOVIĆ, Z. STAMENKOVIĆ, S. AYED 
 

parabolic concentrator was done in Wolfram Mathematica v.8.0. The numerical solution 

of the mathematical model was used to obtain geometric parameters such as the radius of 

the smaller and larger semi axis of the ellipse, the focal length, and the tangent slope for 

the three offset reflectors. Parameters obtained from mathematical analysis were used as 

input parameters for 3D modeling in the CAD program CATIA V5R19 - Dassault 

Systems, USA. The first step was to design a rotational paraboloid with diameter D = 

5000 mm and focal length f = 1600 mm. The next step was to design a circular cylinder 

with diameter D = 1100 mm, which was positioned parallel to the optical axis of the 

rotational paraboloid at the distance of 100 mm from the optical axis. The three cylinders 

were positioned parallel to the optical axis and the angle between the axes of the cylinders 

was 120°. Unlike a conventional paraboloid concentrator, the offset parabolic concentrator 

system fixed focus concentrator is a lateral part of a paraboloid as shown in Fig. 5a. Fig. 6 

shows the structure and geometric model of the new type of solar offset parabolic 

concentrator. The choice of the optimal position of the solar thermal absorber – receiver 

was carried out on the basis of Monte Carlo ray tracing analysis model of the offset type 

parabolic concentrator dish and receiver. The optimal focal distance is 1155 mm, while the 

theoretical focal distance is 1600 mm - focal hot spot. 

PARABOLOID

Available

aperture

area

Lateral section of

a paraboloid

(Offset parabolic

concentrator)

FOCUS

Beam
solar
radiation

DIRECTRIX

VERTEX

Y

X

1100 mm

2500 mm

    

 a) b) 

Fig. 5 a) Section of the offset parabolic solar dish concentrator from baseline paraboloid; 

b) Process of determining a offset parabolic solar dish concentrator 

The mathematical representation of the parabolic concentrator is paraboloid which can be 

represented as a surface obtained by rotating the parabola around the axis. Mathematical 

equations for the parabolic dish solar concentrator in Cartesian coordinate systems are 

defined as:  

 fzyx 4
22
  (1) 

 



        Optical Model and Numerical Simulation of New Offset Type Parabolic Concentrator... 175 

 

Table 1 Geometric parameters of the offset parabolic dish concentrator, Pavlovic et al. [16] 

Design parameter Numerical value Unit 

Major diameter of reflector Dref 1.20 [m] 

Minor diameter of reflector Dref 1.10 [m] 

Cross-section of opening offset parabolic concentrator Aproj 5.31 [m
2
] 

Sheltered area of concentrator Ashadow 0 [m
2
] 

Effective area of offset concentrator Aap,ref 2.85 [m
2
] 

Receiver diameter  0.20 [m] 

Diameter of baseline paraboloid 5 [m] 

Depth of baseline paraboloid 0.98 [m] 

Depth of offset parabolic concentrator 0.33 [m] 

Focal length 1.6 [m] 

ψ1 - rim angle  43.15 [
0
] 

Absorber area 0.0314 [m
2
] 

Geometric concentration ratio CRg = Aap/Arec 96.01 [-] 

Optical (flux) concentration ratio CR0 = Irec/ Iap= Irec /DNI 87,07 [-] 

Surface reflectance ρ 0.60 [-] 

Direct solar radiation Id 800 W/m
2
 

            
 a) b) 

Fig. 6 a) Structure of the new type of solar offset parabolic concentrator; 

b) Geometrical model of the new type of solar offset parabolic concentrator 

Usually the paraboloids that are used in solar collectors have rim angles from 10 to 90 

degrees. The relationship between the relative aperture and the rim angle is given by: 

 
)2/tan(4

1
/

rim

Df


  (2) 

Intercept factor φ represents the fraction of the radiation intercepted by the cavity receiver 

and is calculated by Eq. (3) with a change over the term of the fraction of the captured 

flux, using Γ
1.975 

instead of Γ.  

The shadow produced by the receiver was considered as a dead area on the projected 

area of dish reflective surface Adish. Power consumption for the tracking and controlling 

systems were neglected. 



176 S. PAVLOVIĆ, D. VASILJEVIĆ, V. STEFANOVIĆ, Z. STAMENKOVIĆ, S. AYED 
 

 

1.975

0

8 sin( )

dish

If

IA





  




 




 (3) 

The incident energy received by solar spiral absorber of offset parabolic dish concentrator 

can be computed from the following equation: 

 ( )
s b e

Q I C    (4) 

The optical efficiency of that solar concentrator can be computed from:  

 
0

( )
c e

     (5) 

3. PHYSICAL MODELS OF TWO TYPES OF SOLAR SPIRAL THERMAL RECEIVERS 

In terms of their configuration, receivers can be flat receivers or cavity receivers. The 

first ones focal absorber surfaces, whilst the latter ones have the absorber surface 

surrounded by an insulated cover, with a sufficient opening to capture the radiation from 

the concentrator. The shape of the receiver depends on its dimension and the concentrator 

focal length/rim angle. Photo thermal conversion in a dish cavity receiver is a key process 

to efficiently utilize solar energy, mainly because the cavity receiver converts the 

collected solar radiation into thermal energy by coupling the complicated heat transfer. 

This paper analyzes two types of solar thermal receivers presented in Fig. 7. The first 

type is the solar thermal receiver with a flat plate. The receiver is a metal disc painted 

black. The second type is the Archimedean spiral smooth pipe directly exposed to 

reflected radiation from the offset dish concentrator. 

The receptor portion of the heat exchanger has three primary components, all made of 

stainless steel. The spiral pipe absorber creates a spiral path for fluid to flow through. 

 
 a) b) 

Fig. 7 Two types of solar thermal receivers: a) flat plate painted black; b) spiral pipe 

The flow rates in spiral absorber pipe are changeable data. The next step is to create 
an experimental installation in the Mechanical Engineering Laboratory for testing and 
thermal hydraulic performance of said heat exchangers in stationary conditions. The 



        Optical Model and Numerical Simulation of New Offset Type Parabolic Concentrator... 177 

 

installations will be able simulations of real solar modules (offset parabolic concentrator). 
They will serve as the basis for investigating the work of the spiral absorber at different 
geometric and spatial configurations, fluid flow, heat input levels, as well as the fluids 
with significantly different thermo-physical properties (water and a solution of propylene 
glycol). In order to assess the efficiency of the heat exchanger the measurement of thermal 
and hydraulic losses will be carried out. 

The spiral smooth pipe absorber is directly exposed to reflected radiation from the dish 
concentrator. Solar energy systems can improve effectiveness of their receivers by covering 
them with a selective absorber coating. The spiral pipe receiver is made of stainless steel AISI 
304 with a coil of 10 mm in outer diameter and 8 mm in inner diameter rolled into a spiral 
shape of 200 mm in diameter. The length of spiral pipe absorber is about 2.5 m. Usually in 
this type of receiver the liquid circulates inside the tube, entering from the rim and leaving at 
the center where the radiation intensity and temperature are higher (Fig. 8a and 8b). To avoid 
pipe deformations, the receiver has a small hole in the center, of about 40 mm in diameter. 
The incidence angle of the offset parabolic concentrator is zero θi = 0. 

        
 a) b) 

Fig. 8 a) Trace of concentrated rays at the spiral absorber pipe; b) spiral flat coil absorber 

Both types of receivers are painted black on the side facing the concentrator so that they 

would be able to absorb the maximum amount of thermal energy. The test plate – a metal 

circular disk, is used to determine where the focal area of the concentrator is. In other words, it 

is used to determine where the receiver should be placed in relation to the concentrator. 

4. RESULTS AND DISCUSSION 

4.1. Optical analysis of the offset parabolic concentrator 

The optical analysis of the offset parabolic concentrator was carried out in the commercial 

software TracePro ver. 7.4.2, Lambda Research Corporation, USA. Two types of absorbers 

were analyzed: the flat plate circular absorber and the spiral smooth pipe absorber. 

4.1.1. Optical analysis of the offset parabolic concentrator  

with a flat plate circular type of absorber  

In TracePro the three offset parabolic reflectors were defined as a surface with reflective 

coating. The reflectance coefficient was 60%. The receiver was a flat plate circular absorber 



178 S. PAVLOVIĆ, D. VASILJEVIĆ, V. STEFANOVIĆ, Z. STAMENKOVIĆ, S. AYED 
 

with the diameter of 200 mm and 5 mm in thickness. The absorbing surface was defined as 
the perfect absorber (α =1). The position of the receiver was found by calculating the 

optimal flux for the given receiver. The optimal position was found at 1155 mm from the 

vertex of the parabolic dish, after several calculations in TracePro. At a distance of 

1155 mm the best value of total flux was obtained - solar power and irradiance flux density 

distribution. After defining the geometry of the offset parabolic solar concentrator, the 

radiation source was defined. The radiation source was circular with the same diameter as 

that of the parabolic dish (2400 mm). The radiation source was placed 1500 mm from the 

vertex of the offset solar parabolic concentrator and had a circular grid pattern for the 

Monte Carlo ray tracing. The spatial profile of generated rays was uniform and the angular 

profile was solar radiation. The input parameter for the optical analysis was the solar 

irradiance which was set to 800 W/m
2
. Experimental values for solar irradiation for the 

City of Niš in Serbia are between 750 W/m
2 
and 900 W/m

2
. The optical system for the offset 

parabolic solar concentrator with traced rays is given in Fig. 9. Since the offset parabolic 

concentrator continually tracked the sun, the incidence angle of solar rays was always 

θ = 0
0
 . For this type of solar concentrator cosine losses do not exist.  

         

X

Y

ZZ

           
Fig. 9 Ray tracing model of the offset 

parabolic solar concentrator with 

the flat plate circular absorber 

Fig. 10 Solar flux distribution  

on the absorber surface 

 

The optical analysis was done by generating 119401 rays and calculating them by the 

Monte Carlo ray trace. From all the emitted rays only 76058 rays reached the absorber 

surface, which was 64% of the emitted rays. The calculated irradiance for the absorbed 

rays on the receiver was from 3.88∙10
-9 

W/m
2
 to 3.25∙10

5 
W/m

2
. The total calculated flux 

on the flat plate receiver was 2188 W. Fig. 10 shows the total irradiance map for the 

absorbed flux on the receiver. 

4.1.2. Optical analysis of the offset parabolic concentrator  

with a spiral smooth pipe absorber  

The second optical analysis was performed on the more complicated model of the 

solar absorber. The solar absorber was the spiral pipe absorber described in the previous 

section. The position of the receiver was found by calculating the optimal flux for the 



        Optical Model and Numerical Simulation of New Offset Type Parabolic Concentrator... 179 

 

given receiver. The optimal position of the receiver was 1155 mm from the vertex of the 

parabolic dish. 

The optical analysis for the system with the smooth pipe absorber was done by 

calculating two sets of rays. The first set contained 119401 rays and the second set 

contained 1078201 rays. All rays were calculated by the Monte Carlo ray trace. For the 

first set of rays, from 119401 emitted rays only 49886 rays reached the absorber surface 

which was 42% of rays. The average irradiance – the local flux density was 57859 W/m
2
. 

The calculated irradiance for the absorbed rays on the receiver was from 1.625∙10
-15 

W/m
2
 to 4.124∙10

5 
W/m

2
. The total calculated solar flux on the spiral pipe receiver was 

1435.4 W. The total irradiance map for the absorbed flux on the receiver for the first set 

of rays is shown in Fig. 11. 

      

Fig. 11 Solar flux distribution on the absorber 

surface - 119 401 simulated rays 

Fig. 12 Solar flux distribution on the absorber 

surface - 1078201 simulated rays 

For the second set of rays, from 1078201 emitted rays only 515418 rays reached the 

absorber surface which was 48% of rays. The average irradiance – the local flux density 

was 66195 W/m
2
. The calculated irradiance for the absorbed rays on the receiver was 

from 1.2207∙10
-15 

W/m
2
 to 3.8733∙10

5 
W/m

2
. The total calculated solar flux on the spiral 

pipe receiver was 1642.3 W. The total irradiance map for the absorbed flux on the 

receiver for the second set of rays is shown in Fig. 12. 

From the presented data for the first and second set of rays it can be concluded that it 

is very important to properly define a set of rays. For a simple solar absorber, such as a 

plate circular disc, a set of 119401 rays is more than enough, but for a complex type of 

the solar absorber, such as a spiral smooth pipe absorber, one ought to define much more 

rays to get valid results. 

5. CONCLUSION 

The authors have developed a completely new model of the offset parabolic dish 

concentrator. The presented simulation results could serve as a useful reference for the 

design and optimization of offset parabolic concentrators. As a next step in the research, the 

experimental verification of simulated results is planned. The authors intend to improve the 



180 S. PAVLOVIĆ, D. VASILJEVIĆ, V. STEFANOVIĆ, Z. STAMENKOVIĆ, S. AYED 
 

design of the absorber by developing a solar receiver with a cavity. This type of receiver has 

significantly smaller convective and radiation losses and greater conversion efficiency of 

solar radiation to heat. 

Acknowledgements: The paper is a part of the research done within the projects: III 42006- 
Research and development of energy and environmentally highly effective polygeneration systems 

based on renewable energy resources and III 45016 - Fabrication and characterization of nano-

photonic functional structures in biomedicine and informatics. Both projects are financed by the 

Ministry of Education, Science and Technological Development of the Republic of Serbia. The 

authors would like to acknowledge the help provided by the Lambda Research Corporation by 

allowing the use of TracePro software for the PhD research of Saša Pavlović. 

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th
 International Conference on Accomplishments in 

Electrical and Mechanical Engineering and Information Technology, Faculty of Mechanical Engineering, Banja 

Luka, Bosnia and Herzegovina.