ABSTRACT
Brazil is the world’s largest sugarcane producer destined for mills producing alcohol, sugar, and electricity cogeneration. Sugarcane transport to the mills is carried out by trucks with trailers and tractors with semi-trailers, which transport the raw material harvested in the field to the mill. The modal road system of sugarcane transport uses this equipment to meet the continuous demand of the harveste draw material, with punctuality in the transport execution and generating a minimum cost. This study aimed to analyze the influence of availability efficiency on the operational and economic performance of different sugarcane transport equipment. A computational model called TransporteCana was developed in a spreadsheet due to the difficulty in meeting the objective under field conditions. The model was checked for possible routine errors, validated, and used in the analysis of variables and generation of results. The results showed that increasing availability efficiency reduces the operational cost of producing the equipment. Large managerial investments for the means of execution are required for high availability efficiencies.
KEYWORDS agricultural mechanization; logistics; planning and management; computational model; truck and trailers; tractor and semi-trailers
INTRODUCTION
The estimated area cultivated with sugarcane in Brazil reached 8.42 million hectares and a total production forecast of 628.10 million tons in the 2021/2022 growing season ( CONAB, 2021 ).
The road transport system is essential to meet the demand for raw material harvested in the field and deliver sugarcane to the mill on time to avoid direct and indirect damage to the raw material quality. According to Santos et al. (2014b) , the demand for the production of processed raw materials depends on the operational performance of the mechanized system. In this sense, operational performance comprises the managerial conditions for the equipment to operate and considers, among the various means of execution, the operational times of service ( Santos et al., 2014a ).
According to Mialhe (1974) , operational times occur through setup, interruption, and production time. Setup time refers to the preparation of the equipment to operate. Interruption time stems from the work of the equipment in operation, such as adjustments and refueling. Production time is exclusively for productive work, that is, when the equipment is effectively performing the agricultural operation. In this context, according to Alizadeh (2011) , Araldi et al. (2013) , Griffel et al. (2020) , Grisso et al. (2002) , Linhares et al. (2012) , Mohamed et al. (2011) , Oduma et al. (2019) , Pitla et al. (2014) , Santos et al. (2018b) , Shamshiri & Ismail (2013) , and Zhou et al. (2015) , the operational times of service result in the field efficiency (Eff), which corresponds, in this study, to the availability efficiency (Efa) of the equipment of the sugarcane transport system. Efa comprises the worked hours that the equipment effectively performs its productive function, the auxiliary hours that are required according to the operation that the equipment necessarily needs for its full use ( Banchi & Lopez, 2007 ). Furthermore, according to these authors, the lost hours correspond to the period that the equipment is ready to operate but is not used due to managerial or climate conditions,which are independent of the equipment, and maintenance hours, which correspond to the time taken to carry out the routine maintenance that the operation requires.
The operational performance of equipment in the management of mechanized agricultural systems has a direct influence on economic performance ( Santos, 2018a ). According to Santos (2019) , it occurs because the operational and economic performance variables are systemically interrelated. Thus, this study aimed to analyze the availability efficiency in the operational and economic performance of different sugarcane transport equipment.
MATERIAL AND METHODS
Amill, called Hypothetical Mill, with its sugarcane transport system (truck with trailers and tractor with semi-trailers), was considered in this study. The predominance of the operation of the transport system in this study, as in any mill in Brazil, occurs with the equipment going to the field and back from the field to it, thus completing the entire loading and unloading cycle, with no restrictions on the form of coupling/uncoupling during the cycle between the truck with trailers and the tractor with semi-trailers.
The Hypothetical Mill has distant plots with an average radius that varies from 10 to 50 km and will be covered by the equipment during the loading and unloading cycle. An Elaborated Scenario, which comprises the description of the economic, technical, managerial, and operational characteristics of the equipment was created to generate the results ( Table 1 ).
Economic, technical, managerial, and operational variables of equipment for the Elaborated Scenario.
Efa, which determines the useful life, in kilometers, of the equipment, agreed with Banchi & Lopes (2007) . The loading and unloading time values were based on data from the study conducted by Carreira (2010) .
A computational model, called TransporteCana , which enables the basic characteristics of the sugarcane transport system in the Brazilian mills, was developed to meet the study objective. The model is based on the flowchart shown in Figure 1 , prepared according to the features proposed by Oakland (2007) .
TransporteCana was developed in an Excel® spreadsheet. The model starts its operation (1) 4 with the entry of data referring to the crop (2), such as the sugarcane production to be transported and the price of the ton of sugarcane delivered to the mill. Item (3) refers to the climate data entry: number of days to conduct the transport, number of Sundays and holidays, and number of inappropriate working days for transport to define the available time in days.
Data entry (4) refers to the technical/management/operational characteristics of the transport: rated engine power, body loads, number of bodies, number of tires, average working speed, working time, new tire service life, retread tire service life, number of tire retreads, average distance radius, loading time, and unloading time.
The association between items (2), (3), and (4) determined the operational performance of the truck with trailer and tractor with semi-trailer set (5): total loading and unloading cycle time, number of loading and unloading in the day, month, and growing season, the total load of the set, the total production capacity of the set, production transported in the day, month, and growing season, distance traveled in the day, month, and growing season, operational fuel consumption in the growing season, production rate, and number of required sets.
The results of operational performance associated with the entry of the economic data of machinery (6) initial value, final value, service life in years and hours, interest per year, storage, insurance, and fees (SIF), licensing, fuel consumption, and repair and maintenance determined the calculation of economic performance (7), which refers to the cost of fuel, repair and maintenance, repair and maintenance of the new tire, repair and maintenance of the retreaded tire, per kilometer and ton, and gross and net gain of the mill with the transported production.
The model results (8) allow the user to evaluate the operational and economic performance of the transport and decide (9) as to the feasibility (10) or not. New data must be inserted in the model in case the transport with the considered equipment is not feasible for the user (11) or the user chooses to evaluate another scenario.
Climate
The local climate determines the available time in growing season days (TAd) to transport the harvested raw material, based on Mialhe (1974) , with adjustments. The available time in growing season days (TAd) was calculated based on the number of days (Nd), number of Sundays and holidays (Nsh), and number of unsuitable working days for transport (Nuwdt), according to [ eq.(1) ].
In which:
TAd is the available time (days);
Nd is the number of days;
Nsh is the number of Sundays and holidays, and
Nuwdt is the number of unsuitable working days for transport.
Operational performance
The total loading and unloading cycle time (TLUCT), the number of loading and unloading in the day (NLUD), production transported in the day (PTD), production transported in the growing season (PTGS), distance traveled in the day (DTD), and distance traveled in the growing season (DTGS) were based on Carreira (2010) . This proposal was adopted because it meets the operationalization of the logistic process (transport) of the sugarcane to a Mill.
The total loading and unloading cycle time (TLUCT) was calculated based on the average distance radius (ADR), average working speed (AWS), loading time (LT), and unloading time (UT) ( Carreira, 2010 ), according to [ eq.(2) ].
In where:
TLUCT is the total loading and unloading cycle time (h);
ADR is the average distance radius (km);
2 is the constant to determine the round-trip distance traveled in the loading and unloading cycle;
AWS is the average working speed (km h−1);
LT is the loading time (min);
UT is the unloading time (min), and
60 is a constant.
The number of loading and unloading in the day (NLUD) was determined based on the working time (WT), total loading and unloading cycle time (TLUCT), and availability efficiency (Efa), based on Carreira (2010) .
The number of loading and unloading in the month (NLUM) was defined by the association between the number of loading and unloading in the day (NLUD) and the total number of days in a month (NDM).
The number of loading and unloading in the growing season (NLUGS) was calculated by the association between the number of loading and unloading in the day (NLUD) and the time available in growing season days (TAd).
The total load of the set (TLS) was determined by the association between the body load (BL) and the number of bodies (NB).
The total production capacity of the set (TPCS) was defined by the ratio between the total load of the set (TLS) and the total loading and unloading cycle time (TLUCT).
The production transported in the day (PTD) was calculated by the association between the number of loading and unloading in the day (NLUD) and the total load of the set (TLS), according to Carreira (2010) .
The production transported in the month (PTM) was determined by the association between the production transported in the day (PTD) and the total number of days in a month (NDM).
The production transported in the growing season (PTGS) was defined by the association between the production transported in the day (PTD) and the time available in growing season days (TAd), according to Carreira (2010) .
The total distance traveled in the loading and unloading cycle (TDTLUC) was calculated based on the average distance radius (ADR), according to [ eq. (3) ].
In which:
TDTLUC is the total distance traveled in the loading and unloading cycle (km).
The distance traveled in the day (DTD) was determined based on the total distance traveled in the loading and unloading cycle (TDTLUC) and the number of loading and unloading in the day (NLUD) ( Carreira, 2010 ), according to [ eq. (4) ].
Where:
DTD is the distance traveled in the day (km day−1).
The distance traveled in the month (DTM) was defined by the association between the distance traveled in the day (DTD) and the total number of days in a month (NDM).
The distance traveled in the growing season (DTGS) was calculated by the association between the distance traveled in the day (DTD) and the time available in growing season days (TAd), according to Carreira (2010) .
The operational fuel consumption in the growing season (OFCGS) of the set truck with trailer and tractor with semi-trailer was determined based on the distance traveled in the growing season (DTGS), fuel consumption (FC), and production transported in the growing season (PTGS).
The production rate (PR) was defined by the ratio between the mill production in the growing season (MPGS) and the time available in growing season days (TAd).
The number of required sets (NRS) was calculated by the ratio between the production rate (PR) and the production transported in the day (PTD).
Economic performance
The fixed cost (FC) of the equipment was calculated based on the adjusted proposal of ASABE (2011 ), defined by the ratio between annual depreciation (AD), annual interest (AI), storage, insurance, and fees (SIF), licensing (LIC), and distance traveled in the growing season (DTGS), according to [ eq.(5) ].
In which:
FC is the fixed cost of the equipment (US$ km−1);
IV is the initial value of the equipment (US$);
FV is the final value of the equipment (decimal);
ESL is the equipment service life (years);
i is the interest rate per year (decimal);
SIF is the storage, insurance, and rates per year (decimal);
LIC is the licensing (US$ year−1), and
DTGS is the distance traveled in the growing season (km year−1).
The variable cost (VC) of the equipment was defined as the sum of the cost of fuel (CF), cost of repair and maintenance (CRM), cost of repair and maintenance of the new tire (CRMNT), and cost of repair and maintenance of the retreaded tire (CRMRT), based on Mialhe (1974) and Balastreire (1990) with adjustments.
Fuel consumption (FCP) of the truck and tractor can be estimated or averaged. The estimated value must be provided when choosing the estimated consumption. The average consumption option is in accordance with the proposal by Banchi et al. (2008) . This proposal provides average values of fuel consumption of sugarcane trucks by the rated power range of the equipment’s engine.
The cost of fuel (CF) of the equipment was calculated by the ratio between the price of a liter of fuel (PL) and fuel consumption (FCP). The price of a liter of fuel (PL) was 0.92 US$ L−1, which was based on the average price of gas stations in the city of Uberaba-MG in 2021.
The cost of repair and maintenance of the truck and tractor (CRMTT) was defined based on ASABE (2011 ) with adjustments.
The cost of repair and maintenance of the trailer (CRMT) and semi-trailer (CRMST) was calculated according to Banchi et al. (2009) .
The cost of repair and maintenance of the new tire (CRMNT) and retreaded tire (CRMRT) of the equipment were based on Goodyear (2017 ) and Rosa (2017) . The cost of repair and maintenance of the new tire (CRMNT) was defined based on the price of a new tire (PNT), number of tires (NT), and the new tire service life (NTSL), according to Goodyear (2017) and Rosa (2017) ( Equation 6 ).
Where:
CRMNT is the cost of repair and maintenance of the new tire (US$ km−1);
PNT is the price of a new tire (US$);
NT is the number of tires, and
NTSL is the new tire service life (km).
The cost of repair and maintenance of the retreaded tire (CRMRT) of the equipment was determined based on the price of the retreaded tire (PRT), number of tire retreads (NTR), number of tires (NT), and retread tire service life (RTSL), according to Goodyear (2017) and Rosa (2017) ( Equation 7 ).
Where:
CRMRT is the cost of repair and maintenance of the retreaded tire (US$km−1),
PRT is the price of the retreaded tire (US$),
NTR is the number of tire retreads, number of tires (NT), and
RTSL is theretread tire service life (km).
The equipment operational cost (EOC) was calculated by the sum between the fixed cost (FC) and variable cost (VC), based on Mialhe (1974) and Balastreire (1990) with adjustments.
The operational cost of the truck and trailer set (OCTTS) was determined by the sum between the operational cost of the truck (OCTk) and the operational cost of the trailer (OCTr).
The operational cost of the tractor and semi-trailer set (OCTSTS) was defined by the sum between the operational cost of the tractor (OCT) and the operational cost of the semi-trailer (OCST).
The operational cost of production of the truck and tractor (OCPTT) was calculated based on the equipment operational cost (EOC), distance traveled in the growing season (DTGS), and production transported in the growing season (PTGS), based on Carreira (2010) and Rosa (2017) with adjustments, according to [ eq.(8) ].
in which:
OCPTT is the operational cost of production of the truck and tractor (US$ t−1);
EOC is the equipment operational cost (US$ km−1);
DTGS is the distance traveled in the growing season (km year−1), and
PTGS is the production transported in the growing season (Mg year−1).
The operational cost of production of the trailer and semi-trailer (OCPTST) was determined similarly to the operational cost of production of the truck and tractor (OCPTT), according to Carreira (2010) and Rosa (2017) with adjustments. The operational cost of production of the truck and trailer set (OCPTTS) was defined by the sum between the operational cost of production of the truck (OCPTk) and the operational cost of production of the trailer (OCPTr). The operational cost of production of the tractor and semi-trailer set (OCPTSTS) was calculated by the sum between the operational cost of production of the tractor (OCPT) and the operational cost of production of the semi-trailer (OCPST). The total cost of the set (TCS) was determined by the sum of the operational cost of production of the set (OCPS) and production transported in the growing season (PTGS).
Economic gains of the mill
The mill gross (MGGPTGS) and net (MNGPTGS) gain with the production transported in the growing season were based on Santos et al. (2014a) , Santos et al. (2015) , and Santos et al. (2017) , with modifications. In this case, the mill gross gain with the production transported in the growing season (MGGPTGS) was calculated by the association between the estimated price per ton of sugarcane delivered to the mill (PTSDM) and the production transported in the growing season (PTGS). In contrast, the mill net gain with the production transported in the growing season (MNGPTGS) was determined by the difference between the mill gross gain with the production transported in the growing season (MGGPTGS) and the total cost of the set (TCS). The estimated price per ton of sugarcane delivered to the mill was 14.69 US$ Mg−1, according to UDOP (2019 ).
Validation
TransporteCana was validated by comparing simulation results with data from the literature (secondary data). Validation, sensitivity analysis, and consistency of the computational model were performed using the operational cost of production.
RESULTS AND DISCUSSION
The climate planning of the Elaborated Scenario of the Hypothetical Mill considered the pluviometric conditions of the Triângulo Mineiro region, in the State of Minas Gerais, between 1980 and 2010, according to the pluviometric data presented by Roldão & Assunção (2012)apudANA (2012 ), and clayey soil. The climate planning of the considered region resulted in atime available in growing season days (TAd) of 235.
Availability efficiency (Efa) is a management variable that represents the time worked, adjustments, and equipment availability. Figure 2 shows the operational cost of production of the sets under two management conditions of availability efficiency, that is, 70 (Elaborated Scenario) and 100%, as a function of the average distance radius between the mill and the production plot. Increasing the average distance radius results in linear growth in cost but higher availability efficiency reduces the cost of the sets. The cost of the truck and trailer set within a radius of 10 km with efficiencies of 70 and 100% was 0.70 and 0.62 US$ Mg−1, respectively, while the tractor and semi-trailer set had a cost of 0.67 and 0.60 US$ Mg−1, respectively.
Operational cost of production and availability efficiency as a function of the average distance radius.
The cost of the truck and trailer set within a radius of 30 km (Elaborated Scenario) was 1.67 and 1.55 US$ Mg−1 with efficiencies of 70 and 100%, respectively. Moreover, the tractor and semi-trailer set reached the cost of 1.62 and 1.51 US$ Mg−1 for these efficiencies, respectively.
The cost of the truck and trailer set was 2.64 and 2.48 US$ Mg−1 within a radius of 50 km with efficiencies of 70 and 100%, respectively, while the tractor and semi-trailer set reached the cost of 2.57 and 2.42 US$ Mg−1, respectively.
The difference between the costs of the truck and trailer set regarding the radius of 10 km and a 70% efficiency showed an increase of 0.97 and 1.94 US$ Mg−1 or 138.55 and 277.11% compared to radii of 30 and 50 km, respectively. The 100% efficiency led to an increase of 0.93 and 1.87 US$ Mg−1 or 151.27 and 302.54%, respectively. In contrast, the difference in cost for the tractor and semi-trailer set relative to the 10 km radius with an efficiency of 70% showed an increase of 0.95 and 1.90 US$ Mg−1 or 140.47 and 280.94% compared to radii of 30 and 50 km, respectively. The 100% efficiency led to an increase of 0.91 and 1.82 US$ Mg−1 or 152.86 and 305.71%, respectively.
Therefore, it is recommended to transport the sugarcane from production plots located up to, on average, a radius of 30 km from the mill, otherwise, the operational cost of production of the equipment will be very high, thus reducing the gains of the mill.
CONCLUSIONS
The increase in availability efficiency is advantageous for the operational cost of production of the equipment.
The tractor and semi-trailer set is more advantageous than the truck and trailer set.
Mills should adopt an excellent management method to facilitate the means of conducting the operation and, therefore, achieve high availability efficiency with the equipment.
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4
The numbers in parentheses refer to the flowchart in Figure 1 .
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Edited by
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Area Editor: Renildo Luiz Mion
Publication Dates
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Publication in this collection
08 July 2022 -
Date of issue
2022
History
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Received
02 June 2021 -
Accepted
26 May 2022