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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 58, 2017 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Remigio Berruto, Pietro Catania, Mariangela Vallone
Copyright © 2017, AIDIC Servizi S.r.l. 
ISBN 978-88-95608-52-5; ISSN 2283-9216 

Mechanisation of Different Logging Operations: 
Environmental Impact Assessment using Life Cycle 

Assessment (LCA) Approach 

Andrea R. Proto*a, Jacopo Bacenettib, Giorgio Macrìa, Marco Fialac, Giuseppe 
Zimbalattia 
a
 Department of Agriculture, Mediterranean University of Reggio Calabria, Feo di Vito 89122, Reggio Calabria, Italy. 

b
 Department of Environmental Science and Policy. Università degli Studi di Milano, via Giovanni Celoria 2, 20133, Milan, 

Italy. 
c
 Department of Agricultural and Environmental Science. Università degli Studi di Milano, via Giovanni Celoria 2, 20133, 

Milan, Italy. 
andrea.proto@unirc.it 
 
Different logging systems (or harvesting systems) can be used for wood extraction. Cable logging system is 
typically carried out on steep slopes and other rough terrain. In these contexts, also cable yarding can be an 
efficient and effective harvesting system. Ninety-five per cent of timber production in southern Italy comes 
from terrain classified as very steep slope, limiting the use of machines for ground-based extraction. Cable 
extraction is a desirable alternative to either a skidder or forwarder on a sensitive site. 
To each harvesting system a different environmental load is associated depending on machine productivity 
and site characteristics. In this study, three different logging systems were analysed and compared using the 
Life Cycle Assessment approach. The compared logging systems are characterised by felling with chainsaw 
and three different extraction methods: by farm tractors equipped with a winch; by a skidder; and by a cable 
crane. The Full Tree harvesting method was adopted for both felling sites; trees were felled and transported to 
roadside with branches and top intact. The functional unit is 1 m

3 of wood; the system boundary involves all 
the operations carried out in the forestry (felling, bunching and extraction) and all the related inputs (diesel 
fuel, lubricating oil, capital goods such as chainsaw, tractors, skidder, cable yarder) and related emissions. 
Inventory data were collected in three different test sites located in southern Italy and concern working times, 
productivity, wood yield, fuel consumption. The cable yarder shows the worst performances for 7 of the 8 
evaluated impact categories. The use of skidder shows a lower impact for 5 of the 8 evaluated impact 
categories while, for the remaining 3, the best performances are achieved by the logging system in which 
tractor is used. For climate change, the impact is equal to 8.57, 8.04 and 10.46 kg CO2eq/m

3 for the 
harvesting system with extraction carried out using tractor, skidder and cable yarder, respectively. 

1. Introduction 

In Europe, energy policies are increasingly promoting the generation of energy from renewable sources (i.e. 
the European Union [EU] target of 27% renewable energy by 2030 and 40% of greenhouse gas [GHG] 
emission reduction) (European commission, 2014; Moneti et al., 2015). Among the different renewable 
sources, woody biomass is an interesting solution for energy generation in rural areas for both electricity and 
heat production (Caserini et al. 2010; Facciotto et al., 2014; Colantoni et al., 2016). Woody biomass can be 
produced from forestry management but also from dedicated plantations in which woody species are grown 
for energy purposes (Pierobon et al., 2015; Negri et al., 2016; Zambon et al., 2016). 
Wood extraction on steep slopes and other rough terrain has typically been associated with cable logging 
systems. Cable yarding proves to be an efficient and effective harvesting system for the extraction of timber 
on steep terrain, and their use in the mountainous regions of Europe is becoming more widespread. 
Nevertheless, in Italy, above all in southern regions, the use of this machinery is still limited (Zimbalatti and 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1758039

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Proto A.R., Bacenetti J., Macri G., Fiala M., Zimbalatti G., 2017, Mechanisation of different logging operations: 
environmental impact assessment using life cycle assessment (lca) approach, Chemical Engineering Transactions, 58, 229-234   
DOI: 10.3303/CET1758039 

229



Proto, 2009). In forests where firewood is produced, cable cranes are not used at all. About 95% of timber 
production in southern Italy comes from very steep slope terrains where the use of machines for ground-based 
extraction is limited (Proto et al., 2016a). In this situation, cable extraction is a desirable alternative to either a 
skidder or forwarder (Macrì et al., 2016). Several studies previously carried out evaluated the economic 
performances of the different logging systems (Han et al., 2004; Putz et al., 2008; Proto et al., 2016b). For 
example, Proto and Zimbalatti (2016) highlighted that also for these machines requiring higher investment 
costs, sufficient margins of value for the producer emerged. Nevertheless, only limited researches have 
considered the environmental impact related to logging systems (Gonzalez-Garcia et al., 2009; Valente et al., 
2011). Depending on machine productivity and site characteristics, each logging system shows its own 
environmental impact.  
Using the Life Cycle Assessment (LCA) approach, this study aims to analyse from an environmental point of 
view three different logging systems (or harvesting systems) composed by different logging operations and 
able to operate in forestry with medium and high sloped soils.  

2. Materials and methods 

2.1 Description of the logging systems 
Three different sites were monitored, each characterised by a harvesting system composed by a different 
sequence of logging operations. Globally the three sites cover an area of 35 ha. In all felling sites, “The Full 
Tree harvesting method” was adopted; therefore, the trees were felled and transported to roadside with 
branches and top intact.  
To each harvesting system, a different environmental performance is associated depending on machine 
productivity and site characteristics. In this study, the compared logging systems are characterised by felling 
with chainsaw and three different extraction methods (Figure 1). After felling (always carried out by 2 workers 
equipped with chainsaw): 

- in Site A (30% and 45% as average and maximum slope, respectively), bunching and extraction are 
carried out using a farm tractor equipped with a winch (in the following this harvesting system is 
referred to as "Harvesting system TRACTOR or HS-TR");  

- in Site B (43% and 65% as average and maximum slope, respectively), bunching and extraction are 
performed by a skidder. Respect to the use of a farm trailer, this solution requires a higher initial 
investment, but achieves higher productivity above all rough terrains (in the following this harvesting 
system is referred to as "Harvesting system SKIDDER or HS-SK"); 

- in Site C (60% and 80% as average and maximum slope, respectively), the trees are directly 
extracted and brought till the roadside using a cable crane. This solution requires the highest 
investment, but can operate also with very steep sloped soils (in the following this harvesting system 
is referred to as "Harvesting systems CABLE CRANE or HS-CR").  

 

 

Figure 1: Schematisation of the three compared harvesting systems.  

2.2 Life Cycle Assessment  
LCA is a useful tool to determine the environmental impact of a product and service and has been widely used 
also for agricultural systems. The LCA approach foresees 4 steps: 1) goal and scope, functional unit and 
system boundary definition, 2) inventory data collection, 3) impact assessment and 4) results interpretation 
(ISO, 2006a, ISO, 2006b). In this study, the selected functional unit (the measurable unit reference to which all 

TRACTOR + WINCHCHAINSAW

FELLING BUNCHING EXTRACTION

TRACTOR + WINCHSITE A – HS_TR

BUNCHING EXTRACTIONSKIDDERCHAINSAW SKIDDER

EXTRACTIONCABLE YARDERCHAINSAW

SITE B – HS_SK

SITE C – HS_CR

230



the results are referred) is 1 m3 of roundwood at the roadside. Concerning the system boundary, the analysis 
considers all the operations carried out in the forestry (felling, bunching and extraction) and all the related 
inputs (diesel fuel, lubricating oil, capital goods such as chainsaw, tractors, skidder, cable yarder) and related 
emissions into the environment. Emissions depend mainly on exhaust gases due to the combustion of fossil 
fuels into internal combustion engines. The inventory data concerning the flow of materials and energy along 
the different logging operations and between the analysed system and the environment were collected in three 
different test sites located in Calabria. For each logging operation, the collected data are:  

- working times,  
- productivity,  
- wood yield,  
- fuels and lubricant consumption. 

 
Table 1 and Table 2 report the inventory data measured during the trials in the three sites. Secondary data 
concerning the production of diesel, petrol-two stroke, lubricant as well as the manufacturing and disposal of 
machines (tractor, skidder, cable crane, chainsaw) and the emissions related to the combustion of the different 
fuels in the internal combustion engines were retrieved from the Ecoinvent database (Ecoinvent, 2012). 

Table 1:  Productivity recorded for the different logging operations 

Parameter 
Felling Bunching Extraction 

Site A 
HS_TR 

Site B 
HS_SK 

Site C 
HS_CR 

Site A 
HS_TR 

Site B 
HS_SK 

Site C 
HS_CR 

Site A 
HS_TR 

Site B 
HS_SK 

Site C 
HS_CR 

Productivity 
(m3/day) 

72 88 62.3 112.8 172.8 - 124.8 204.0 55.2 

Workers 
(number) 

2 2 2 3 3 - 3 3 3 

 
Table 2:  Main inventory data for the different logging operations 

Parameter 
Felling Bunching Extraction 

Site A 
HS_TR 

Site B 
HS_SK 

Site C 
HS_CR 

Site A 
HS_TR 

Site B 
HS_SK 

Site C 
HS_CR 

Site A 
HS_TR 

Site B 
HS_SK 

Site C 
HS_CR 

Machine Chainsaw Chainsaw Chainsaw 
Tractor 

with winch
Skidder 

with winch
- 

Tractor 
with winch 

Skidder 
with winch 

Cable 
crane 

Power 
(kW) 

4.8 4.8 4.8 75 110 - 75 110 85 

Mass 
(kg) 

7.1 7.1 7.1 4160 12160 - 4160 12160 6185 

Life span 
(year) 

3 3 3 15 15 - 15 15 15 

Economic 
lifespan 

3000 3000 3000 12000 10000 - 12000 10000 10000 

Annual use 
(h) 

1440 1440 1440 1600 1280 - 1600 1280 1080 

Diesel fuel 
consumption 

(kg/h) 
- - - 12.6 18.7 - 14.3 21.3 16.2 

Petrol blend 
consumption 

(kg/h) 
1.0 1.2 0.8 - - - - - - 

 
During the 3rd step the environmental impacts are selected and, after classification and characterisation, the 
inventory data are converted in few numeric indexes. Each index represents an environmental impact (or 
effect) also called impact category. In this study, the Recipe (Goedkoop et al., 2008) characterisation methods 
was used and the following impact categories were evaluated: climate change (CC), ozone depletion (OD), 
particulate matter formation (PM), terrestrial acidification (TA), freshwater eutrophication (FE), marine 
eutrophication (ME), mineral depletion (MD) and fossil depletion (FD). 

231



3. Results and discussion 

Table 3 shows the comparison among the three different harvesting systems. More in details, the absolute 
values for the three harvesting systems and the impact variation respect to HS-TR (the harvesting system in 
which the extraction is carried out with tractor) are reported.  
For impact categories such as marine eutrophication the variation among the logging systems is limited, while 
for others (e.g., metal depletion) the differences are wider. 

Table 3:  Environmental impact assessment: Absolute values and comparison. 

Impact category Unit 
HS-TR 
(Site A) 

HS-SK 
(Site B) 

HS-CR 
(Site C) 

Value Value ∆ Value ∆ 
Climate change kg CO2 eq 8.57 8.04 -6% 10.46 22% 
Ozone depletion mg CFC-11 eq 1.42 1.27 -11% 1.66 17% 

Terrestrial acidification kg SO2 eq 0.026 0.025 -3% 0.032 26% 
Freshwater eutrophication g P eq 0.352 0.496 41% 0.563 60% 

Marine eutrophication kg N eq 0.0044 0.0047 8% 0.0047 8% 
Particulate matter formation kg PM10 eq 0.011 0.011 1% 0.015 31% 

Metal depletion kg Fe eq 0.207 0.439 112% 0.499 141% 
Fossil depletion kg oil eq 2.662 2.440 -8% 3.174 19% 

 
The harvesting system carried out in the Site C (HS-CR) and characterised by extraction with cable crane 
shows the highest environmental impact for all the evaluated impact categories except for ME, where the 
higher impact is related to harvesting system 2 characterised by the skidder use. This latter shows the best 
performance for CC, OD, TE and FD with an impact reduction respect to harvesting system 1 ranging from -
3% to -11%.  
 

 

Figure 2: Comparison among the different harvesting systems (for the different impact categories the unit of 
measure of the score are reported in the X- axe.  

Among felling, bunching and extraction, this latter represents the logging operation responsible for the highest 
proportion of the impact, except for ME where the most impacting operation is felling. For HS_CR, the higher 
impact arises mainly from the extraction carried out by means of cable crane; this operation involves an 
impact higher than the sum of bunching and extraction in the other two harvesting systems. Although with 
variable relevance for the different operations, the main environmental hotspots are: 

0

2

4

6

8

10

12

14

16

H
S_

TR

H
S_

SK

H
S_

CR

H
S_

TR

H
S_

SK

H
S_

CR

H
S_

TR

H
S_

SK

H
S_

CR

H
S_

TR

H
S_

SK

H
S_

CR

H
S_

TR

H
S_

SK

H
S_

CR

H
S_

TR

H
S_

SK

H
S_

CR

H
S_

TR

H
S_

SK

H
S_

CR

H
S_

TR

H
S_

SK

H
S_

CR

kg CO2 eq mg CFC-11 eq kg SO2 eq x
100

g P eq x 10 g N eq g PM10 eq kg Fe eq x 10 kg oil eq

Climate
change

Ozone
depletion

Terrestrial
acidification

Freshwater
eutroph.

Marine
eutroph.

Particulate
matter form.

Metal
depletion

Fossil
depletion

Sc
or

e

Felling Bunching Extraction

232



- Fuel consumption, above all for OD and FD (>95% of the total impact) but also for PM, TA and TE 
(from 25-30% of the total impact), 

- Lubricant consumption is relevant for felling (e.g., from 33% to 52% for CC, PM, TA and TE) when 
vegetable oil is consumed, while is negligible (<1% in all the evaluated impact categories) in 
bunching and extraction where fossil lubricant is consumed, 

- Machinery manufacturing, maintenance and disposal for mineral depletion (MD) impact category, 
- The emissions related to fuel combustion in the engine of chainsaw, tractor, skidder and cable yarder 

show a different role between felling, where petrol and vegetable oil are used, and bunching and 
extraction, in which there is the consumption of diesel and fossil lubricant. For felling, these 
emissions are relevant for FE and CC (about 40%). For the operation carried out by machines 
equipped with a diesel engine, combustion emissions are the main hotspot for CC, TE and ME (about 
75-85%). 

Figure 3 shows the environmental hotspots for the extraction operation carried out in HS-CR with cable crane; 
for this logging operation, the production of cable for forestry operation (substituted every 2 years) is 
responsible for 53% of Metal Depletion and 30% of Freshwater Eutrophication (due to mine operations). 
Nevertheless, considering the three whole logging systems (HS_TR; HS_SK; HS_CR) cable production 
involves a negligible environmental impact for all evaluated impact categories. 
 

 

Figure 3: Environmental hotspots for the extraction with cable crane.  

4. Conclusions 

This study evaluated, using the LCA approach, the environmental impact of three different logging systems (or 
harvesting systems) for wood extraction in Southern Italy (Calabria Region). The compared harvesting 
systems were monitored over an area of about 35 ha and primary data were collected. The cable logging 
system, typically carried out on steep slopes and other rough terrain, shows the highest environmental impact, 
while the use of tractor and skidder achieve better environmental performances. Nevertheless, despite its 
higher environmental impact, cable extraction is a desirable alternative on sensitive sites with high slope 
where tractors and skidder cannot be used. In conclusion, this results bring a new and important perspective 
to classic agricultural and forestry engineering and allows placing forest operations within a wider context. 

Acknowledgment 

This study is a part of the project Project “ALForLab” (PON03PE_00024_1) co-funded by the National 
Operational Programme for Research and Competitiveness (PON R&C) 2007-2013, through the European 
Regional Development Fund (ERDF) and national resource (Revolving Fund -Cohesion Action Plan (CAP) 
MIUR). 

0

20

40

60

80

100

Climate
change

Ozone
depletion

Terrestrial
acidification

Freshwater
eutrop.

Marine
eutrop.

Particulate
matter
form.

Metal
depletion

Fossil
depletion

%

Combustion emissions Diesel prod. Mobile cable yarder prod.
Lubricating oil prod. Cable for forestry oper. prod.

233



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