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DOLMAR PS5105C
General information
Technical data
Producer / distributor
Economy / calculation
Chainsaws for motor manual harvesting and tree care
Power
kW:
2.8
CC:
50
Cutting lengths:
38-45 cm
Motor
Single-cylinder two-stroke engine with elec. ignition system
Power
2.8 kW
Cubic capacity
50.0 ccm
Fuel tank capacity
0.470 Liter
Lubricant tank capacity
0.270 Liter
Cutting lengths
38-45 cm
Division of chain
0,325
Chain lubrication
Automatisch
Chain brake
Automatically and manually triggered
Optional equipment
-
Operating weight
5.4 kg
Fuel consumption
1.4 l/h
DOLMAR GmbH.
Jenfelder Straße 38
D-22045 Hamburg
T: 0049-40-66986-0
F: 0049-40-66986-355
E: service@dolmar.com
I: www.dolmar.de
Makita Werkzeug Ges.m.b.H.
Airportstraße 4
A-2401 Fischamend
T: +43 (0) 2232 / 777 00
E: verkauf@makita.at
Type in your own numbers here and press
Annual workload
Annual workload
Number of operating hours in which a machine is used per year.
The annual workload cannot be higher than the maximum annual workload. If a bigger value is beeing put in, the maximum annual workload will be used by the program.
hrs.
BFW
KWF
FAO
Costs per hour
Costs per hour
In this calculation only direct costs for a machine/equipment are retrieved. This does not include labour costs for operation or transfer of machinery nor costs for administration, buildings etc. of an enterprise.
Depreciation
Cost of depreciation per operating hour = Pr / (Nr * JA)
Pr
...Price of machinery/equipment
Nr
...Reduced time of economic use in years
JA
...Annual workload in operating hours
Interest
Interest
Interest is calculated for one half of the price of the machinery for a reduced time of economic use. This ensures an interest which is the same for all years of use.
Expense of interest per operating hour = (Pr / 2) * (p / 100) * (Nr / Hr)
Pr
...Price
p
....Interest rate in percent
Nr
...Reduced time of use in years
Hr
...Reduced operating hours of use
Repair cost
Cost of repair
The calculation is done using a coefficient deduced from empiric values. This coefficient is the relation between cost of repair and the price of the new equipment/machinery for maximum operating hours of economic use. For a lower annual workload the cost of repair is reduced by a factor consisting of reduced hours of use divided by maximum hours of use. This takes the fact of a lower total amount of operating hours and therefore lower repair costs into consideration.
Cost of repair per operating hour = (Pr / H) * (Hr / H) * r
Pr
...Price of equipment/machinery
H
....Maximum hours of economic use
Hr
...Reduced duration of use in operating hours
r
....Cost of repair price coefficient
Fuel and lubrification
Depreciation chain
Depreciation swivel blade
Suggested price
Suggested price
Suggested prices are equivalent to depreciation sums. Put in this price including expenses for parts like tires, cables or tools. For example for chainsaws prices are to be put in inclusive expenses for swivel blade and sawing chain.
For calculation the expenses for these parts are subtracted from the depreciation sum and calculated seperately. Reason for this are differences in the maximum number of hours of economic use.
In case of sled winches suggested price is given without cables, as cable equipment can vary very much in quantity and material. In this case you should put in your own price without cables.
¤
Max. operating hours of economic use
Max. operating hours of economic use
Total number of operating hours for a device at maximum annual workload and economic use.
hrs.
Max. years of economic use
Maximum economic useful life
Useful life in years, in which the machine can be operated with economic success.
The Maximum economic useful life is a hypothetical value which is only valid for an annual workload of null hours. Using an elliptic equation a reduced useful life ist derivated and used for further calculation.
years
Maximum annual workload
Maximum annual workload
Highest possible number of operating hours which one can use a machinery/equipment, independent from the situation of the own enterprise.
If this value is higher than the maximum operating hours of economic use then the maximum annual workload is set to the value for maximum operating hours of economic use, because our calculating routine cannot deal with a useful life lower than one year.
hrs.
Interest rate
Interest rate
Annual interest for the investition expressed in percent.
%
Cost of repair as a prize coefficient
Cost of repair as a price coefficient
The calculation is done using a coefficient deduced from empiric values. This coefficient is the relation between cost of repair and the price of the new equipment/machinery for maximum operating hours of economic use. For a lower annual workload the cost of repair is reduced by a factor consisting of reduced hours of use divided by maximum hours of use. This takes the fact of a lower total amount of operating hours and therefore lower repair costs into consideration.
Required garage space
Required garage space
Required space of machine/equipment in cubic meters.
If null, this number will be calculated if any values for length, width and height are found in the database.
m³
Cost of building per cubic meter/yr.
Cost of Building
Cost of Building per cubic meter and year in ¤.
¤/m³
Fuel consumption
l/h
Fuel price
¤/l incl. VAT
Cost of lubrification as pct. of fuel price
Percentage of lubrification
Percentage of fuel cost per operating hour used for calculation of lubrification cost per operating hour.
%
Suggested price
¤
Max. operating hours of economic use
hrs.
Suggested price
¤
Max. operating hours of economic use
hrs.
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