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Peterson 25 1/4 Ton

1973
Designer
Doug Peterson
Builder
Eichenlaub Boat Co.
Association
Quarter Ton Class
# Built
4
Hull
Monohull
Keel
Fin
Rudder
Spade
Construction
strip planked mahog.w/glass

Dimensions

Length Overall
25 0 / 7.6 m
Waterline Length
20 2 / 6.2 m
Beam
8 0 / 2.4 m
Draft
4 5 / 1.4 m
Displacement
4,700 lb / 2,132 kg
Ballast
1,900 lb / 862 kg (Lead)
Drawing of Peterson 25 1/4 Ton

Rig and Sails

Type
Sloop
Reported Sail Area
262′² / 24.3 m²
Total Sail Area
269′² / 25 m²
Mainsail
Sail Area
106′² / 9.9 m²
P
28 3 / 8.6 m
E
7 6 / 2.3 m
Air Draft
?
Foresail
Sail Area
163′² / 15.2 m²
I
31 8 / 9.7 m
J
10 3 / 3.1 m
Forestay Length
33 4 / 10.2 m

Auxilary Power

Make
?
Model
?
HP
?
Fuel Type
?
Fuel Capacity
?

Accomodations

Water Capacity
?
Holding Tank Capacity
?
Headroom
?
Cabins
?

Calculations

Hull Speed
6.7 kn
Classic: 6.03 kn

Hull Speed

The theoretical maximum speed that a displacement hull can move efficiently through the water is determined by it's waterline length and displacement. It may be unable to reach this speed if the boat is underpowered or heavily loaded, though it may exceed this speed given enough power. Read more.

Formula

Classic hull speed formula:

Hull Speed = 1.34 x √LWL

A more accurate formula devised by Dave Gerr in The Propeller Handbook replaces the Speed/Length ratio constant of 1.34 with a calculation based on the Displacement/Length ratio.

Max Speed/Length ratio = 8.26 ÷ Displacement/Length ratio.311
Hull Speed = Max Speed/Length ratio x √LWL

6.65 knots
Classic formula: 6.03 knots
Sail Area/Displacement
14.9
<16: under powered

Sail Area / Displacement Ratio

A measure of the power of the sails relative to the weight of the boat. The higher the number, the higher the performance, but the harder the boat will be to handle. This ratio is a "non-dimensional" value that facilitates comparisons between boats of different types and sizes. Read more.

Formula

SA/D = SA ÷ (D ÷ 64)2/3

  • SA: Sail area in square feet, derived by adding the mainsail area to 100% of the foretriangle area (the lateral area above the deck between the mast and the forestay).
  • D: Displacement in pounds.
14.94
<16: under powered
16-20: good performance
>20: high performance
Ballast/Displacement
40.4
>40: stiffer, more powerful

Ballast / Displacement Ratio

A measure of the stability of a boat's hull that suggests how well a monohull will stand up to its sails. The ballast displacement ratio indicates how much of the weight of a boat is placed for maximum stability against capsizing and is an indicator of stiffness and resistance to capsize.

Formula

Ballast / Displacement * 100

40.43
<40: less stiff, less powerful
>40: stiffer, more powerful
Displacement/Length
253.0
200-300: moderate

Displacement / Length Ratio

A measure of the weight of the boat relative to it's length at the waterline. The higher a boat’s D/L ratio, the more easily it will carry a load and the more comfortable its motion will be. The lower a boat's ratio is, the less power it takes to drive the boat to its nominal hull speed or beyond. Read more.

Formula

D/L = (D ÷ 2240) ÷ (0.01 x LWL)³

  • D: Displacement of the boat in pounds.
  • LWL: Waterline length in feet
252.97
<100: ultralight
100-200: light
200-300: moderate
300-400: heavy
>400: very heavy
Comfort Ratio
20.9
20-30: coastal cruiser

Comfort Ratio

This ratio assess how quickly and abruptly a boat’s hull reacts to waves in a significant seaway, these being the elements of a boat’s motion most likely to cause seasickness. Read more.

Formula

Comfort ratio = D ÷ (.65 x (.7 LWL + .3 LOA) x Beam1.33)

  • D: Displacement of the boat in pounds
  • LWL: Waterline length in feet
  • LOA: Length overall in feet
  • Beam: Width of boat at the widest point in feet
20.85
<20: lightweight racing boat
20-30: coastal cruiser
30-40: moderate bluewater cruising boat
40-50: heavy bluewater boat
>50: extremely heavy bluewater boat
Capsize Screening
1.9
<2.0: better suited for ocean passages

Capsize Screening Formula

This formula attempts to indicate whether a given boat might be too wide and light to readily right itself after being overturned in extreme conditions. Read more.

Formula

CSV = Beam ÷ ³√(D / 64)

  • Beam: Width of boat at the widest point in feet
  • D: Displacement of the boat in pounds
1.91
<2: better suited for ocean passages
>2: better suited for coastal cruising

Notes

The first of the Doug Peterson designed 1/4 tonners were built by Carl Eichenlaub at a mid-west factory. The first was ‘El Principio’,
The MG 26 (sold in Europe) is also thought to be from this same design.

Other 1/4 ton designs from Peterson; A very imprecise time line:

1975: Similar and from same molds by Posiedon Marine, some of which were sold as kits.
Also built by Chita Inc. of Japan, Chaser in Canada.. Ended up in possession of Bayliner, (US 25).

1976: New design, ‘Star Eyed Stella’ (4th, Int. 1/4 ton cup of 1976.). (Peterson design #39)

1978: Daggerboard version. SEAWAY 25 (Stephenson Marine in Australia.)

1978: New design for Chita Inc.
1980 ?: Design for Navimor of Poland (CONRAD 560)

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Measurements:

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