We can use the following formula to calculate the weight of solids in the suspension:

W = V * (Gs / (1 + e)) * (H - H') * ρw

where:

W = weight of solids in the suspension
V = volume of suspension (1000 ml = 1 L)
Gs = specific gravity of solids (2.68)
e = void ratio (assumed to be zero for a uniform soil suspension)
H = initial depth of suspension (1000 mm)
H' = final depth of suspension (10.5 cm = 0.105 m)
ρw = unit weight of water (9.81 kN/m3)

Plugging in the values, we get:

W = 1 * (2.68 / (1 + 0)) * (1 - 0.105/1000) * 9.81
W = 0.239 kN

Next, we can use the following formula to calculate the effective diameter at the 30 minute mark:

d10 = K * (H - H') / log10(H / H')

where:

d10 = effective diameter corresponding to the 30 minute reading
K = constant based on the hydrometer used (assumed to be 0.1 for this problem)
H = initial depth of suspension (1000 mm)
H' = final depth of suspension (10.5 cm = 0.105 m)

Plugging in the values, we get:

d10 = 0.1 * (1000 - 0.105) / log10(1000 / 0.105)
d10 = 0.026 mm

Finally, we can use the following formula to calculate the percentage of particles finer than the effective diameter:

% finer = (1 - (d10 / D50)^2) * 100

where:

D50 = diameter corresponding to 50% finer on the particle size distribution curve (assumed to be 10 times the effective diameter for this problem)

Plugging in the values, we get:

D50 = 10 * d10
D50 = 0.26 mm

% finer = (1 - (0.026 / 0.26)^2) * 100
% finer = 0.99%

Therefore, the weight of solids in the suspension is 0.239 kN, the effective diameter corresponding to the 30 minute reading is 0.026 mm, and the percentage of particles finer than this size is 0.99%.