Continuous Slot Pvc Well Screen

Posted on 11-05-2021 by admin

Continuous Pvc Heart
Continuous Slot Pvc Well Screen
10 Slot Pvc Well Screen
Well Screens Pvc

The following collapse formulae provide the user practical tools to estimate collapse strengths of various types of casing and screen. It is important that one pays particular attention to the material and manufacturing standards for the casing and screen specified so that acceptable tolerances are considered and adequate safety factors applied.

Timoshenko’s Formula, shown below, is commonly accepted to be the most accurate method available for estimating the collapse strength of steel pipe with diameter/thickness ratios common to those used in the construction of water wells.

Slot sizes 8-10-12-15-18-20-30-40-60 list price effective 3/17/2019 pvc plastic well screens schedule 40 sawed slot type not all slot sizes available for all pipe sizes other slot sizes available upon quotation 4” pallet quantity pricing on page 3 note: please specify 6 row or 8 row for 5' note: if 5' screen has 6 rows our open area chart is. Well Screens. Well screens are filtering devices used to prevent excess sediment from entering the well. They attach to the bottom of the casing, allowing water to move through the well, while keeping out most gravel and sand. The most popular screens are continuous slot, slotted pipe, and perforated pipe.

Where: P_cr = Theoretical collapse strength of a perfectly round tube

Where: P_e = Collapse pressure with ellipticity (psi)

E = Young’s Modulus for Steel (3×10⁷)

u = Poisson’s Ratio (0.3)

D_o = Outside diameter of casing (inches)

t = Wall thickness (inches)

S = Yield strength (mild steel = 35,000 psi)

e = ellipticity, frequently assumed as 0.01

Shutter Screen, sometimes referred to as Louver Screen, actually has a greater collapse strength than casing of the same diameter and wall thickness due to the corrugating effect of the louvers. As a result, shutter screen’s collapse strength is up to 60% stronger than the pipe from which it was made.

Factors which determine the extent of increased strength include: the thickness/diameter ratio, slot size, slot length, and number of perforations. Modifications of the formula above can provide an estimate for the collapse strength of shutter screen.

P_s = P_e 1.20 P_f = P_e 1.35 P_sf = P_e 1.60

Where: P_e = Collapse pressure with ellipticity (psi)

P_s = Collapse pressure of Standard shutter screen (psi)

P_f = Collapse pressure of Ful Flo shutter screen (psi)

P_sf = Collapse pressure of Super Flo shutter screen (psi)

Collapse strength of continuous slot screen is dependent on diameter of the screen, size, shape, and material type of wire used in its manufacture, and the slot size. The following formula can be used to estimate the collapse strength of continuous slot screen.

Where: I = Moment of Inertia (in)⁴

Where: P_cs = Collapse pressure of continuous slot screen (psi)

E = Young’s Modulus for Steel (3×10⁷)

w = Width of wire on external face (inches)

s = Slot width of screen (inches)

D = Mean diameter of the screen (inches)

h = Wire height (inches)

b = Width of minor base of wire (inches)

The following is the ASTM F 480 formula for determining the collapse strength of PVC pipe manufactured in accordance with said standards.

Where: P_c = Collapse pressure of PVC pipe (psi)

E = Young’s Modulus for PVC (4×10⁵)

u = Poisson’s Ratio (0.33)

D_o = Outside diameter of pipe (inches)

t = Wall thickness (inches)

Another formula used to determine the collapse strength of PVC is shown below. This formula, is more conservative than the ASTM formula. However, since most PVC materials are made to minimum allowable wall thickness rather than nominal sizes, it may provide a more accurate estimate of actual collapse strength.

Physical properties of PVC vary with temperature. The values obtained with these formulas are consistent with a temperature of 70°F. As the temperature rises, PVC working strength decreases by approximately 0.5 psi per degree Fahrenheit above 70°F. Obviously, much care must be taken during cementing operations or in other high temperature environments.

Weight of a blank casing, or pipe, can be found using the following formula.

Where: W = Weight of casing (lbs/ft)

D_o = Outside diameter of casing (inches)

t = Wall thickness (inches)

m = Variable for casing material: Carbon Steel = 10.68;

Stainless Steel = 10.93; PVC = 2.04

Users must determine the yield strength for casing and screen. This measures the point at which the casing or screen will be damaged by deformation due to the stress of the hanging weight. This calculation is used to evaluate suitability of use relative to expected loads.

(ignoring buoyant forces) is determined by the following formula:

Where: Y_p = Yield point of casing (lbs)

S = Yield strength (mild steel = 35,000 psi)

D_o = Outside diameter of casing (inches)

t = Wall thickness (inches)

= pi or 3.14159

For shutter type screen, this formula can be modified as shown here:

Where: Y_sp = Yield point of slotted pipe or shutter screen (lbs)

Y_p = Yield point of casing (lbs) from above

l = Slot length perpendicular to the axis of the pipe (inches)

n = Number of circumferential slots

D_o = Outside diameter of casing (inches)

t = Wall thickness (inches)

= pi or 3.14159

For continuous slot screen we must determine the yield point for the screen and adjust for the joint connecting the screen body to the welding ring. This establishes the “safe hanging weight” of the screen. This is accomplished with the formula shown here:

Where: Y_cs = Yield point of continuous slot screen (lbs)

S = Yield strength (mild steel = 35,000 psi)

r = Radius of rods or diameter/2 (inches)

n = Number of rods

j = Joint efficiency of connection between screen and weld

ring (generally assumed to be 0.70)

sf = Safety factor (assumed for this example at 0.5)

= pi or 3.14159

Well Production at AWWA Standard of 1.5 feet per second: To calculate the flow in gallons per minute per foot of screen, first calculate the percentage of open area of the screen, then use that result to calculate the flow. Determine the open area for the type of screen used then convert area to a percentage. Then multiply the percentage by 12 inches per foot, by the outside diameter, by pi, and the conversion constant of 4.8:

To calculate the flow in gallons per minute per foot of screen, first calculate the percentage of open area of the screen, then use that result to calculate the flow. Determine the open area for the type of screen used then convert area to a percentage. Then multiply the percentage by 12 inches per foot, by the outside diameter, by pi, and the conversion constant of 4.8:

Calculation of percent of open area:

Where: A_p = Open Area (percent%)

A = Open Area (sq.inches)

D_o = Average outside diameter of screen (inches)

Calculation of open area for shutter type screen:

Continuous Pvc Heart

Where: A = Open Area (sq.inches)

l = Slot length (inches)

o = Width of slot opening (inches)

n = Number of slots per foot

Calculation of the flow in gallons per minute per foot of screen:

Where: F = Flow (gpm/ft of screen)

A_p = Open Area (percent%)

D_o = Average outside diameter of screen (inches)

= pi or 3.14159