Install water piping, Gv90, Boiler manual – Weil-McLain GV90+ User Manual

Part number 550-142-054/0411

15

GV90+

gas

-

fired

water

boiler

— Boiler Manual

Install water piping

(continued)

System water piping methods

Most piping methods shown in this manual use

primary/secondary connection to the boiler loop.

These designs ensure proper flow through the

GV90+ boiler, for the most efficient and reliable

operation of the boiler and the heating system.

For other piping methods, consult your local Weil-

McLain representative.

Circulators

Do not remove either of the GV90+ internal pumps

for use elsewhere in the system. Both pumps are

required for proper operation. Removing a pump

will cause the boiler to malfunction. Substantial

property damage could result.

Never install another pump in series with the

GV90+ boiler

. Forced flow can cause improper op-

eration of the boiler controls. Substantial property

damage could result.

Failure to comply could result in unreliable perfor-

mance and nuisance shutdowns from insufficient

flow.

Circulator flow rate

Size system circulators based on the flow rate required to achieve

the temperature change needed. You can closely estimate tem-

perature rise (or drop) through a circuit by using the following

formula, where TD is temperature rise (or drop), FLOW is flow

rate (in gpm), and BTUH is the heat load for the circuit:

FLOW

=

BTUH

—–—–—–—–

TD x 500

Examples

:

Consider a system loop for a system with total heating load equal

to 210,000 Btuh. The desired temperature drop through the system

piping is 20°F. Then the required flow rate is:

FLOW

=

210,000

—–—–—–—–

20 x 500

=

21 gpm

SIMPLIFIED: For 20° temperature drop, FLOW = MBH / 10.

Circulator head requirement

The circulator must be capable of delivering the required flow

against the head loss that will occur in the piping. Determine

the pipe size needed and the resultant head loss using accepted

engineering methods. The simplified pipe sizing here is limited

to residential systems, and does not include systems with fan coil

units or radiant tubing.

The following simplified method for pipe and cir-

culator sizing must be limited to residential applica-

tions using baseboard (finned or cast iron), cast iron

radiators or convectors. DO NOT apply for radiant

heating, fan coil units or commercial installations.

Simplified pipe/circulator selection

1. Install the boiler and piping using the recommended piping

layouts in this manual.

2. Size the piping and components for each circuit in the space

heating system using Figure 16.

At the flow rates listed, the

head loss in all piping will be 0.04 feet per foot of pipe.

a. Determine the heating load (Btuh) for each circuit.
b. Calculate the flow rate for each circuit using its load.

To use a 20°F temperature drop, just divide the

MBH (1,000’s of Btuh) by 10.

Example — Flow for 20°F temp drop with 35,000

Btuh:

FLOW = 35 MBH / 10 = 3.5 gpm

c. Find the pipe size in Figure 16 that has a max flow rate

just larger than that required for the circuit.

d. Find the total equivalent length (TEL) of the circuit.

TEL accounts for losses through fittings and valves by

using the equivalent length of pipe that would cause

the same head loss. Add these numbers to the measured

length of the circuit to find TEL in feet.

TEL is usually close to 1.5 times the length of the

circuit for residential baseboard, radiator or convec-

tor applications.

e. Measure the length of each circuit from the circulator

outlet back to its inlet. Then multiply this length times

1.5 to get the approximate TEL of the circuit.

f. Find the head loss for each circuit:

TEL = 1.5 X Circuit Length

(feet)

HEAD = TEL X 0.04

(feet water column)

g. NOTE: Size system header piping for the total flow of

all connected zones.

3. Example:

a. For a circuit with heating load = 45,000 Btuh (= 45

MBH). Measured length of circuit is 88 feet.

b. Flow = 45 MBH / 10 = 4.5 gpm.
c. TEL = 1.5 x 88 feet = 132 feet.
d. From Figure 16, select 1" pipe (max flow = 8 gpm).
e. Head loss = TEL x 0.04 = 132 x 0.04 = 5.28 feet.
f. Select a circulator that can deliver at least 4.5 gpm at a

head of 5.28 feet. (Read the NOTICE below.)

To use this method, limit the flow through ¾"

finned-tube baseboard to 3.9 gpm, or use 1" base-

board and limit flow to 7.1 gpm. If the total load

of the circuit requires more flow, split the circuit

into two or more.

Figure 16

Flow rates for 0.04 feet head loss per foot of

copper pipe (based on water at140°F)

Pipe size

(inches)

MAX Flow rate (GPM)

@ 0.04 feet per foot

Pipe size

(inches)

MAX Flow rate (GPM)

@ 0.04 feet per foot

¾

4

2

45

1

8

2½

75

1¼

14

3

140

1½

22

4

290