Electrical – State PCE 120 2ORTA User Manual

11

electrIcal

General

The installation must conform with these instructions and the local

code authority having jurisdiction and the requirements of the power

company. In the absence of local codes, the installation must comply

with the current editions of the National Electrical Code, NFPA 70 or

the Canadian Electrical Code CSA C22.1.
An electrical ground is required to reduce risk of electrical shock

or possible electrocution. The water heater should be connected

to a separate grounded branch circuit with over-current protection

and disconnect switch. The water heater should be grounded in

accordance with national and local codes.
Voltage applied to the heater should not vary more than +5% to -10%

of the model and rating plate marking for satisfactory operation.
DO NOT ENERGIZE THE BRANCH CIRCUIT FOR ANY REASON

BEFORE THE HEATER TANK IS FILLED WITH WATER. DOING

SO WILL CAUSE THE HEATING ELEMENTS TO BURN OUT AND

VOID WARRANTY.
The factory wiring is attached to a terminal block within the external

junction box unit. The branch circuit is connected to the terminal

block within this junction box. The water heater should be connected

to a separate, grounded, branch circuit with overcurrent protection

and disconnect switch. The water heater should be grounded in

accordance with national and local codes.

branch cIrcuIt

The branch circuit wire size should be established through reference

to the current edition of NFPA-70, the National Electrical Code

or other locally approved source in conjunction with the heater

amperage rating. For convenience, portions of the wire size tables

from the Code are reproduced here. The branch circuit should be

sized at 125 percent of the heater rating and further increase wire

size as necessary to compensate for voltage drop in long runs.

calculatInG aMperaGe/oVercurrent protectIon

The heaters come from the factory in two configurations:

1. Two wire C-2 circuit for single element heater equipped with a

high limit control, single phase power input.

2. Four wire A-8 circuit for dual element heater equipped with two

high limit controls, single phase or three phase power input.

The heater with dual elements is factory wired for connection to

a three wire, three-phase delta branch circuit, non-simultaneous

operation. In addition a ground conductor is required.
Element connection is for non-simultaneous operation. This means

only one element at a time operates. The wiring diagram, on page

12, shows the heater may be field converted to simultaneous

element operation by moving the red wire on “J” terminal to L1. It is

then possible for both elements to operate at once as determined

by the thermostats. Regardless of element connection the heater

operates in an “unbalanced” fashion.
The heater may be field converted to single-phase operation by moving

the wire on L3 of the terminal block to L2. L3 is not used, see page 12.
The heater, now in single-phase non-simultaneous operation, may

be field-converted to single phase simultaneous operation by moving

the red wire on terminal “J” to L1, see page 12.

This is an example of calculating heater amperage for both types

of element operation. From this, the branch circuit conductor and

overcurrent protection sizing can be established.
The example is of a three-phase 240 volt unit with two, 6 kw

elements. The notations are for units field converted to single-phase.

Check the heater model and rating plate for actual specifications

and substitute those values in the following.

table 3

Non-simultaneous:

(as factory wired)

Simultaneous:

(Field conversion)

3000 : 240 = 12.5 amps*

3000 : 240 = 12.5 amps*

12.5 x 1.73 = 21.6 amps

*NOTE: as a single-phase non-

simultaneous unit.

*NOTE: as a single-phase

simultaneous unit the total is:

12.5 x 2 = 25 amps

The rating of the overcurrent protection should be computed on the

basis of 125 percent of the total connected load amperage. Where the

standard ratings and settings do not correspond with this computation,

the next higher standard rating or setting should be selected.
Portion of Table 310-16 (NFPA-70) follows:

Allowable Ampacities of Insulated Copper Conductors. Not more

than three conductors in Raceway or Cable or Direct Burial (Based

on Ambient Temperature of 30° C, 86° F).
These ampacities relate only to conductors described in Table

310-13 in Code.
For ambient temperatures over 30° C (86° F), see Correction

Factors, Note 13 in Code.
For ambient temperatures over 30° C (86° F), see Correction

Factors, Note 13 in Code.

table 4

Size

Temperature Rating of Conductor

See Table 310-13 in Code

AMG

MCM

60°C

(140°F)

75°C

(167°F)

Types:

RUW, (14-2), T, TW, UF

Types:

RH, RHW, RUH, (14-2),

THW, THWN, XHHW, USE

18

16

14

- - -

- - -

15

- - -

- - -

15

12

10

8

20

30

40

20

30

45

6

4

3

55

70

80

65

85

100

Portion of Table 310-18 follows:

Allowable Ampacities of Insulated Aluminum and Copper -Clad

Aluminum Conductors.
Not more than three conductors in Raceway or Cable or Direct Burial

(Based on Ambient Temperature of 30° C, 86° F. These ampacities

relate only to conductors described in Table 310-13 in Code.
For ambient temperatures over 30° C (86° F), see Correction Factors,

Note 13 in Code.

table 5

Size

Temperature Rating of Conductor

See Table 310-13 in Code

AMG

MCM

60°C

(140°F)

75°C

(167°F)

Types:

RUW, (12-2), T, TW, UF

Types:

RH, RHW, RUH, (12-2),

THW, THWN, XHHW, USE

12

10

15

25

15

25

8

6

30

40

40

50

4

3

55

65

65

75

2

1

75

85

90

100