WMB8000 Series

WebMaster Multi I/O Boiler Controllers

Part 1. General

1.1 Scope

A. This section describes the requirements for a multiple input/output

boiler controller.

B. Under this item, the contractor shall furnish and install the
multi I/O boiler control equipment and accessories as indicated on
the plans and as herein specified.

1.2 Submittals

A. The following information shall be included in the

submittal for this section:

1. Data sheets and catalog literature for the WebMaster multi

I/O boiler controller and sensors.

2. Interconnection and dimensional drawings.

3. List of spare parts

Part 2. Products

2.1 Multi I/O boiler controller

A. The multi I/O boiler control system shall be a capable of measuring

conductivity and temperature of up to four boilers. The conductivity
sensors shall be a contacting style. All sensors shall have integral
signal conditioning. Additional inputs shall include an interlock,
two water meter inputs, eight optional 4-20 mA inputs and six
optional digital inputs. Outputs shall include eight mechanical
relays, and four optional 4-20 mA outputs. Digital communications
shall be via USB, Ethernet, and/or optional modem. Up to 16
controllers may be networked together over Ethernet. Integration
with DCS, SCADA system or building energy management systems
shall be possible using the optional Modbus TCP/IP feature. The
controller shall be accessible via the Internet for configuring, data
logging, and control of relay outputs. The controller shall provide
notification of alarm conditions via relay, pager, and/or email.

B. Control Module:
1. Enclosure: Fiberglass, NEMA 4X, lockable hinged door
with clear window.

2. Power: 100-240 VAC  10%, 50/60 Hz

3. Inputs:
Input signals STANDARD
Water meter Contactor: Isolated dry contact (relay, reed switch or
Hall Effect) 0-10 Hz, 50 msec minimum width
Paddlewheel Water Meter: Isolated dry contact (relay, reed switch
or Hall Effect) 0-300 Hz, 1.5 msec minimum width
Interlock: Isolated dry contact (relay, reed switch or Hall Effect) 0-
10 Hz, 50 msec minimum width
Input signals OPTIONAL
Digital Inputs (1-4) Isolated dry contact (relay, reed switch or Hall
Effect) 0-10 Hz, 50 msec minimum width
Digital Inputs (5-6) Isolated dry contact (relay, reed switch or Hall
Effect) 0-300 Hz, 1.5 msec minimum width
Point Level Switch: Isolated dry contact (relay, reed switch or Hall
Effect)
Flow Feedback: Isolated dry contact (relay, reed switch or Hall
Effect)
Analog Inputs (1-8) 4-20 mA: 2-wire or 3 -wire, internally
powered by 24 VDC, 25 ohm input resistance, 1000 ohm
maximum load.
Sensor STANDARD (1) Signal (isolated) ±1.5V, Temp (isolated)
1K
Sensor OPTIONAL (3) Signal (isolated) ±1.5V, Temp (isolated)
1K

4. Outputs:
STANDARD
Mechanical relays: At 115 VAC, 10 amp (resistive), 1/8 HP
At 230 VAC, 6 amp (resistive), 1/8 HP
R1-R4 are fused together as one group, total current not to exceed
5.5A
R5-R8 are fused together as one group, total current not to exceed
5.5A
Relays may switch mains voltage or may be dry contact, according
to model number. Powered relays have NO and NC terminals
available. Only powered relays are fused.
Digital: USB, Ethernet 10 Base T
OPTIONAL
4-20 mA (1-4): Isolated, 500 ohm maximum resistive load,
internally powered
5. Software features:

Conductivity control relays shall feature adjustable control

direction and dead band.

Chemical feed shall be selectable from blowdown and feed,

feed as a percentage of blowdown, feed as a percentage of
time, and feed based on a water meter contactor input.

A self test shall be available to verify the integrity of the

control module’s sensor input circuitry.

A reminder for electrode calibration shall be available.

Control of a cooling tower, boiler, closed loop, or process

shall be possible using a single controller.

Manual activation of the relays shall be easily

accomplished via the keypad, or a PC.

A maximum output on-time shall be available on the

control relays to prevent runaway control.

Any relay may be reconfigured to any one of a number of

control algorithms, responding to the signal from any input
desired.

The optional analog inputs shall be configurable for level

sensors, corrosion monitors, or any other type of
transmitter, providing appropriate units of measure and
scaling.

The optional digital inputs shall be configurable for level

switches, chemical feed verification switches or generic
interlock operation.

Status reports and data files shall be sent automatically via

email on either a cyclical basis or for a specific date range.

The controller set points may be entered by downloading

them from one controller, and uploading them into another
controller.
 Access to the controller shall be possible using an USB
connection, Ethernet, direct modem-to-modem, via the
Internet, or via the local display and keypad,
simultaneously if desired.

No proprietary software shall be required on the user’s

computer to communicate with the controller, or to view or
change set points.

The controller software shall be able to be upgraded

remotely via the Internet.

C. Sensors:

Contacting Conductivity
1. Operating principle: The conductivity sensor shall be
driven with a low voltage AC signal, and the return signal
voltage will vary with the conductivity of the intervening
solution. The temperature sensor within this sensor
compensates for the effect of temperature on the
conductivity signal.
2. Materials of construction: 316 SS, PEEK
3. Process connections: ¾” NPT
4. Temperature range: 32-392 F, 0-200 C
5. Pressure range: 0-250 psi

D. Controller and Sensor Performance

1. Range: 0 to 10,000 S/cm conductivity

2. Accuracy: 1 S/cm conductivity
3. Resolution: 1 S/cm conductivity
4. Maximum separation between controller and sensor shall
be 250 feet

E. Indication

1. Graphic User Interface

A 64 x 128 Pixel Backlit LCD Graphics Module display

shall indicate the process values, and the status of outputs
and alarms.

Eight LED lamps shall indicate the on/off status of the

control outputs.
 F. Equipment

The multi I/O boiler controller shall be a Walchem WebMaster

WMB8000 series.

Part 3. Operator Functions

3.1 Calibration

A. The conductivity electrode calibration shall be a one point

calibration, utilizing a solution of a known conductivity.

B. Three levels of access codes shall be available to protect all

set points and calibrations, while allowing the user to view
any set point.

3.2 Control Module Function Details

A. The conductivity control outputs shall be on/off control

with adjustable dead band.

B. There shall be five options for blowdown control:

continuous sampling, intermittent sampling with fixed
blowdown time, intermittent sampling with blowdown time
proportional to the deviation from set point, and the above
intermittent sampling modes with two distinct frequencies
of sampling based on the time of day.

C. The conductivity control directions shall be selectable.

D. The inhibitor chemical feed output shall be on/off control

with four choices of feed modes.

E. All control relays shall have limit timers to prevent

runaway control.

Part 4. Execution

4.1 Installation

A. The sensors shall be installed in a location where they will always

remain immersed in the sample.

A. The sensors shall be installed in a location where there is good

solution movement and where they will respond rapidly to changes
 B. The sensor cables shall be routed such that they are separated from
any AC voltage by at least 6 inches.

C. If the sensor cable needs to be extended beyond the standard

length, then 24 AWG, 3 twisted pair, shielded cable shall be
utilized.

E. If the optional 4 – 20 mA output or water meter contactor are

installed, then 22-26 AWG, twisted pair, shielded cable shall be
utilized.

F. The sample line shall be tapped from the skimmer line of the
boiler, and be a minimum of ¾” pipe up to the location of the
sensor, with sufficient back-pressure provided by a valve or orifice
plate downstream of the sensor, to prevent flashing at the sensor.

Part 5. Warranty

5.1 Terms

A. The manufacturer of the above specified equipment shall guarantee

equipment of its manufacture, and bearing its identification to be free from
defects in workmanship and material for a period of 24 months for
electronics and 12 months for sensors and mechanical parts from date of
delivery from the factory or authorized distributor under normal use and
service and otherwise when such equipment is used in accordance with
instructions furnished by the manufacturer and for the purposes disclosed
in writing at the time of purchase, if any.

B. In the event a component fails to perform as specified and having

been returned to the manufacturer transportation charges prepaid, and is
proven defective in service during the warranty period, the manufacturer
shall repair or replace the defective part. Replaceable elastomeric parts
and glass components are expendable and are not covered by any
warranty.

Part 6. Options

6.1 Related Equipment

A. Solenoid valve or motorized ball valve for blowdown control

B. Flow control valve or orifice plate for providing back-pressure and
to control rate of blowdown
C. Water meter for makeup flow
D. Level switch or level transmitter for chemical level monitoring
E. Metering pumps for chemical feed
 F. Sample cooler with pressure reduction for systems over 250 psi.

Part 7. Spare Parts

7.1 Recommended Spare Parts

A. 102833 Fuse, F1, 1.6 amp

B. 102834 Fuse, F2 and F3, 6.3 amp
C. 190768 Electrode, conductivity