METROLOGIC INSTRUMENTS, INC.
MX001 Industrial Control Interface
Installation and User’s Guide
TABLE OF CONTENTS
Introduction................................................................................................1
Opening the MX001 Industrial Control Box...............................................2
Internal Components.................................................................................3
LED Status Indicators ...............................................................................4
Configuring the MX001 for 115 or 230 Volt Operation
USA: 115V Operation............................................................................5
USA: 230V Operation............................................................................6
Europe/Asia:230V Operation.................................................................7
Europe/Asia: 115V Operation................................................................8
Locating the Three Strain Reliefs and the Signal Connector....................9
Connecting External Wiring to the MX001................................................9
Power Requirements for the MX001.........................................................9
Connecting the AC Power Input Cable ...................................................10
Connecting the TRIAC Controlled Power Output Cable.........................11
Temporarily Disabling the TRIAC Output................................................12
Sensor Support .......................................................................................13
Connecting the Sensor........................................................................14
Temporarily Disabling the Sensor and/or Sensor Alarm.....................14
Sensors Powered Independently that Provide
either 12V, 5V or a 10mA DC Output Signal.......................................15
Sensors that Provide Switch Closures or Relay Type Output.............17
Low Voltage Self-Contained DC Sensors with
a Current Sinking Output.....................................................................18
Low Voltage Self-Contained DC Sensors with
a Current Sourcing Output..................................................................19
Universal Self-Contained Sensors that Provide
a Single Pole/Double Throw (SPDT) Relay Output.............................20
ii
TABLE OF CONTENTS
Sensors Powered Independently that Provide Either
12V, or a 10mA DC Output Signal with a Sensor Alarm.....................22
Sensors that Provide Switch Closures or Relay Type
Output with a Sensor Alarm.................................................................24
Low Voltage Self-Contained DC Sensors with Current
Sinking Outputs and Sensor Alarm .....................................................25
Universal Self-contained Sensors That Provide Single
Pole/Double Throw (SPDT) Relay Outputs for Both
Object Sensing and Sensor Alarm ......................................................27
Closing the MX001 Industrial Control Box ..............................................29
Connecting the MX001 to the Scanner...................................................29
Cable Pin Outs for the 8-Pin and 19-Pin Connectors .............................30
Specifications ..........................................................................................31
Troubleshooting ......................................................................................32
Limited Warranty.....................................................................................40
Notices ....................................................................................................41
iii
INTRODUCTION
Metrologic’s MX001 Industrial Control Interface enhances Metrologic’s line of
industrial laser scanners. It does this by providing a way to connect an external
object sensor to the scanner and a way for the scanner to control an external
device through an electronic switch (a TRIAC). This enables the scanner to
sense the presence of objects to be scanned and then provide a line voltage
output signal if the scanned object meets preprogrammed conditions.
The MX001 can be configured to support any object sensor that can supply a
12V, 5V or 10mA output signal. It will also support switch closure (relay) type
sensor output. Additionally, the MX001 can provide 12V DC power (at 200mA
maximum) to a low voltage, DC type sensor unit making external sensor power
supplies unnecessary.
The MX001’s electronic switch or TRIAC, allows the scanner to control an
external device directly by switching a line voltage output signal off or on and can
handle device loads of up to a maximum of 6 amps US and Canada, 5 amps
Europe. The switching can take place in response to a good scan, a no read
scan, or a mismatch between scanned label data and expected label data
preprogrammed into the scanner for comparison purposes. The scanner can also
activate the TRIAC switch in response to a host system command sent through
the RS-232 scanner-host communications link.
This manual shows how to wire and configure the MX001 Industrial Control Box
so that it will work properly when connected to its associated sensor, output
device and TECH series scanner. Programming the associated TECH series
scanner is necessary to define how the object sensor and TRIAC switch will
operate. Tech series industrial scanners are programmed by using Metrologic’s
HoloSet® configuration software which operates through an RS-232 port of an
IBM XT, AT or compatible PC. In order to program the scanner a HoloSet kit
containing the necessary communications cable, software and manual will be
needed. Please refer to that manual for further details on how to configure the
scanner for use with the MX001 box.
1
OPENING THE MX001 INDUSTRIAL CONTROL BOX
To open the MX001 box for wiring and configuration, proceed as follows:
1. Loosen the lid clamp screw with a flat blade screwdriver.
2. Disengage the clamp by pushing the lid down, then move the clamp to
the left, and rotate it outward in a counterclockwise direction.
3. Once the clamp is disengaged, open the lid.
2
INTERNAL COMPONENTS
The following illustration and list explain the parts that pertain to the installation
and operation of the MX001.
1
F2
Control
2
9
3
F1
TRIAC
J2
4
5
11
10
J1
7
D2
C
D1
C
D3
C
D4
C
8
12V
Triac
S IN
A IN
6
Figure 1
1. Power Transformer
Supplies a stepped down and isolated voltage that
produces the 12V DC power for the industrial
control box and external sensor.
2. F2 Control Fuse Holder
Contains the fuse that controls the 12V DC power
in the industrial control box.
3. F1 TRIAC Fuse Holder
Contains the fuse that controls the power for the
TRIAC output.
4. Power Terminal Block
(Line Power Input)
Provides the input connection point for the AC line
that supplies
power to the industrial control box.
5. TRIAC Terminal Block
(Controlled Power Output)
6. LED Status Indicators
Provides the output connection point
for the scanner controlled.
power output (switched by the TRIAC).
These light up when the +12V power
supply, TRIAC, sensor, or sensor alarm circuits are
active.
7. Voltage Selector Switch
Used to configure the industrial control
box to match the incoming line voltage.
8. J1 Jumper
Configures sensor input.
9. J2 Jumper
Configures the sensor alarm input.
Provides the connection points for the sensor.
10. Sensor Terminal Block
11. Protective Earthing Connectors To connect line cord protective earthing conductors to
industrial control box enclosure.
3
LED STATUS INDICATORS
The LED, (light emitting diode) status indicators are found just below the voltage
selector switch. They indicate the operating state of the 12V power supply, the
TRIAC and the status of the sensor and sensor alarm inputs. An LED will glow
when a circuit is active. From these visual indications, it can be determined if the
MX001 box is active and what action the scanner and sensor are performing in
your system. The following list explains the function of each indicator. They
appear inside the box in the order illustrated in Figure 2.
D1
C
D2
C
D3
D4
C
12V
TRIAC
S IN
A IN
Figure 2
Green +12V (D1)
Indicates that the +12V control and sensor power supply is active
Red TRIAC (D2)
Indicates that the TRIAC switched power output circuit is active.
Red S IN (D3)
Indicates that the sensor circuit is active because an object is being sensed.
Red A IN (D4)
Indicates that the sensor alarm circuit is active because the sensing conditions
are marginal.
Note:
The red TRIAC, S IN and A IN LED’s perform two functions.
Besides circuit activity (status), these indicators also monitor the
connection between the MX001 box and the scanner and will not
light if that connection is broken. Thus, if lit, the indicators also
show the user that the inter-connecting signal (link) cable between
the scanner and the MX001 box is good.
4
CONFIGURING THE MX001 FOR 115 OR 230 VOLT OPERATION
Before applying power to the MX001, it must first be configured for either
115 or 230 volt operation as required. This is accomplished by using the
voltage selector switch and the installation of the proper fuses. Refer to one
of the procedures on the following pages that apply to your voltage requirement
to learn which fuses should be inserted into the F1 and F2 fuse holders. (Refer to
Figure 3)
If fuse replacement becomes necessary, replace with the same type of fuse
originally supplied. Damage to the unit may result if the same type of fuse is not
used.
F2
Control
F1
TRIAC
Figure 3
USA: 115V Operation
1. Move the voltage selector to the right with a small screwdriver so that the
115V legend shows in the window.
2. Open the fuse kit and remove the following:
•
•
•
(2) Gray Fuse Holder Caps
(1) 10 Amp 250V Fast Acting ¼ x 1 ¼ Inch Fuse
(1) 1/8 Amp 250V Slow Blow ¼ X 1 ¼ Inch Fuse
3. Press the end of the 10 Amp fuse into one of the gray fuse holder caps until
it seats.
4. Insert the fuse and cap into the F1 TRIAC fuse holder with the screwdriver
slot pointing toward the power transformer.
5. Using a small screw driver, press the cap down into the fuse holder body
and turn the cap ¼ turn clockwise to lock the cap in place. This results in the
cap slot pointing toward the top and bottom of the box.
5
CONFIGURING THE MX001 FOR 115 OR 230 VOLT OPERATION
USA: 115V Operation (continued)
6. Press the end of the 1/8 Amp fuse into the other gray fuse holder cap unitl it
seats.
7. Insert the fuse and cap into the F2 control fuse holder with the screwdriver
slot pointing toward the power transformer.
8. Using a small screwdriver, press the cap down into the fuse holder body and
turn the cap ¼ turn clockwise to the lock the cap in place. This results in the
cap slot pointing toward the top and bottom of the box.
USA: 230V Operation
1. Move the voltage selector to the left with a small screwdriver so that the
230V legend shows in the window.
2. Open the fuse kit and remove the following:
•
•
•
(2) Gray Fuse Holder Caps
(1) 10 Amp 250V Fast Acting ¼ x 1 ¼ Inch Fuse
(1) 1/16 Amp 250V Slow Blow ¼ x 1 ¼ Inch Fuse
3. Press the end of the 10 Amp fuse into one of the gray fuse holder caps until
seals.
4. Insert the fuse and cap into the F1 TRIAC fuse holder with the screwdriver
slot pointing toward the power transformer.
5. Using a small screwdriver, press the cap down into the fuse holder body and
turn the cap ¼ turn clockwise to lock the cap in place. This results in the cap
slot pointing toward the top and bottom of the box.
6. Press the end of the 1/16 Amp fuse into the other gray fuse holder cap until
it seats.
7. Insert the fuse and cap into the F2 control fuse holder with the screwdriver
slot pointing toward the power transformer.
8. Using a small screwdriver, press the cap down into the fuse holder body and
turn the cap ¼ turn clockwise to lock the cap in place. This results in the cap
slot pointing toward the top and bottom of the box.
6
CONFIGURING THE MX001 FOR 115 OR 230 VOLT OPERATION
Europe/Asia: 230V Operation
1. Move the voltage selector to the left with a small screwdriver so that the
230V legend shows in the window.
2. Open the fuse kit and remove the following:
•
•
•
(2) Black Fuse Holder Caps
(1) 6.3 Amp 250V Fast Acting, High Interrupt 5 x 20 mm Fuse
(1) 50ma 250V Time Delay 5 x 20 mm Fuse
3. Press the end of the 6.3 Amp fuse into one of the black fuse holder caps
until it seats.
4. Insert the fuse and cap into the F1 TRIAC fuse holder with the screwdriver
slot pointing toward the power transformer.
5. Using a small screwdriver, press the cap down into the fuse holder body and
turn the cap ¼ turn clockwise to lock the cap in place. This results in the cap
slot pointing toward the top and bottom of the box.
6. Press the end of the 50mA fuse into the other black fuse holder cap until it
seats.
7. Insert the fuse and cap into the F2 control fuse holder with the screwdriver
slot pointing toward the power transformer.
8. Using a small screwdriver, press the cap down into the fuse holder body and
turn the cap ¼ turn clockwise to lock the cap in place. This results in the cap
slot pointing toward the top and bottom of the box.
7
CONFIGURING THE MX001 FOR 115 OR 230 VOLT OPERATION
Europe/Asia: 115V Operation
1. Move the voltage selector to the right with a small screwdriver so that the
115V legend shows in the window.
2. Open the fuse kit and remove the following:
•
•
•
(2) Black Fuse Holder Caps
(1) 6.3 Amp 250V Fast Acting, High Interrupt 5 x 20mm Fuse
(1) 125mA 250V Time Delay 5 x 20mm Fuse
3. Press the end of the 6.3 Amp fuse into one of the black fuse holder caps
until it seats.
4. Insert the fuse and cap into the F1 TRIAC fuse holder with the screwdriver
slot pointing toward the power transformer.
5. Using a small screwdriver, press the cap down into the fuse holder body and
turn the cap ¼ turn clockwise to lock the cap in place. This results in the cap
slot pointing toward the top and bottom of the box.
6. Press the end of the 125mA fuse into the other black fuse holder cap until it
seats.
7. Insert the fuse and cap into the F2 control fuse holder with the screw driver
slot pointing toward the power transformer.
8. Using a small screwdriver, press the cap down into the fuse holder body and
turn the cap ¼ turn clockwise to lock the cap in place. This results in the cap
slot pointing toward the top and bottom of the box.
8
LOCATING THE THREE STRAIN RELIEFS AND THE SIGNAL CONNECTOR
There are three strain reliefs and one 8-pin signal connector located on the
bottom of the MX001 box. The two large strain reliefs on the left side allow the
use of flexible cordage for MX001 power input and controlled power (TRIAC)
output in that order. If your application requires the use of conduit for power
wiring, these two strain reliefs can be easily removed and standard conduit
fittings can be used in their place. The smaller strain relief is used to secure the
signal/ power cable from the object sensor that is a user supplied part. The 8-pin
signal connector is used to connect the MX001 box to the scanner through the
scanner link cable.
CONNECTING EXTERNAL WIRING TO THE MX001
External wiring is connected to the MX001 by means of “lift clamp” terminal
blocks. These blocks have an opening in their base that will accept a wire with ¼
inch of insulation removed. Connections are made by first turning the terminal’s
binding screw counterclockwise with a small screwdriver which “opens” the
terminal allowing it to accept the wire. The stripped wire is then inserted into the
opening in the terminal and then clamped in place by turning the associated
terminal screw clockwise until tight.
There are two sets of terminal blocks inside the MX001. The larger set of 6
terminals on the left of the voltage selector switch handle the AC power wiring
while the smaller set of 6 terminals on the right handle the sensor wiring.
Two terminals mounted on the MX001 enclosure near the protective earthing
symbol are intended to be used for ground connection of the AC power input
cable and TRIAC controlled power output cable.
POWER REQUIREMENTS FOR THE MX001
The MX001 control box neither supplies nor draws operating power from the
scanner to which it is connected. It contains an indepen-dent, regulated and
totally isolated 12 volt DC power supply that is used to drive the (optocoupled)
sensor and TRIAC signal circuit links to the scanner. Therefore, the MX001 must
be powered from the AC line at all times to allow it to communicate with the
scanner.
9
CONNECTING THE AC POWER INPUT CABLE
1. Make sure power is not being applied to the power cable that is to be
connected to the unit.
2. Open the terminals in the power terminal block by turning each screw
counterclockwise until there is enough space to insert wires.
3. Strip off 1 ¾ inches of the power cable’s outer jacket.
4. Strip the insulation off each cable wire ¼ of an inch.
5. Feed the power cable through the first, large strain relief on the left.
6. Connect each wire to the appropriate locations noted in the table below and
secure the wires in the terminal block and protective earthing terminal by
turning each screw clockwise. (Refer to the MX001 box or to Figure 4 for the
order of the terminals for the power wires.)
7. Secure the cable by turning the strain relief’s domed sealing nut clockwise
until tight.
Protective
Earthing
Terminals
Figure 4
NOTE: Do not connect any wires to the first terminal.
Terminal Block
Cable Color in USA
and Canada
Cable Color in
in Europe
Neutral
Line In
White
Black
Blue
Brown
Protective
Earthing
Cable Color in USA
and Canada
Cable Color in
in Europe
Terminals
Ground
Green
Yellow-Green
10
CONNECTING THE TRIAC CONTROLLED POWER OUTPUT CABLE
The MX001 box contains a power line TRIAC that acts as an electronic power
output switch operated by the scanner and capable of controlling a current load
of 6 amps in the USA. In Europe, the maximum current load supported is 5
Amps. The TRIAC controlled output voltage equals the line input voltage when
the scanner activates the TRIAC. How the TRIAC will operate is defined by the
HoloSet Program.
1.
2.
Make sure power is not being applied to the unit.
Open the terminals in the TRIAC terminal block by turning each screw
counterclockwise until there is enough space to insert wires.
3.
4.
5.
6.
Strip off 1 ¾ inches of the power output cable’s outer jacket.
Strip the insulation off each cable wire ¼ of an inch.
Feed the power output cable through the second large strain relief.
Connect each wire to the appropriate locations noted in the table below and
secure the wires in the terminal block and protective earthing terminal by
turning each screw clockwise. (Refer to the MX001 box or to figure 5 for the
order of the terminals for the TRIAC wires.)
Protective
Earthing
Terminals
Figure 5
Note: Do not connect any wires to the fourth terminal.
Terminal Block
Cable Color in USA
and Canada
Cable Color in
in Europe
Neutral
Line In
White
Black
Blue
Brown
Protective
Earthing
Cable Color in USA
and Canada
Cable Color in
in Europe
Terminals
Ground
Green
Yellow-Green
Caution: Damage will occur to the unit if the TRIAC output is
shorted.
11
TEMPORARILY DISABLING THE TRIAC OUTPUT
If, during set up or maintenance, there is a need to disable the TRIAC output of
the MX001, simply remove the F1 TRIAC fuse. This disconnects the AC line
voltage from the TRIAC circuitry and output terminal block, but leaves the TRIAC
LED indicator active allowing checks to be made for TRIAC circuit activity without
activating the TRIAC controlled device.
12
SENSOR SUPPORT
There are many different types of sensors available, which will work with the
MX001 control box.
Common types:
1.
Sensors powered independently which provide 12V, 5V, or a 10mA DC
output signal (sourcing type output).
2.
3.
Sensors that provide switch closures or relay type outputs.
Low voltage, self-contained DC sensors that provide current sourcing
and/or sinking type outputs.
4.
“Universal” self-contained sensors that provide a single pole, double throw
(SPDT) relay output.
In all cases, the sensor’s output signal or switch closure is expected to become
active when an object has been sensed.
The easiest sensor to use with the MX001 is a low voltage (a 10-30 volt) DC, self
contained, sensor. The industrial control box can power this type of sensor with
12V DC at 200 mA maximum and will interface to either a (PNP) current
sourcing, or (NPN) current sinking output. (Current sourced or sunk = 10 mA.) A
switch closure (relay) type output is also supported. All output types are expected
to become active when an object has been sensed.
Additionally, some sensors also provide an “alarm” output that warns the user
when sensing conditions are becoming marginal. This optional output is also
supported through the MX001. The option forces the scanner to emit a repetitive
warning tone when the sensor’s alarm output becomes active.
How the sensor interacts with the scanner depends upon which sensor options
were chosen in the HoloSet program. Refer to that manual for further details.
13
SENSOR SUPPORT
Connecting the Sensor
Reference the documentation that came with your sensor to determine the
function of each sensor wire. Then, refer to one of the procedures on the
following pages that apply to your sensor for information on how to hook up the
appropriate wires and position the configuration jumper on the appropriate pins of
its header. If your sensor supports the alarm function, begin looking for the
procedure for your sensor on page 22.
Temporarily Disabling the Sensor and/or Sensor Alarm
If, during set up or maintenance, there is a need to disable the sensor and/or
sensor alarm inputs of the MX001, proceed as follows:
•
•
To disable the sensor, position the J1 (S SET UP) jumper on
pins 2 and 3 of its header.
To disable the sensor alarm, position the J2 (A SETUP) jumper on pins 2
and 3 of its header.
These procedures disconnect the sensor’s output signals from the MX001’s input
circuitry without physically disconnecting any sensor wiring.
14
SENSOR SUPPORT
Sensors Powered Independently that Provide Either 12V, 5V or a
10mA DC Output Signal
1.
2.
Make sure power is not being applied to the unit.
Open the terminals in the sensor terminal block by turning each screw
counterclockwise until there is enough space to insert wires.
3.
4.
5.
6.
Strip off 2 ¼ inches of the sensor cable’s outer jacket.
Strip the insulation off each cable wire ¼ of an inch.
Feed the sensor cable through the small strain relief.
Insert the sensor’s DC common (or negative) output wire into the S IN-
terminal block and secure the wire by turning the terminal’s screw
clockwise.(Refer to the MX001 box or Figure 6 for the order of the terminals
for the sensor wires)
7.
8.
9.
Insert and secure the sensor’s positive output wire to the
S IN+ terminal.
Secure the cable by turning the strain relief’s domed sealing nut clockwise
until tight.
Depending upon your sensor’s output, perform one of the following steps.
•
For a 12V DC output signal, position the jumper on pins 1 and 2 of the
J1 (S SET UP) header. (Refer to Figure 7)
•
For a 5V DC output signal, position the jumper on pins 3 and 4 of the
J1 (S SET UP) header. (Refer to Figure 7)
•
For a 10mA DC output signal, position the jumper on pins 4 and 5 of
the J1 (S SET UP) header. (Refer to Figure 7)
Figure 6
15
SENSOR SUPPORT
Sensors Powered Independently that Provide Either 12V, 5V or a
10mA DC Output Signal
Caution: When configured for a 10mA DC source input, the
MX001 box expects a current limited 10 mA DC signal to be
supplied by the sensor. Failure to limit this current to 10mA can
damage the sensor input circuitry of the system.
Current limiting can be accomplished by using an external limiting resistor of the
appropriate value (which is dependent upon the sensor’s DC signal output
voltage level). This resistor is connected between the S IN+ input of the MX001
box and the sensor.
Sensor Output Voltage – 3V
Approximate Resistance =
10mA
J1
J1
If the source is a 12V DC signal:
If the source is a 5V DC signal:
1
1
2
2
3
4
4
5
5
6
1
1
6
S SET UP
3
6
6
S SET UP
J1
If the source is a 10mA DC signal:
1
2
3
4
5
6
1
6
S SET UP
Figure 7
16
SENSOR SUPPORT
Sensors that Provide Switch Closures or Relay Type Output
1.
2.
Make sure power is not being applied to the unit.
Open the terminals in the sensor terminal block by turning each screw
counterclockwise until there is enough space to insert wires.
3.
4.
5.
6.
Strip off 2 ¼ inches of the sensor cable’s outer jacket
Strip the insulation off each cable wire ¼ of an inch.
Feed the sensor cable through the small strain relief.
Insert one of the sensors signal output wires into the COMMON terminal
and secure the wire by turning the terminal’s screw clockwise. (Refer to the
MX001 box or to Figure 8 for the order of the terminals for the sensor
wires.)
7.
8.
9.
Insert and secure the sensor’s other signal output wire into the S IN-
terminal.
Secure the cable by turning the strain relief’s domed sealing nut clockwise
until tight.
Position the jumper on pins 5 and 6 of the J1 (S SET UP) header. (Refer to
Figure 9).
Figure 8
J1
1
2
3
4
5
6
1
S SET UP
6
Figure 9
17
SENSOR SUPPORT
Low Voltage Self-Contained DC Sensors with a Current Sinking
Output
1.
2.
Make sure power is not being applied to the unit.
Open the terminals in the sensor terminal block by turning each screw
counterclockwise until there is enough space to insert wires.
3.
4.
5.
6.
Strip off 2 ¼ inches of the sensor cable’s outer jacket.
Strip the insulation off each cable wire ¼ of an inch.
Feed the sensor cable through the small strain relief.
Inserts the sensor’s DC common wire into the COMMON terminal and
secure the wire by turning the terminals’s screw clockwise. (Refer to the
MX001 box or to Figure 10 for the order of the terminals for the sensor
wires.)
7.
Insert and secure the sensor’s +DC power input wire into the +12V OUT
terminal.
8.
9.
Insert and secure the sensor’s signal output wire into the S IN- terminal.
Secure the cable by turning the strain relief’s domed sealing nut clockwise
until tight.
10. Position the jumper on pins 5 and 6 of the J1 (S SET UP) header. (Refer to
Figure 11).
Figure 10
J1
1
2
3
4
5
6
1
S SET UP
6
Figure 11
18
SENSOR SUPPORT
Low Voltage Self-Contained DC sensors with a Current Sourcing
Output
1.
2.
Make sure power is not being applied to the unit.
Open the terminals in the sensor terminal block by turning each screw
counterclockwise until there is enough space to insert wires.
3.
4.
5.
6.
Strip off 2 ¼ inches of the sensor cable’s outer jacket.
Strip insulation off each cable wire ¼ of an inch.
Feed the sensor cable through the small strain relief.
Connect a small jumper wire between the COMMON and the S IN-
terminals. Secure the jumper wire in the S IN- terminal by turning the
terminal’s screw clockwise. (Refer to the MX001 box or to Figure 12 for the
order of the terminals for the sensor wires.
7.
Connect the sensor’s DC common wire to the COMMON terminal and
secure the sensor and jumper wire by turning the terminal’s screw
clockwise.
8.
9.
Insert and secure the sensor’s +DC power input wire into the +12V OUT
terminal.
Insert and secure the sensor’s sourcing output wire into the
S IN+ terminal.
10. Secure the cable by turning the strain relief’s domed sealing nut clockwise
until tight.
11. Position the jumper on pins 1 and 2 of the J1 (S SET UP) header. (Refer to
Figure 13).
Figure 12
J1
1
2
3
4
5
6
1
S SET UP
6
Figure 13
19
SENSOR SUPPORT
“Universal” Self-Contained Sensors that Provide a Single
Pole/Double Throw (SPDT) Relay Output
1.
Make sure the “universal” sensor can operate on +12 volts DC at 200mA or
less. If so, then the MX001 box can supply the +12 volts necessary to
power the “universal” sensor.
2.
3.
Make sure power is not being applied to the unit.
Open the terminals in the sensor terminal block by turning each screw
counterclockwise until there is enough space to insert wires.
4.
5.
6.
7.
Strip 2 ¼ inches of the sensor cable’s outer jacket
Strip the insulation off each cable wire ¼ of an inch.
Feed the sensor cable through the small strain relief.
Insert the sensor’s +DC power input wire into the +12V OUT terminal and
secure the wire by turning the terminal’s screw clockwise. (Refer to the
MX001 box or to Figure 14 for the order of the terminals for the sensor
wires.)
8.
9.
Insert the sensor’s –DC or common power input wire and the relay output
common signal wire into the COMMON terminal and secure both wires.
Determine from the literature supplied with your sensor which sensor relay
output makes contact with its common terminal when an object is sensed. If
the output cannot be determined, go on to Step 10. Otherwise, skip to Step
11.
10. Temporarily apply power to the MX001 box to activate the sensor and then
determine with a continuity tester or ohm meter which relay output (the
normally closed [NC] or the normally open [NO] output) make contact with
the COMMON terminal when the sensor “sees” the object to be scanned.
11. Remove any power applied to the MX001 (in Step 10) and connect and
secure the relay output wire previously determined to the S IN- terminal.
(The other relay output wire may be cut off or connected to the MX001
COMMON terminal if desired).
12. Secure the cable by turning the strain relief's domed sealing nut clockwise
until tight.
20
SENSOR SUPPORT
“Universal” Self-Contained Sensors that Provide a Single
Pole/Double Throw (SPDT) Relay Output
13. Position the jumper on pins 5 and 6 of the J1 (S SET UP) header. (Refer to
Figure 15).
Figure 14
J1
1
2
3
4
5
6
1
S SET UP
6
Figure 15
21
SENSOR SUPPORT
Sensors Powered Independently that Provide Either 12V, 5V or a
10mA DC Output Signal with a Sensor Alarm
1.
2.
Make sure power is not being applied to the unit.
Open the terminals in the sensor terminal block by turning each screw
counterclockwise until there is enough space to insert wires.
3.
4.
5.
6.
Strip off 2 ¼ inches of the sensors cable’s outer jacket.
Strip the insulation off each cable wire ¼ of an inch.
Feed the sensor cable through the small strain relief.
Insert the sensor’s DC common (or negative) output wire into the
S IN- terminal block and secure the wire by turning the terminal’s screw
clockwise. (Refer to the MX001 box or to Figure 16 for the order of the
terminals for the sensor wires.)
7.
8.
Insert and secure the sensor’s positive output wire into the S IN+ terminal.
Insert and secure the sensor’s alarm DC common (or negative) output wire
into the A IN- terminal and the sensor’s alarm positive output wire into the
A IN+ terminal.
9.
Secure the cable by turning the strain relief’s domed sealing nut clockwise
until tight.
10. Depending upon your sensor’s output, perform one of the of the following
steps:
Figure 16
22
SENSOR SUPPORT
Sensors Powered Independently that Provide Either 12V, 5V or a
10mA DC Output Signal with a Sensor Alarm
•
•
•
For 12V DC output signals, position the jumpers on pins 1 and 2 of the
J1 (S SET UP) and J2 (A SET UP) headers. (Refer to Figure 17)
For 5V DC output signals, position the jumpers on pins 3 and 4 of the
J1 (S SET UP) and J2 (A SET UP) headers. Refer to Figure 17)
For 10mA DC output signals, position the jumpers on pins 4 and 5 of
the J1 (S SET UP) and J2 (A SET UP) headers. (Refer to Figure 17)
Caution: When configured for a 10mA DC source input, the MX001 box
expects a current limited 10 mA DC signal to be supplied by the
sensor. Failure to limit this current to 10 mA can damage the sensor
input circuitry of the system.
Current limiting can be accomplished by using external limiting resistors of
an appropriate value (which are dependent upon the sensor’s DC signal
output voltage level). One resistor is connected between the S IN+ input of
the MX001 box and the sensor. The other resistor is connected between the
A IN+ input of the MX001 box and the sensor (for the sensor alarm circuit).
Sensor Output Voltage – 3V
Approximate Resistance =
10 mA
If the source is a 12 V DC Signal:
A SET UP
J1
1
6
1
1
2
3
4
5
2
3
4
5
6
6
1
S SET UP
6
J2
J1
1
A SET UP
6
1
1
2
3
4
5
2
3
4
5
6
6
J2
1
S SET UP
6
1
A SET UP
6
J1
1
1
2
3
4
5
2
3
4
5
6
6
J2
1
S SET UP
6
Figure 17
23
SENSOR SUPPORT
Sensors that Provide Switch Closures or Relay Type
Output with a Sensor Alarm
1. Make sure power is not being applied to the unit.
2. Open the terminals in the sensor terminal block by turning each screw
counterclockwise until there is enough space to insert wires.
3. Strip off 2 ¼ inches of the sensor cable’s outer jacket.
4. Strip the insulation off each cable wire ¼ of an inch.
5. Feed the sensor cable through the small strain relief.
6. Insert one of the sensor’s signal output wires and one of the sensor’s alarm
output wires into the COMMON terminal and secure the wires by turning the
terminal’s screw clockwise. (Refer to the MX001 box or to Figure 18 for the
order of the terminals for the sensor wires.)
7. Insert and secure the sensor’s remaining signal output wire into the S IN-
terminal.
8. Insert and secure the sensor’s remaining alarm output wire into the A IN-
terminal.
9. Secure the cable by turning the strain relief’s domed sealing nut clockwise
until tight.
10. Position the jumpers on pins 5 and 6 of the J1 (S SET UP) and J2 (A SET
UP) headers. (Refer to Figure 19)
Figure 18
1
A SET UP
6
1
1
6
2
3
4
5
5
J1
J2
6
2
3
4
1
S SET UP
6
Figure 19
24
SENSOR SUPPORT
Low Voltage Self-Contained DC Sensors with Current Sinking
Outputs and Sensor Alarm
1.
2.
Make sure power is not being applied to the unit.
Open the terminals in the sensor terminal block by turning each screw
counterclockwise until there is enough space to insert wires.
3.
4.
5.
6.
Strip off 2 ¼ inches of the sensor cable’s outer jacket.
Strip the insulation off each cable wire ¼ of an inch.
Feed the sensor cable through the small strain relief.
Insert the sensor’s DC common wire into the COMMON terminal and
secure the wire by turning the terminal’s screw clockwise. (Refer to the
MX001 box or to Figure 20 for the order of the terminals for the sensor
wires.)
7.
Insert and secure the sensor’s +DC power input wire into the +12V OUT
terminal.
8.
9.
Insert and secure the sensor’s signal output wire into the S IN- terminal.
Insert and secure the sensor’s alarm signal output wire into the A IN-
terminal.
10. Secure the cable by turning the strain relief’s domed sealing nut clockwise
until tight.
11. Position the jumpers on pins 5 and 6 of the J1 (S SET UP) and J2 (A SET
UP) headers. (Refer to figure 21).
1
A SET UP
6
1
1
2
2
3
4
5
5
6
J2
J1
3
4
6
1
S SET UP
6
Figure 20
Figure 21
25
SENSOR SUPPORT
Low Voltage Self-Contained DC Sensors with Current Sourcing
Output and Sensor alarm
1.
2.
Make sure power is not being applied to the unit.
Open the terminals in the sensor terminal block by turning each screw
counterclockwise until there is enough space to insert wires.
3.
4.
5.
6.
Strip off 2 ¼ inches of the sensor cable’s outer jacket.
Strip the insulation off each cable wire ¼ of an inch.
Feed the sensor cable through the small strain relief.
Connect a small jumper wire between the COMMON and the S IN-
terminals and secure the jumper in the S IN- terminal by turning the
terminal’s screw clockwise. (Refer to the MX001 box or to Figure 22 for the
order of the terminals for the sensor wires.)
7.
8.
9.
Connect a small jumper wire between the COMMON and the A IN- terminal
and secure the jumper in the A IN- terminal.
Connect the sensor’s DC common wire to the COMMON terminal and
secure the jumpers and wire by turning the terminal’s screw clockwise.
Insert and secure the sensor’s +DC power input wire into the +12V OUT
terminal.
10. Insert and secure the sensor’s signal output wire into the S IN+ terminal.
11. Insert and secure the sensor’s alarm output wire into the A IN+ terminal.
Secure the cable and turn the strain relief’s domed sealing nut clockwise
until tight.
12. Position the jumpers on pins 1 and 2 of the J1 (S SET UP) and J2 (A SET
UP) headers. (Refer to Figure 23)
1
A SET UP
6
6
2
3
4
5
5
1
1
J2
J1
6
2
3
4
1
S SET UP
6
Figure 22
Figure 23
26
SENSOR SUPPORT
“Universal” Self-contained Sensors That Provide Single
Pole/Double Throw (SPDT) Relay Outputs for Both Object Sensing
and Sensor Alarm
1.
Make sure the “universal” sensor can operate on +12 volts DC at 200ma or
less. If so, then the MX001 box can supply the +12 volts necessary to
power the “universal” sensor.
2.
3.
Make sure power is not being applied to the unit.
Open the terminals in the sensor terminal block by turning each screw
counterclockwise until there is enough space to insert wires.
4.
5.
6.
7.
Strip off 2 ¼ inches of the sensor cable’s outer jacket.
Strip the insulation off each cable wire ¼ of an inch.
Feed the sensor cable through the small strain relief.
Insert the sensor’s +DC power input wire into the +12V OUT terminal and
secure the wire by turning the terminal’s screw clockwise. (Refer to the
MX001 box or to figure 24 for the order of the terminals for the sensor
wires.)
8.
9.
Insert the sensor’s -DC or common power input wire and both the object
sense and alarm relay output common signal wires into the COMMON
terminal and secure all three wires.
Determine from the literature supplied with your sensor which sensor relay
output makes contact with its common terminal when an object is sensed. If
the output cannot be determined, go on to Step 10. Otherwise, skip to Step
11.
10. Temporarily apply power to the MX001 box to activate the sensor and then
determine with a continuity tester or ohm meter which relay output (the
normally closed [NC] or the normally open {NO] output) makes contact with
the COMMON terminal when the sensor “sees" the object to be scanned.
11. Remove any power applied to the MX001 (in Step 100 and connect and
secure the “sense” relay output wire previously determined to the S IN-
terminal. (The other sense relay output wire may be cut off or connected to
the MX001 COMMON terminal if desired).
27
SENSOR SUPPORT
“Universal” Self-contained Sensors That Provide Single
Pole/Double Throw (SPDT) Relay Outputs for Both Object Sensing
and Sensor Alarm
12. Determine from the literature supplied with your sensor which sensor alarm
relay output makes contact with its common terminal when sensing
conditions become marginal. If the output cannot be deter-mined, go on to
Step 13. Otherwise, skip to Step 14.
13. Temporarily apply power to the MX001 box again to activate the sensor
and try to make sensing conditions marginal by placing the object to be
sensed at a greater than normal distance from the sensor or misalign the
sensor to activate the sensor’s alarm output. (Most sensors have a small
indicator that shows when the alarm output is active by being either on or
off depending upon the type of sensor.) Determine with a continuity tester
or ohm meter which relay output (the normally closed [NC or the normally
open {NO] output) makes contact with the COMMON terminal when the
sensor indicates that its alarm output is active.
14. Remove any power applied to the MX001 box (in Step 13) and connect and
secure the “alarm” relay output wire previously determined to the A IN-
terminal. (The other alarm relay output wire may be cut off or connected to
the MX001 COMMON terminal if desired.)
15. Secure the cable by turning the strain relief’s domed sealing nut clockwise
until tight.
16. Position the jumpers on pins 5 and 6 of the J1 (S SET UP) and J2 (A SET
UP) headers (Refer to Figure 25).
Figure 24
1
A SET UP
6
6
2
3
4
5
5
1
J2
J1
6
1
2
3
4
1
S SET UP
6
Figure 25
28
CLOSING THE MX001 INDUSTRIAL CONTROL BOX
1.
2.
Close the lid of the MX001 box.
Rotate the clamp clockwise while pushing down on the lid. Then move the
clamp to the right, positioning it over the ledge on the lid.
3.
Fasten the clamp in place by tightening its screw with a flat blade
screwdriver.
CONNECTING THE MX001 TO THE SCANNER
The supplied, scanner link cable is used to connect the MX001 box to a TECH
series scanner. This one meter cable carries the MX001’s control signals and is
terminated with an 8 and a 19 pin connector. (Other cable lengths are available,
contact Metrologic for details.)
1.
Find the 8-pin male end of the scanner link cable and locate the wide
connector key found above pins A and G. Align this key with the
corresponding key on the MX001’s signal connector. Push in on the cable
connector slightly and rotate its ring clockwise until the connector locks in
place with a click.
2.
Likewise, the 19-pin female connector found on the other end of this cable
is connected to the 19-pin male connector on the scanner case. This
connector is the one closest to the scanner window.
29
CABLE PIN OUTS FOR THE 8-PIN AND 19-PIN CONNECTORS
The standard scanner link cable length is 3 feet – 1 meter. Other scanner link
cable lengths are available upon request. Contact Metrologic Customer Service
for additional details.
If there is a need to lengthen the scanner link cable, use a cable with #26 wire.
The scanner link cable can be easily extended to 100 feet without signal
difficulty. The following are listings of the cable pin outs for the 19-pin female and
the 8-pin male ends of the link cable. (Refer to Figures 26 and 27)
19-Pin Female Mil Spec Connector
Pin
Function
A
V
M
U
B
L
P
N
T
A
B
C-L
M
N
TRIAC1+
TRIAC1-
RESERVED
SENSOR+
SENSOR-
C
R
K
D
J
S
E
H
F
G
P
R
S-V
SENSE ALARM+
SENSE ALARM-
RESERVED
Figure 26
8-Pin Male Mil Spec Connector
Pin
Function
G
A
A
B
C
D
E
F
TRIAC+
TRIAC-
SENSOR+
SENSOR-
SENSE ALARM/AUX+
SENSE ALARM/AUX-
RESERVED
RESERVED
B
F
H
C
E
D
G
H
Figure 27
30
SPECIFICATIONS
MX001 Specifications
Application: Industrial Control Interface
L-bracket with TECH scanner or independently
mounted
Orientation:
Dimensions: 152mm L x 102mm W x 76mm D (6” x 4” x 3”)
Weight: 1.36 Kg (93 lbs.)
Case Material: Oil Tight J1C box
12 V at 200mA for low voltage
Electrical:
DC type object sensor
6 Amp TRIAC output (5 Amp in Europe) 12V, 5V,
System Interfaces:
10mA or switch closure object sensor input
Four LED’s for: 12V Power supply, TRIAC, sensor
Status Indicators:
and sensor alarm
UL, CSA and IEC: UL and CUL listed, CE
Specifications are subject to change without notice.
31
TROUBLESHOOTING
No Operation – Green LED off:
1. Check power input wiring for correct connection and security at power
terminal block. (Wires must be stripped before insertion into the terminal
block and terminal block screws must be tight, clamping the stripped
wire firmly in the block.)
2. Check for AC power input between LINE IN and NEUTRAL terminals of
the power terminal block.
3. Check F2 Control fuse.
F2 Control Fuse Open:
1. Review the MX001 manual detailing the fuse installation procedure and
check the F2 Control fuse for correct rating. (Depends upon line
voltage in use.)
2. If a low voltage DC type sensor is connected to the MX001 and is using
the MX001 as its power source (+12V OUT in use), make sure this
sensor does not draw more than 200mA of current from the MX001 or
that the sensor is incorrectly connected or shorted.
No Operation Sensor & TRIAC with Green LED on
(other LED’s do not light):
1. Check that the scanner link cable is connected to the MX001 and
scanner.
2. Check the connection of the MX001 internal link cable to the printed
circuit board at J3 (Lower right corner).
3. Check for proper connection of the sensor (if used) plus proper
positioning of the S and A set up jumpers at J1 and J2. (Depends upon
sensor type.)
4. Check for proper HoloSet programming of the TRIAC. (To check TRIAC
output, temporarily program the scanner via HoloSet to support only the
TRIAC with TRIAC Normally On. This will activate the red TRIAC LED
and the TRIAC output continuously.)
32
TROUBLESHOOTING
No TRIAC Output with Red TRIAC LED On:
1.
Check that the TRIAC load is properly connected to the TRIAC
terminal block. (Wires must be stripped before insertion into the
terminal block and terminal block screws must be tight, clamping the
stripped wire firmly in the block.)
2.
3.
Check for AC power output between the TRIAC OUT and NEUTRAL
terminals of the TRIAC terminal block when the TRIAC LED is on.
Check the fuse in the F1 TRIAC fuse holder.
F1 TRIAC Fuse Open:
1.
2.
Review the section detailing the fuse installation procedure and
check the F1 TRIAC fuse for correct rating (10 or 6.3 Amps). Make
sure one of the F2 CONTROL fuses have not been installed in place
of the correct TRIAC fuse.
Check that the TRIAC load has been properly connected to the
TRIAC terminal block and does not draw current greater than the
rating of the F1 TRIAC fuse installed (10 Amp in USA or 6.3 Amp in
Europe/Asia).
3.
4.
Check that the TRIAC load does not draw an excessively large
surge or start up current that is beyond the capabilities of the MX001
fuse rating.
Check to make sure the TRIAC load is not or has not been
accidentally shorted. If a short is found, remove the short and check
for proper TRIAC operation after installing a new F1 TRIAC fuse.
(See item 5.)
5.
Disconnect the normal TRIAC load and temporarily connect a 60W
light bulb in a wired test socket to the TRIAC output. If the bulb does
not light when the red LED TRIAC indicator is on after a new fuse
has been installed or if the bulb lights continuously with the red LED
TRIAC indicator off, then MX001 TRIAC circuit damage is indicated.
The Mx001 can be damaged if the TRIAC output is accidentally
shorted.
NOTE: TRIAC load refers to the device that is connected by the MX001 TRIAC.
33
TROUBLESHOOTING
TRIAC Output Active with Red TRIAC LED off:
Tests for AC power output from the TRIAC should only be made when a device
or load is connected between the TRIAC OUT and NEUTRAL terminals of the
TRIAC terminal block. Attempting to measure output voltage with nothing
connected to the TRIAC terminal block will result in a false output reading which
may show partial or full line voltage present at all times. This is due to the TRIAC
snubber circuit in the MX001 that protects the TRIAC from surge damage due to
inductive loads. This circuit produces a small amount of AC output (5mA) at the
TRIAC terminal block that can be measured when no load is connected there
but is of no consequence otherwise.
To test properly for AC power output from the TRIAC, temporarily connect a 60W
light bulb in a wired test socket to the TRIAC output. This lamp will provide a
proper load for the TRIAC. If the bulb lights when the red LED TRIAC indicator is
OFF, then MX001 circuit damage is indicated as the problem. The unit can be
damaged if the TRIAC output is accidentally shorted.
No Sensor Input Indication (Red S in LED does not light):
1. Review the documentation that came with your sensor to learn the type
of output the sensor provides. Review the MX001 manual and find the
set up procedure that applies to your sensor. Check for proper
connection of the sensor to the MX001 sensor terminal block plus
proper positioning of the S set up jumper J1. (Depends upon sensor
type in use.)
2. Check your sensor for output indication. Most sensors have a small
indicator on them or their controller that lights when the sensor output is
active. Make sure the sensor is active when expected.
3. Check the positioning of the sensor making sure it is oriented correctly.
4. Check sensor gain/sensitivity adjustment for correctness. Most sensors
provide this adjustment to adapt to various sensing conditions. Check to
see if the gain/sensitivity is not set too low in diffuse proximity type
sensors or not set too high in beam break type sensors. Review the
documentation that came with your sensor to learn how to make this
adjustment correctly.
5. Make sure the MX001 scanner link cable is connected to both the
scanner and the MX001.
34
TROUBLESHOOTING
Reversed Sensor Input Indication
(Red S in LED goes off when object is sensed):
1. Some sensors provide the option of output activation when they sense
or do not sense an object. Having the sensor set up to produce an
output when it does not sense an object will result in reversed sensing
conditions. The MX001 expects to receive an active output signal from
the sensor (source voltage/current or switch closure) when the object to
be scanned is being sensed. Review the documentation that came with
your sensor to learn what type of output it provides and how to configure
it.
2. Some sensors that provide switch closure type output provide both
normally open (NO) and normally closed (NC) switched outputs. If the
sensor as connected is providing a reversed sensing condition (switch
closure when no object is being sensed), disconnect the switched
output used and connect the other switched output in its place.
3. If the sensor in use provides an output only when an object is not being
sensed and cannot be configured otherwise, contact Metrologic for
special instructions on how to adapt to this type of sensor.
Erratic Sensor Operation:
1. Check the sensor wiring for correct connection and security at the
sensor terminal block. (wires must be stripped before insertion into the
terminal block and terminal block screws must be tight, clamping the
stripped wire firmly in the block.)
2. Check the positioning of the sensor making sure it is oriented correctly
and not dirty.
3. Check sensor gain/sensitivity adjustments for correctness. Most sensors
provide this adjustment to adapt to various sensing conditions. Review
the documentation that came with your sensor to learn how to make this
adjustment correctly. If this adjustment is made incorrectly, the sensor
will act erratically.
35
TROUBLESHOOTING
Continuous Sensor Input Indication
(Red S IN LED continuously on):
1. Review the documentation that came with your sensor to learn the type
of output the sensor provides. Review the MX001 manual and find the
set up procedure that applies to your sensor. Check for proper
connection of the sensor to the MX001 sensor terminal block plus
proper positioning of the S set up jumper at J1. (Depends upon sensor
type in use.)
2. Check your sensor for output indication. Most sensors have a small
indicator on them or their controller that lights when the sensor output is
active. Make sure the sensor is not providing a continuous output.
3. Some sensors provide the option of output activation when they sense
or do not sense an object. Having the sensor set up to produce an
output when it does NOT sense an object will result in continuous
sensor output when the sensor is idle. Review the documentation that
came with your sensor to learn what type of output it provides and how
to configure it. The MX001 box expects to receive an active output
signal from the sensor (source voltage/current or switch closure) when
an object to be scanned is being sensed.
4. Check sensor gain/sensitivity adjustment for correctness. Most sensors
provide this adjustment to adapt to various sensing conditions. Check to
see if the gain/sensitivity is not set too low in beam break type sensors
or not set to high in diffuse proximity type sensors. Review the
documentation that came with your sensor to learn how to make this
adjustment correctly.
Continuous Sensor Alarm Indication
(Red A IN LED continuously on):
1. Review the documentation that came with your sensor to learn the type
of alarm output the sensor provides. Review the MX001 manual and
find the set up procedure that applies to your sensor. Check for proper
connection of the sensor alarm output to the MX001 sensor terminal
block plus proper positioning of the A Set Up jumper at J2. The MX001
expects to receive an active alarm output signal from the sensor (source
voltage/current or switch closure) when sensing conditions have
become marginal.
2. If the sensor in use provides an alarm output only when sensor
conditions are not marginal and cannot be configured otherwise,
contact Metrologic for special instructions on how to adapt to this type of
sensor.
36
TROUBLESHOOTING
Erratic Sensor Alarm Indication (Red A IN LED blinks):
1. Check the positioning of the sensor to make sure it is oriented correctly.
2. Check to see if the sensor is dirty and clean it if necessary.
3. Check sensor gain/sensitivity adjustment for correctness. Most sensors
provide this adjustment to adapt to various sensing conditions. Review
the documentation that came with your sensor to learn how to make this
adjustment correctly. If this adjustment is made incorrectly, the sensor
may produce an erratic alarm output.
Scanner cannot be placed in program mode using HoloSet label:
1. Disconnect then reconnect power to the scanner. Enter scanner
program mode by choosing Enter Program Mode from the HoloSet
Main Menu.
2. If the scanner has been programmed for sensor support, the scanner
will not scan any label including the HoloSet label unless a sensor is
connected to the MX001 box and activated.
3. If the scanner has been programmed to support DTR, the scanner will
not scan any label including the HoloSet label unless the DTR input is
active.
Scanner cannot be placed in program mode using HoloSet menu:
1. Disconnect then reconnect power to the scanner. Retry entering
program mode by choosing Enter Program Mode from the HoloSet
Main Menu.
2. Check to see if the HoloSet communication cable is plugged into your
PC correctly.
3. Make sure the correct COM option (COM 1 or 2 as required) is being
used.
37
TROUBLESHOOTING
Operational Check Out Procedure for the MX001 Box:
The following procedure provides a basic test of the MX001 hardware and
confirms effective communication with the HoloSet program. This quick test
should be preformed before the MX001 box has been configured by the HoloSet
program for its final application. These steps are not required for proper
installation and application programming of the MX001 box.
1. Do not connect a sensor to the MX001 at this time. Tighten each sensor
terminal block screw by turning each screw clockwise.
2. Temporarily place both S and A SET UP jumpers (J1 and J2) at
positions 5 and 6.
3. Connect a standard 60W light bulb in a wired test socket to the TRIAC
terminal block at the TRIAC OUT and NEUTRAL terminals. This lamp
will act as a load for the TRIAC. (Do Not try to monitor TRIAC output
without a load connected.)
4. Connect the MX001 box to the scanner with the scanner link cable.
5. Apply power to both the MX001 and the scanner. The green LED inside
the MX001 should light.
6. If a volt meter is available, measure the DC output voltage between the
+12V OUT and COMMON terminals on the sensor terminal block. This
voltage should be between 11.5 and 12.5 volts DC.
7. Temporarily program the TECH options of the scanner using HoloSet
for the following:
•
•
•
•
•
Support Line Sensor
Support Line Sensor Alarm
Support TRIAC
TRIAC Normally On
Activate on No Read
8. After programming, the MX001’s red TRIAC LED should light and the
test light bulb should be on.
9. Short the S IN- terminal screw to the COMMON terminal screw with a
short piece of wire. The red S IN LED should light and the test light bulb
connected to the TRIAC output should flash off then back on.
38
TROUBLESHOOTING
10. Short the A IN- terminal screw to the COMMON terminal screw with a
short piece of wire. The red A IN LED should light and the scanner
should emit a repetitive warning tone as long as this connection is
maintained.
11. Disconnect then reconnect power to the scanner. Enter scanner
program mode by choosing Enter Program Mode from the HoloSet
Main Menu. (Do not try to use the HoloSet bar code label at this time)
DISABLE all TECH options then re-program the scanner. This
neutralizes the test program disabling the unconnected sensor inputs
and turns the TRIAC output off.
12. If needed, the scanner can now be programmed for your particular
application.
39
LIMITED WARRANTY
The MX001 interface is manufactured by Metrologic at its Blackwood, New Jersey, USA
facility. The MX001 interface has a two (2) year limited warranty from the date of
manufacture. Metrologic warrants and represents that all MX001 interface is free of all
defects in material, workmanship and design, and have been produced and labeled in
compliance with all applicable US Federal, state and local laws, regulations and ordinances
pertaining to their production and labeling.
This warranty is limited to repair, replacement of Product or refund of Product price at the
sole discretion of Metrologic. Faulty equipment must be returned to the Metrologic facility in
Blackwood, New Jersey, USA or Puchheim, Germany. To do this, contact Metrologic’s
Customer Service/Repair Department to obtain a Returned Material Authorization (RMA)
number.
In the event that it is determined that the equipment failure is covered under the warranty,
Metrologic shall, as its sole option, repair the Product or replace the Product with a
functionally equivalent unit and return such repaired or replaced Product without charge
for service or return freight, whether distributor, dealer/reseller, or retail consumer, or
refund an amount equal to the original purchase price.
This limited warranty does not extend to any Product which, in the sole judgement of
Metrologic, has been subjected to abuse, misuse, neglect improper installation, or
accident, nor any damage due to use or misuse produced from integration of the Product
into any mechanical, electrical or computer system. The warranty is void if the case of
Product is opened by anyone other than Metrologic’s repair department or authorized
repair centers.
THIS LIMITED WARRANTY, EXCEPT AS TO TITLE, IS IN LIEU OF ALL OTHER WARRANTIES OR
GUARANTEES, EITHER EXPRESS OR IMPLIED, AND SPECIFICALLY EXCLUDES, WITHOUT
LIMITATION, WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
PURPOSE UNDER THE UNIFORM COMMERCIAL CODE, OR ARISING OUT OF CUSTOM OR
CONDUCT. THE RIGHTS AND REMEDIES PROVIDED HEREIN ARE EXCLUSIVE AND IN LIEU OF
ANY OTHER RIGHTS OR REMEDIES. IN NO EVENT SHALL METROLOGIC BE LIABLE FOR ANY
INDIRECT OR CONSEQUENTIAL DAMAGES, INCIDENTAL DAMAGE, DAMAGES TO PERSON OR
PROPERTY, OR EFFECT ON BUSINESS OR PROPERTY, OR OTHER DAMAGES OR EXPENSES
DUE DIRECTLY OR INDIRECTLY TO THE PRODUCT, EXCEPT AS STATED IN THIS WARRANTY.
IN NO EVENT SHALL ANY LIABILITY OF METROLOGIC EXCEED THE ACTUAL AMOUNT PAID TO
METROLOGIC FOR THE PRODUCT. METROLOGIC RESERVES THE RIGHT TO MAKE ANY
CHANGES TO THE PRODUCT DESCRIBED HEREIN.
CORPORATE HEADQUARTERS,
NORTH AMERICA
METROLOGIC EUROPEAN REPAIR CENTER
(MERC)
Metrologic Instruments, Inc.
90 Coles Rd.
Blackwood, NJ 08012-4683
Customer Service Department
Tel: 1-800-ID-METRO
Fax: 856-228-6673
Metrologic Eria Ibérica, SL
C/Alfonso Gomez, 38-40, 1D
28037 Madrid
Tel: +34 913 751 249
Fax: +34 913 270 437
Email: [email protected]
MTLG AUTO ID INSTRUMENTS (SHANGHAI) CO., LTD
Suzhou Sales Office
BLK A, Room# 03/03-04
No.5 Xinghan Street, Xinsu Industrial Square
China-Singapore Suahou Industrial Park, Suzhou, PRC
Tel: 86-512-67622550
Fax: 86-512-67622560
Email: [email protected]
40
NOTICES
Changes or modifications not expressly approved by the party responsible for
compliance could void the user’s authority to operate the equipment.
Class A Devices
This equipment has been tested and found to comply with limits for a Class A digital
device, pursuant to part 15 of the FCC Rules. These limits are designed to provide
reasonable protection against harmful interference when the equipment is operated in
a commercial environment. This equipment generates, uses and can radiate radio
frequency energy and, if not installed and used in accordance with the instruction
manual, may cause harmful interference to radio communications. Operation of this
equipment in a residential area is likely to cause harmful interference, in which case
the user will be required to correct the interference at their own expense. Any
unauthorized changes or modifications to this equipment could void the user’s
authority to operate this device.
This device complies with part 15 of the FCC Rules. Operation is subject to the
following two conditions: (1) This device may not cause harmful interference, and (2)
this device must accept any interference received, including interference that may
cause undesired operation.
Notice
This Class A digital apparatus complies with Canadian ICES-003.
Remarque
Cet appareil numérique de classe A est conforme à la norme canadienne NMB-003.
European Standard
Warning
This is a class A product. In a domestic environment this product may cause radio
interference in which case the user may be required to take adequate measures.
Funkstöreigenschaften nach EN55022:1998
Warnung!
Dies ist eine Einrichtung der Klasse A. Diese Einrichtung kann im Wohnbereich
Funkstörungen verursachen. In diesem Fall kann vom Betreiber verlangt werden,
angemessene Massnahmen durchzuführen.
Standard Europeo
Attenzione
Questo e’ un prodotto di classe A. Se usato in vicinanza di residenze private
potrebbe causare interferenze radio che potrebbero richiedere all’utilizzatore
opportune misure.
Attention
Ce produit est de classe “A”. Dans un environnement domestique, ce produit peut
être la cause d’interférences radio. Dans ce cas l’utiliseteur peut être amené à
predre les mesures adéquates.
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March 2004, Version 01
Printed in the USA
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