Beijer ELECTRONICS X2 pro 15 Led Backlight Hmi Touch Panel Instruction Manual
- August 9, 2024
- Beijer ELECTRONICS
Table of Contents
Hardware and Installation Manual
X2 pro 15 – B2
MAEN224
2024-01
X2 pro 15 Led Backlight Hmi Touch Panel
Foreword
All HMI panels are developed to satisfy the demands of human-machine
communication. Built-in functions such as displaying and controlling text,
dynamic indication, time channels, alarm and recipe handling are included. The
HMI panel works primarily in an object-oriented way, making it easy to
understand and use. Configuration is carried out on a PC using iX Developer
software. The project can then be transferred and stored in the HMI panel
itself. Various types of automation equipment such as PLCs, servos or drives
can be connected to the HMI panels. In this manual, the term “the controller”
refers to the connected equipment. This manual explains how to install the HMI
panel. Please refer to the iX Developer reference manual for further
information.
Copyright © 2023 Beijer Electronics AB. All rights reserved.
The information in this document is subject to change without notice and is
provided as available at the time of publishing. Beijer Electronics AB,
including all its group companies, reserves the right to change any
information without updating this publication. Beijer Electronics AB,
including all its group companies, assumes no responsibility for any errors
that may appear in this document. Read the entire document prior to installing
and using this equipment. Only qualified personnel may install, operate or
repair this equipment. Beijer Electronics AB, including all its group
companies, are not responsible for modified, altered or renovated equipment.
Because the equipment has a wide range of applications, users must acquire the
appropriate knowledge to use the equipment properly in their specific
applications. Persons responsible for the application and the equipment must
themselves ensure that each application is in compliance with all relevant
requirements, standards and legislation in respect to configuration and
safety. Only parts and accessories manufactured according to specifications
set by Beijer Electronics AB, including all its group companies, may be used.
BEIJER ELECTRONICS AB, INCLUDING ALL ITS GROUP COMPANIES, SHALL NOT BE LIABLE
TO ANYONE FOR ANY DIRECT, INDIRECT, SPECIAL, INCIDENTAL OR CONSEQUENTIAL
DAMAGES RESULTING FROM THE INSTALLATION, USE OR REPAIR OF THIS EQUIPMENT,
WHETHER ARISING IN TORT, CONTRACT, OR OTHERWISE. BUYER’S SOLE REMEDY SHALL BE
THE REPAIR, REPLACEMENT, OR REFUND OF PURCHASE PRICE, AND THE CHOICE OF THE
APPLICABLE REMEDY SHALL BE AT THE SOLE DISCRETION OF BEIJER ELECTRONICS AB,
INCLUDING ALL ITS GROUP COMPANIES.
Head Office
Beijer Electronics AB
Box 426
201 24 Malmö, Sweden
www.beijerelectronics.com / +46 40 358600
Safety Precautions
Both the installer and users of the HMI panel must read and understand this manual.
1.1. General
- Read the safety precautions carefully.
- Check the delivery for transportation damage. If damage is found, notify the supplier as soon as possible.
- Do not use the HMI panel in an environment with high explosive hazards.
- The supplier is not responsible for modified, altered, or reconstructed equipment.
- Use only parts and accessories manufactured according to specifications of the supplier.
- Read the installation and operating instructions carefully before installing, using or repairing the HMI panel.
- Never allow fluids, metal filings or wiring debris to enter any openings in the HMI panel. This may cause fire or electrical shock.
- Only qualified personnel may operate the HMI panel.
- Storing the HMI panel where the temperature is lower or higher than recommended in this manual can cause the LCD display liquid to congeal and become isotropic.
- The LCD display liquid contains a powerful irritant. In case of skin contact, wash immediately with plenty of water. In case of eye contact, hold the eye open, flush with plenty of water and get medical attention.
- The figures in this manual serve an illustrative purpose. Because of the many variables associated with any particular installation, the supplier cannot assume responsibility for actual use based on the figures.
- The supplier neither guarantees that the HMI panel is suitable for your particular application, nor assumes responsibility for your product design, installation or operation.
- It is recommended to turn on and shut down the HMI panel at least once before installing any components or cards, or before connecting the HMI panel to external devices, for example serial devices.
- For Marine panels only:
- The HMI panel must be installed and operated as described in this document to meet this certification.
- Observe precautions for handling electrostatic discharge sensitive devices.
1.2. Hazardous Materials
Part description | Toxic and hazardous materials or elements |
---|---|
PCB and electronic components | Pb |
PBDE
X| O| O| O| O| O
O: Indicates that the concentration of the hazardous substance in all
homogeneous materials in the parts is below the relevant threshold of the GB/T
26572-2011 standard.
X: Indicates that the concentration of the hazardous substance of at least one
of all homogeneous materials in the parts is above the relevant threshold of
the GB/T 26572-2011 standard. But still complies with the EU RoHS Directive
2011/65/EU.
1.3. Disposal Requirements Under WEEE Regulations
For professional users in the European Union: If you wish to discard
electrical and electronic equipment (EEE), please contact your dealer or
supplier for further information.
For disposal in countries outside of the European Union: If you wish to
discard this product please contact your local authorities or dealer and ask
for the correct method of disposal.
1.4. UL and cUL Installation
CAUTION
This section is only valid for UL labeled X2 panels.
-
This equipment is suitable for use in Class 2 non-hazardous locations only.
[Combinations of equipment in your system are subject to investigation by the local authority having jurisdiction at the time of installation]. -
All devices have to be supplied by a Class 2 power supply.
WARNING
-
Only UL and cUL approved expansion units are allowed to be connected to the port designated “EXPANSION”. At the moment there are no such units evaluated or allowed.
-
Explosion hazard! Substitution of components may impair suitability for Class I, Division 2.
-
Battery may explode if mistreated. Do not recharge, disassemble or dispose of in fire.
-
This product contains a battery; this must only be changed in an area known to be non-hazardous.
-
Replace the battery with a BR2032 battery. Use of another type of battery may present a risk of fire or explosion.
-
For use on a flat surface of a type 4X enclosure indoor use only.
-
Use minimum 75°C copper conductors only.
-
To make wiring connections to the power supply connector, follow the table with cable and torque specifications below:
Terminal Block Connector| Wire Size AWG| Torque (Lb.In.)
---|---|---
X1/X100 Phoenix connectors| AWG 30 – 12| 5 – 7
X1/X100 Anytek connectors| AWG 24 – 12| 3.5
X1/X100 DECA connectors| AWG 24 – 12| 7 -
These devices are Class 2 supplied programmable controllers (industrial PCs) for the use in industrial control equipment and are intended to be (front) panel mounted (Type 12 and 4x for indoor use only).
CAUTION
The enclosure provides a degree of protection of at least IP20, but when
installed in an apparatus, it should meet IP65.
1.5. During Installation
-
The operator panel is designed for stationary installation on a planar surface, where the following conditions are fulfilled:
• no high explosive risks
• no strong magnetic fields
• no direct sunlight
• no large, sudden temperature changes -
Install the HMI panel according to the accompanying installation instructions.
-
Ground the HMI panel according to the accompanying installation instructions.
-
Only qualified personnel may install the HMI panel.
-
Separate the high voltage, signal, and supply cables.
-
Make sure that the voltage and polarity of the power source is correct before connecting the HMI panel to the power outlet.
-
Peripheral equipment must be appropriate for the application and location.
1.6. During Use
- Keep the HMI panel clean.
- Emergency stop and other safety functions may not be controlled from the HMI panel.
- Do not use excessive force or sharp objects when operating the touch screen.
1.7. Service and Maintenance
- Only qualified personnel should carry out repairs.
- The agreed warranty applies.
- Before carrying out any cleaning or maintenance operations, disconnect the equipment from the electrical supply.
- Clean the display and surrounding front cover with a soft cloth and mild detergent.
- The battery must be replaced by an authorized Beijer Electronics service center.
1.7.1. Cleaning the Display
We recommend using a dry, clean cloth to wipe off dust regularly. Use alcohol
or ammonia-based cleaning agent for cleaning only when necessary. When other
solvents or cleaning agents are used, be sure to follow manufacturers’
instructions. The agent should be applied to a clean cloth and should not be
sprayed directly onto the panel surface. After cleaning the agent should be
removed. Ammonia-based glass cleaners (typically 5-10% ammonia) or 75% alcohol
can be used to clean the surface of PCAP and resistive touch panels. When you
clean the surface of your touch panel, please follow these steps:
- Apply cleaning agent (alcohol, bleach, or glass cleaner) to a clean cloth. Make sure the cloth is well saturated.
- Wipe the touch panel surface in a “Z” motion (see illustration below).
- Dry the panel thoroughly with a dry cloth, removing as much of the cleaning solution as possible.
- Do not mix bleach and ammonia because this will produce a dangerous chemical reaction.
- Please do not spray cleaning solution directly onto the touch panel surface.
NOTE
- Cleaning solutions containing bleach, alcohol, and ammonia are corrosive to touch panel surface coatings and ITO film. Do not leave the solution on the touch panel surface for more than 2 minutes. Make sure to remove all residue when finished cleaning.
- Do not use sharp tools to clean the surface of the touch screen.
- Do not use air guns, water jets, or steam, to clean the surface of the touch screen as they may damage touch screen functionality.
- If condiments, food, or drinks are spilled on the surface of the touchscreen, please remove it immediately.
- Ensure moisture does not seep through the cable connection area from the edges during cleaning.
1.8. Dismantling and Scrapping
- Recycle the HMI panel and parts of it according to local regulations.
- The following components contain substances that might be hazardous to health and the environment: lithium battery, electrolytic capacitor, and display.
1.9. Appearance of Air in Touch Screen
The layer structure of the touch screen contains air. In rare cases, the
appearance of bubbles can arise. This is purely cosmetic and does not affect
the functionality of the HMI panel. The appearance can occur under certain
environmental conditions such as changes in temperature, humidity, or
atmospheric pressure.
Naming Convention
The name of each panel is based on its properties according to the table below.
Naming Convention
X2 family | Size (inches) | Generation/Version | Variant | |
---|---|---|---|---|
base | 4 | v2 | SC | Soft Control |
pro | 5 | SM | Soft Motion | |
marine (= with BL) | 7 | HB | High Brightness | |
control (= with SC) | 10 | HP | High Performance | |
motion (= with SM) | 12 | BL | Black | |
extreme | 15 | 12V | 12 Volt | |
21 | SL | Sealed | ||
RO | Rugged Only | |||
CO | Certification Only | |||
web | Web |
Examples:
- X2 base 5 v2
- X2 pro 7
- X2 control 10
- X2 marine 12 SC
- X2 marine 15 HB SC
- X2 extreme 7 12V*
- X2 extreme 12 HP SC*
- X2 extreme 7 SL HP*
- X2 extreme 12 SL HP SC*
- X2 extreme 7 CO*
- X2 extreme 12 SL HP RO
NOTE
Not all combinations are available.
NOTE
* indicates variants including IECEx\ATEX and C1D2 accreditation.
Installation
3.1. Space Requirements
- Maximum installation plate thickness: 8 mm.
The following drawings show the space requirements in millimeters when
installing the HMI panel.
The drawings are only illustrative and may be out of proportion.
3.2. Installation Process
The following is needed:
- A Phillips/slot screwdriver
Do the following:
-
Unpack and check the delivery. If damage is found, notify the supplier.
NOTE
Place the on a stable surface during installation. Dropping the HMI panel or letting it fall may cause damage. -
To cut a correct opening for the HMI panel, use the cut out dimensions in the outline drawing.
A separate cut out drawing is available for download from the Beijer Electronics web site. For more information, see chapters HMI Panel Drawings and Technical Data. -
Make sure that the mounting surface of the cutout is smooth and cleaned from any burrs or debris.
-
Install the HMI panel into the cutout.
-
Secure the HMI panel in position by screwing the slotted thumb screw clockwise, allowing the built-in bracket to flip out and tighten against the cabinet as shown.Tighten the screws to 0.7 ± 0.2 Nm.
-
In cases where the front panel seal (IP54 or greater, NEMA-4X) is critical, use a torque wrench to ensure all screws are torqued within the specification above.
-
Connect the cables in the specified order, according to the following drawing and steps.The image is illustrative only and may differ slightly from the actual panel.
• Connect cable A.
• Connect cable B, using 14-20 AWG (2.08–0.52 mm²), 180–220 N-cm torque.
• Connect cable C.
• Connect cable D. The recommended cross-section of the cable is 1.5 mm². -
Carefully remove the protective film over the HMI panel display, taking care to avoid static electricity that could damage the panel.
CAUTION
- The HMI panel must be brought to ambient temperature before it is started up. If condensation forms, ensure that the HMI panel is dry before connecting it to the power outlet.
- Ensure that the HMI panel and the controller system have the same electrical grounding (reference voltage level), otherwise errors in communication may occur.
- Ensure that the voltage and polarity of the power source is correct.
- Separate high voltage cables from signal and supply cables.
- Shielded communication cables are recommended.
3.2.1. Connections to the Controller
For information about the cables to be used when connecting the HMI panel to
the controller, please refer to the help file for the driver in question.
3.2.2. Other Connections and Peripherals
Cables, peripheral equipment and accessories must be suitable for the
application and its environment. For further details or recommendations,
please refer to the supplier.
Technical Data
Parameter | X2 pro 15 – B2 |
---|---|
Front panel, W×H×D | 410 × 286 × 8 mm |
Cutout dimensions, W×H | 394 × 270 mm |
Mounting depth | 53 mm (153 mm including clearance) |
Standalone mounting | VESA 75 × 75 |
Note: Maximum screw length for VESA mounting is 4 mm. Usage of longer screws
may lead to damage.
Front panel seal| IP 65
Rear panel seal| IP 20
Touch screen material| Polyester on glass, ITO film, resistive
Frame overlay| Autoflex EBA 180L
Touch screen operations| 1 million finger touch operations
Reverse side material| Powder-coated aluminum
Frame material| Powder-coated aluminum
Weight| 3.85 kg
CPU| i.MX6 DualLite
Dual ARM Cortex-A9 Core 1.0GHz
1 MB L2 cache
Serial ports| Standard D-sub (9 Pin, female) COM1: RS-232 with RTS/CTS COM2:
RS-422/RS-485
COM3: RS-485
1×RS-232 Rx/Tx with RTS/CTS and 1×RS-422 or 2×RS-485 or 1x CAN2.0B .
Ethernet LAN A| 10/100 Mbit Base-T (shielded RJ45 with LEDs)
Ethernet LAN B| 10/100 Mbit Base-T (shielded RJ45 with LEDs)
USB| 2 × USB Host 2.0, max output current 500 mA
Supports up to USB 2.0 High Speed
External storage media| 1 × SD card
Flash memory (application memory)| 1.5 GB SSD (eMMC)
Memory RAM| 1 GB (DDR3)
NVRAM| N/A
LED| 1 × Multi color
Real time clock| Yes
Battery| BR 2032 lithium battery replaceable
Parameter| X2 pro 15 – B2
---|---
Power consumption at rated voltage| 31.2 W
Fuse| Internal DC fuse, 4 AT, 5 × 20 mm
Power supply| +24 VDC (18–32 V DC)
CE: The power supply must conform with the requirements according to
EN/IEC 60950 and EN/IEC 61558-2-4.
UL and cUL: The power supply must conform with the requirements for class
2 power supplies.
Display| TFT-LCD with LED backlight
1280 × 800 pixels, 262k colors
Active area of display| 15.4” diagonal
Pixel errors| Class I (ISO 9241-307)
Backlight brightness| 450 Cd/m2
Backlight lifetime| 50,000 hours
Operating temperature| -10°C to +60°C
Storage temperature| -20°C to +70°C
Relative humidity in operation| 5 – 85% non-condensation
Vibration| 1g, according to IEC 60068-2-6, Test Fc
Mechanical shock| 15g, half-sine, 11ms according to IEC60068-2-27
Approvals and certifications| CE/FCC/KCC Information is available on
www.beijerelectronics.com
UL approval| Information is available on www.beijerelectronics.com
and UL.com
Marine certificates| Information is available on
www.beijerelectronics.com
4.1. Compass Safe Distance
Variant | Condition | Standard Compass | Steering Compass |
---|---|---|---|
X2 pro 15 | Non-energized | 95 cm | 85 cm |
Non-energized after magnetization | 95 cm | 85 cm | |
Energized and operating | 95 cm | 85 cm |
Chemical Resistance
5.1. Metal Casing
The frame and casing material is powder-coated aluminum. This powder paint
withstands exposure to the following chemicals without visible change:
Acetic acid 10% | Phosphoric acid 4% |
---|---|
Citric acid 10% | Phosphoric acid 10% |
Diesel | Sea water |
Distilled water | Sodium chloride 2% |
Edible oil | Sodium chloride 20% |
Fuel oil | Sulphuric acid 20% |
Hydrogen peroxide 3% | Tap water |
The powder paint shows limited resistance to the following chemicals at room temperature:
Butanol | Nitric acid 3% |
---|---|
Hydrochloric acid 5% | Nitric acid 10% |
Isopropyl alcohol | Phosphoric acid 43% |
Sodiumhypochlorite 10% | Turpentine |
NOTE
If exposure to any of the above chemicals is demanded, it is recommended to
first test the chemical in a hidden spot of the metal casing.
The powder paint shows little or no resistance to the following chemicals at room temperature:
Acetic acid, conc. | Methyl-ethyl ketone | Toluene |
---|---|---|
Acetone | Nitric acid 30% | Trichlorethylene |
Ammonia 5% | Phenol | Xylene |
Ammonia, conc. | Sodium hydroxide 5% | 97 octane unleaded petrol |
Ethyl acetate | Sodium hydroxide 30% | 98 octane leaded petrol |
5.2. Touch Screen and Overlay Material
5.2.1. Protective Film
The Autoflex protective film covers the overlay surrounding the screen.
Solvent Resistance
The protective film withstands exposure of more than 24 hours duration under
DIN 42115 Part 2 to the following chemicals without visible change:
Acetonitrile | Diesel | Petroleum spirit¹ |
---|---|---|
Ajax / Vim in solution | Downy / Lenor1 | Phosphoric acid (<30%) |
Alkalicarbonate solution¹ | Ethanol | Potassium ferricyanide |
Ammonia (<40%)¹ | Glycerine | Potassium hydroxide (<30%) |
Acetic acid (<50%) | Glycol | Pure Turpentine |
Ariel powder in solution¹ | Gumption¹ | SBP 60/95¹ |
Bleach1 | Hydrochloric acid (<36%) | Sulfuric acid (<10%) |
Castor oil | Linseed oil | Tomato ketchup |
Caustic soda (<40%)¹ | Methanol | Trichloroacetic acid (<50%) |
Cutting oil | Nitric acid (<10%) | White Spirit |
Cyclohexanol | Paraffin oil | Windex1 |
Diacetone alcohol | Persil powder in solution¹ | Wisk |
¹Extremely faint glossing of the texture was noted.
The Autoflex protective film withstands DIN 42 115 Part 2 exposure of up to 1
hour duration to glacial acetic acid without visible change.
The Autoflex protective film is not resistant to high pressure steam at over
100°C or the following chemicals:
Concentrated mineral acids | Benzyl alcohol |
---|---|
Concentrated caustic solution | Methylene chloride |
5.2.2. Touch Screen Surface
The touch screen surface on the HMI panel withstands exposure to the following
solvents without visible change:
Solvents | Time |
---|---|
Acetone | 10 minutes |
Isopropanol | 10 minutes |
Toluene | 5 hours |
The touch screen surface on the HMI panel is made of polyester with a hard coat to resist scratches and withstand exposure to many solvents without visible change.
5.2.3. Touch Screen Protector
For harsh environments and exposure to outdoor conditions, it is recommended
to use a protective film to guard the touch screen from damage. This optional
part can be ordered from Beijer Electronics.
HMI Panel Drawings
6.1. Connectors
Pos | Connector | Description |
---|---|---|
1 | Power supply | +24 V DC (18–32 V DC) |
2 | USB | USB Host 2.0, max output current 500mA |
3 | LAN A | 1×10/100 Base-T (shielded RJ45) |
4 | LAN B | 1×10/100 Base-T (shielded RJ45) |
5 | COM | Serial communication port |
6.1.1. Communication Ports
Pin | D-sub-9, female |
---|---|
COM 1 | COM 2 |
1 | |
RS-485 Tx+/Rx+ | |
2 | RS-232 RxD |
3 | RS-232 TxD |
4 | |
5 | GND |
6 | |
RS-485 Tx-/Rx- | |
7 | RS-232 RTS |
8 | RS-232 CTS |
9 |
The connector supports up to three independent communication channels and can be configured for RS-232 and RS-422 or 2x RS-485 or 1x CAN.
NOTE
In order to utilize two communication ports, the Y-split cable CAB109 can be
used.
To use RS-232 and RS-422, use CAB 109.
6.2. HMI Panel Outline
NOTE
A Step CAD file is available on
www.beijerelectronics.com
Additional Installation Tips
When experiencing communication problems in noisy environments or when operating close to temperature limits, the following recommendations are to be noticed.
7.1. Grounding the HMI Panel
The mounting clamps of the HMI panel do not provide a secure grounding connection between the panel and the device cabinet, see 1 in drawing above. To ground the HMI panel:
- Connect a wire, that is sized correctly according to local electrical codes, between the quickconnect terminal connector on the HMI panel and the chassis of the panel, see 2 in drawing above.
- Connect a wire or grounding braid, that is sized correctly according to local electrical codes, between the chassis of the HMI panel and the closest grounding point on the door, see 3 in drawing above.
- Connect a strong but short grounding braid between the door and the device cabinet, see 4 in drawing above.
- Twist the cables onto the 24 V DC feed, see 5 in drawing above.
• 2 turns around the ferrite core provide 4 times the suppression of 1 turn.
• 3 turns around the ferrite core provide 9 times the suppression of 1 turn.
• Connect a wire or grounding braid, that is sized correctly according to local electrical codes, between the chassis of the HMI panel and the closest grounding point.
NOTE
The grounding wires should be short and the conductor should have a large
area.
A long, thin grounding wire has a very high impedance (resistance) at high
frequencies and does not guide disturbances to the ground.
Multi-wire conductors are better than single wire conductors with the same
area.
A braided conductor wire with the same area is even better. The best is a
short, thick grounding braid.
7.2. Ethernet Connection in the HMI Panel
In some industrial units for Ethernet, the RJ45 contact’s shield is connected
to the chassis via a capacitor, see 1 in drawing above.
The Ethernet shield of the HMI panel is directly connected to the chassis, see
2 in drawing above.
Check whether the other Ethernet unit has its shield directly grounded or
grounded via a capacitor.
NOTE
In many cases, connecting the shielded Ethernet cabling to the chassis at
both ends is inappropriate. Humor grounding loops can occur. Unshielded
cabling may even result in fewer communication errors.
A good solution may be to use a shielded Ethernet cable, but to connect the
shield at one end only.
One option is to break the shield, see 3 in drawing above.
A more elegant method is to expand the shielded Ethernet cabling with a piece
of unshielded Ethernet cable, see 4 in drawing above.
The shield can be grounded via an external 0.1 μF/250 V film capacitor, see 5
in drawing above. This connects the HF transients to ground.
7.3. To Achieve Better EMC Protection
- Initially, use the original cabling from Beijer Electronics primarily.
- Place the 24 V DC and communications cabling in one cable trunk/cable duct and 230/380 V AC in another. If the cables need to be crossed, cross them at 90° only. Avoid combining the cabling for stronger 24 V DC outputs with the communication cabling.
- Use shielded cables for RS-232 communication.
- Use twisted pair and shielded cabling for RS-422 and RS-485.
- Use the cabling intended for the bus type; Ethernet, Profibus, CC-Link, CAN, Device Net etc.
- Install and connect according to applicable specifications for the relevant bus standard.
- Use shielded cabling for Ethernet, preferably with foil and a braided shield.
- D-sub covers should be shielded, and the shield should be connected to the cover 360° where the cable enters.
- Connect the shield at both ends.
With longer distances, there is a risk that the ground potential may be different. In that case, the shield should only be connected at one end. A good alternative is to connect the other end of the shield to the ground via a 0.1 μF / 250 V film capacitor. Both ends are then connected to the ground in terms of HF, but only connected to the ground at one end in terms of LF, thus avoiding the 50/60 Hz grounding loops.
- Use an EMC cable gland or regular plastic cable gland, remove the outer jacket and connect the shield to the installation plate with a 360° metal cable clamp.
- Place the 24 V DC and communications cabling in one cable trunk/cable duct and 230/380 V AC in another. If the cables need to be crossed, cross them at 90° only. Avoid combining the cabling for stronger 24 V DC outputs with the communication cabling.
NOTE
Ferrite cores that are snapped onto the shielded cabling may remove minor
disturbances. Large ferrite pieces that are snapped onto unshielded cabling
and where the wires go 2-4 times around the cores are approximately 5-25 times
more efficient.
7.4. Ambient Temperature
The maximum ambient temperature for the HMI panel is provided in the
specifications. The ambient temperature refers to the temperature in the
device cabinet which cools the HMI panel’s electronics.
In most cases, the ambient temperature for the HMI panel is significantly
higher than the device cabinet’s ambient temperature.
If the cabinet is tall and there are a number of heat-generating devices, the
temperature at the top of the cabinet is considerably higher than the
temperature increase that would be expected. All electronics are sensitive to
heat. The lifespan of an electrolytic capacitor is cut in half with an 8-10 °C
increase in temperature. A 15-20 °C temperature increase results in a quarter
of the lifespan etc. Rittal has a good program for estimating the anticipated
average temperature in the cabinet as well as a large program for controlling
the temperature in the device cabinet.
An enamel-coated steel cabinet has a radiant heat value of 5.5 W/m² per °C.
Installing a fan inside the cabinet evens out the temperature, while moving
air provides considerably better cooling than still air.
Install the fan so that it sits in a cooler area and blows cold air against
the HMI panel. If the fan is mounted at the top and sucks warm air upwards,
the ambient temperature of the fan becomes higher, resulting in a shorter
lifespan.
An approximate value of the net power consumption for the HMI panel can be
calculated by multiplying the supply voltage with the current drawn by the HMI
panel. This is assuming that all supplied power is transformed to heat.
NOTE
Please ensure that the temperature will not exceed the maximum ambient
operating temperature in the enclosure. This can be influenced by other heat
generating devices.
7.5. Safety
If a power supply that meets safety standards is used and only powers the HMI
panel, there is no problem. See 1 in drawing above.
However, if a 24 V unit that also powers other units is used, there is reason
to be cautious, see 2 in drawing above. The HMI panel does not have insulation
that meets safety requirements in the event of a potential short circuit
between 230 V AC and 24 V DC. It is assumed that the 24 V power supply is
secure, for example, SELV according to EN 60950 (protection against electric
shock) and UL 950.
NOTE
Here is an example that explains why a secure 24 V DC power supply can be
ruined by mixing 24 V relay contacts with 230 V AC relay contacts in a smaller
controller. Check that the clearances and creepage distances between 24 V DC
and 230 V AC fulfill EN 60950 or UL 950. If not, input a separate 24 V unit
into the HMI panel.
If there is a substantial distance between the relay contacts for 24 V DC and
230 V AC, it is OK to use the same 24 V devices for all feeds. See 3 in
drawing above.
Connect 0 V on the 24 V power supply to the ground, see 4 in drawing above.
This offers three advantages:
- Safety is increased. The 24 V power supply is not live in the event of a faulty connection or short circuit between 0 V (24 V) and 230 V phase.
- Transients on the 24 V feed are connected to the ground.
- No risk that the 24 V feed is at a high level in relationship to the ground. This is not unusual since there is high static electricity.
7.6. Galvanic Isolation
The HMI panel has galvanic isolation against the 24 V DC power supply but no galvanic isolation between the communication ports for RS-232, RS-422, RS-485, CAN and USB. Only the Ethernet connection has galvanic isolation.
When a PC is connected to the HMI panel, the internal 0 V (GND) of the panel
is connected to the protective ground via the PC.
A number of USB devices can have the shield connected together with the
protective ground. Here, the 0 V (GND) of the HMI panel is connected to the
protective ground when, for example, a USB memory stick, keyboard, or similar
device is plugged in.
If a number of units are connected that have a 0 V and a ground connection,
and these are connected to various grounding points, there is a substantial
risk of problems. Grounding currents go through communication cables, the rear
plate of the controller, internally in the HMI panel, and can cause errors.
Use external units to improve communication and achieve galvanic isolation.
Westermo has good industry-standard insulators that are also insulated from
the 24 V DC feed.
NOTE
It is very important to make sure that the 24 V feed in the external
insulation unit is not connected to one of the communication outlets. If it
does not have 100% insulation against the 24 V feed, disturbances and
grounding currents from the 0 V on the 24 V side disrupt the communication.
Using this type of unit solves one problem but creates a larger problem! A
substandard installation may work now, but problems may arise when other
devices are connected.
7.7. Cable and Bus Termination RS-485
- If maximum transfer distance and maximum transfer speed is needed, shielded and twisted pair cable should be used. The mutual capacitance may not exceed 52.5 pF/m, and the cable area should be at least 0.25 mm² (AWG 24).
- 0 V, the reference voltage for communication should be included in the cabling. With two-way communication use two pairs; one pair for communication and one pair for 0 V.
- The shield must be grounded at one end. The other end is usually grounded, but with longer distances or when there is a difference in the ground potential, the shield should be connected to the ground via 0.1 μF / 250 V film capacitor to prevent ground current in the braided shield. Some manufacturers recommend that the shield be grounded at each node. Various manufacturers have different systems for bus termination.
Depending on the recipients’ design, the bus wires may be on the same level or require pull-up or pull-down to ensure that no faulty signals are detected when the bus is in resting mode (all transmitters are disconnected).
7.8. CAN Interface
7.8.1. Cable Recommendations
-
Use shielded, twisted pair cable to improve noise immunity and to reduce radiated emissions.
Characteristic impedance: 120 Ohm (typical)
Propagation delay: 5 ns/m
Mutual capacitance: 40 pF/m (typical, wire to wire) -
Recommended cable cross section:
Bus length 0-40 m: 0.25-0.34 mm² (AWG23,AWG22), 70 mOhm/m
Bus length 40-300 m: 0.34-0.6 mm² (AWG22,AWG20), < 60 mOhm/m
Bus length 300-600 m: 0.5-0.6 mm² (AWG20), < 40 mOhm/m
Bus length 600-1000 m: 0.75-0.8 mm² (AWG18), < 26 mOhm/m -
GND should be included in the cabling to provide a reliable reference Ground for each CAN node (potential equalization). Use two wire pairs; one pair for communication and one pair for GND. Do not use the cable shield to connect GND.
7.8.2. Termination
- To achieve the best signal integrity, noise immunity and reliable bus performance, the CAN network must be terminated at its two most distant CAN nodes with 118Ohm… 130Ohm resistors. The recommended resistor value is 120 Ohm/1%/0.25W on each end.
- Place the termination resistor near the CAN bus connector (as close as possible).
- This product has no integrated termination resistors. They must be added externally.
7.8.3. Restrictions and Recommendations
- The maximum supported bit rate depends on bus load, bus topology, number of nodes, bus termination, propagation delay of each CAN node and the bus length.
- Do not connect more than 32 nodes to one CAN network without using a repeater.
- If the bus length exceeds about 200 m, it is recommended to use CAN nodes with built-in galvanic isolation.
- If the bus length exceeds 1000 m, a CAN bus repeater should be used.
- For additional information refer to the driver documentation for FreeCAN and Can Open in the iX Developer software.
7.9. USB Flash Drive
The USB port, or ports, are of 2.0 standard and support FAT16, FAT32 and exFAT
file systems for USB flash drives (option, sold separately).
Size limitations for file systems:
- FAT16: up to 2 GB
- FAT32: up to 32 GB
- exFAT: up to 2 TB
7.10. Image Sticking
When utilizing TFT LCD HMI panels in applications where a fixed or partially
fixed image remains displayed on the screen for extended periods of time,
users may experience a phenomenon referred to by the LCD industry as Image
Sticking. Image sticking, sometimes also called “image retention” or
“ghosting”, is a phenomenon where a faint outline of a previously displayed
image remains visible on the screen when the image is changed.
Image sticking can be caused by:
- Static images
- No screensaver
- Sharp contrast transition (e.g. black/white)
- High ambient temperatures
How Image sticking can be avoided or reduced:
- Use the screensaver functionality (see SW manual).
- Changing constantly between static and dynamic images.
- Avoid excessive brightness differences between foreground and background elements.
- Use colors with similar brightness.
- Use complementary colors in follow-up images.
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