`
`CABLE GLAND TYPE
`: TMC2X
`
`INGRESS PROTECTION
`: IP66, NEMA 4X
`
`PROCESS CONTROL SYSTEM
`: BS EN ISO 9001
`
`
`
`: ISO/IEC 80079-34:2011
`EXPLOSIVE ATMOSPHERES CLASSIFICATION
`ATEX CERTIFICATION No
`
`: SIRA 09ATEX1165X
`ATEX CERTIFICATION CODE
`
`: II 2G 1D, Ex d IIC, Ex e IIC Gb, Ex ta IIIC Da
`IECEx CERTIFICATION No
`
`: IECEx SIR.09.0069X
`IECEx CERTIFICATION CODE
`
`: Ex d IIC Gb / Ex e IIC Gb, Ex ta IIIC Da
`c-CSA-us CERTIFICATION No
`
`: 2194053
`c-CSA-us CERTIFICATION CODE
`
`: Class I Div 1 and 2 Groups A, B, C and D; Class II, Div 1 and 2, Groups E, F and G; Class III, Div 1 and 2; Enclosure Type 4X
`
`
`
`: Ex d IIC; Ex e II: Class I, Zone 1, AEx d IIC; AEx e II; AEx ta IIC
`INSTALLATION INSTRUCTIONS
`Installation should only be performed by a competent person using the correct tools. Read all instructions before beginning installation.
`
`INSTALLATION GUIDANCE NOTES
`1.
`In accordance with NEC requirements, glands with NPT and Metric entry threads are suitable for both Divisions and Zones.
`2.
`In accordance with CEC requirements, glands with NPT threads are suitable for both Divisions and Zones. Glands with Metric threads are only suitable for Zones unless fitted with an approved Metric
`to NPT thread conversion adaptor.
`For IEC and/or ATEX installations:
` - All tapes/shields/foils must be removed and any twisted pairs/triples unwound to form individual conductors.
` - Drain Wires: Pass sleeving/heat shrink tube over the drain, making sure it is positioned within the resin Tube/Resin Dam area. If required, shrink the tube by applying heat, then treat the drain
`wire as a conductor.
`For NEC Class 1 Div 1 and Zone 1 see article 501.15 of the NEC.
`
`4.
`
`3.
`
`SPECIAL CONDITIONS FOR SAFE USE
`1.
`The glands shall only be fitted to enclosures where temperatures, at the point of mounting, is below 85°C.
`2.
`The cable shall be effectively clamped as close as possible to the gland.
`3.
`When used for Ex e or Ex ta applications, the user shall provide a suitable interface seal between the gland and associated enclosure to maintain the level of ingress protection of the enclosure they
`are fitted to.
` The TMC2X cable glands comrpise of a flameproof labyrinth joint having length and gap dimensions which are other than those specified in IEC 60079-1 and are not intended to be repaired.
`
`4.
`
`Order Reference (NPT)
`
`Entry Thread
`
`Aluminium
`
`Nickel Plated Brass
`
`Stainless Steel
`
`NPT
`
`NPT
`Option
`
`Cable Armour Diameter
`
`Minimum
`Thread
`Length
`
`Cable Jacket
`Diameter
`
`Min Max
`
`Max Over
`Conductors
`
`Across
`Flats
`
`Max
`
`Across
`Corners Nominal
`Assembly
`Length
`
`Max
`
`RapidEx
`Pack
` Suffix
`
`Separate
`RapidEx
`Order Ref
`
`Shroud
`
`Approx
`Weight
`Aluminium
`(Ozs)
`
`0.500 0.750
`
`1.200
`
`1.320
`
`2.440
`
`0.690 0.990
`
`1.480
`
`1.628
`
`2.957
`
`0.870 1.180
`
`1.020 1.370
`
`1.810
`
`1.991
`
`3.154
`
`2.050
`
`2.255
`
`3.547
`
`2.360
`
`2.596
`
`3.591
`
`PVC06
`
`2.290
`
`PVC09
`
`3.000
`
`PVC11
`
`5.110
`
`PVC15
`
`6.700
`
`PVC18
`
`8.820
`
`SCAN FOR INSTALLATION VIDEOS
`
`INSTALLATION INSTRUCTIONS FOR
`CMP CABLE GLAND TYPE TMC2X
`
`CMP TYPE TMC2X CABLE GLAND / GLAND FOR USE WITH INTERLOCKED & CORRUGATED
`CONTINUOUSLY WELDED METAL CLAD (TYPE MC OR MC-HL) OR TECK ARMORED AND
`ARMORED & JACKETED CABLES IN ORDINARY, WET & HAZARDOUS LOCATIONS.
`
`INCORPORATING EU DECLARATION OF CONFORMITY TO DIRECTIVE 2014/34/EU
`
`CABLE GLAND
` TYPE TMC2X
`
`1/2”
`TMC2X-050A075 TMC2X-050NB075 TMC2X-050SS075
`-
`TMC2X-075A075 TMC2X-075NB075 TMC2X-075SS075
`3/4”
`TMC2X-075A099 TMC2X-075NB099 TMC2X-075SS099
`-
`TMC2X-050A099 TMC2X-050NB099 TMC2X-050SS099
`1”
`TMC2X-100A118 TMC2X-100NB118
`TMC2X-100SS118
`TMC2X-075A118 TMC2X-075NB118
`-
`TMC2X-075SS118
`1-1/4”
`TMC2X-125A137 TMC2X-125NB137
`TMC2X-125SS137
`-
`TMC2X-100A137 TMC2X-100NB137
`TMC2X-100SS137
`1-1/2”
`TMC2X-150A162 TMC2X-150NB162
`TMC2X-150SS162
`-
`TMC2X-125A162 TMC2X-125NB162
`TMC2X-125SS162
`1-1/2”
`TMC2X-150A190 TMC2X-150NB190
`TMC2X-150SS190
`-
`TMC2X-125A190 TMC2X-125NB190
`TMC2X-125SS190
`2”
`TMC2X-200A200 TMC2X-200NB200 TMC2X-200SS200
`-
`TMC2X-150A200 TMC2X-150NB200
`TMC2X-150SS200
`TMC2X-250A233 TMC2X-250NB233 TMC2X-250SS233 2-1/2”
`TMC2X-200A233 TMC2X-200NB233 TMC2X-200SS233
`-
`TMC2X-150A233 TMC2X-150NB233
`TMC2X-150SS233
`-
`TMC2X-300A272 TMC2X-300NB272 TMC2X-300SS272
`3”
`TMC2X-250A272 TMC2X-250NB272 TMC2X-250SS272
`-
`TMC2X-200A272 TMC2X-200NB272 TMC2X-200SS272
`-
`TMC2X-350A325 TMC2X-350NB325 TMC2X-350SS325 3-1/2”
`TMC2X-300A325 TMC2X-300NB325 TMC2X-300SS325
`-
`TMC2X-400A376 TMC2X-400NB376 TMC2X-400SS376
`4”
`TMC2X-350A376 TMC2X-350NB376 TMC2X-350SS376
`-
`TMC2X-400A425 TMC2X-400NB425 TMC2X-400SS425
`4”
`
`-
`3/4”
`-
`1/2”
`-
`3/4”
`-
`1”
`-
`1-1/4”
`-
`1-1/4”
`-
`1-1/2”
`-
`2”
`1-1/2”
`-
`2-1/2”
`2”
`-
`3”
`-
`3-1/2”
`-
`
`0.78
`0.80
`0.80
`0.78
`0.98
`0.80
`1.00
`0.98
`1.03
`1.00
`1.03
`1.00
`1.53
`1.03
`1.63
`1.53
`1.03
`1.63
`1.63
`1.53
`1.68
`1.63
`1.73
`1.68
`1.73
`
`Armour
`Armour
`Stop Out
`Stop In
`Min Max Min Max
`0.42
`0.55 0.55 0.63
`0.42
`0.55 0.55 0.63
`0.60
`0.65 0.65 0.89
`0.60
`0.78 0.78 0.89
`0.79
`0.86 0.86 1.10
`0.79
`0.98 0.98 1.10
`0.94
`1.08 1.08 1.28
`0.94
`1.18 1.18 1.28
`1.22
`1.35 1.35 1.50
`1.22
`1.42 1.42 1.50
`-
`-
`1.51 1.72
`-
`-
`1.51 1.72
`1.57
`1.70 1.70 1.88
`1.57
`1.70 1.70 1.88
`-
`-
`1.81 2.21
`-
`-
`1.81 2.21
`-
`-
`1.81 2.21
`2.14
`2.46 2.17 2.61
`2.14
`2.46 2.46 2.61
`2.14
`2.46 2.46 2.61
`2.49
`2.78 2.78 2.97
`2.49
`2.78 2.78 2.97
`2.95
`3.45 3.45 3.54
`2.95
`3.45 3.45 3.54
`-
`-
`3.56 3.94 3.700 4.250
`
`1.300 1.620
`
`1.570 1.900
`
`1.650 2.000
`
`1.910 2.330
`
`2.270 2.720
`
`2.620 3.250
`
`3.160 3.760
`
`CMP Document No. FI401 Issue 12, CSA Issue 7 09/14, IEC Issue 7 11/14
`
`Logo’s shown for illustration purposes only. Please check certification for details
`
`0.51
`0.51
`0.71
`0.51
`0.94
`0.71
`1.20
`0.94
`1.46
`1.20
`1.46
`1.20
`1.63
`1.46
`2.13
`1.90
`1.46
`2.55
`2.13
`1.90
`2.98
`2.98
`3.38
`3.38
`3.38
`
`2.560
`
`2.816
`
`3.587
`
`2.750
`
`3.025
`
`3.756
`
`2.950
`
`3.245
`
`3.972
`
`3.540
`
`3.894
`
`4.098
`
`4.330
`
`4.763
`
`4.665
`
`4.840
`
`5.324
`
`5.230
`
`5.753
`
`4.953
`
`5.161
`
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`1EX
`
`RAPIDEX30
`RAPIDEX30
`RAPIDEX30
`RAPIDEX30
`RAPIDEX30
`RAPIDEX30
`RAPIDEX30
`RAPIDEX30
`RAPIDEX80
`RAPIDEX30
`RAPIDEX80
`RAPIDEX30
`2RAPIDEX80
`RAPIDEX80
`2RAPIDEX80 PVC28
`2RAPIDEX80
`RAPIDEX80
`3RAPIDEX80 PVC31
`2RAPIDEX80
`2RAPIDEX80
`3RAPIDEX80
`3RAPIDEX80
`4RAPIDEX80
`3RAPIDEX80
`4RAPIDEX80
`
`PVC37
`
`PVC21
`
`PVC23
`
`PVC28
`
`PVC32
`
`LSF33
`
`LSF34
`
`9.450
`
`11.060
`
`12.770
`
`24.690
`
`42.680
`
`53.440
`
`59.190
`
`Note: *Order Code Example: TMC2X-050A075 - “TMC2X” (Gland Type) - “050” (1/2” NPT Thread) - “A” (Material Aluminium) - “075” (Max Cable Diameter 0.75”)
`
`Dimensions are displayed in inches unless otherwise stated
`
`CMP Products Limited on its sole responsibility declares that the equpement referred to herein conforms to the requirements of the ATEX Directive 2014/34/EU and the following standards:-
`
`EN 60079-0:2012, EN 60079-1:2007, EN 60079-7:2007, EN 60079-15:2010, EN 60079-31:2009, BS 6121:1989, EN 62444:2013
`
`TMC2X - Corrugated & Interlocked
`Metal Clad Armor (MC) or TECK90,
`Continuously Welded Metal Clad Armor
`(MCHL), ACIC-HL, ACWU90-HL, RC90-HL,
`RA90-HL
`
`David Willcock - Certification Engineer (Authorised Person)
`CMP Products Limited, Cramlington, NE23 1WH, UK
`24th June 2015
`
`Glasshouse Street • St. Peters • Newcastle upon Tyne • NE6 1BS
`Tel: +44 191 265 7411 • Fax: +44 1670 715 646
`E-Mail: customerservices@cmp-products.co.uk • Web: www.cmp-products.com
`Notified Body: Sira Certification Service, Unit 6, Hawarden Industrial Park, Hawarden, CH5 3US
`
`0518
`
`www.cmp-products.com
`
`Cooper v. CMP; IPR2018-00994
`CMP Ex 2010; page CMP0862
`
`
`
`INSTALLATION INSTRUCTIONS FOR CMP TMC2X
`CABLE GLAND COMPONENTS - It is not necessary to dismantled the cable gland any further than illustrated below
`1.
`RapidEx Resin
`2.
`Resin Tube
`3.
`Entry Component
`4.
`Sealant Tape or Inner Jacket
`5.
`Resin Dam
`6.
`End Stop
`7.
`Grounding Spring
`8.
`Jacket Seal
`9.
`Outer Nut
`
`4.
`
`5.
`
`6.
`
`7.
`
`1.
`2.
`3.
`PLEASE READ ALL INSTRUCTIONS CAREFULLY BEFORE BEGINNING THE INSTALLATION
`
`1. Cable preparation — Without Inner Jacket
`Strip back the jacket armor to suit the equipment geometry.
`
`Outer Jacket
`
`Tape
`
`Cable Fillers
`
`Cable Cores
`
`2.
`Cut Tape to Length
`Length = Rear of hexagon to front of Outer Nut
`
`3. Electrical tape MUST be wrapped around the tips of the cable cores.
`This is to ensure the cable cores are together and also to cover any sharp edges
`that could potentially tear the Resin Dam during installation.
`
`8.
`
`9.
`
`4. Pass the cable through the gland until the armor makes contact with the end stop. If it is not possible for the insulated con-
`ductors to pass through the end stop then it should be removed so that the armor can make contact with the integral end stop
`within the entry component. At this stage unscrew the Outer Nut and slide it back over the cable, enough to have access to the
`Armor Spacer. If no access is gained repeat step 2 and trim the outer jacket up to “L” plus 10%. Assemble the gland.
`
`Hand tighten the Outer Nut to compress the
`Grounding Spring to secure the armor. Do not over
`tighten the Outer Nut. Remove electrical tape from
`cable core tips. Separate the cable cores slightly to
`allow resin to flow between them. When insulating
`grounding conductors are present, spread the
`strands slightly to allow the resin to form a full seal.
`
`Refer to ‘RapidEx’ assembly instructions to fill
`the gland resin tube with the required amount
`of RapidEx.
`
`Note: For instrumentation cables utilizing shielded cable, individual/
`overall drain wires, see Installation Guidance Notes overleaf.
`
`3.
`After the tape has been applied, cut
`the cable fillers to the edge of the tape.
`
`---
`---
`
`5. Once the resin has cured, loosen the Outer Nut to ensure that the Grounding Spring is not gripping the cable. Slide the Outer
`Nut back over the cable, enough to loosen the Armor Spacer from the Entry Component. Screw the Entry Component into the
`enclosure. Retighten the Armor Spacer when the entry component is fully tightened into the enclosure.
`
`Using the measure guide, wrap electrical tape around the
`fillers and cores of the cables to the required length
`1.
`
`1. Cable preparation — With Inner Jacket
`Strip back the jacket armor to suit the equipment geometry.
`
`Cut Inner Jacket to Length
`Length = Rear of hexagon to front of Outer Nut
`
`---
`---
`
`Using the measure guide, cut the cable inner jacket
`(and any cable fillers) to the required length. If inner
`jacket is too large for the Resin Dam, cut off and
`replace with electrical tape.
`
`2. Using the armor measure guide, expose the armor further by stripping back the cable jacket
`
`Cut Outer Jacket to Length
`Length = Groove in hexagon to rear of Outer Nut
`
`6. Finally, holding the cable central in the gland, tighten the Outer Nut to compress the Grounding Spring to secure the armor
`and the seal to engage the cable jacket. Do not over tighten the Outer Nut. The Entry Component and Outer Nut do not have to
`close face to face.
`
`NOTE: When the outer jacket is at its
`maximum, cut distance may have to be
`increased by up to 10%.
`
`---
`---
`
`www.cmp-products.com
`
`www.cmp-products.com
`
`Cooper v. CMP; IPR2018-00994
`CMP Ex 2010; page CMP0863
`
`