Spirax Sarco BCV Blowdown Control Valves half inch to 2inch Installation and Maintenance Instructions
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IM-P403-103 4035950 / 1 AB Issue 1 BCV Blowdown Control Valves DN15 to DN50 (½" to 2") Installation and Maintenance Instructions Electrically actuated BCV boiler blowdown valve 1. Safety information 2. General product information and application 3. Technical data 4. Installation and dimensions 5. AHL1 Actuator with spring return 6. Flow setting 7. Rotating the electrical actuator 8. Wiring of the electrical actuator Pneumatically actuated BCV boiler blowdown valve 9. Pneumatic actuator Stroke adjustment 10.Maintenance 11.Spare parts © Copyright 2013 Printed in France 2 IM-P403-103 AB Issue 1 1. Safety information Safe operation of these products can only be guaranteed if they are properly installed, commissioned, used and maintained by qualified personnel (see Section 1.11 on this document) in compliance with the operating instructions. General installation and safety instructions for pipeline and plant construction, as well as the proper use of tools and safety equipment must also be complied with. WARNING 1. Your attention is drawn to any National or Regional regulations concerning boiler blowdown. In the UK, guidance is given in HSE Guidance Note PM60. the EL actuator is used it must be electrically isolated before any maintenance is carried out. 2. When 1.1 Intended use Referring to the Installation and Maintenance Instructions, name-plate and Technical Information Sheet, check that the product is suitable for the intended use / application. The products listed below comply with the requirements of the European Pressure Equipment Directive 97 / 23 / EC (PED) and carry the mark when so required. Pressure equipment not bearing the mark is classified 'Sound Engineering Practice' in accordance with Article 3, Paragraph 3 of the PED. Note: By law, SEP products cannot be marked with the symbol. BCV blowdown control valves fall within the following PED categories: Product DN15 - DN25 PN40 PN63 PN100 BCV4 ASME 300 ASME 600 JIS 20K KS 20K IM-P403-103 AB Issue 1 DN32 Group 1 Gases Group 2 Gases Group 1 Liquids Group 2 Liquids SEP SEP SEP SEP 2 SEP SEP SEP DN40 - DN50 2 1 SEP SEP DN15 - DN25 SEP SEP SEP SEP DN32 2 SEP 2 SEP DN40 - DN50 2 1 2 SEP DN15 - DN25 SEP SEP SEP SEP DN32 2 SEP SEP SEP DN40 - DN50 2 1 2 SEP DN15 - DN25 SEP SEP SEP SEP DN32 2 SEP 2 SEP DN40 - DN50 2 1 2 SEP DN15 - DN25 SEP SEP SEP SEP DN32 2 SEP SEP SEP DN40 - DN50 2 1 SEP SEP 3 Group 1 Gases Product DN15 - DN25 PN40 PN63 PN100 BCV6 ASME 300 DN32 JIS 20K KS 20K PN25 ASME 125 Group 2 Liquids SEP SEP SEP SEP 2 SEP SEP SEP DN40 - DN50 2 1 SEP SEP SEP SEP SEP SEP 2 SEP 2 SEP DN32 DN40 - DN50 2 1 2 SEP DN15 - DN25 SEP SEP SEP SEP 1 SEP SEP SEP DN32 DN40 2 1 SEP SEP DN50 2 1 2 SEP SEP SEP SEP SEP DN32 2 SEP 2 SEP DN40 - DN50 2 1 2 SEP DN15 - DN25 SEP SEP SEP SEP 2 SEP SEP SEP DN32 DN40 - DN50 2 1 SEP SEP DN15 - DN25 SEP SEP SEP SEP DN32 - DN40 1 SEP SEP SEP DN50 BCV7 Group 1 Liquids DN15 - DN25 DN15 - DN25 ASME 600 Group 2 Gases 2 1 SEP SEP DN15 - DN25 SEP SEP SEP SEP DN40 - DN50 1 SEP SEP SEP ASME 250 KS 10 DN15 - DN25 SEP SEP SEP SEP DN40 - DN50 2 1 SEP SEP DN15 - DN25 SEP SEP SEP SEP ASME 600 DN32 2 SEP 2 SEP DN40 - DN50 2 1 2 SEP DN15 - DN25 BCV8 PN63 PN100 SEP SEP SEP SEP DN32 2 SEP 2 SEP DN40 - DN50 2 1 2 SEP i) Check material suitability, pressure and temperature and their maximum and minimum values. If the maximum operating limits of the product are lower than those of the system in which it is being fitted, or if malfunction of the product could result in a dangerous overpressure or overtemperature occurrence, ensure a safety device is included in the system to prevent such over-limit situations. ii) Determine the correct installation situation and direction of fluid flow. 4 IM-P403-103 AB Issue 1 iii) Spirax Sarco products are not intended to withstand external stresses that may be induced by any system to which they are fitted. It is the responsibility of the installer to consider these stresses and take adequate precautions to minimise them. iv) Remove protection covers from all connections and protective film from all name-plates, where appropriate, before installation on steam or other high temperature applications. 1.2Access Ensure safe access and if necessary a safe working platform (suitably guarded) before attempting to work on the product. Arrange suitable lifting gear if required. 1.3Lighting Ensure adequate lighting, particularly where detailed or intricate work is required. 1.4 Hazardous liquids or gases in the pipeline Consider what is in the pipeline or what may have been in the pipeline at some previous time. Consider: flammable materials, substances hazardous to health, extremes of temperature. 1.5 Hazardous environment around the product Consider: explosion risk areas, lack of oxygen (e.g. tanks, pits), dangerous gases, extremes of temperature, hot surfaces, fire hazard (e.g. during welding), excessive noise, moving machinery. 1.6 The system Consider the effect on the complete system of the work proposed. Will any proposed action (e.g. closing isolation valves, electrical isolation) put any other part of the system or any personnel at risk? Dangers might include isolation of vents or protective devices or the rendering ineffective of controls or alarms. Ensure isolation valves are turned on and off in a gradual way to avoid system shocks. 1.7 Pressure systems Ensure that any pressure is isolated and safely vented to atmospheric pressure. Consider double isolation (double block and bleed) and the locking or labelling of closed valves. Do not assume that the system has depressurised even when the pressure gauge indicates zero. 1.8Temperature Allow time for temperature to normalise after isolation to avoid danger of burns. 1.9 Tools and consumables Before starting work ensure that you have suitable tools and / or consumables available. Use only genuine Spirax Sarco replacement parts. 1.10 Protective clothing Consider whether you and / or others in the vicinity require any protective clothing to protect against the hazards of, for example, chemicals, high / low temperature, radiation, noise, falling objects, and dangers to eyes and face. IM-P403-103 AB Issue 1 5 1.11 Permits to work All work must be carried out or be supervised by a suitably competent person. Installation and operating personnel should be trained in the correct use of the product according to the Installation and Maintenance Instructions. Where a formal 'permit to work' system is in force it must be complied with. Where there is no such system, it is recommended that a responsible person should know what work is going on and, where necessary, arrange to have an assistant whose primary responsibility is safety. Post 'warning notices' if necessary. 1.12Handling Manual handling of large and / or heavy products may present a risk of injury. Lifting, pushing, pulling, carrying or supporting a load by bodily force can cause injury particularly to the back. You are advised to assess the risks taking into account the task, the individual, the load and the working environment and use the appropriate handling method depending on the circumstances of the work being done. 1.13 Residual hazards In normal use the external surface of the product may be very hot. If used at the maximum permitted operating conditions the surface temperature of some products may reach temperatures of 580°C (1076°F). Many products are not self-draining. Take due care when dismantling or removing the product from an installation (refer to 'Maintenance instructions'). 1.14Freezing Provision must be made to protect products which are not self-draining against frost damage in environments where they may be exposed to temperatures below freezing point. 1.15Disposal Unless otherwise stated in the Installation and Maintenance Instructions, this product is recyclable and no ecological hazard is anticipated with its disposal providing due care is taken. 1.16 Returning products Customers and stockists are reminded that under EC Health, Safety and Environment Law, when returning products to Spirax Sarco they must provide information on any hazards and the precautions to be taken due to contamination residues or mechanical damage which may present a health, safety o environmental risk. This information must be provided in writing including Health and Safety data sheets relating to any substances identified as hazardous or potentially hazardous. 1.17 conformity of actuators Low Voltage Directive 2006 / 95 / EC EN 60730 1 EN 60730 2 14 Over Voltage category III Degree of pollution III Electrical actuator: EMC Directive 2004 / 108 / EC EN 61000 6 2 EN 61000 6 4 Pneumatic actuator: See the Technical Information for the PN9000 series 6 IM-P403-103 AB Issue 1 2. General product information and application 2.1 Description and application Spirax Sarco's BCV blowdown control valves are manufactured using the market proven SPIRA-TROL body. These valves have been specifically designed for the blowdown of steam boilers or for other high pressure drop, low flow applications, and are generally used with a blowdown controller as part of an automatic TDS control system. The valve may also be used for other high pressure drop, low flowrate applications such as boiler feedpump recirculation. Two versions are available: - Electrically actuated. - Pneumatically actuated. Electrically actuated Standards These products fully comply with the requirements of the European Pressure Equipment Directive 97 / 23 / EC. Certification These products are available with material certification to EN 10204 3.1. Note: All certification / inspection requirements must be stated at the time of order placement. Note: For additional product information see Technical Information sheet TI-P403-102. 2.2 Size and pipe connections ½", ¾", 1", 1¼", 1½" and 2" Screwed BSP or NPT, Socket weld and Butt weld. DN15, DN20, DN25, DN32, DN40 and DN50 Flanged: EN 1092 PN25, PN40, PN63 and PN100 ASME class 125, 150, 250, 300 and 600 JIS / KS 10K, 20K, 30K and 40K Pneumatically actuated Fig. 1 BCV blowdown control valves IM-P403-103 AB Issue 1 7 2.3 Available models: Material Connections Socket weld Flanged Screwed Butt weld Carbon steel BCV41 BCV42 BCV43 BCV44 Stainless steel BCV61 BCV62 BCV63 BCV64 SG iron BCV71 BCV73 BCV82 Alloy steel BCV83 BCV84 BCV blowdown control valves are compatible with the following actuators and positioners: Version Actuator Electric AHL1 series Pneumatic Positioners PN9_ _ _ series PP5 (pneumatic) EP5 (electropneumatic) ISP5 (intrinsically safe electropneumatic) SP200is, SP400 and SP500 (microprocessor based electropneumatic) SP300 (digital communications) 3. Technical data Media Water 3.1Actuator technical data Actuator AHL1 Series Supply voltage Standard 24 Vac, Optional card 230 Vac and 100 Vac Supply frequency 50 to 60 Hz Power consumption 10 to 18 Actuator speed 2 mm / s, 4 mm / s or 6 mm / s Actuators thrust maximum 2 kN Maximum shut-off value 42 bar g Size Actuator DN15 to DN25 ½" to 1" AHL1 series / PN9123E DN32 to DN50 1¼" to 2" AHL1 series / PN9223E Maximum ambient temperature 24 volt version (Connect to class 2 circuit only) 110 / 230 volt versions 8 Maximum shut-off value 42 bar g -5°C to +55°C (23°F to 131°F) -5°C to +50°C (23°F to 122°F) IM-P403-103 AB Issue 1 3.2 Pressure / temperature limits see BCV41 Screwed BCV43 Section 3.3, Flanged EN 1092 page 10 BCV41 Screwed BCV42 see Socket weld BCV43 Section 3.4, Flanged ASME BCV44 page 11 Butt weld see BCV43 Section 3.5, Flanged JIS / KS page 12 see BCV61 Screwed BCV63 Section 3.6, Flanged EN 1092 page 13 BCV61 Screwed BCV62 see Socket weld BCV63 Section 3.7, Flanged ASME BCV64 page 14 Butt weld see BCV63 Section 3.8, Flanged JIS / KS page 15 see BCV71 Screwed BCV73 Section 3.9, Flanged EN 1092 page 16 see BCV71 Screwed BCV73 Flanged ASME BCV73 Flanged JIS / KS BCV83 Flanged EN 1092 Section 3.10, page 17 see Section 3.11, page 18 see BCV82 Section 3.12, page 19 Socket weld BCV83 see Flanged ASME BCV84 Butt weld Section 3.13, page 20 see TDS83 IM-P403-103 AB Issue 1 Flanged JIS / KS Section 3.14, page 21 9 3.3 BCV4_ Pressure / temperature limits BCV41 Screwed BSP BCV43 Flanged EN 1092 Temperature °C B D A Steam saturation curve C A C Pressure bar g D The product must not be used in this region. A - A B - C B - D Flanged EN 1092 PN40 and Screwed BSP Flanged EN 1092 PN63 Flanged EN 1092 PN100 PN40, PN63 or PN100 Body design conditions: PMA TMA Maximum allowable pressure Maximum allowable temperature Minimum allowable temperature PMO TMO Maximum operating pressure for saturated steam service Maximum operating temperature Minimum operating temperature JIS / KS 20K, 30K or 40K PN40 40 bar g @ 50°C PN63 63 bar g @ 50°C PN100 100 bar g @ 50°C PN40 300°C @ 27.6 bar g PN63 400°C @ 37.5 bar g PN100 400°C @ 59.5 bar g PN40 -10°C PN63 -29°C PN100 -29°C PN40 31.1 bar g @ 237°C PN63 47.0 bar g @ 261°C PN100 70.8 bar g @ 287°C PN40 300°C @ 27.6 bar g PN63 400°C @ 37.5 bar g PN100 400°C @ 59.5 bar g PN40 -10°C PN63 -29°C PN100 -29°C Designed for a maximum cold hydraulic test pressure of: 1.5 x PMA of the relative end connection of choice 10 IM-P403-103 AB Issue 1 3.4 BCV4_ Pressure / temperature limits Pressure psi g BCV43 Flanged ASME Temperature °C BCV42 Socket weld E G H Steam saturation curve BCV44 Butt weld F G Pressure bar g H Temperature °F BCV41 Screwed NPT The product must not be used in this region. E - F E - G E - H Flanged ASME class 150 Flanged ASME class 300, Screwed NPT and Socket weld class 300 Flanged ASME class 600, Socket weld class 600 and Butt weld PN40, PN63 or PN100 Body design conditions: PMA TMA Maximum allowable pressure Maximum allowable temperature Minimum allowable temperature PMO TMO Maximum operating pressure for saturated steam service Maximum operating temperature Minimum operating temperature JIS / KS 20K, 30K or 40K ASME class 150, class 300 or ASME class 600 ASME 150 19.6 bar g @ 38°C 284 psi g @ 100°F ASME 300 51.1 bar g @ 38°C 741 psi g @ 100°F ASME 600 102.1 bar g @ 38°C 1 480 psi g @ 100°F ASME 150 425°C @ 5.5 bar g 797°F @ 80 psi g ASME 300 425°C @ 28.8 bar g 797°F @ 418 psi g ASME 600 425°C @ 57.5 bar g 797°F @ 834 psi g ASME 150 -29°C -20°F ASME 300 -29°C -20°F ASME 600 -29°C -20°F ASME 150 13.9 bar g @ 197°C 201 psi g @ 386°F ASME 300 41.7 bar g @ 254°C 605 psi g @ 489°F ASME 600 80.0 bar g @ 295°C 1 160 psi g @ 563°F ASME 150 425°C @ 5.5 bar g 797°F @ 80 psi g ASME 300 425°C @ 28.8 bar g 797°F @ 418 psi g ASME 600 425°C @ 57.5 bar g 797°F @ 834 psi g ASME 150 -29°C -20°F ASME 300 -29°C -20°F ASME 600 -29°C -20°F Designed for a maximum cold hydraulic test pressure of: 1.5 x PMA of the relative end connection of choice IM-P403-103 AB Issue 1 11 BCV43 Flanged JIS / KS Temperature °C 3.5 BCV4_ Pressure / temperature limits K M J Steam saturation curve L J L Pressure bar g M The product must not be used in this region. J - J K - L K - M Flanged JIS / KS 20K Flanged JIS / KS 30K Flanged JIS / KS 40K PN40, PN63 or PN100 Body design conditions: PMA TMA Maximum allowable pressure Maximum allowable temperature Minimum allowable temperature PMO TMO Maximum operating pressure for saturated steam service Maximum operating temperature Minimum operating temperature JIS / KS 20K, 30K or 40K JIS / KS 20K 34 bar g @ 120°C JIS / KS 30K 51 bar g @ 120°C JIS / KS 40K 68 bar g @ 120°C JIS / KS 20K 300°C @ 20 bar g JIS / KS 30K 425°C @ 30 bar g JIS / KS 40K 425°C @ 40 bar g JIS / KS 20K -10°C JIS / KS 30K -29°C JIS / KS 40K -29°C JIS / KS 20K 30.6 bar g @ 236°C JIS / KS 30K 44.6 bar g @ 258°C JIS / KS 40K 58.5 bar g @ 276°C JIS / KS 20K 300°C @ 20 bar g JIS / KS 30K 425°C @ 30 bar g JIS / KS 40K 425°C @ 40 bar g JIS / KS 20K -10°C JIS / KS 30K -29°C JIS / KS 40K -29°C Designed for a maximum cold hydraulic test pressure of: 1.5 x PMA of the relative end connection of choice 12 IM-P403-103 AB Issue 1 BCV61 Screwed BSP BCV63 Flanged EN 1092 Temperature °C 3.6 BCV6_ Pressure / temperature limits B A C Steam saturation curve D A C Pressure bar g D The product must not be used in this region. A - A B - C B - D Flanged EN 1092 PN40 and Screwed BSP Flanged EN 1092 PN63 Flanged EN 1092 PN100 PN40, PN63 or PN100 Body design conditions: PMA TMA Maximum allowable pressure Maximum allowable temperature Minimum allowable temperature PMO TMO Maximum operating pressure for saturated steam service Maximum operating temperature Minimum operating temperature JIS / KS 20K, 30K or 40K PN40 40 bar g @ 100°C PN63 63 bar g @ 100°C PN100 100 bar g @ 100°C PN40 400°C @ 27.4 bar g PN63 580°C @ 39.5 bar g PN100 580°C @ 62.7 bar g PN40 -10°C PN63 -29°C PN100 -29°C PN40 32.2 bar g @ 240°C PN63 49.2 bar g @ 264°C PN100 75.1 bar g @ 291°C PN40 400°C @ 27.4 bar g PN63 580°C @ 39.5 bar g PN100 580°C @ 62.7 bar g PN40 -10°C PN63 -29°C PN100 -29°C Designed for a maximum cold hydraulic test pressure of: 1.5 x PMA of the relative end connection of choice IM-P403-103 AB Issue 1 13 3.7 BCV6_ Pressure / temperature limits Pressure psi g BCV63 Flanged ASME Temperature °C BCV62 Socket weld BCV64 Butt weld F G H F Steam saturation curve G Pressure bar g H Temperature °F BCV61 Screwed NPT E The product must not be used in this region. E - F E - G E - H Flanged ASME class 150 Flanged ASME class 300, Screwed NPT and Socket weld class 300 Flanged ASME class 600, Socket weld and Butt weld class 600 PN40, PN63 or PN100 JIS / KS 20K, 30K or 40K ASME class 150, class 300 or ASME class 600 ASME 150 19.0 bar g @ 38°C 275 psi g @ 100°F ASME 300 49.6 bar g @ 38°C 719 psi g @ 100°F ASME 600 99.3 bar g @ 38°C 1 440 psi g @ 100°F ASME 150 538°C @ 1.4 bar g 1 000°F @ 20 psi g ASME 300 538°C @ 25.2 bar g 1 000°F @ 365 psi g ASME 600 538°C @ 50.0 bar g 1 000°F @ 725 psi g ASME 150 -29°C -20°F ASME 300 -29°C -20°F ASME 600 -29°C -20°F ASME 150 13.8 bar g @ 197°C 200 psi g @ 386°F ASME 300 33.8 bar g @ 242°C 490 psi g @ 467°F ASME 600 64.6 bar g @ 281°C 937 psi g @ 538°F ASME 150 538°C @ 1.4 bar g 1 000°F @ 20 psi g ASME 300 538°C @ 25.2 bar g 1 000°F @ 365 psi g ASME 600 538°C @ 50.0 bar g 1 000°F @ 725 psi g ASME 150 -29°C -20°F ASME 300 -29°C -20°F ASME 600 -29°C -20°F Body design conditions: PMA TMA Maximum allowable pressure Maximum allowable temperature Minimum allowable temperature PMO TMO Maximum operating pressure for saturated steam service Maximum operating temperature Minimum operating temperature Designed for a maximum cold hydraulic test pressure of: 1.5 x PMA of the relative end connection of choice 14 IM-P403-103 AB Issue 1 BCV63 Flanged JIS / KS Temperature °C 3.8 BCV6_ Pressure / temperature limits K L J Steam saturation curve M J Pressure bar g L M The product must not be used in this region. J - J K - L K - M Flanged JIS / KS 20K Flanged JIS / KS 30K Flanged JIS / KS 40K PN40, PN63 or PN100 Body design conditions: PMA TMA Maximum allowable pressure Maximum allowable temperature Minimum allowable temperature PMO TMO Maximum operating pressure for saturated steam service Maximum operating temperature Minimum operating temperature JIS / KS 20K, 30K or 40K JIS / KS 20K 34 bar g @ 120°C JIS / KS 30K 51 bar g @ 120°C JIS / KS 40K 68 bar g @ 120°C JIS / KS 20K 425°C @ 20 bar g JIS / KS 30K 490°C @ 30 bar g JIS / KS 40K 490°C @ 40 bar g JIS / KS 20K -10°C JIS / KS 30K -29°C JIS / KS 40K -29°C JIS / KS 20K 30.6 bar g @ 236°C JIS / KS 30K 44.6 bar g @ 258°C JIS / KS 40K 58.5 bar g @ 276°C JIS / KS 20K 425°C @ 20 bar g JIS / KS 30K 490°C @ 30 bar g JIS / KS 40K 490°C @ 40 bar g JIS / KS 20K -10°C JIS / KS 30K -29°C JIS / KS 40K -29°C Designed for a maximum cold hydraulic test pressure of: 1.5 x PMA of the relative end connection of choice IM-P403-103 AB Issue 1 15 3.9 BCV7_ Pressure / temperature limits BCV71 Screwed BSP BCV73 Flanged EN 1092 Temperature °C A B Steam saturation curve B Pressure bar g The product must not be used in this region. A - B Flanged EN 1092 PN25 and Screwed BSP PN25 Body design conditions: JIS / KS 10K PMA Maximum allowable pressure PN25 25.0 bar g @ 120°C TMA Maximum allowable temperature PN25 300°C @ 20 bar g PN25 -10°C Minimum allowable temperature PMO Maximum operating pressure for saturated steam service PN25 22.5 bar g @ 220°C TMO Maximum operating temperature PN25 300°C @ 20.0 bar g PN25 -10°C Minimum operating temperature Designed for a maximum cold hydraulic test pressure of: 1.5 x PMA of the relative end connection of choice 16 IM-P403-103 AB Issue 1 3.10 BCV7_ Pressure / temperature limits BCV73 Flanged ASME C E Steam saturation curve D D Temperature °F BCV71 Screwed NPT Temperature °C Pressure psi g Pressure bar g E The product must not be used in this region. C - D C - E Flanged ASME class 125 Flanged ASME class 250 and Screwed NPT PN25 JIS / KS 10K ASME class 125 or ASME class 250 ASME 125 11.5 bar g @ 140°C 166 psi g @ 284°F ASME 250 26.7 bar g @ 140°C 387 psi g @ 284°F ASME 125 232°C @ 8.6 bar g 449°F @ 125 psi g ASME 250 232°C @ 17.2 bar g 449°F @ 249 psi g ASME 125 -29°C -20°F ASME 250 -29°C -20°F ASME 125 10.0 bar g @ 184°C 145 psi g @ 363°F ASME 250 18.0 bar g @ 209°C 261 psi g @ 408°F ASME 125 232°C @ 8.6 bar g 449°F @ 125 psi g ASME 250 232°C @ 17.2 bar g 449°F @ 249 psi g ASME 125 -29°C -20°F ASME 250 -29°C -20°F Body design conditions: PMA Maximum allowable pressure TMA Maximum allowable temperature Minimum allowable temperature PMO Maximum operating pressure for saturated steam service TMO Maximum operating temperature Minimum operating temperature Designed for a maximum cold hydraulic test pressure of: 1.5 x PMA of the relative end connection of choice IM-P403-103 AB Issue 1 17 3.11 BCV7_ Pressure / temperature limits BCV73 Flanged JIS / KS Temperature °C F G Steam saturation curve G Pressure bar g The product must not be used in this region. F - G Flanged JIS / KS 10K PN25 Body design conditions: JIS / KS 10K PMA Maximum allowable pressure JIS / KS 10K 13.7 bar g @ 120°C TMA Maximum allowable temperature JIS / KS 10K 300°C @ 9.8 bar g Minimum allowable temperature JIS / KS 10K -10°C PMO Maximum operating pressure for saturated steam service JIS / KS 10K 12.3 bar g @ 191°C TMO Maximum operating temperature JIS / KS 10K 300°C @ 9.8 bar g JIS / KS 10K -10°C Minimum operating temperature Designed for a maximum cold hydraulic test pressure of: 1.5 x PMA of the relative end connection of choice 18 IM-P403-103 AB Issue 1 BCV83 Flanged EN 1092 Temperature °C 3.12 BCV8_ Pressure / temperature limits A B C Steam saturation curve B Pressure bar g C The product must not be used in this region. A - B A - C Flanged EN 1092 PN63 Flanged EN 1092 PN100 PN63 or PN100 Body design conditions: PMA Maximum allowable pressure TMA Maximum allowable temperature Minimum allowable temperature PMO Maximum operating pressure for saturated steam service TMO Maximum operating temperature Minimum operating temperature JIS / KS 30K or 40K PN63 63 bar g @ 300°C PN100 100 bar g @ 300°C PN63 490°C @ 42.8 bar g PN100 490°C @ 68.0 bar g PN63 -29°C PN100 -29°C PN63 63.0 bar g @ 280°C PN100 99.0 bar g @ 310°C PN63 490°C @ 42.8 bar g PN100 490°C @ 68.0 bar g PN63 -29°C PN100 -29°C Designed for a maximum cold hydraulic test pressure of: 1.5 x PMA of the relative end connection of choice IM-P403-103 AB Issue 1 19 3.13 BCV8_ Pressure / temperature limits Pressure psi g BCV84 Butt weld Temperature °C BCV83 Flanged ASME D E Steam saturation curve Pressure bar g E Temperature °F BCV82 Socket weld The product must not be used in this region. D - E Flanged ASME class 600, socket weld and butt weld PN63 or PN100 Body design conditions: JIS / KS 30K or 40K ASME class 600 PMA Maximum allowable pressure ASME 600 103.4 bar g @ 50°C 1 500 psi g @ 122°F TMA Maximum allowable temperature ASME 600 538°C @ 29.8 bar g 1 000°F @ 432 psi g ASME 600 -29°C -20°F Minimum allowable temperature PMO Maximum operating pressure for saturated steam service ASME 600 85.7 bar g @ 300°C 1 243 psi g @ 572°F TMO Maximum operating temperature ASME 600 538°C @ 29.8 bar g 1 000°F @ 432 psi g ASME 600 -29°C -20°F Minimum operating temperature Designed for a maximum cold hydraulic test pressure of: 1.5 x PMA of the relative end connection of choice 20 IM-P403-103 AB Issue 1 3.14 BCV8_ Pressure / temperature limits TDS83 Flanged JIS / KS Temperature °C G H F Steam saturation curve Pressure bar g F H The product must not be used in this region. F - F G - H Flanged JIS / KS 30K Flanged JIS / KS 40K PN63 or PN100 Body design conditions: PMA Maximum allowable pressure TMA Maximum allowable temperature Minimum allowable temperature PMO Maximum operating pressure for saturated steam service TMO Maximum operating temperature Minimum operating temperature JIS / KS 30K or 40K JIS / KS 30K 51 bar g @ 120°C JIS / KS 40K 68 bar g @ 120°C JIS / KS 30K 490°C @ 30.0 bar g JIS / KS 40K 510°C @ 40.0 bar g JIS / KS 30K -29°C JIS / KS 40K -29°C JIS / KS 30K 44.6 bar g @ 257°C JIS / KS 40K 58.6 bar g @ 274°C JIS / KS 30K 490°C @ 30.0 bar g JIS / KS 40K 510°C @ 40.0 bar g JIS / KS 30K -29°C JIS / KS 40K -29°C Designed for a maximum cold hydraulic test pressure of: 1.5 x PMA of the relative end connection of choice IM-P403-103 AB Issue 1 21 4. Installation and dimensions Note: Before actioning any installation observe the 'Safety information' in Section 1. For unit sizes see Figures 5 and 6 on pages 24 and 25. The actuator should be protected from excessive heat. Actuator sealing is to IP54. Additional protection is recommended for outdoor installation. The valve may be installed in horizontal or vertical lines with flow in the direction of the arrow. Do not install with the actuator below the valve. For boiler blowdown applications the ideal take-off point for the blowdown is from a boiler side connection (see Figures 2 and 3), to reduce the possibility of scale entering the blowdown valve. If the bottom connection has to be used, make a 'T' connection upstream of the main bottom blowdown valve as shown in Figure 4. We recommend that where possible the 'T' is taken off the top of the blowdown line to reduce any problems of scale. The ¼" BSP plug may be removed and the connection used for boiler water sampling. A sample cooler is recommended. Fit a stop valve between the boiler and the BCV blowdown control valve. A check valve is recommended downstream of the BCV. For single boiler installations the blowdown may discharge into the main blowdown line downstream of the main blowdown valve. In the UK, regulations for multi-boiler installations require the automatic blowdown lines to be separate from the main blowdown lines. For further information see Health and Safety Executive Guidance Note PM60. Note: When installing with an S11 chamber, use M12 bolts for PN16, PN25, PN40 and ASME 300 flanged connections. Probe elbow Boiler CP32 twin tip conductivity probe used to measure the TDS of the boiler water, for the purpose of monitoring and controlling blowdown. Stop valve Check valve To sample cooler Electrically actuated BCV blowdown control valve shown. Alternatively use the pneumatically actuated BCV version. Blowdown to heat recovery system or blowdown vessel Fig. 2 Installation on a probe elbow 22 IM-P403-103 AB Issue 1 Electrically actuated BCV blowdown control valve shown. Alternatively use the pneumatically actuated BCV version. Stop valve Boiler Blowdown to heat recovery system or blowdown vessel Sensor in S11 chamber Check valve To sample cooler Fig. 3 Installation on a boiler side connection Electrically actuated BCV blowdown control valve shown. Alternatively use the pneumatically actuated BCV version. Boiler Stop valve Stop valve Blowdown to heat recovery system or blowdown vessel Check valve Strainer Sensor in S11 chamber 300 mm (12") Pipeline distance between boiler and sensor to be as short as possible Main blowdown valve Main blowdown to blowdown vessel Fig. 4 Installation on a boiler with no suitable side connection IM-P403-103 AB Issue 1 23 Electric actuation - Dimensions / weights (approximate) in mm and kg Weight A B C D Size ASME ASME ASME 125 300 600 ASME ASME 125 600 ASME 300 PN40 PN100 PN40 PN100 ASME ASME ASME ASME 125 600 125 600 ASME ASME 300 300 PN40 PN100 PN40 PN100 DN15 - 190.5 203 130 210 392 422 230 42.5 49.5 12 DN20 - 190.5 206 150 230 392 422 230 57.0 49.5 12.8 18 DN25 184 197 210 160 230 392 422 230 54.5 56.5 13 19 16 DN32 - - 251 180 260 421 449 230 65.5 71.5 19.5 25 DN40 222 235 251 200 260 421 449 230 76.5 71.5 20 28 DN50 254 267 286 230 300 416 449 230 84.5 85.5 23 33 C Electric actuation B D Fig. 5 A 24 IM-P403-103 AB Issue 1 Pneumatic actuation - Dimensions / weights Size ASME 125 ASME 300 PN40 B1 ASME 600 C1 PN100 (approx.) in mm and kg Weight ASME 125 ASME 300 PN40 ASME 600 PN100 DN15 378 408 170 12 16 DN20 378 408 170 12.8 18 DN25 378 408 170 13 19 DN32 432 460 300 30.5 36 DN40 432 460 300 31 39 DN50 427 460 300 34 44 C1 Pneumatic actuation B1 Fig. 6 IM-P403-103 AB Issue 1 25 5. AHL1 Actuator with spring return Y02158 Y10161 Fig. 7 AHL1 actuator 2 0% 0V of op Di er re at cti io on n 1 n n io io ct rat ire e D f op o 100 % Output signal y 10 V B07650 Fig. 8 26 IM-P403-103 AB Issue 1 Type Running time Pushing Force Stroke Weight Motor s / mm Spring s N mm kg 2 / 4 / 6 15...30 2000 0...40 5.6 24 V ± 20%, 50...60 Hz 24 V ± 15% 230 V ± 15% Power consumption 7.5 W 20 VA Stroke 8…49 mm Number of spring returns > 40.000 Response time for 3-point 200 ms Maximum temperature of medium 130°C Permitted ambient temperature –10...55(60)°C Permitted ambient humidity < 95% rh without condensation Degree of protection IP66 (EN 60529) Protection class III (IEC 60730) Switches Switching c apac it y AHL1 Series Voltage supply with accessories Maximum 250 V Minimum current 250 mA at 12 V IM-P403-103 AB Issue 1 27 Operation After a new start, or after a start following activation of the reset (terminal 21), up to 45 seconds of waiting time will pass before the drive is available again. The run time of the drive can be set according to the specific requirements, using switches S1 and S2. The external hand crank allows you to adjust the position manually. When the hand crank is folded out, the motor is switched off. After the hand crank is folded back, the spring function is active again and the setpoint position is adopted again (without initialisation). If the hand crank is unfolded, the drive stays in this position. Initialisation and feedback signal The drive initialises itself automatically, the drive moves to the lower limit stop on the valve, thus enabling automatic connection with the valve spindle. Then it moves to the upper limit stop, and the value is recorded and saved with the help of a path measurement system. To trigger an initialisation, fold the hand crank out and back in again twice within 4 seconds. Both the LEDs will then flash red. Spring return If the voltage supply fails or is switched off, or if a monitoring contact (terminal 21) responds, the brushless DC motor releases the gear and the drive is moved into the respective end position (de-pending on the design version) by the pre-tensioned spring. As this happens, the control function of the drive is disabled for 45 seconds (both LEDs flash green) so that the end position can be reached in every case. The reset speed is controlled with the help of the motor so that there are no pressure surges in the line. The brushless DC motor has three functions: as a magnet to hold the position, as a brake (by acting as a generator) and as a motor for the control function. After a spring return function, the drive does not re-initialise itself. LED display The display consists of two dual-colour LEDs (red / green): No LED lit: No power supply (terminal 21) LEDs flashing red: Initialisation procedure Both LEDs lit green: Waiting time after switching on or after spring return LEDs are flashing red and green: Drive is in manual mode LED lit red: Upper limit stop or 'CLOSED' position reached Upper LED flashing green: Drive running, moving towards 'CLOSED' position LED lit green: Drive stationary, last direction of running 'CLOSED' LED lit red: Lower limit stop or 'OPEN' position reached Lower LED flashing green: Drive running, moving towards 'OPEN' position LED lit green: Drive stationary, last direction of running 'OPEN' 28 IM-P403-103 AB Issue 1 Additional technical information The yellow housing, comprising the front section, rear section and connection cover, only serves the purpose of a cover. The crank for manual adjustment is located on the front. The DC motor, the con-trol electronics, the supporting components and the maintenance-free gear are accommodated in the housing. Note on ambient temperatures: if the medium temperature in the valve is up to 110°C, the ambient temperature may reach 60°C. For medium temperatures above 110°C, the ambient temperature must not exceed 55°C. Warnings: • If the temperature of the medium in the valve is high, the drive columns and the shaft may also reach high temperatures. • Drives with safety functions must be regularly checked to see that they are in working order (trial run). • If a failure of the final control element could cause damage, additional protective precautions must be taken. • It is forbidden to dismantle the springs in the device due to the high risk of injuries. IM-P403-103 AB Issue 1 29 6. Flow setting Table 1 Blowdown valve capacities Valve size DN15 DN20 DN25 DN32 DN40 DN50 Kvs value 0.5 0.5 0.5 1.6 1.6 1.6 For conversion: C v (UK) = Kv x 0.963 C v (US) = Kv x 1.156 Kvs chart Pressure psi g Water flow m3 / h Water flow UK gallons / h Pressure bar g 30 IM-P403-103 AB Issue 1 Capacities Water flow m3 / h Water flow UK gallons / h % opening IM-P403-103 AB Issue 1 31 Flow for stroke 20 mm Kv 0.5 1.6 Differential pressure (bar) Hot water flow (m3/h) Differential pressure (bar) Hot water flow (m3/h) 0 0.0 0 0.0 0.5 0.4 50 3.5 1 0.5 60 3.9 10 1.6 70 4.2 20 2.2 80 4.5 30 2.7 90 4.7 40 3.2 100 5.0 0 0.0 0 0.0 0.5 1.1 50 11.3 1 1.6 60 12.4 10 5.1 70 13.4 20 7.2 80 14.3 30 8.8 90 15.2 40 10.1 100 16.0 Valve size DN15 to DN25 DN32 to DN50 Flow for stroke 15 mm Kv 0.375 1.200 32 Differential pressure (bar) Hot water flow (m3/h) Differential pressure (bar) Hot water flow (m3/h) 0 0.0 0 0.0 0.5 0.3 50 2.7 1 0.4 60 2.9 10 1.2 70 3.1 20 1.7 80 3.4 30 2.1 90 3.6 40 2.4 100 3.8 0 0.0 0 0.0 0.5 0.8 50 8.5 1 1.2 60 9.3 10 3.8 70 10.0 20 5.4 80 10.7 30 6.6 90 11.4 40 7.6 100 12.0 Valve size DN15 to DN25 DN32 to DN50 IM-P403-103 AB Issue 1 Flow for stroke 10 mm Kv 0.25 0.80 Differential pressure (bar) Hot water flow (m3/h) Differential pressure (bar) Hot water flow (m3/h) 0 0.0 0 0.0 0.5 0.2 50 1.8 1 0.3 60 1.9 10 0.8 70 2.1 20 1.1 80 2.2 30 1.4 90 2.4 40 1.6 100 2.5 0 0.0 0 0.0 0.5 0.6 50 5.7 1 0.8 60 6.2 10 2.5 70 6.7 20 3.6 80 7.2 30 4.4 90 7.6 40 5.1 100 8.0 Valve size DN15 to DN25 DN32 to DN50 7. Rotating the actuator The actuator may be rotated on the valve body so that the terminal cover points are in the most convenient direction. Handwheel Fig. 9 IM-P403-103 AB Issue 1 33 8. Wiring All wiring materials and methods shall comply with relevant EN and IEC standards where applicable. For installations in the US and Canada, the controller and valve must be wired in accordance to the Local and National Electrical code (NEC) or the Canadian Electrical Code (CEC). Check the actuator label to ensure the operating voltage is correct for the mains supply. Suitable ac voltages are: 230 V version (additional card) 195 V - 265 V 110 V version (additional card) 96 V - 127 V 24 V version 19.3 V - 28 V Frequency 50 - 60 Hz Maximum power consumption Fig. 10 Additional card Fig. 11 34 IM-P403-103 AB Issue 1 L N 1 2a 2b 230 V µC 21 N 2a S1 S2 S3 S4 M 2b Module 230 V On Off AVF234S S1; S2 = Drivetime S3; S4 = Characteristic 2a Valve opening 2b Valve closing Fig. 12 Limit switches configuration Fig. 13 The limit switches box is already installed in the actuator cover. Xs1 = Adjust to positioning the valve opening Xs2 = Adjust to positioning the valve closing Note: The Xs2 is set-up during the coupling with the valve consequently it cannot be altered. Fig. 14 Turn the potentiometers Xs1 to adjust the stroke to the optimum for your application. 1. Set the potentiometer 2. Measure the stroke of the valve 3. Adjust the set-up of the potentiometer IM-P403-103 AB Issue 1 35 9. Pneumatic actuator stroke adjustment The valve is supplied with a low flowrate setting of 10 mm ( ") stroke. To increase the stroke to 15mm ( ") or 20 mm (¾"): - - Isolate the valve from the boiler pressure and energise the solenoid valve so that the air supply can be manually controlled by the regulator. Apply just enough air pressure to open the valve fully (see Figure 15). 26, 27 13, 14 Fig. 15 - - 25 Remove the clamp nuts and screws (26 and 27), and the clamp front and rear (13 and 14). 10 Turn off the air supply and allow the actuator to retract fully (see Figure 15). 11 Fig. 16 - - - Loosen the actuator lock-nut (25), and screw the connector (10) fully into the spindle. Loosen the nut locking the valve stem to the adaptor (11). Position the adaptor so that only 8 mm of the valve stem thread is engaged (see Figures 17 and 18). Caution The valve stem must not protrude beyond the surface of the adaptor, other wise the clamp will not fit corectly and may be damaged (see Figure 18). 4 Fig. 17 Correct - 8 mm thread engagement 8 Fig. 18 Incorrect - thread protruding above the adaptor 36 IM-P403-103 AB Issue 1 - - Pull the valve stem upwards to fully close the valve. Measuring from the top of the stuffing box, mark the new stroke required on the valve stem - 15 mm or 20 mm (Figure 19) Fig. 19 - Push the valve stem down so that the mark lines up with the stuffing box (Figure 20). Fig. 20 - - - - Apply air pressure to allow the actuator to descend fully. Unscrew the actuator connector until it just contacts the valve stem adaptor without opening the valve (Figure 21). Tighten adaptor and actuator lock-nuts. Refit the clamp, and its nuts and screws. Fig. 21 Please note: It may be necessary to make final adjustments to the actuator connector and the valve adaptor to ensure the clamp anti-rotation lugs engage with the yoke, and that the pointer is still on the scale. IM-P403-103 AB Issue 1 37 10. Maintenance Note: Before actioning any maintenance, observe the 'Safety information' in Section 1. Warning for all stainless steel valves The 316 type stainless steel used in the construction of these products particularly for screwed or close fitting parts, is very susceptible to galling or cold welding. This is an inherent characterisitic of this type of material and great care should therefore be taken when dismantling or reassembling. If the application permits, it is recommended that a light smear of a PTFE based grease is applied to any mating parts before reassembly. 10.1General Valve parts are subject to normal wear and must be inspected and replaced as necessary. Inspection and maintenance frequency depends on the severity of the service conditions. This section provides instructions on replacement packing, stem, plug and seat and bellows. All maintenance operations can be performed with the valve body in the line. Annually The valve should be inspected for wear and tear replacing any worn or damaged parts such as valve plug and stem, valve seat and gland seals, refer to Section 10 'Spare parts'. Note 1: High temperature graphite packed seals are subject to wear during normal operation. We therefore recommend the graphite packing be replaced during this routine inspection to prevent premature failure of the packing during normal operation. Note 2: It is recommended that all soft seals and gaskets be replaced whenever the valve is disassembled. New torque values with lubrication: The following new torque values should be used with lubricated nuts / bolts: Table 2 Recommended tightening torques Control valve sizes DN15 to DN50 SPIRA-TROL valve size Torque (N m) JE / JEA DN15 - DN25 100 DN32 - DN50 130 1 3 4 2 Fig. 22 Bonnet tightening sequence 38 IM-P403-103 AB Issue 1 10.2 Removal of valve bonnet Note: This procedure is necessary before carrying out any of the maintenance procedures detailed below: - Ensure that the valve is depressurised and clear of media and isolate it both upstream and downstream. Caution: care should be taken when disassembling the valve in case of residual pressure being trapped between the isolation points. Remove the actuator from the valve. Refer to the Installation and Maintenance Instructions covering Spirax Sarco actuators. - - - - - - Unscrew the stuffing box nuts (18). Undo and remove the bonnet nuts (27). Remove the bonnet (2) and plug and stem assembly (8). Remove and discard the body gasket. 10.3 Replacement of graphite gland packing - Remove the lock-nut (3), stuffing box nuts, gland flange and gland follower (18), ensuring - - that the groove is clean and undamaged, replace with new item. Remove the gland follower (9) and retain, withdraw the graphite packing (14) and discard. Remove the spacer and lower bearing (16). Clean and examine these components and the upper bearing replacing any that show signs of damage or deterioration. Clean the gland cavity and reassemble the gland components in the order shown in Figure 23. Note that the lower bearing must be fitted with the radiused edge downwards. When fitting the graphite seals, the scarf joints in each seal must be offset from the one below by 90°. Fig. 23 - - Scarf joint Fit the packing follower and stuffing box ring into position. Lubricate the stuffing box nuts. Install and tighten the packing flange nuts finger tight. and hold the packing without compressing them. Final adjustment of the gland must be carried out after refitting the bonnet as detailed in Section 10.5. IM-P403-103 AB Issue 1 39 10.4 Removal and refitting of the valve plug / stem assembly and seat - Lift out the seat retaining cage (5) - - - - - followed by the seat (6). Remove the seat back gasket (7) and discard. Clean all components, including the seat recess in the valve body. Examine the seat and plug / stem assembly for damage or deterioration and renew as necessary. Note: Score marks or scaly deposits on the valve stem will lead to early failure of the gland seals and damage to seat and plug sealing faces will result in leakage rates higher than those specified for the valve. Fit a new seat gasket (7) in the body seat recess followed by the seat (6). Refit the cage (5) ensuring that the flow windows are lower most and that it sits squarely on the seat without impinging on the valve body. 5 6 7 Fig. 24 40 IM-P403-103 AB Issue 1 10.5 Refitting the bonnet Caution: The following must be carefully followed to enable the correct reassembly of the control valve, and the subsequent test that is required to ensure that the plug moves freely inside the valve seat: - Fit new bonnet gasket. - Ensure the plug stem is fully extended without the upper stem threads making contact with stem seals on the top of the bonnet. - Replace the bonnet and stem assembly to the valve body, locating the plug centrally into the seat. - Holding the Plug in position, push the bonnet down on to the valve body. - Proceed to tighten the bonnet into position by following Step 1 through to 7: 1 Fit bonnet nuts. 2 Finger tighten opposing bonnet nuts or bolts evenly in pairs. 3 Raise the stem to the highest position. 4 Firmly and briskly push the stem fully down. IM-P403-103 AB Issue 1 Repeat Steps 1 to 4 finger tightening bonnet nuts or bolts individually until tight. 41 6 5 Using a torque wrench lightly and evenly tighten each bolt or nut by 45°, following the sequence illustrated in Figure 22, page 38. 7 After each tightening sequence lift the stem fully. Firmly and briskly push the stem fully down. - Repeat Steps 5, 6 and 7 until the bonnet nuts or bolts have an even tension. - Continue Steps 5, 6 and 7 but use a torque wrench set at 10% of maximum required torque setting. - Again, repeat Steps 5, 6 and 7, incrementally increasing the torque value to 20%, 40%, 60%, 80% and finally 100% of the required torque value (as specified in Table 2, page 38). - Pull the plug off its seat, rotate by 120° and slowly push it back down into the seat checking for any signs of resistance as the plug comes into contact with the seat. - Repeat the above Step, three more times. - If any resistance is felt, this can indicate the plug and seat is misaligned and the process will need repeating. - Tighten the the stuffing box nuts (18) until: i) PTFE gland assembly: A gap of 10 mm between the underside of the gland flange and the bonnet is achieved. ii) Graphite gland assembly: A gap of 12 mm between the underside of the gland flange and the bonnet is achieved. - - - - 3 18 Refit the lock-nut (3). Reinstall the actuator. Bring the valve back into service. Check for leakage at the gland. Note: Recheck the graphite seals and retighten the gland if necessary after a few hundred cycles as the seals fully bed in. Fig. 25 42 IM-P403-103 AB Issue 1 11. Spare parts A C1 B Spare parts The spare parts available are detailed below. No other parts are supplied as spares. D2 Fig. 26 E G Please note that the spare parts available for the BCV TDS blowdown control valve are the same for both the electrically and pneumatically actuated versions. Available spares Actuator clamping nut Gasket set Stem seal kits Graphite packing Plug stem Linear trim and seat kit (No gaskets supplied) A B, G C1 D2, E How to order spares Always order spares by using the description given in the column headed 'Available spares', and state the size and type of valve and specify clearly the full product description as found on the label of the valve body, as this will ensure that the correct spare parts are supplied. Example: 1 off Actuator clamping nut for a Spirax Sarco DN15 BCV43HWSUSS blowdown control valve. IM-P403-103 AB Issue 1 43 44 IM-P403-103 AB Issue 1 ">
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