RESILIENT SEATED BUTTERFLY VALVES

1 RESILIENT SEATED BUTTERFLY VALVES . TECHNICAL SALES MANUAL. THE HIGH PERFORMANCE COMPANY. Contents Introduction to Torques .. 3. Reduced Disc Diameter Bray Series 30/31/3A VALVES .. 6. Seating & Unseating Torques .. 7. Series 20/21 and 30/31/3A Torques Imperial (Lb-Ins) .. 8. Series 20/21 and 30/31/3A Torques Metric (Nm) .. 9. Series 32/33, 35/36 Torques Imperial (Lb-Ins) .. 10. Series 32/33, 35/36 Torques Metric (Nm) .. 10. Series 22/23 Torques Imperial (Lb-In) and Metric (Nm) .. 11. Dynamic Torque Factors (Imperial) .. 12. Dynamic Torque Factors (Metric) .. 13. Valve Sizing Coefficients .. 14. Series 20/21 - Valve Sizing Coefficient (Cv) .. 15. Series 22/23 - Valve Sizing Coefficient (Cv).

2 15. Series 30/31/31H/3A/3AH/31U - Valve Sizing Coefficient (Cv) .. 16. Series 32/33/35/36/35F/36H - Valve Sizing Coefficient (Cv) .. 16. Series 20/21 - Valve Sizing Coefficient (Kv) .. 17. Series 22/23 - Valve Sizing Coefficient (Kv) .. 17. Series 30/31/31H/3A/3AH/31U - Valve Sizing Coefficient (Kv) .. 18. Series 32/33/35/36/35F/36H - Valve Sizing Coefficient (Kv) .. 18. Examples of Typical Flange to Valve Bolting* .. 19. Flange Bolt Tensioning .. 20. Series 20/21 - Standard Metal Specifications .. 23. Series 22/23 - Standard Metal Specifications .. 23. Series 30/31, 31H, 3A/3AH, 31U - Standard Metal Specifications .. 24. Series 32/33, 35/36, 35F, 36H - Standard Metal Specifications.

3 25. All statements, technical information, and recommendations in this bulletin are for general use only. Consult Bray representatives or factory for the specific requirements and material selection for your intended application. The right to change or modify product design or product without prior notice is reserved. RESILIENT SEATED BUTTERFLY VALVES Torques Torques INTRODUCTION TO TORQUES CASE I (Angle = 0 , Disc in Closed Position). There are a number of torques which BUTTERFLY VALVES TT = Th + Tbf + Tss+ Tsu may experience such as: Analyzed Tsu - Seating and Unseating Torque Total Torque for Case I using a symmetrical disc BUTTERFLY Td - Dynamic Torque Resulting from fluid flow valve is the sum of hydrostatic torque, bearing friction torque, stem seal, friction torque, and seating/unseating Tbf Bearing Friction Torque torque.

4 Tss Stem Seal Friction Torque A. Hydrostatic Torque (Th). Te Eccentricity Torque resulting from We will ignore discussion of the hydrostatic torque disc offset from centerline of stem (either values as they are generally insignificant compared to single, double or triple offset). the seating/unseating, bearing friction and stem seal Th Hydrostatic Torque torque values (the safety factor applied to seating/. unseating, stem seal friction and bearing friction torque Factors which influence the BUTTERFLY valve torque val- values more than compensates for the hydrostatic torque ues shown above are: which is usually less than 2% of these total torques). Type of Seat and Seat Material B.

5 Bearing Friction Torque (Tbf). Interference of Seat and Disc Shaft Diameter Bearing friction torque occurs because pressure forces against the disc are transmitted to the stem. As the stem Valve Diameter is forced against the bearing supports, bearing friction Bearing Coefficient of Friction torque is created between the stem material and the support material as the stem is turned. Bearing friction Angle of Opening torques are normally included in the seating/unseating Shut-off Pressure torque values. Fluid Velocity Bearing friction torques can be determined by using Disc Shape and Configuration the following equation: Piping System and Location/Orientation of Valve in Tbf =.

6 785 Cf Dv2 (d/2) P. Pipe Line Where: System Head Characteristics Physical Size of Disc/Shaft Obstructing Flow Tbf = Bearing Friction Torque Disc Edge Finish Cf = Coefficient of Friction (approximately .25. for non-corroded stem to cast iron body). With respect to BUTTERFLY VALVES , the two major conditions (dimensionless). for determining total valve operating torque (TT) exists as follows: Dv = Valve Diameter (Inches). d = Diameter of Shaft (Inches). P = Pressure Differential (psi). C. Stem Seal Friction Torque (Tss). For all practical purposes stem seal friction torque values are insignificant when compared to seating/unseating and bearing friction torques. Stem seal friction torques are normally included in the seating/unseating torque values.

7 All information herein is proprietary and confidential and may not be copied or reproduced without the expressed written consent of BRAY INTERNATIONAL, Inc. Introduction : 3 The technical data herein is for general information only. Product suitability should be based solely upon customer's detailed knowledge and experience with their application. RESILIENT SEATED BUTTERFLY VALVES Torques D. Seating/Unseating Torques (Tsu) B. Stem Seal Friction Torque (Tss). The seating/unseating torque value (Tsu) is a function of See Case I discussion. This torque value is normally in- the pressure differential, the seat material's coefficient cluded in the Dynamic torque value. of friction, the finished surface of the disc edge, the C.

8 Dynamic Torque (Td). amount of interference between the seat and disc In a symmetrical disc design, dynamic torque occurs when flanged in piping, the seat thickness, and the between the closed position, 0 and the full open type of service (media) for which the valve is being used. position, 90 . With the disc in the partially open In determining the Tsu values for Bray RESILIENT SEATED position, velocity of the fluid passing the leading disc BUTTERFLY VALVES , Bray has developed Seating/Unseating edge is less than the velocity passing the trailing edge. Torque Charts incorporating all bearing friction and stem This variance in velocity past the leading disc edge and seal friction torques for three classes of services for both trailing disc edge results in an unbalanced distribution the VALVES with standard discs (rated to full pressure) and of pressure forces on the upstream side of the face of for VALVES with reduced diameter discs (rated for 50 psi the disc.)

9 The total pressure forces acting perpendicular [ bar]). The three service classes are: to the disc face on the leading edge half of the disc are Class A Non-Corrosive, Lubricating Service greater than the total pressure acting perpendicular on Class B General Service the trailing half of the disc. This uneven distribution of Class C Severe Service pressure on the disc face (exists on both sides of the disc). results in a torsional force which tries to turn the disc Please review the guidelines for each class in the technical to the closed position (Figure 1). This torsional closing manual when determining which Seating/Unseating force can become greater than the seating/unseating Torque Class should be used.

10 Most BUTTERFLY VALVES are torque value depending on the valve angle of opening used in Class II, General Service applications. and differential pressure. E. Total Torque (TT). To determine dynamic torque, the following equation The total torque values for Bray symmetrical disc is applied: VALVES for Case I applications are shown in the Seating/. Td = Cdt d3 P. Unseating Torque Charts within this manual. Where: CASE II (Disc in Partial To Full Opening Position). Td = Dynamic Torque (lbs- in). TT = Tbf + Tss+ Td Cdt = Coefficient of Dynamic Torque (based on disc The total Torque for Case II using a symmetrical disc shape and angle of opening) (dimensionless). BUTTERFLY valve is the summation of bearing friction torque, d = Diameter of Disc (Inches).