1. FUNDAMENTALS OF CONVEYOR SYSTEMS Presented by: Laura Hoggan, Rubber & Plastics

2. Topics to be Covered  System Maintenance  Belt Maintenance  Anatomy of a belt  Common Frac Sand belt specifications and designs

3. Section I: System Maintenance

4. System Square  A conveyor system frame is like a car frame, if your frame is not square it will throw off other components, creating wear and tear.  The Dragon Tail is the most susceptible area for being out of square, check it often!

5. Cleaning Good system maintenance can be summed up in two words, “Good Housekeeping”. Check pulleys and rollers for material build-up.

6. Loading Area  Having the right equipment and a good transaction area is a key component in system life and belt life.  Bad Loading can result in:  Catastrophic failure  Damage to belt  Tracking issues

7. TO-DO LIST!  Follow OEM guide for lubrication schedule  Visually inspect:  Rollers, Pulleys, Return rollers & belt guides for excessive wear, built up material and damage.  Belt Splice for wear on lace, cracks, missing components.  Sidewall for damage and missing sections  Inspect belts:  Tracking properly  Tension

8. Section II: Belt Maintenance

9. Belt Tracking/Training Considerations  Conveyor belt moves toward the end of the roller/idler it contacts first  Check conveyor system for structural misalignments  Check pulleys and idlers for misalignment and material build-up  Check belt splice for accuracy and straightness  Observe belt in operation empty and loaded for tracking tendencies  Eliminate Spillage, Off-center loading and build-up of materials, factors that cause tracking issues

10. Splice Failures  Inspect lace to ensure all parts are still present  Inspect Vulcanized splices for cracking, splitting and loose sidewall sections

11. Belt Repair  Flexco® offers a variety of rip repair fasteners. With these you can patch soft spots before they become rips or a cut or tear in your belt to extend your belt life  Eli-Flex rubber repair kits for holes, tears, splits, gouges and excess wear areas  SuperScrew patch kits for holes and tears. Provides water tight

12. What happens if I install the wrong belt spec?  Belt will wear faster than expected  Belt may potentially fail  Cleats and/or Sidewall may separate from belt

13. Section III: Anatomy of a belt

14. Belt Specification Breakdown  3 = Number of Tension Plies  2 = Number of Cross Rigid Plies

15. What is a Ply?  A rubber coated layer of fabric  Each “fabric” layer is a ply  Commonly a Polyester/Nylon material  Are the strength member of the belt How do you know how many plies you have?  Count the number of layers of fabric visible in the belt

16. CROSS RIGID BELT  Engineered for applications that take a sharp upturn, with a heavy cleat and/or corrugated sidewall.  Cross Rigid belts are rigid across the belt (fill or weft direction)  Provides lateral reinforcement that keeps the belting rigid  Cross Rigid belting will withstand deflection from horizontal to incline without bowing or sagging during operations.

17. Belt Specification Breakdown  3 = Number of Tension Plies  2 = Number of Cross Rigid Plies  330 = Working tension per inch width

18. Working Tension  Working tension is a factor of the fabric/ply  Rated on a per inch width  Fabric strength has a direct impact on minimum pulley diameter requirements Why does it matter?  Belt can snap in operation if not rated for the tension of the system

19. Belt Specification Breakdown  3 = Number of Tension Plies  2 = Number of Cross Rigid Plies  330 = Working tension per inch width  1/8 = Thickness of Rubber top cover

20. Top Cover Thickness  Provides an impact and abrasion resistance layer, protecting the belt fabric  There are standard cover thicknesses which vary based on the plies and tension rating of the belt  Custom thicknesses are available but usually require a minimum quantity purchase

21. Belt Specification Breakdown  3 = Number of Tension Plies  2 = Number of Cross Rigid Plies  330 = Working tension per inch width  1/8 = Thickness of Rubber top cover  1/16 = Thickness of Rubber bottom cover

22. Bottom Cover of a Conveyor Belt  May have a rubber bottom or a “bare-back” bottom  PVC belts are:  COS = Cover one Side  CBS = Cover both sides  Rubber Belts are:  Called out by actual thickness of cover materials

23. What is a “Bare-Back”?  A conveyor belt with no bottom rubber cover  Bottom of conveyor belt is the fabric from the bottom ply Why use a “Bare-Back”?  Slider Bed Applications  Fabric bottom has a lower coefficient of friction than a Rubber bottom

24. Belt Specification Breakdown  3 = Number of Tension Plies  2 = Number of Cross Rigid Plies  330 = Working tension per inch width  1/8 = Thickness of Rubber top cover  1/16 = Thickness of Rubber bottom cover  MOR / Grd II = The type of Rubber Material used in the belt

25. What Rubber Compounds are common? RMA GRADE 2 MOST COMMON COMPOUND GREAT FOR ALL GENERAL MATERIALS AND PRODUCTS GOOD IMPACT AND ABRASION RESISTANCE MOR MAINLY FOR ANY APPLICATION WHERE OILS WILL BE PRESENT. IS MODERATELY RESISTANT TO OILS AND SOLVENTS RMA GRADE 1 MAINLY FOR HIGH IMPACT, CUTTING AND ABRASION APPLICATIONS MORE NATURAL RUBBER BEST IMPACT, ABRASION AND GOUGE RESISTANCE

26. Section IV: Common Belt Specifications and Designs in Fracking

27. Profile Belts  Why use a profile belt?  Inclines greater than 20°  To prevent roll back of material  Common Profiles  Herringbone  Chevron  V-Cleat  MaxClimb  MegaClimb

28. Sidewall Belt; No cleats Frac Sand Belt Configurations  Typically on Sand Delivery Units  Sand Delivery Units receive sand transported to the well site.  Uses a combination of hoppers and conveyor belts to move frac sand to the T-Belt during fracking operations.  Operates on Troughing Idlers Details:  Sidewall height from 2” to 4”  Available on any belt specification

29. Narrow Width MaxClimb w/ Sidewall Frac Sand Belt Configurations  Typically on the T-Belt (Dual Belt Units)  Takes discharge from multiple Sand Delivery Units and delivers to the blenders.  Compartmented belt allows for high angle discharge of materials. Details:  30” and Narrower belts  1-1/4” tall cleats  Sidewall heights of 2” to 6”

30. MaxClimb w/ Sidewall Frac Sand Belt Configurations  Typically on the T-Belt (Single Belt Units)  Takes discharge from multiple Sand Delivery Units and delivers to the blenders.  Compartmented belt allows for high angle discharge of materials. Details:  30” and Wider belts  1-1/4” tall cleats  Sidewall heights of 2” to 6”

31. 3” Peg Belt w/ Sidewall Frac Sand Belt Configurations  “Peg” or “Finger” Belt  Conveys continuous flow of material  Powder to moderate lump sizes  Up to 45° Angles  High material capacity  Can be on Delivery Units or T-Belt Units Details:  24” or 30” Wide (Peg pattern is 20”)  Available on any belt specification  Pegs are 70 durometer

32. Hot Vulcanized Super Screw  Mechanically fastened to belt  Can be installed on one end to expedite field installation  Reduces the installation time and tools required  Provides 5x greater adhesion than chemical bonds  Prevents product spillage through the splice Belt End Preparation Frack Sand can corrode and wear down metal fasteners that are not protected with a rubber cover. Inspect often to prevent failure! Mechanical Splice  Installed in Factory, no tools needed in field

33. How do I know what belt to use?  Belt selection is based on;  Minimum pulley diameter  The configuration of the conveyor system including;  Type & Style of return  Incline  Changes in incline  Slider bed or troughed rollers  Overall length  Height of incline  Weight of material

34. Can I change Styles of Frac Belts?  For the most part, Yes.  Ensure new belt configuration fits the system, checking the following:  Sidewall Height  Cleat clearances (recess, height, etc.)  Belt configuration may alter the speed at which a belt operates to deliver the same tonnage per minute.

35. Frac Sand Environmental Concerns Small Pulley Diameters Small pulley diameters put chemical bonds under stress, causing pre-mature failure Extreme Environments Extreme cold in South Dakota, Pennsylvania, Canadian markets Cold temperatures degrade the chemical bond, causing pre-mature failure Hot vulcanized sidewall is lasting 5x longer than Chemical bonds Field Location Difficulties Timeliness to get to breakdown area Exposure to environment Potential lack of equipment / power sources

36. How to determine quality of a belt  Import vs. Domestic  Location of manufacturing doesn’t matter, the quality does.  Safety Factors  Ply Adhesion  Elongation  Quality of Value-Add Process;  Key term: Hot Vulcanization