How to Design a Conveyor System Using LFT Modular Conveyor Components : STEP 1) Determine Product Size: In this conveyor system design example, we will be conveying a product box that is 8.0” (203.2 mm) long and 6.0” (152.1mm) wide. Next determine the product orientation on the conveyor belt. Let’s assume that we will be conveying the product box in the direction of the long dimension. 8.0” 203.2mm STEP 2) Select the Belt Width Req’d: In this example the product box width dimension of 6.0” (152.1mm) will determine the conveyor belt width. LFT belts come in stock widths in 3.0” (76.2mm) increments. Based on this width dimension, select the next belt width size larger than your product width to allow for guide rails and mounting bracket spacing. For this product width select a 9.0” (228.6mm) belt width. 6.0” 152.1mm Determine Product Size STEP 3) Layout the Conveyor Path: The conveyor system that you will be designing and assembling will transfer a product from one point (A) to a second point (B) on your plant floor. Determine your path, take measurements, and make a rough layout sketch. Select the Belt Width Required In this conveyor system layout example, the conveyor starts at a box forming machine. It continues past a box filling machine, sealerlabeler machine, and a box loader machine, where the product boxes are pushed unto an accumulator. The measured distances are on the sketch. STEP 4) Conveyor System Basics: Every conveyor system will always have certain basic sub-sections or modules to make it function. There will always be a (Drive Module) on one end, and a (Idler Module) on Layout the Conveyor Path 1/7 the other end of the conveyor line. Between these two modules there will usually be a combination of (Straight Section) and (Curved Section) modules mounted together to form the overall conveyor system. There are endless possibilities of conveyor layout configurations using the LFT Modular Conveyor Components. STEP 5) Determine the Type of Material Construction Required for the Conveyor System: LFT offers (2) material construction options depending on the application: ● FDA-USDA Sanitary Construction ● General Industrial Construction Idler Module (Qty 1 Req’d) LFT Series 900 Drive Module The FDA-USDA sanitary construction conveyors are fabricated from #304 stainless steel and FDA-USDA polymers on all surfaces which contacts product. Washdown motors and gear reducers options are also available. Class 100 cleanroom construction is also available upon request. Curved Section Module (Qty 3 Req’d) The general industrial construction conveyors are fabricated from painted carbon steel, aluminum, and various polymers. Powder coated option is available upon request. In this example we will select a sanitary construction with a washdown motor and gear reducer. LFT Series 300 Support Leg Straight Section Module (Qty 4 Req’d-Various Lengths) STEP 6) Determine the LFT Conveyor Module Types Needed to Configure the Conveyor System Layout: In this conveyor system design example, there are a number of different conveyor section types used. Based on the layout sketch, the conveyor line can be divided into the following sub-sections or modules: ● (1) Idler End Section ● (3) Curved Sections ● (2) Long Straight Sections ● (2) Short Straight Sections ● (1) Drive End Module LFT Conveyor Accessories Drive End Module (Qty 1 Req’d) 2/7 STEP 7) Determine the Bearing Type Required : LFT offers (2) bearing type options for both the drive and idler section modules: ● External Mounted Bearings ● Internal Mounted Bearings External mounted bearings are standard and are used for end or butt product transfers. Internal mounted bearings are used for side product transfers on the idler and drive end section modules. Example of External Mounted Bearings (Washdown Type) In this example external mounted bearings are used. STEP 8) Determine the Number of Support Legs and the Conveyor Height Required for the Conveyor System: In determining the number of support leg assemblies required for your conveyor system layout, each individual section or module requires: ● Idler End Module (1 support) ● Straight Section Module (3 ft (915mm) or 4ft (1219mm) (1 support) ● Straight Section Modules (6 ft (1830mm) or 8 ft (2438mm ) (2 supports) ● Curved Sections (1 support) ● Drive End Module (1 support) In determining your conveyor height, LFT Leg Support Assemblies have a height range option of 30” (762mm) to 45” (1143mm) available in 1” (25.4mm) increments. Select the height that best suits your application. Support Leg Assembly (Single Strut) STEP 9) Select the Belt Material for the Conveyor System: LFT offers (2) standard belt materials (POM- and PP), and (7) nonstandard belt materials (PE, GR, AS-POM, FR, PVDF, PA6, and PA6.6). Each belt type is linked with stainless steel pins (Type 304 or 316). (Refer to the LFT website Belt Products page for a full description and options) In this this example the POM belt material will be selected with (304 SST) link pins. Both POM and PP are FDA and USDA approved. POM Sanitary Belt Material 3/7 STEP 10) Calculating the Gear Reducer Speed Ratio, Motor Type, and Motor Horsepower for your Conveyor System: LFT offers the following drive components as part of our Modular Conveyor Product offering: ● AC/DC Gearmotor Assemblies ● AC/DC Motors (56C mtg) ● RA Gear Reducers (56C mtg) ● AC/DC Electronic Motor Drives STEP 10.1) Determine the Product Transfer Rate Required for your Process Application: >Determine the maximum conveyor transfer rate for your process. The transfer rate unit for calculation purposes is (products per minute or products/minute) (In this example: Transfer Rate = 60 products/minute) STEP 10.2) Calculate the Conveyor Surface Linear Speed Required for your Application: >Known or calculated data so far: -Transfer Rate = 60 products/minute -Product Length = 8.0” Calculate the Conveyor Surface Linear Speed that Will Transfer in (1 Minute): (in Feet/minute) >Determine the desired (nominal gap distance) between products on the conveyor: (In this example: Assume a (gap distance) of 2.0”) >Determine the total conveyor length transferred in (1) minute: -(Conveyor Length/minute = 60 x (8.0” + 2.0”) = 600 Inches/minute) >Convert the transfer rate units to Feet/Minute: -(Conveyor Transfer Rate (Feet/Minute) = (600 inch/min) ÷ (12) = 50 Feet /Minute STEP 10.3) Calculate the Gear Reducer Output Speed (RPM) Required for your Application: >Known or calculated data so far: -Transfer Rate = 60 products/minute -Product Length = 8.0” -Conveyor Transfer Rate = 50 feet/minute >In this calculation the nominal pitch diameter of the belt sprockets are required. The nominal pitch diameter (PD) of all LFT Modular Conveyors equals (5.88” diameter). >Calculate the gear reducer output RPMs: Gear Reducer Output: (RPM’s) = (Conveyor Length/Minute) ÷ (3.14 x PD) = (600.0”/minute) ÷ (3.14 x 5.88”) = (600.0”/minute) ÷ (18.46”) = 32.50 RPMs 4/7 -Conveyor Length/minute = 600.0” (15240mm) per minute STEP 10.4) Calculate the Motor Horsepower (HP) Required for your Application: >Known or calculated data so far: -Transfer Rate = 60 products/minute -Product Length = 8.0” -Conveyor Transfer Rate = 50 feet/minute -Gear Reducer Output Speed = 32.50 RPMs >Determine the combined weight of the product on the entire conveyor length and the total weight of the conveyor belt: -Based on the measurements on the design sketch layout, the overall length of conveyor = 55 feet -Based on this length (55 ft) and the length of product with the gap (8” product + 2” gap), the total number of products on the total conveyor length = 55 ft ÷ (10”/12) = 66 products -For this example the product weight is 1.50 lbs each. Based on this the total product weight on the conveyor (66 x 1.50 = 99 lbs) -Next, determine the total conveyor belt weight. In this example the belt material is (POM with SST link pins). Based on available belt data on the web page the belt weight density = (2.62 lbs/ft2) >The overall conveyor area = (Belt Length) x 2 x (Belt Width/12) = (55 ft long) x 2 x (9”/12) = (82.5 ft2) >The total belt weight = (Total Belt Area) x (Belt Wt Density) = (82.5 ft2) x (2.62 lbs/ft2) = (216.15 lbs) >Determine the coefficient of friction of the belt. LFT conveyors incorporate a multi-under rail slider bed fabricated from UHMW-PE. -To be conservative, the average (Coefficient of Friction = 0.30) >Calculate the Required Motor Horsepower for your Conveyor System Layout: >Known or calculated data so far: -Transfer Rate = 60 products/minute -Product Length = 8.0” -Conveyor Linear Transfer Rate = 50 feet/minute -Gear Reducer Output Speed = 32.50 RPMs -Total Product Weight = 99 lbs -Total Conveyor Belt Weight = 216.5 lbs -Belt/Slider Bed Coefficient of Friction (uF) = 0.30 >Finally, determine the gear reducer efficiency factor for the motor horsepower Calculation: -Assume the gear reducer efficiency factor = 0.80 5/7 >Calculate the Conveyor Motor Horsepower (Hp): (Product Weight + Belt Weight) x (Belt uF ) x (Belt Transfr. Rate in (fpm)) Motor (Hp) = 33,000 x (Gear Reducer Effec.) x (Safety Buffer Factor of 0.90) (99 lbs + 216.5 lbs) x (0.30 ) x (50.0 (fpm)) Motor (Hp) = 33,000 x (0.80) x (0.90) (4732.5) Motor (Hp) = (23,760) Motor (Hp) = 0.1992 Hp (Use the next larger motor HP size. ) Motor (Hp) = 0.250 HP STEP 11) Determine the Conveyor Accessories Required: LFT offers many conveyor accessories to complete your conveyor design. A complete listing can be found on the LFT Product web page. These conveyor accessories include: ● Guide Rails ● Guide Rail Brackets ● Rail Support Rods ● Rail Splice Brackets ● Swivel Guide Rod Brackets ● Straight Guide Rod Brackets ● Pneumatic Stops ● Electric Stops 6/7 Technical Support and Accounting: Lord & Frey Technologies 27068 La Paz Rd. Suite #273 Aliso Viejo, CA 92656 Phone: (803) 403-9288 Web: (www.LordFreyTechnologies.com) Sales: (Sales@LordFreyTechnologies.com) Technical Support: (TechSupport@LordFreyTechnologies.com ) 7/7
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