1. Catalogs
  2. ENIDINE
  3. amortisseurs industriels A4

amortisseurs industriels A4

amortisseurs industriels A4
1 / 180 PagesView full catalog

amortisseurs industriels A4

Product catalog summary
Company Overview
ITT Enidine is a global leader in energy absorption and vibration isolation products for industries such as industrial, aerospace, defense, marine, and rail. Founded in 1966, it operates globally with facilities in the USA, Germany, France, Japan, and China, known for engineering excellence and technical support.
New Technologies and Enhancements
ITT Enidine emphasizes innovation in energy absorption and vibration isolation, using advanced tools like 3-D CAD modeling and finite element analysis. They focus on rapid product development and custom designs to meet specific customer needs.
Theory of Energy Absorption
Energy absorption is vital for reducing noise, damage, and vibration in high-speed machinery. ITT Enidine's shock absorbers convert kinetic energy into thermal energy, providing controlled deceleration, resulting in longer machine life and improved production quality.
Product Selection
The document outlines various product series, including adjustable and non-adjustable shock absorbers, heavy-duty shock absorbers, and vibration isolation products, with technical data and typical applications.
Global Service and Support
ITT Enidine offers global support through a trained distribution network and customer service specialists, providing tools like the Enisize Sizing Portal for product selection and design assistance.
Overview of Shock Absorbers
Industrial shock absorbers differ from automotive types in damping force characteristics, with industrial absorbers handling higher damping forces due to stronger materials.
Adjustment Techniques
Proper adjustment of shock absorbers is crucial for energy dissipation and noise reduction, ensuring smooth deceleration and minimal noise.
Sizing Shock Absorbers
A six-step process for sizing shock absorbers includes identifying parameters like load weight and impact velocity, with calculations for kinetic energy and total energy per cycle.
Specifications and Calculations
  • Horizontal Applications: Examples include rotating masses and doors, with calculations for kinetic energy and total energy per cycle.
  • Vertical Applications: Examples cover rotating arms and beams, considering gravity's effect on energy calculations.
  • Crane Applications: Scenarios involve cranes against solid stops, emphasizing worst-case scenarios.
Recommendations: Specific shock absorber models are suggested based on calculated energy requirements.
Specifications: Lists various models of shock absorbers with stroke lengths, maximum shock forces, and damping types, categorized into adjustable and non-adjustable types.
Procedures: Outlines calculation methods for selecting shock absorbers, including determining maximum impact mass per buffer and calculating kinetic energy.
Standards and Recommendations: Shock absorbers meet ISO quality standards, emphasizing environmentally friendly materials and RoHS compliance.
Key Features: Adjustable shock absorbers allow fine-tuning of damping force, with special materials and finishes for specific customer requirements.
Technical Data: Includes a quick selection guide for shock absorbers, organized by energy capacity per cycle.
Non-Adjustable Series: Describes non-adjustable shock absorbers designed for consistent performance and maximum energy absorption in compact sizes.
Features and Benefits: Emphasizes flexibility, reliability, and long-life operation of shock absorbers, highlighting tamperproof design and compliance with ISO quality standards.
Applications: Suitable for packaging, high-speed automation, and medical devices, designed to handle varying energy conditions.
Accessories: Lists accessories such as jam nuts and lock rings, enhancing functionality and mounting flexibility.
Graphs and Curves: Sizing curves illustrate minimum impact velocity and energy absorption characteristics for different models.
Heavy Duty Series Shock Absorbers: Designed to decelerate large energy capacity loads smoothly and safely, meeting various safety specifications.
Mounting and Accessories: Various mounting configurations are available, with optional accessories like magnetic proximity sensors.
Key Data Summary: Includes detailed tables listing dimensions, maximum energy capacities, and other critical parameters for each model.
Rate Controls: ADA/DA Series Rate Controls regulate speed and time for mechanisms, enhancing performance in various applications.
Advantages of Rate Controls: Include longer machine life, improved production quality, safer operation, and competitive advantage.
Technical Specifications: Outlines various models of ADA and DA series, detailing damping direction, stroke, propelling force, and energy capacity.
Wire Rope Isolators: Designed for vibration and shock absorption, with specifications for static load, deflection, and stiffness values.
Materials and Customization: Optional materials for wire ropes and mount bars are available, with customization options.
Performance and Applications: Suitable for applications like electronic motor isolation and medical equipment, with equations for predicting system performance.
WEAR™ Pipe Restraints: Wire rope isolators used in industries like nuclear plants, offering environmental stability and corrosion resistance.
Wire Mesh Isolators: Made from wire mesh material, providing high-damping characteristics for applications like engines and sensitive electronics.
Technical Capabilities: ITT Enidine offers custom engineering solutions with capabilities in 3D modeling and system analysis.
See more

Catalog excerpts

amortisseurs industriels A4-1

Shock and Vibration Products Shock and VIbration Products

 Open the catalog to page 1
amortisseurs industriels A4-2

ITT Enidine provides quality energy absorption and vibration isolation products and services to a variety of heavy industries throughout the globe. These industries include; steel and aluminum rolling mills, manufacturers of mill equipment, gantry cranes, ship to shore cranes, overhead bridge crane manufacturers and automated stacker cranes. ITT is a diversified leading manufacturer of highly engineered critical components and customized technology solutions for growing industrial end-markets in energy, infrastructure, automation and heavy industries. Building on its heritage of innovation, ITT...

 Open the catalog to page 2
amortisseurs industriels A4-3

Table of Contents Product Selection General ECO OEM/OEMXT Series (Adjustable Shock Absorbers) Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19-20 Technical Data and Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21-34 Adjustment Techniques/Typical Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35-36 TK/STH Series (Non-Adjustable Shock Absorbers) Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ....

 Open the catalog to page 3
amortisseurs industriels A4-4

Company Overview ITT Enidine Overview Company Overview With its world headquarters located in Orchard Park, New York, USA, ITT ENIDINE Inc. is a world leader in the design and manufacture of standard and custom energy absorption and vibration isolation product solutions within the Industrial, Aerospace, Defense, Marine and Rail markets. Product ranges include shock absorbers, gas springs, rate controls, air springs, wire rope isolators, heavy industry buffers and emergency stops. With facilities strategically located throughout the world and in partnership with our vast global network of distributors,...

 Open the catalog to page 4
amortisseurs industriels A4-5

New Technologies and Enhancements Research and Development New Products and Services ITT Enidine engineers continue to monitor and influence trends in the motion control industry, allowing us to remain at the forefront of new energy absorption and vibration isolation product development. Our experienced engineering team has designed custom solutions for a wide variety of challenging applications, including automated warehousing systems and shock absorbers for hostile industrial environments such as glass manufacturing, among others. These custom application solutions have proven to be critical...

 Open the catalog to page 5
amortisseurs industriels A4-6

Theory of Energy Absorption ITT Enidine Theory of Energy Absorption Overview As companies strive to increase productivity by operating machinery at higher speeds, often the results are increased noise, damage to machinery/products, and excessive vibration. At the same time, safety and machine reliability are decreased. A variety of products are commonly used to solve these problems. However, they vary greatly in effectiveness and operation. Typical products used include rubber bumpers, springs, cylinder cushions and shock absorbers. The following illustrations compare how the most common products...

 Open the catalog to page 6
amortisseurs industriels A4-7

Theory of Energy Absorption ITT Enidine Overview Shock Absorber Performance When Weight or Impact Velocity Vary When conditions change from the original calculated data or actual input, a shock absorber’s performance can be greatly affected, causing failure or degradation of performance. Variations in input conditions after a shock absorber has been installed can cause internal damage, or at the very least, can result in unwanted damping performance. Variations in weight or impact velocity can be seen by examining the following energy curves: This is explained by observing the structural design...

 Open the catalog to page 7
amortisseurs industriels A4-8

Shock Absorber Sizing Examples Typical Shock Absorber Applications_ SHOCK ABSORBER SIZING Follow the next six steps to manually size ITT Enidine shock absorbers: STEP 1: Identify the following parameters. These must be known for all energy absorption calculations. Variations or additional information may be required in some cases. A. Weight of the load to be stopped (Kg). B. Velocity of the load upon impact with the shock absorber (m/s). C. External (propelling) forces acting on the load (N), if any. D. Cyclic frequency at which the shock absorber will operate. E. Orientation of the application's...

 Open the catalog to page 8
amortisseurs industriels A4-9

Shock Absorber Sizing Examples Typical Shock Absorber Applications B. To Determine the Approximate Stroke (Conventional Damping Only) S = ek SYMBOLS a = Acceleration (m/s2) A = Width (m) B = Thickness (m) C = Number of cycles per hour d = Cylinder bore diameter (mm) D = Distance (m) E k = Kinetic energy (Nm) E t = Total energy per cycle (Nm/c), E k + E w EtC= Total energy to be absorbed per hour (Nm/hr) E w = Work or drive energy (Nm) Fd = Propelling force (N) Fp = Shock force (N) H = Height (m) Hp = Motor rating (kw) I = Mass moment of inertia (kgm2) K = Radius of gyration (m) L = Length (m) P...

 Open the catalog to page 9
amortisseurs industriels A4-10

Shock Absorber Sizing Examples ■ Shock Absorber Sizing Examples Typical Shock Absorber Applications Overview EXAMPLE 3: Vertical Moving Load with Propelling Force Upward STEP 1: Application Data (M) Mass = 1 550 kg (V) Velocity = 2 m/s (d) 2 Cylinders bore dia. = 150mm (P) Operating pressure = 5 bar (C) Cycles/Hr = 200 STEP 3: Calculate work energy Fd =2 x [0,0785 x d2 x P] -[9,8 x M] Fd = 2 x [0,0785 x 1502 x 5] -[9,8 x 1 550] Fd = 2 472,5 N Ew = Fd X S EW = 2 472,5 x 0,125 Ew = 309 Nm STEP 4: Calculate total energy per cycle ET = EK + EW Et = 3 100 + 309 Et = 3 409 Nm/c STEP 5: Calculate total energy...

 Open the catalog to page 10
amortisseurs industriels A4-11

Shock Absorber Sizing Examples Typical Shock Absorber Applications _LOverview EXAMPLE 6: Horizontal Moving Load with Propelling Force STEP 1: Application Data (M) Mass = 900 kg (V) Velocity = 1,5 m/s (d) Cylinder bore dia. = 75mm (P) Operating pressure = 5 bar (C) Cycles/Hr = 200 STEP 2: Calculate kinetic energy M ,,2 Ek = -y x V2 900 2 STEP 3: Calculate work energy Fd = 0, 0785 x d2 x P Fd = 0, 0785 x 752 x 5 Fd = 2 208,9 N Ew = Fd x S EW = 2 208,9 x 0,05 EW = 110 Nm/c STEP 4: Calculate total energy per cycle ET = ek + E W Et = 1 012,5 + 110 ET = 1 122,5 Nm/c STEP 5: Calculate total energy...

 Open the catalog to page 11
*Prices are pre-tax. They exclude delivery charges and customs duties and do not include additional charges for installation or activation options. Prices are indicative only and may vary by country, with changes to the cost of raw materials and exchange rates.