Electrofusion welding

Last updated

Electrofusion welding is a form of resistive implant welding used to join pipes. A fitting with implanted metal coils is placed around two ends of pipes to be joined, and current is passed through the coils. Resistive heating of the coils melts small amounts of the pipe and fitting, and upon solidification, a joint is formed. It is most commonly used to join polyethylene (PE) and polypropylene (PP) pipes. Electrofusion welding is the most common welding technique for joining PE pipes. [1] Because of the consistency of the electrofusion welding process in creating strong joints, it is commonly employed for the construction and repair of gas-carrying pipelines. [2] The development of the joint strength is affected by several process parameters, and a consistent joining procedure is necessary for the creation of strong joints.

Contents

Advantages and disadvantages

Advantages of electrofusion welding:

Disadvantages of electrofusion welding:

Equipment

Electrofusion welds are performed by attaching a controlled power supply to the electrofusion fitting. There are typically two modes of operation.

Constant voltage is typically used for high pressure pipelines such as mains gas and water. Fittings are fitted with a barcode specified to an ISO standard. Typically fittings will be welded at 39.5v, but manufacturers can choose voltages in whole numbers from 8 to 48v. The welding time is specified on the label in seconds or minutes

Accessories

Electrofusion pipe fitting Electrofusion fitting.jpg
Electrofusion pipe fitting

Electrofusion welding employs fittings that are placed around the joint to be welded. Metal coils are implanted into the fittings, and electric current is run through the coils to generate heat and melt part of the pipes, forming a joint upon solidification. There are two possible fittings used in electrofusion welding: couplers and tapping tees (saddles). Coupler fittings contain two separate regions of coils, creating two distinct fusion zones during welding. The inner diameter of the coupler is typically slightly larger than the outer diameter of the pipes. This is to increase the ease of assembly in the field and allows for minor inconsistencies in pipe diameter. Proper insertion of the pipes in the coupler is critical for the creation of a strong joint. Incorrect placement of the coupler can cause the coils to move and lead to the extrusion of molten polymer material from the joint, reducing the joint's strength. Tapping tees, or saddles, are less common but operate under the same principles as a coupler. They require clamping to ensure a proper fit up with the pipes.

Fitting installation

Installation of couplers and tapping tee fittings require slightly different procedures. Common installation steps for each are given below.

Couplers

  1. Wash pipe ends to create clean surfaces for joining
  2. Square pipe ends to facilitate optimal fit-up
  3. Clean area where coupler will be placed with isopropyl alcohol
  4. Mark the pipes slightly beyond half the length of the coupler, to indicate where scraping will take place in later steps
  5. Mark the area to be scraped
  6. Scrape pipe in marked areas to remove surface layer, allowing clean pipe material to contact the coupler
  7. Examine scraped area thoroughly, making sure that fresh pipe material is exposed throughout area
  8. Insert pipe ends into coupling to appropriate depth
  9. Secure coupler using clamp
  10. Connect fitting to control box using electrical leads
  11. Apply fusion cycle
  12. Allow joint to be undisturbed for the entire prescribed cooling time
  13. Pressure test pipe
  14. Back fill pipe with appropriate contents
  15. Begin service

Tapping tee

  1. Wash pipe area to be joined to create clean surfaces for joining
  2. Clean area where tapping tee will be placed with isopropyl alcohol
  3. Mark the pipes slightly beyond the edges of the tapping tee location
  4. Scrape pipe in marked areas to remove surface layer, allowing clean pipe material to contact the tapping tee
  5. Examine scraped area thoroughly, making sure that fresh pipe material is exposed throughout area
  6. Place tapping tee onto joint
  7. Secure tapping tee using clamp
  8. Connect fitting control box using electrical leads
  9. Apply fusion cycle
  10. Allow joint to be undisturbed for the entire prescribed cooling time
  11. Pressure test pipe
  12. Back fill pipe with appropriate contents
  13. Begin service [3]

Power requirements

Electrofusion welding requires electrical current to be passed through the coils implanted in the fittings. Since the electrical energy input is an excellent indicator of the joint strength that develops during fusion, it is necessary to have consistent electrical power input. Energy input during the joining process is typically measured by controlling the time it takes for the current to pass through the fitting. However, energy input can also be monitored by controlling overall temperature, molten polymer temperature, or molten polymer pressure. [4]

A control box takes electrical power from a generator and converts it into an appropriate voltage and current for electrofusion joining. This provides consistent energy input for each application. The most common input voltage for electrofusion welding fittings is 39.5V, as it provides the best results without risking operator safety. The current is input as an alternating current (AC) waveform.

Welding process

Stages during welding

Electrofusion welding is characterized by four distinct stages that occur during the welding process:

  1. Incubation period
  2. Joint formation and consolidation
  3. Plateau region
  4. Cooling period

During the incubation period, heat is introduced into the joint as current is passed through the coil. Although there is no joint strength at this point, the polymer expands and the joint gap is filled. During joint formation and consolidation, melting begins. Melt pressure has begun to build, and the majority of the joint's strength is developed during this stage. The strength increase is due primarily to the constraint of the increasing molten material by the cold zones in the surrounding fitting. The plateau region signals the stabilization of the joint strength. Despite this, the heat of the joint is still increasing with time during this stage. The cooling period occurs after current is no longer applied to the coils. The molten polymer material solidifies and forms the joint.

Current during welding

Most electrofusion welding power supplies are constant voltage machines. Constant current machines would provide more consistent energy input due to the smaller fluctuations in current applied to the coils during welding. However, this additional consistency is generally not worth the higher cost of these machines. When a constant voltage machine is used, the value of the applied current slowly decreases throughout the welding process. This effect is due to the increasing resistance of the coils as energy is applied. As heat is generated in the coils, their temperature increases, leading to a higher electrical resistance in the coils. This increased electrical resistance causes a smaller current to be generated from the same voltage level as the process progresses. The extent of the current decrease is determined by the material used for the coil. The energy input per unit area can be calculated and used to monitor the process. Typical values for this range from 2–13 J/mm2, with a value of 3.9 J/mm2 having been found to produce the strongest joints. [5] [6]

Temperature in different areas of a joint during the electrofusion welding process Temperature history.png
Temperature in different areas of a joint during the electrofusion welding process

Temperature during welding

Large temperature gradients exist in the electrofusion joint during the fusion cycle. The low thermal conductivity of polymers is the main cause of these large gradients. Recent efforts to model the thermal history at various locations using finite element modeling have been successful. [7] [8] [9] [10]

Pressure during welding

As the temperature in the joint increases, polymer begins to melt and a fusion zone is formed. The molten polymer in the fusion zone exerts an outward force on the surrounding solid polymer material, referred to as "cold zones". These cold zones cause a pressure to develop in the molten fusion zone. The pressure in the fusion zone takes some time to reach its maximum value, usually not reaching the peak until about a quarter of the way into the joining process. After the current is shut off and cooling begins, the pressure slowly decreases until the joint is uniform temperature.

Properties of joints

The strength of an electrofusion joint is measured using tensile and peel tests on coupons taken from the fusion zone of the joint. Two methods have been developed to assess the effect of fusion time on joint strength:

  1. Simulating an electrofusion joint solely for testing purposes
  2. Removing test coupons from standard electrofusion welded joints

The strength of the joint develops throughout the welding process, and this development is affected by the fusion time, joint gap, and pipe material. These are detailed below.

Effect of fusion time on joint strength

As fusion time begins, there is an incubation period where no strength develops. Once enough time has passed for the molten material to begin solidifying, the joint strength begins to develop before plateauing at the maximum strength. If power is applied after full joint strength is achieved, the strength will start to decline slowly. [5] [11]

Effect of joint gap on joint strength

The joint gap is the distance between the electrofusion fitting and the pipe material. When no joint gap is present, the resulting joint strength is high but not maximum. As joint gap increases, the joint strength increases to a point, then begins to decline fairly sharply. At larger gaps sufficient pressure cannot build during the fusion time, and the joint strength is low. [12] The effect of joint gap on strength is why the scraping of the pipes before welding is a critical step. Uneven or inconsistent scraping can result in areas where the joint gap is large, leading to low joint strength.

Effect of pipe material on joint strength

Pipe materials with higher molecular weights (MW), or densities, will have slower material flow rates when in the molten state during fusion. Despite the differences in flow rates, the final joint strength is generally consistent over a fairly wide range of pipe molecular weights. [13] [14] [15] [16]

Related Research Articles

<span class="mw-page-title-main">Plumbing</span> Systems for conveying fluids

Plumbing is any system that conveys fluids for a wide range of applications. Plumbing uses pipes, valves, plumbing fixtures, tanks, and other apparatuses to convey fluids. Heating and cooling (HVAC), waste removal, and potable water delivery are among the most common uses for plumbing, but it is not limited to these applications. The word derives from the Latin for lead, plumbum, as the first effective pipes used in the Roman era were lead pipes.

<span class="mw-page-title-main">Welding</span> Fabrication or sculptural process for joining materials

Welding is a fabrication process that joins materials, usually metals or thermoplastics, by using high heat to melt the parts together and allowing them to cool, causing fusion. Welding is distinct from lower temperature techniques such as brazing and soldering, which do not melt the base metal.

<span class="mw-page-title-main">Polyethylene</span> Most common thermoplastic polymer

Polyethylene or polythene (abbreviated PE; IUPAC name polyethene or poly(methylene)) is the most commonly produced plastic. It is a polymer, primarily used for packaging (plastic bags, plastic films, geomembranes and containers including bottles, etc.). As of 2017, over 100 million tonnes of polyethylene resins are being produced annually, accounting for 34% of the total plastics market.

<span class="mw-page-title-main">Plastic welding</span> Welding of semi-finished plastic materials

Plastic welding is welding for semi-finished plastic materials, and is described in ISO 472 as a process of uniting softened surfaces of materials, generally with the aid of heat. Welding of thermoplastics is accomplished in three sequential stages, namely surface preparation, application of heat and pressure, and cooling. Numerous welding methods have been developed for the joining of semi-finished plastic materials. Based on the mechanism of heat generation at the welding interface, welding methods for thermoplastics can be classified as external and internal heating methods, as shown in Fig 1.

Electric resistance welding (ERW) is a welding process where metal parts in contact are permanently joined by heating them with an electric current, melting the metal at the joint. Electric resistance welding is widely used, for example, in manufacture of steel pipe and in assembly of bodies for automobiles. The electric current can be supplied to electrodes that also apply clamping pressure, or may be induced by an external magnetic field. The electric resistance welding process can be further classified by the geometry of the weld and the method of applying pressure to the joint: spot welding, seam welding, flash welding, projection welding, for example. Some factors influencing heat or welding temperatures are the proportions of the workpieces, the metal coating or the lack of coating, the electrode materials, electrode geometry, electrode pressing force, electric current and length of welding time. Small pools of molten metal are formed at the point of most electrical resistance as an electric current is passed through the metal. In general, resistance welding methods are efficient and cause little pollution, but their applications are limited to relatively thin materials.

<span class="mw-page-title-main">High-density polyethylene</span> Class of polyethylenes

High-density polyethylene (HDPE) or polyethylene high-density (PEHD) is a thermoplastic polymer produced from the monomer ethylene. It is sometimes called "alkathene" or "polythene" when used for HDPE pipes. With a high strength-to-density ratio, HDPE is used in the production of plastic bottles, corrosion-resistant piping, geomembranes and plastic lumber. HDPE is commonly recycled, and has the number "2" as its resin identification code.

<span class="mw-page-title-main">Pipe (fluid conveyance)</span> Tubular section or hollow cylinder

A pipe is a tubular section or hollow cylinder, usually but not necessarily of circular cross-section, used mainly to convey substances which can flow — liquids and gases (fluids), slurries, powders and masses of small solids. It can also be used for structural applications; hollow pipe is far stiffer per unit weight than solid members.

<span class="mw-page-title-main">Electrofusion</span>

Electrofusion is a method of joining MDPE, HDPE and other plastic pipes using special fittings that have built-in electric heating elements which are used to weld the joint together.

<span class="mw-page-title-main">Plastic extrusion</span> Melted plastic manufacturing process

Plastics extrusion is a high-volume manufacturing process in which raw plastic is melted and formed into a continuous profile. Extrusion produces items such as pipe/tubing, weatherstripping, fencing, deck railings, window frames, plastic films and sheeting, thermoplastic coatings, and wire insulation.

<span class="mw-page-title-main">Piping and plumbing fitting</span> Connecting pieces in pipe systems

A fitting or adapter is used in pipe systems to connect straight sections of pipe or tube, adapt to different sizes or shapes, and for other purposes such as regulating fluid flow. These fittings are used in plumbing to manipulate the conveyance of water, gas, or liquid waste in domestic or commercial environments, within a system of pipes or tubes.

<span class="mw-page-title-main">Plastic pipework</span> Tubular section or hollow cylinder made of plastic

Plastic pipe is a tubular section, or hollow cylinder, made of plastic. It is usually, but not necessarily, of circular cross-section, used mainly to convey substances which can flow—liquids and gases (fluids), slurries, powders and masses of small solids. It can also be used for structural applications; hollow pipes are far stiffer per unit weight than solid members.

<span class="mw-page-title-main">Heat fusion</span>

Heat fusion is a welding process used to join two different pieces of a thermoplastic. This process involves heating both pieces simultaneously and pressing them together. The two pieces then cool together and form a permanent bond. When done properly, the two pieces become indistinguishable from each other. Dissimilar plastics can result in improper bonding.

Hot plate welding, also called heated tool welding, is a thermal welding technique for joining thermoplastics. A heated tool is placed against or near the two surfaces to be joined in order to melt them. Then, the heat source is removed, and the surfaces are brought together under pressure. Hot plate welding has relatively long cycle times, ranging from 10 seconds to minutes, compared to vibration or ultrasonic welding. However, its simplicity and ability to produce strong joints in almost all thermoplastics make it widely used in mass production and for large structures, like large-diameter plastic pipes. Different inspection techniques are implemented in order to identify various discontinuities or cracks.

Vibration welding refers to a process in which two workpieces are brought in contact under pressure, and a reciprocating motion (vibration) is applied along the common interface in order to generate heat. The resulting heat melts the workpieces, and they become welded when the vibration stops and the interface cools. Most machinery operates at 120 Hz, although equipment is available that runs between 100–240 Hz. Vibration can be achieved either through linear vibration welding, which uses a one dimensional back and forth motion, or orbital vibration welding which moves the pieces in small orbits relative to each other. Linear vibration welding is more common due to simpler and relatively cheaper machinery required.

Spin welding is a form of friction welding used to join thermoplastic parts. The parts to be welded must be round, and in plane with each other. Like all other welding methods this process utilizes heat, time, and pressure to create a weld joint. Heat is generated via internal friction generated between the two parts when rotating and subjected to a load normal to the weld joint. This frictional heat causes the plastic to melt and a bond to be created.

Extrusion welding is one of the processes used to weld thermoplastics and composites, developed in the 1960s as an evolution of hot gas welding. It can be a manual or automated process.

Advanced thermoplastic composites (ACM) have a high strength fibres held together by a thermoplastic matrix. Advanced thermoplastic composites are becoming more widely used in the aerospace, marine, automotive and energy industry. This is due to the decreasing cost and superior strength to weight ratios, over metallic parts. Advance thermoplastic composite have excellent damage tolerance, corrosion resistant, high fracture toughness, high impact resistance, good fatigue resistance, low storage cost, and infinite shelf life. Thermoplastic composites also have the ability to be formed and reformed, repaired and fusion welded.

HDPE pipe is a type of flexible plastic pipe used for fluid and gas transfer and is often used to replace ageing concrete or steel mains pipelines. Made from the thermoplastic HDPE, its high level of impermeability and strong molecular bond make it suitable for high pressure pipelines. HDPE pipe is used across the globe for applications such as water mains, gas mains, sewer mains, slurry transfer lines, rural irrigation, fire system supply lines, electrical and communications conduit, and stormwater and drainage pipes. However, most United States municipal governments restrict its use on public works projects.

IR welding is a welding technique that uses a non-contact heating method to melt and fuse thermoplastic parts together using the energy from infrared radiation. The process was first developed in the late 1900s, but due to the high capital cost of IR equipment the process was not commonly applied in industry until prices dropped in the 1990s. IR welding typically uses a range of wavelengths from 800 to 11,000 nm on the electromagnetic spectrum to heat, melt, and fuse the interface between two plastic parts through the absorption and conversion of the IR energy into heat. Laser welding is a similar joining process that applies IR radiation at a single wavelength.

Implant induction welding is a joining method used in plastic manufacturing. The welding process uses an induction coil to excite and heat electromagnetically susceptible material at the joint interface and melt the thermoplastic. The susceptible material can be contained in a gasket placed between the welding surface, or within the actual components of a composite material. Its usage is common for large, unusually shaped, or delicate parts that would be difficult to weld through other methods.

References

  1. "Welding of Large Diameter PE Pipes a Special Challenge". Pipeline and Gas Journal. 223: 30–33. 1993.
  2. Shi, Jianfeng; Zheng, Jinyang; Guo, Weican; Xu, Ping; Qin, Yongquan; Zuo, Shangzhi (2009-10-08). "A Model for Predicting Temperature of Electrofusion Joints for Polyethylene Pipes". Journal of Pressure Vessel Technology. 131 (6): 061403–061403–8. doi:10.1115/1.4000202. ISSN   0094-9930.
  3. 1 2 Fischer, G. (2017). Electrofusion Installation and Training Manual. Shawnee, OK.
  4. D. Usclat, “Producing a Good Joint Electrofusion Fittings,” Proc. Ninth Plastic Fuel Gas Pipe Symposium, p. 57, The American Gas Association, Arlington, Va. (November 1985).
  5. 1 2 H. Nishimura, M. Nakakura, BA S. Shishido, A. Masaki, H. Shibano, and F. Nagatani, "Effect of Design Factors of EF joints on Fusion Strength," Proc. Eleventh Plastic Fuel Gas Pipe Symposium, p. 99, The American Gas Association, Arlington, Va. (October 1989).
  6. D. Usclat, "Characteristics of a Good Joint with Electrofusion Fittings," Proc. 6th Znt. Conf. on Plastics Pipes, paper 31A, The Plastics and Rubber Institute, London (March 1985).
  7. Shi, Jianfeng; Zheng, Jinyang; Guo, Weican; Xu, Ping; Qin, Yongquan; Zuo, Shangzhi (2009-10-08). "A Model for Predicting Temperature of Electrofusion Joints for Polyethylene Pipes". Journal of Pressure Vessel Technology. 131 (6): 061403–061403–8. doi:10.1115/1.4000202. ISSN   0094-9930.
  8. G. L. Pitman. "Electrofusion Welding Prediction and Computer-Aided Design of Fittings," &id. paper 29.
  9. M. F. Kanninen, G. S. Buczala, C. J. Kuhlman, S. T. Green, S. C. Grigory, P. E. O’Donoghue, and M. A. Mc- Carthy, "A Theoretical and Experimental Evaluation of the Long Term Integrity of an Electrofusion Joint," Proc. Plastics Ppes WZZ, paper B2f 3, The Plastics and Rubber Institute, London (September 1992).
  10. A. Nakashiba, H. Nishimura, and F. Inoue, "Fusion Simulation of Electrofusion Joints for Gas Distribution," Polym. Eng. Sci., 33. 1146 (1993).
  11. Masaki, A.; Nishimura, H.; Akiyama, S. (September 1991). "Verification of EF Joint Fusion Strength Evaluation Using Model Specimen". Proc. Twelfth Plastic Fuel Gas Pipe Symposium: 298.
  12. D. Usclat, "Characteristics of a Good Joint with Electro- fusion Fittings," Proc. 6th Znt. Conf. on Plastics Pipes, paper 31A, The Plastics and Rubber Institute, London (March 1985)
  13. L. Ewing and L. Maine, "The Electrofusion of PE Gas Pipe Systems in British Gas," Roc. Eighth Plastic Fuel Gas Pipe Symposium, p. 57, The American Gas Association, Arlington, Va. (November 1983)
  14. J. Bowman, "The Assessment of the Strength of Electrofusion Joints," Proc. Twelfth Plastic Fuel Gas Pipe Symposium, p. 31 1, The American Gas Association, Arlington, Va. (September 1991).
  15. J. Bowman, "Fusion Joining of Cross-linked Polyethylene Pipe," Proc. Advances in Joining Plastics and Composites, TWI, Cambridge, England (June 1991)
  16. D. C. Harget, J. Skarelius, and F. Imgram "Crosslinked Polyethylene-Extending the Limits of Pressure Pipe System Performance," Proc. Plastics Pipes WZZ, Paper E1/5 The Plastics and Rubber Institute, London (September 1992)
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.